Management of Group A Streptococcal Sore Throat for the Prevention of Acute Rheumatic Fever 2011 © Ministry of Health 2011 Published by: New Zealand Guidelines Group (NZGG) PO Box 10 665, The Terrace, Wellington 6145, New Zealand ISBN (Electronic): 978-1-877509-60-5 Copyright The copyright owner of this publication is the Ministry of Health, which is part of the New Zealand Crown. Content may be reproduced in any number of copies and in any format or medium provided that a copyright acknowledgement to the New Zealand Ministry of Health is included and the content is neither changed, sold, nor used to promote or endorse any product or service, or used in any inappropriate or misleading context. For a full copyright statement, go to www.health.govt.nz/about-site/copyright. Funding and independence This work was funded by the Ministry of Health. The work was researched and written by NZGG employees or contractors. Appraisal of the evidence, formulation of recommendations and reporting are independent of the Ministry of Health. Statement of intent NZGG produces evidence-based best practice guidelines to help health care practitioners, policymakers and consumers make decisions about health care in specific clinical circumstances. The evidence is developed from systematic reviews of international literature and placed within the New Zealand context. While NZGG guidelines represent a statement of best practice based on the latest available evidence (at the time of publishing), they are not intended to replace the health practitioner’s judgment in each individual case. Citation: New Zealand Guidelines Group. Management of Group A Streptococcal Sore Throat. Wellington: New Zealand Guidelines Group; 2011. Copies of the evidence review are available online at www.nzgg.org.nz. Contents Acknowledgments .......................................................................................................... v About the evidence review ............................................................................................ v Purpose...................................................................................................................... v The need for a guidance .............................................................................................. v Scope of the evidence review....................................................................................... v Target audience .......................................................................................................... v Treaty of Waitangi ...................................................................................................... vi Key point development process................................................................................... vi Definitions.................................................................................................................. vi Summary .......................................................................................................................... 1 Key messages ............................................................................................................1 1 Introduction and context ...................................................................................... 2 GAS throat infection ....................................................................................................2 Acute rheumatic fever..................................................................................................2 GAS throat infection in New Zealand ............................................................................3 Acute rheumatic fever in New Zealand..........................................................................3 Ethnic disparities .........................................................................................................9 Signs and symptoms of GAS throat infection ............................................................... 13 2 Rapid Antigen Diagnostic Tests........................................................................ 15 Rapid Antigen Diagnostic Test in people with a current sore throat ............................... 15 Rapid Antigen Diagnostic Test in people with a res olved sore throat ............................. 40 Timing of testing........................................................................................................ 41 3 Antibiotic treatment ............................................................................................ 42 Antibiotic type ........................................................................................................... 42 Antibiotic dose .......................................................................................................... 51 Antibiotic duration...................................................................................................... 60 4 Asymptomatic GAS infection............................................................................. 70 4.1 Prevalence of GAS sore throat ............................................................................. 70 Relationship between prevalence of asymptomatic GAS throat infection and rheumatic fever................................................................................................ 72 5 Community swabbing ......................................................................................... 75 Rheumatic fever outbreaks ........................................................................................ 75 Swabbing asymptomatic community members and households in areas of outbreak .......................................................................................................... 77 Appendix 1: Methods.................................................................................................... 84 Cont ribut ors .............................................................................................................. 84 Research process ..................................................................................................... 85 Research questions ................................................................................................... 85 Reviewing the literat ure ............................................................................................. 87 E vidence appraisal .................................................................................................... 89 Appendix 2: Abbreviations and glossary................................................................... 92 Abbreviations ............................................................................................................ 92 Glossary ................................................................................................................... 94 References..................................................................................................................... 95 Acknowledgments NZGG would like to thank Dr Richard Milne and his co-authors for granting us permission to use their analysed data on incidence of acute rheumatic fever in New Zealand, and Dr Rajesh Khanna, DHB (Paed), MPH; Co-ordinator, National Child Health Research Centre, National Institute for Health and Family Welfare, Delhi, for reviewing the analysis of Rapid Antigen Diagnostic Tests. About the evidence review Purpose The purpose of this evidence review is to provide an evidence-based summary of current New Zealand and overseas evidence to inform best practice in the management of people with Streptococcal A infection of the throat (pharyngitis) especially with the aim of preventing one of the more serious sequalae: Acute rheumatic fever (ARF). The need for a guidance Acute rheumatic fever rates in New Zealand have failed to decrease since the 1980s and remain some of the highest reported in a developed country. 1, 2 In response to this ongoing problem, the Ministry of Health wished to understand whether there were specific strategies for managing Group A beta-hemolytic streptococcal throat infection (GAS) throat infections that could help to lower the rate of ARF and prevent chronic rheumatic heart disease. Scope of the evidence review The evidence review specifically addresses the diagnosis of people with suspected GAS throat infection using Rapid Antigen Diagnostic tests, and the management of people with confirmed GAS throat infection using antibiotics. The review also provides information on asymptomatic GAS throat infection and community swabbing. It should be noted that the management of GAS throat infection in people with confirmed ARF, acute or chronic rheumatic heart disease or in people with recurrent GAS throat infection is beyond the scope of this work and has been excluded. Target audience The evidence review and guidance is intended primarily for the providers of care for New Zealanders with GAS throat infection. Treaty of Waitangi The New Zealand Guidelines Group acknowledges the importance of the Treaty of Waitangi to New Zealand, and considers the Treaty principles of partnership, participation and protection as central to improving Māori health. NZGG’s commitment to improving Māori health outcomes means we work as an organisation to identify and address Māori health issues relevant to each piece of guidance. In addition, NZGG works to ensure Māori participation is a key part of the development process. It is important to differentiate between involving Māori in the guidance development process (the aim of which is to encourage participation and partnership), and specifically considering Māori health issues pertinent to the topic at all stages of the development process. While Māori participation in guidance development aims to ensure the consideration of Māori health issues by the expert advisory group, this is no guarantee of such an output; the entrenched barriers Māori may encounter when involved in the health care system (in this case guidance development) need to be addressed. NZGG attempts to challenge such barriers by specifically identifying points in the development process where Māori health must be considered and addressed. In addition, it is expected that Māori health is considered at all points in the guidance in a less explicit manner. Key point development process NZGG convened a multidisciplinary expert advisory group (EAG) comprising members nominated by a diverse range of stakeholder groups. The research questions developed by the Ministry of Health and NZGG were discussed with the EAG and were used to inform the search of the published evidence, from which systematic evidencedbased statements for best practice were derived. A one-day, face-to-face meeting of the full EAG was held, plus additional teleconferences, at which evidence was reviewed and key practice points were developed. Full methodological details are provided in Appendix 1. Definitions Several common terms are currently in use for Group A beta-haemolytic streptococcal pharyngitis. NZGG has elected to use the term ‘GAS throat infection’ throughout this document in an attempt to keep the document clear and easy to read. Summary Key messages Antibiotics should be initiated as soon as possible as there is no evidence to support current practice of delaying treatment by up to nine days and there is no evidence to support any other recommendation about the timing of treatment. Children at high risk of developing rheumatic fever should continue to receive empiric (immediate) antibiotic treatment and the presence of GAS should continue to be confirmed by laboratory culture. To establish asymptomatic carriage rate in the school population, where an intervention is planned, all consented children should be swabbed before and after the intervention, regardless of symptoms to allow evaluation of programme effectiveness. There is reliable evidence about the efficacy of rapid antigen diagnostic tests, which give a result much faster than swabbing and testing. Once daily amoxicillin is the first choice for antibiotic treatment for a GAS throat infection. Studies comparing amoxicillin with penicillin V report comparable outcomes. Amoxicillin is likely to achieve better compliance because of its daily dosing and ability to be taken with food compared with penicillin V’s more frequent dosing and the requirement to take it on an empty stomach. Management of Streptococcal A Sore Throat 1 1 Introduction and context GAS throat infection Streptococcal pharyngitis is caused by a Group A beta-haemolytic streptococcal infection and can trigger an inflammatory response in pharyngeal cells that causes many of the signs and symptoms of streptococcal pharyngitis. 3 Group A streptococcus (GAS) is a bacterium often found in the throat and on the skin and can be carried by people who have no symptoms of illness.4 It affects the pharynx including the tonsils and possibly the larynx. After an incubation period of 2 to 5 days 5, 6 there is an abrupt onset of illness with sore throat and fever.7 The tonsils and pharynx are inflamed and tonsillar exudate may be present.3 Throat pain is typically described as severe and is associated with difficulty in swallowing.3 Symptom severity varies and the presence of classically associated symptoms such as headache, malaise or gastrointestinal symptoms may be present in only 35% to 50% of patients.3 GAS sore throat is a communicable disease, spread through close contact with an infected individual. A definitive diagnosis is made based on the results of a throat culture. One of the more serious complications is acute rheumatic fever (ARF). Evidence indicates that antibiotic treatment for GAS throat infection in communities where the complication is common can reduce progression to ARF by more than twothirds.8 Acute rheumatic fever Acute rheumatic fever is an autoimmune response to infection with GAS bacteria. In New Zealand this response is primarily thought to be due to GAS throat infections. Though there has been discussion of the role of GAS skin infections in ARF (skin sepsis), convincing evidence has yet to be found to support this theory. 9 The ensuing generalised inflammatory response to the GAS infection occurs in certain organs; the heart, joints, central nervous system (ie, brain) and skin. Inflammation of the heart (carditis) can cause long-term damage to the heart valves requiring heart valve replacement surgery. The consequence of recurrent exposure to ARF is the development of rheumatic heart disease (RHD) which may include valvular disease and cardiac myopathy and sequlae such as heart failure, atrial fibrillation, systemic embolism, stroke, endocarditis and the requirement for cardiac surgery.10 In the 1990s RHD was responsible for 120 deaths per year in New Zealand. 1 Management of Streptococcal A Sore Throat 2 GAS throat infection in New Zealand While most sore throats are thought to be viral in origin, estimates of the numbers of sore throats due to GAS vary widely.3 Evidence on rates is slim. A review completed by the World Health Organization11 investigated the current evidence in relation to the burden of GAS infections on a worldwide scale and estimated that in children in developing countries (New Zealand was included in this group given the high rates of rheumatic fever in specific communities within New Zealand) the number of sore throats due to GAS could be as high as 40%.11 This estimate was based on the findings from three studies from populations where ARF is common: New Zealand (primarily in Māori and Pacific communities), Kuwait and Northern India. As the authors state, a positive GAS finding was not confirmed with serology and hence the true rate may be lower. New Zealand data is currently being collected in a school-based sore throat swabbing programme in Opotiki.12 Interim data shows that between October 2009 and December 2010, 8% of children reporting sore throats who were swabbed had a GAS infection (211 positive swabs of 2489 taken). Data collection is ongoing and analysis of trends would currently be premature. 12 This data supports those accepted estimates that between 3% and 36% of sore throats are due to a GAS infection.3 There is currently no national data collected by ESR (Environmental Science and Research) for GAS infections in New Zealand independent of the notification of rheumatic fever. Acute rheumatic fever in New Zealand Acute rheumatic fever is reported two ways in New Zealand. The most current data, available publically in rate form, is that reported by the ESR as part of its annual surveillance of notifiable diseases. ESR collects this data from the regional public health units. Local District Heath Boards (DHBs) and treating hospital clinicians are required to use a specific ARF reporting process to notify regional public health services of the ARF cases hospitalised within their region; this data is then reported to ESR by each region (who each have their own database to hold this data). This data may be reported from the DHBs to the regional public health units late and in bundles or not at all, given it requires a separate reporting process. The second source of ARF data in NZ comes from the National Minimum Dataset (NMDS). This is a centralised dataset, in which all hospital encounters are coded within the hospitals themselves and entered straight into the database, the direct report nature does mean the NMDS data is viewed as more reliable and valid. However, given the large numbers of data involved in the NMDS, rates for ARF are not calculated on an annual basis. Management of Streptococcal A Sore Throat 3 Case Numbers of acute rheumatic fever Acute rheumatic fever appears to have been virtually eradicated from most ‘developed’ countries yet rates in New Zealand have failed to decrease since the 1980s and remain some of the highest reported in a developed country.1, 2 The Ministry of Health’s ESR Annual Surveillance Report of notifiable disease has reported annually between 100 and 150 cases over the last decade (all ages).13 In 2010, 155 initial cases and 13 recurrent cases of rheumatic fever were notified (for all ages),14 while analysis of the hospital admissions and ICD discharge data provided in the NMDS indicated that from 1987 to 2008 there were between 150 and 230 cases per year (all ages).13 Hospitalisation data indicates that the primary episode of ARF usually occurs in children aged between 5 to 14 years (Figure 1.1) 1, 2 and a recent analysis of the NMDS hospitalisation data (using data up to 2009) reported 115 index cases of ARF in children aged 5 to14 years in 2009 (Table 1.1).15 In 2010, approximately 75% (117 cases) of initial attack ARF cases notified were in those aged less than 15 years, with the highest age-specific rate in the 10 to 14 years age group (25.4 per 100 000 population, 75 cases).14 Figure 1.1 Number of hospitalisations between 2004 and 2010 for acute rheumatic fever by age Source: National Minimum Data Set1, 2 Management of Streptococcal A Sore Throat 4 Table 1.1 Annual index cases by year and ethnicity for children 5 to 14 years of age 1993 2009 %change Ratio of 2009 to 1993 Cases Māori Pacific Islands European/Other 32 17 17 62 48 5 +98% +185% -168% Total 64 115 +79% 2.0 2.9 0.3 1.8 Source: Milne, R., D. Lennon, et al. (2010). Burden and cost of rheumatic fever and rheumatic heart disease in New Zealand: focus on school age children. A report to the Ministry of Health. Auckland, New Zealand, Health Outcomes Associates Limited. Rates of acute rheumatic fever It is reported that rates of ARF in New Zealand since 1980 have remained at about 15 cases per 100,000 children aged 5 to 15 years of age.13 An analysis of hospitalisation data between 2000 and 200915 found a mean incidence rate for New Zealand children (all ethnicities) of 17.2 per 100,000, and distinct inequalities in the rates between different ethnic groups (Table 1.2). Table 1.2 ARF incidence rates for New Zealand children 5 to 14 years of age (2000–2009) Māori Pacific NonMāori/Pacific Rate ratio * Total Mean 40.2 81.2 2.1 17.2 -95%CI 36.8 73.4 1.6 16.1 +95%CI 43.8 89.6 2.5 18.2 Māori 19.5 Pacific 39.3 15.5 24.5 31.3 49.8 CI = confidence interval * Compared to non-Mā ori/Pacific Source: Milne, R., D. Lennon, et al. (2010). Burden and cost of rheumatic fever and rheumatic heart disease in New Zealand: focus on school age children. A report to the Ministry of Health. Auckland, New Zealand, Health Outcomes Associates Limited. Of concern is that the inequality between ethnic groups has been widening over time. In the period studied (1993–2009) incidence rates increased by 79% and 73% for Māori and Pacific children respectively and declined by 71% for non-Māori/Pacific categories, with an overall increase of 59%15 (Figure 1.2). Māori and Pacific children 5 to 14 years of age accounted for 92% of new cases of ARF in the period 2000 to 2009 and comprised 30% of children in the 2006 census. 15 Management of Streptococcal A Sore Throat 5 Figure 1.2 Annual index cases and incidence rates for acute rheumatic fever in 1993–2009 for children 5 to 14 years of age Source: Milne, R., D. Lennon, et al. (2010). Burden and cost of rheumatic fever and rheumatic heart disease in New Zealand: focus on school age children. A report to the Ministry of Health. Auckland, New Zealand, Health Outcomes Associates Limited. Management of Streptococcal A Sore Throat 6 The notification rates from ESR since 2000 for all ages and ethnicities are displayed in Figure 1.3 for both initial and recurrent attacks.14 Figure 1.3 Rates of notified rheumatic fever per 100,000 from 2000 to 2010 Source: ESR, 2011 Acute rheumatic fever in New Zealand by region ESR reports rates for initial ARF attack by DHB, ethnic group, age and sex for the 2010 year. The highest rate of notified cases in 2010 was in Tairawhiti DHB (15.1 per 100,000 population, 7 cases), followed by Counties Manukau (10.6 per 100,000, 52 cases) and Northland (10.2 per 100,000, 16 cases) DHBs.14 However, given the small numbers, rates by DHB are more meaningful if examined over time. Analysis of the 2000 to 2009 hospitalisation data found that Counties Manukau DHB had the highest mean annual incidence rate for children (93.9 per 100,000) and contributed 298/700 cases (43%).15 Ninety-nine percent of index cases in Counties Manukau were in children of Māori or Pacific ethnicity. Table 1.3 displays incidence for the 2000 to 2009 years by DHB, ethnicity and decile. Management of Streptococcal A Sore Throat 7 Table 1.3 Index ARF cases and incidence rates for deciles 9 and 10 children aged 5 to 14 years, by District Health Board Index ARF cases in 2000-2009 NonMāori/ Māori Pacific Pacific Total DHBa Counties Manukau 111 Mean annual incidence per 100,000 NonMāori/ Māori Pacific Pacific Total 183 4 298 115.8 121.6 5.6 93.9 Northland 62 1 4 67 99.7 48.3 13.6 71.5 Capital and Coast 9 23 3 35 50.9 102.2 16.1 59.5 Auckland 13 49 5 67 58.3 86.8 12.1 55.7 Bay of Plenty 39 3 5 47 63.7 147.1 17.8 51.5 Tairawhiti 19 1 1 21 60.5 85.5 11.7 51.0 Hawke's Bay 27 7 3 37 60.9 107.5 12.2 49.0 Lakes 19 5 1 25 50.5 196.1 6.6 45.2 Waikato 43 3 4 50 60.4 36.6 7.3 37.2 10 2 0 12 43.2 51.7 0.0 22.7 20 14 7 41 18.8 29.6 3.9 12.4 372 291 37 700 64.9 96.0 7.5 51.0 332 278 28 638 75.1 104.1 8.7 61.9 95% 95% 81% 94% Na Na Na Na 81% 84% 64% 76% Na Na Na Na b Midcentral Remaining 11 c Total Top 10 DHBs % total cases e % population d CCDHB=Capital and Coast DHB; CMDHB=Counties Manukau DHB; DHB=District Health Board; Na=not applicable a Sorted by total incidence rate Waitemata patients were also hospitalised at Auckland hospital (ADHB) c Includes five North Island and all six South Island DHBs d Percentage of all index cases occurring in the top10 DHBs e Percentage of NZ population 5–14 years of age b Source: Milne, R., D. Lennon, et al. (2010). Burden and cost of rheumatic fever and rheumatic heart disease in New Zealand: focus on school age children. A report to the Ministry of Health. Auckland, New Zealand, Health Outcomes Associates Limited. International rates of acute rheumatic fever International comparisons for rates of ARF are problematic (due to global data quality issues) and estimates of the annual number of ARF cases must be considered a very crude estimate.11, 16 The World Health Organization estimates median incidence of 10 per 100,000 in established market economies; the data was not stratified by initial and recurrent attack.11 Recent data derived from Aboriginal communities in Australia indicates an incidence of 374 cases per 100,000,11 which is extremely high. Data on rates of ARF in Aboriginal communities is probably most usefully compared with data on the incidence in Māori and Pacific communities, rather than overall New Zealand incidence. A systematic review which focused only on prospective population-based studies of first incidence of ARF (all ages) computed a mean yearly incidence rate of ≤10 cases per 100,000 in the USA and Western Europe and less than 10 cases per 100,000 in Eastern Europe, Australia and the Middle East.18 The only study that met the inclusion Management of Streptococcal A Sore Throat 8 criteria for the Australasian area was a New Zealand study from 1984 authored by Talbot.17 This was assessed by the authors as being of high quality. In that study, overall incidence in New Zealand was reported as being 22 per 100,000 in a population of people aged less than 30 years. A subgroup analysis from the Talbot study showed an incidence of greater than 80 per 100,000 for Māori. Again the authors highlighted the paucity of high quality population-based prospective studies of ARF around the world. Mortality data related to ARF is also problematic.11 Reliable cause-specific mortality data relating to ARF and RHD are only available from indigenous populations living in relative poverty in wealthy countries (such as New Zealand). However, the New Zealand data cited is relatively old (1985–1987); age standardised mortality for RHD (with or without rheumatic fever) for non-Māori were reported at 2.0 per 100,000 per year, and 9.6 per 100,000 per year for Māori.11 Ethnic disparities As has been highlighted in earlier sections, Māori and Pacific children experience a disproportionally high rate of ARF in New Zealand and rates of disparity are widening1,15 (Figure 1.2). In the 10 years to 2005, the 5 to 14 year-olds rate for nonMāori and Other children was reported to be 3.0 per 100,000 (lower than the age standardised rate for all people of 3.4 per 100,000), while for Māori and Pacific children rates were 34.1 and 67.1 per 100,000 respectively.1 More recent analysis has found this disparity to have increased: for the period from 2000 to 2009, Māori children experienced an initial ARF rate of 40.2 per 100,000 (CI 36.8 to 43.8, p=.05), Pacific children 81.2 per 100,000 (CI 73.4 to 89.6, p=.05) and non-Māori children 2.1 per 100,000 (CI 1.6 to 2.5, p=.05) (Table 1.2). From 1996 to 2005, the New Zealand European and Others ARF rate decreased significantly while Māori and Pacific peoples’ rates increased. Compared with New Zealand European and Others, rate ratios were 10.0 for Māori and 20.7 for Pacific peoples.1 These disparities continued to increase after 2005. Incidence rates between 2000 and 2009 for children 5 to 14 years were about 20-fold higher for Māori children and 40-fold higher for Pacific children in this age group compared with nonMāori/Pacific categories.15 Rate ratios for Māori children were 19.5 and for Pacific children were 39.3, when compared with non-Māori children (Table 1.2). During 1993 and 2009 the ethnic disparity for Māori and Pacific children compared with nonMāori/Pacific children widened both in relative terms (the ratio of incidence rates) and in absolute terms (the difference in incidence rates) (Table 1.4). Management of Streptococcal A Sore Throat 9 Table 1.4 Changes in ethnic disparity over time for children 5 to 14 years of age during a the period 1993–2009 Incidence rate ratio b Incidence rate difference per c 100,000 per year 1993 2009 1993 2009 Māori 5.8 36.3 21.2 44.5 Pacific 11.7 72.0 47.0 89.7 a Based on linear regression of incidence rates on year Incidence rate of Māori or Pacific children divided by that for non-Māori/Pacific children c Difference in incidence rates between Māori or Pacific compared to non-Māori/Pacific b Source: Milne, R., D. Lennon, et al. (2010). Burden and cost of rheumatic fever and rheumatic heart disease in New Zealand: focus on school age children. A report to the Ministry of Health. Auckland, New Zealand, Health Outcomes Associates Limited. Deaths associated with chronic RHD have increased from an average of 123 deaths per annum between 1971 and 1980 to 186 reported deaths in 2006.13 For Māori this equates to a prevalence rate for mortality of 8.5/100,000 population (95%CI 7.0 to 10.3) and for non-Māori 1.4/100,000 population (95%CI 1.2 to 1.5). Rheumatic heart disease mortality was over six times greater in Māori than non-Māori (relative risk (RR) 6.27 [95%CI 4.95 to 7.94]).13 Māori experience of rheumatic fever prevention and management It is important to point out that the susceptibility of both Māori and Pacific children to rheumatic fever is most likely attributable to economic deprivation (and associated factors) experienced by Māori and Pacific people in New Zealand (ie, overcrowding, poor housing conditions, rural locations and decreased access to and utilisation of health care services)13. However, while a World Health Organization report into global burden of GAS-related disease states that ‘The burden of GAS diseases and the association of these diseases with poverty cannot be ignored’,11 the evidence to date has not been designed to reliably indicate which particular factors contribute to the high rates of rheumatic fever in New Zealand. NZGG could not locate any specific data that explored Māori or Pacific people’s experiences of, or access to, care for rheumatic fever. However, given that the majority of sore throats are managed in primary care settings, research relating to Māori experiences of primary care and general practice is relevant.19 In a qualitative investigation into Māori experience of health care in New Zealand, themes to emerge from hui with 86 Māori regarding general practice care is encapsulated in the following statement: Participants’ experiences of general practice were, in the main, related to how they had been treated by health staff, and their hesitancy about seeking treatment. This hesitancy, or ‘wait and see’ attitude, described by many participants was associated with their financial concerns and their values and beliefs, as well as with their knowledge of how general practice staff were likely to treat them based on their previous experiences (Jansen et al). 19 Management of Streptococcal A Sore Throat 10 Further surveying of a larger group of Māori (n=651), the majority of whom had either school- or pre-school aged children (54.2%), revealed, in general, a satisfaction with health services. However, clustering of the survey results found that that those in the younger age bracket (aged 39 years or less) reported a greater reluctance to use health and disability services, and a greater dissatisfaction with the interactions they had with these services. Of particular concern in relation to the management of sore throats in primary care is that a significantly-higher proportion of the younger respondents agreed that: they had to be quite sick and usually waited until the last minute before going to the doctor it was too expensive to go every time they were sick the doctor was not good value for money they do not like taking drugs for their illnesses. Further reporting on the same study, but comparing Māori and non-Māori experiences of access to primary care,20 found differences in reported access to general practice care. For example, there were significant differences between Māori and non-Māori participants in terms of being: seen in the timeframe needed (93% of Māori 96.5% of non-Māori); given a suitable time (93.8% of Māori 98.3% of non-Māori); given a choice of times (68.3% of Māori 77.8% of non-Māori); and being seen on time (64.2% of Māori 75.1% of non-Māori). The authors state that there may be a number of issues that explain the discrepancies, including non-medical staff attitudes to Māori patients, Māori cultural beliefs (including the tendency to noho whakaiti – to not cause a ruckus), and self-selection bias into the study. However, in relation to treatment of sore throat, timely access to a medical practitioner when required is very important. Once a sore throat is recognised as a serious issue by individuals and whānau living in high risk communities, a responsive primary care service upon presentation is no doubt critical to both treatment success and further developing those individual’s and community’s confidence in an equitable and responsive healthcare system.20 In terms of use of and access to treatments specifically relevant to the prevention of rheumatic fever, a study of antibiotic use in Te Tairawhiti between 2005 and 2006, revealed that Māori are dispensed fewer antibiotics than non-Māori, and the differences increase for Māori living in rural areas. Forty-eight percent of Māori people and 55% of non-Māori received one or more antibiotic prescriptions during the study period. Both Māori and non-Māori living in rural areas received fewer prescriptions for antibiotics, but the difference was much larger for Māori than for non-Māori. There was very low prevalence for antibiotic prescriptions for rural Māori children (aged <6 years) (43%) compared with that for rural non- Māori (68%) or urban dwellers (80% and 85% for Māori and non- Māori, respectively). Unfortunately no statistical analysis was completed to determine if the differences were significant. However, given that in the Tairawhiti DHB area rates of rheumatic fever in 2010 were the highest in the country at 15.1 per 100 000 population, the report highlights a serious issue that warrants further exploration and certainly consideration in the context of the prevention of ARF in young Māori.21 Management of Streptococcal A Sore Throat 11 Messages from research with Māori are clear; their experiences with primary healthcare services could be improved. For the New Zealand health systems and individual practitioners within that system it is important to consider how such experiences may impact upon the effective management of sore throats and the prevention of ARF. Indigenous populations’ experience of rheumatic fever care Given the lack of data identified specific to Māori experiences of ARF prevention and management, research with indigenous Aboriginal Australians may be useful to consider in the context of sore throat management approaches with both Māori and Pacific people, until more specific research is conducted. Qualitative research on patient’s experiences of rheumatic fever programmes in Aboriginal communities in the Northern Territories provides useful insight for the implementation of rheumatic fever prevention programmes. In a study of Aboriginal people in the Kimberly region of Australia with a diagnosis of rheumatic fever or rheumatic heart disease there was a varied understanding of either disease or its management. The findings highlighted the need for culturally-appropriate access to information about the disease, and the importance of the relationship between patient and healthcare workers – compliance with medication was closely linked with positive patient-staff interactions.22 Although the study was mainly about secondary prophylaxis, the findings may equally apply in the prevention of rheumatic fever and GAS throat infection prevention. A second qualitative study exploring the experiences of 15 patients with RHD or a history of rheumatic fever, 18 relatives and 18 health care workers in a remote Aboriginal community, found a mix of staff and patient factors influence the success of the programme in terms of compliance to a secondary prophylaxis regime. 23 Staffing factors that influence compliance included: appropriately trained, socially and culturally competent staff, staff willingness to treat patients at home, and an active recall system. Individual and family factors that encouraged uptake of regimes were an enhanced belief that the disease is chronic and serious, confidence in the health service and a feeling of holistic care, and family support for the treatment and belief in the efficacy of the treatment. The same study found that staff factors that inhibited uptake included: negative perception of the secondary prophylaxis programme, conflicting priorities for staff, no effective strategy for dealing with absent patients, staff fatigue and frustration.23 Individual and family factors inhibiting uptake included: conscientious refusal of treatment, inconvenience to the patient, not ‘belonging’ to the health service, lack of family support and lack of confidence in the treatment. Management of Streptococcal A Sore Throat 12 Specific issues relating to primary care workforce requirements that have been noted during rheumatic fever work with aboriginal communities in Australia may also apply to New Zealand.24 Examples include: a lack of trained health professionals willing to stay for extended periods of time in remote communities to provide co-ordinated care, and a high turnover of nursing staff (in remote communities). There is also a scarcity of appropriately-trained Aboriginal health workers (these people are often considered the key players of the primary health service in remote settings), who are often pulled in many directions at the community level. This leads to a high burden of work and responsibility, with associated high rates of burnout.24 Signs and symptoms of GAS throat infection Signs and symptoms of GAS throat Infection Sore throat is one of the common signs and symptoms of streptococcal pharyngitis. 6 Four guidelines were identified that summarised data on signs and symptoms of GAS throat infection;25-28 all agree that the cardinal symptoms suggestive of streptococcal pharyngitis include: history of fever tender anterior cervical adenopathy exudative tonsillitis lack of cough. A systematic review found that the most useful findings for evaluating the likelihood of streptococcal pharyngitis are the presence of tonsillar exudate, pharyngeal exudate, or exposure to streptococcal pharyngitis in the previous two weeks (positive likelihood ratios, 3.4, 2.1, and 1.9 respectively) and the absence of tender anterior cervical nodes, tonsillar enlargement or exudate (negative likelihood ratios, 0.60, 0.63, and 0.74, respectively).3 GAS throat infection: timing, length The Ministry of Health asked the research question below in an attempt to gain a better understanding of the window of opportunity for throat swabbing in people with suspected GAS throat infection. NZGG undertook a literature review to answer the question. Research question: When do sore throats occur in the natural course of streptococcal pharyngitis and how long they tend to last? Management of Streptococcal A Sore Throat 13 Body of evidence Two guidelines from the United States agree that patients are more likely to present with GAS throat infection in the colder months of winter and spring.25, 26 The New Zealand Heart Foundation guideline found that evidence was sparse in relation to other climatic conditions and cite no clear seasonal peak in Auckland over a four-year period. The natural history is for symptoms to subside within 3 to 5 days unless suppurative complications intervene.7, 25 Children are most infectious during the acute phase of the illness;5, 7 however, they may remain infectious for more than two weeks. 5 Transmission is by inhalation of large droplets or direct contact with respiratory secretions. Summary of findings No evidence was found to suggest seasonal variation in GAS throat infection in New Zealand. Evidence from narrative reviews reported the incubation period to be 2 to 5 days and for symptoms to subside within 3 to 5 days from onset. Narrative reviews also report that children are most infectious during the acute phase of the illness. However, they may remain infectious for more than two weeks. Management of Streptococcal A Sore Throat 14 2 Rapid Antigen Diagnostic Tests This chapter addresses diagnostic testing for people with suspected Streptococcal A infection of the throat, specifically, the accuracy of the Rapid Antigen Diagnostic Test (RADT). The chapter includes the following topics: the accuracy of the RADT in people with a current sore throat the accuracy of the RADT in people with a resolved sore throat timing of testing. Rapid Antigen Diagnostic Test in people with a current sore throat Research question: In children and adults with sore throats, what is the accuracy of the Rapid Antigen Diagnostic (RAD) testing compared to culture to confirm GAS? We did not identify any existing English language systematic reviews investigating RADT for GAS throat infection. We undertook a systematic review and outline the specific methodology here, as it differs to the other sections in this report. Methodology for the remaining chapters can be found in Appendix 1. Methods Selection of studies for inclusion Study design This review included diagnostic accuracy studies of which there are two basic types, defined by the Centre for Reviews and Dissemination; single-gate design and two-gate design. Full details of the designs of these studies is reported elsewhere.29 Single- and two-gate studies were eligible for inclusion if they compared a RADT/s with culture in a primary or secondary care setting. Studies were included only if they provided sufficient data to construct a 2x2 contingency table which displays numbers of true positive cases, false positive cases, false negative cases, and true negative cases. Participants Studies in adults and children who presented to a healthcare facility (primary or secondary care setting) with symptoms suggestive of streptococcal A throat infection were eligible for inclusion. Studies in animals and studies with fewer than 10 participants were excluded. Studies where RADTs were done to assess outcomes or disease progression after treatment was started were also excluded. Management of Streptococcal A Sore Throat 15 Index test Rapid antigen tests for diagnosing Streptococcal A pharyngitis were the index tests considered in this review. Any rapid antigen test was considered, including: optical immunoassay immunochromatographic detection double sandwich immunoassay latex particle agglutination Polymerase chain reaction (PCR) assays. Reference standard Culture for diagnosing Streptococcal A pharyngitis was the reference standard considered in this review. Studies carrying out throat swab culture carried out on blood agar at the same time as the index RAD test (or with minimal gap) were eligible for inclusion. Data extraction and management For each included study, we used standard evidence tables to extract characteristics of participants, data about the index tests and reference standard, and aspects of study methods. We extracted indices of diagnostic performance from data presented in each primary study by constructing 2x2 contingency tables of true positive cases, false positive cases, false negative cases, and true negative cases. If these were not reported, we reconstructed the contingency table using the available information on relevant parameters (sensitivity, specificity or predictive values). In cases of studies where only a subgroup of participants met the review inclusion criteria, data was extracted and presented only for that particular subgroup. There were some studies where patients had undergone two different index tests with throat swab culture as the reference standard. In such studies, pooled analysis was done utilising data from the more common type of index test so as to avoid double counting. Assessing study quality Study quality was assessed using the QUADAS checklist,30 with each item scored as a yes/no response, or noted as unclear if insufficient information was reported to allow a judgment to be made; the reasons for the judgment made were documented. Results of the quality assessment are presented in the text, and in graphs using the Cochrane Collaboration’s Review Manager 5 software.31 A summary score estimating the overall quality of an article was not calculated since the interpretation of such summary scores is problematic and potentially misleading.32, 33 Data analysis and synthesis Sensitivity, specificity, positive and negative predictive values, and likelihood ratios (with 95% confidence intervals) were calculated for each test using the methods described by the Centre for Reviews and Dissemination and are presented in tables. Efforts were made to identify common threshold points for each test so as to enable Management of Streptococcal A Sore Throat 16 calculation of pooled estimates of sensitivity and specificity. Coupled forest plots and summary receiver operator curves (sROCs) were generated (with 95% confidence intervals), giving graphical representations of sensitivity and specificity of a test in each study and allowing for assessment of diagnostic threshold and the area under the curve (AUC). Significant heterogeneity was considered where I2 was greater than 50%. Threshold effect was assessed by visual inspection of the sROC curve and by computing Spearmans correlation coefficient between the logit of sensitivity and logit of 1-specificity. In order to explore heterogeneity, we carried out predefined subgroup analysis for adults and children, and also for the different groups of rapid antigen tests identified in the literature. Where >10 studies were included in any pooled group, regression analyses were undertaken to investigate potential sources of observed heterogeneity. Additionally, we conducted sensitivity analysis excluding two-gate studies. All analyses were conducted using MetaDiSc software.34 Interpreting the results Diagnostic threshold Threshold effects are common in diagnostic studies and occur when the included studies use different thresholds (explicitly or implicitly) to define positive and negative test results; this can be the reason for detectable differences in sensitivity and specificity (heterogeneity). RAD tests utilise specific antibodies to detect the disease causing organisms and their results come as positive or negative only. However, threshold variability is expected since the results are based on visual inspection rather than a standardised measurement. In this analysis, threshold effects have been investigated in two ways: a) by visual inspection of the relationship between pairs of accuracy estimates in ROC curves. If threshold effect is present, the ROC curve will show increasing sensitivities with decreasing specificities, or vice versa, and is often described as a ‘shoulder-arm’ pattern or a ‘smooth curve’ b) by statistical computation of Spearmans correlation where a strong positive correlation suggests a threshold effect. Summary measures In a ROC curve the true positive rate (sensitivity) is plotted in function of the false positive rate (100-specificity) for different cut-off points of a parameter. Each point on the ROC curve represents a sensitivity/specificity pair corresponding to a particular study. The area under the ROC curve is a measure of how well a parameter can distinguish between two diagnostic groups (diseased/normal). The value for the area under the ROC curve can be interpreted as follows: an area of 0.84, for example, means that a randomly-selected individual from the positive group has a test value larger than that for a randomly-selected individual from the negative group in 84% of the time. When the variable under study cannot distinguish between the two groups, that is, where there is no difference between the two distributions, the area will be equal to 0.5 (the ROC curve will coincide with the diagonal). Management of Streptococcal A Sore Throat 17 When there is a perfect separation of the values of the two groups, ie, there no overlapping of the distributions, the area under the ROC curve equals 1 (the ROC curve will reach the upper left corner of the graph). The area under the curve was interpreted using the following: 0.9 – 1 = excellent 0.8 – 0.9 = good 0.7 – 0.8 = fair 0.6 – 0.7 = poor 0.5 – 0.6 = very poor.35 Meta-regression If substantial heterogeneity was identified, the reasons for variability were explored by meta-regression using the Littenberg and Moses Linear model36 weighted by the inverse of the variance where there were more than 10 studies in any pooled group. Estimations of coefficients of the model were performed by least squares method. The outputs from meta-regression modelling are the coefficients of the model, as well as the relative diagnostic odds ratio (rdOR) with respective confidence intervals. If a particular study level co-variate is significantly associated with diagnostic accuracy, then its coefficient will have a low p-value and the rdOR will give a measure of magnitude of the association.34 Body of evidence Thirty-one studies were identified investigating the use of RAD tests in people with suspected GAS throat infection and are presented in Table 2.1. Studies were conducted in several countries across the world – 10 studies in the USA, four in Canada, four in Western Europe (Sweden, Switzerland, Spain and Norway) three each in the UAE, Brazil and Turkey, three in Asia (Philippines, Hong Kong and Korea), one in Southern Europe (Cyprus) and one multicentre study spanning Brazil, Croatia, Latvia and Egypt (see Table 2.1). Except for a single two-gate study (diagnostic case control), all other studies were single-gate in design. The sample size in the studies ranged from 50 to 2472 patients (mean 587). Of the 31 included studies, 19 studies reported data in children, nine reported data in adults, four studies reported data in both children and adults (three reported as a single data set, one reported as two separate data sets), and in one study age was unclear. Management of Streptococcal A Sore Throat 18 15 commercial brands employing four main types of RAD tests were identified in the included studies. These were: nine brands employing chromatographic immunoassay tests: (QuickVue In-Line Strep A [Quidel Corporation]; Acceava Strep A [Inverness Medical Professional Diagnostics, Princeton, NJ, USA]; Genzyme OSOM Strep A [Genzyme Diagnostics, Street, San Diego, CA]; Abbott TestPack Plus Strep A [Abbott Laboratories]; Beckton-Dickinson Link 2 Strep A Rapid Test; Accustrip [Jant Pharmacutical Corportation, USA]; SD Bioline Strep A RAT [SD, Korea]; Detector strep A direct [Immunostics] and the Step A Rapid Test Device [SARTD] [Nova Century Scientific Inc.]) three brands employing sandwich immunoassays Tests: (Diaquick [DIALAB, Austria]; Kodak SureCell Strep A test [Kodak, USA]; INTEX Strep A Test II [INTEX Diagnostic Pharmazeutische Produkte, AG]) single brand employing optical immunoassay: (Strep A OIA MAX [Thermo Biostar/Inverness Medical Professional Diagnostics, Princeton, NJ, USA]) two brands using latex particle agglutination tests: (PathoDx Strep A kit [Inter Medico]; Reveal color step A test [Murex]). We did not identify any studies investigating immune-PCR assays. Twenty-six of the included studies investigated a single index test compared to culture; five studies used two or more index tests of which only one (the most common) was included in the pooled results to avoid double counting. Fourteen of the included studies used sheep blood agar as the reference standard, four used horse blood agar, one used goat blood agar, ten used blood agar but did not specify type and two studies did not report the culture medium. Management of Streptococcal A Sore Throat 19 Summary of findings Table 2.1: Characteristics of included studies Reference (study design) Rogo et al Single-gate37 Gurol et al Single-gate38 Sarikaya et al Single-gate39 Country USA Turkey Prevalence Participants Age Reference standard Type of RAD test Sens Spec PPV NPV LR+ LR- n=228 90% w ere children Culture (5% sheep blood agar) Acceava 98.4% 98.8% 96.9% 99.4% 81 (95%CI 20, 320)* 0.02 (0.00, 0.11)* OSOM 98.5% 99.4% 98.5% 99.4% 160 (95%CI 23, 1126)* 0.02 (95%CI 0.00, 0.11)* 28.9% QuickVue 92.3% 96.3% 90.9% 96.9% 25 (95%CI 11, 55)* 0.08 (0.03, 0.19)* 28.5% QuickVue 64.6% 96.8% 81.0% 92.8% 81 (95%CI 20, 320)* 0.02 (0.00, 0.11)* 0 to 9 years 70% 97.8% 90.3% 91.8% 32 (95%CI 10, 100)* 0.31 (0.19, 0.49)* 22.5% 20+ years 59.4% 96.1% 70.4% 93.8% 15 (95%CI 7.31, 32)* 0.42 (0.28, 0.64)* 13.4% n=453 All age groups Culture (5% sheep blood agar) 28.1% n=100 Adults aged 18 to 64 Culture (5% sheep blood agar) QuickVue 68.2% 89.7% 65.2% 90.9% 6.65 (95%CI 3.25, 14) 0.02 (0.19, 0.66) Brazil Croatia Egypt Latvia n=2472 Children 2 to 12 years Culture (5% sheep blood agar) OIA MAX 79% 92% 80% 92% 10 (95%CI 8.67, 12) 0.23 (0.20, 0.26) Kim Single-gate41 Korea n=293 Children (age not specified) Culture (no detail) SD Bioline Strep A 95.9% 91.8% 95.9% 91.8% 11.75 (95%CI 6.04, 22.84) 0.04 (95%CI 0.02, 0.09) Llor et al Single-gate42 Spain n=222 Adults over 14 years Culture (5% blood agar) OSOM 94.5% 91.6% 78.8% 98.1% 11.28 (95%CI 6.8, 18.69) 0.06 (95%CI 0.02, 0.18) Rimoin et al Single-gate40 Turkey 28.1% 28.7% Management of Streptococcal A Sore Throat 20 66.5% 24.7% Reference (study design) Country Participants Age Reference standard Prevalence Tanz et al Single-gate43 USA n= 1848 Children 3 to 18 years Culture (5% sheep blood agar) QuickVue Al-Najjar and Uduman Single-gate44 UAE n=425 Children (80% under 5) Culture Camardan et al Single-gate45 Turkey n=1248 Children Overall Culture (7% sheep blood agar) Type of RAD test Sens Spec PPV NPV LR+ LR- 71% 97% 91.65% 88.85% 26 (95%CI 19, 36) 0.29 (95%CI 0.26, 0.34) Diaquick 96% 99% 96% 99% 136 (95%CI 44, 419) 0.04 (0.01, 0.13) INTEX Strep A Test II 89.7% 97.2% 95.1% 93.88% 32 (95%CI 21, 49) 0.11 (95%CI 0.08, 0.14) 0 to 6years 89.7% 96.9% 90.8% 96.54% 29 (95%CI 18, 48) 7 to 12 years 90% 97.5% 97.67% 89.27% 36 (95%CI 16, 80) 13+ years 87.1% 97.7% 96.43% 91.49% 38 (95%CI 5.5, 261) 29.9% 14.3% 0.11 (95%CI 0.07, 0.17) 0.10 (95%CI 0.07, 0.15) 0.13 (95%CI 0.05, 0.33) 25.2% 32.4% Maltezou et al Single-gate46 Cyprus n=451 Children 2 to 14 years Culture (5% blood agar) Beckton-Dickinson Link 2 Strep A Rapid Test 83.1% 93.3% 82.4% 93.6% 12 (7.82, 18) 0.18 (0.13, 0.26) Fontes et al Single-gate47 Brazil n=229 Children 1 to 18 years Culture (5% lamb blood agar) Latex particle agglutination 90.7 89.1 72.1 96.9 8.36 (5.42, 13) 0.10 (0.04, 0.24) Wright et al Single-gate48 USA n=350 Children 0 to 18 years Culture (blood agar) 85.5% 97% 91% 95% 31 (95%CI 15, 65) 0.15 (95%CI 0.09, 0.25) 79.5% 95% 84.6% 93% 17 (95%CI 9.62, 30) 0.21 (95%CI 0.14, 0.33) OSOM QuickVue 38.1% 53.9% 41.3% 23.6% Management of Streptococcal A Sore Throat 21 24.6% 24.6% Reference (study design) Abu Sabbah and Ghazi Single-gate49 Prevalence Country Participants Age Reference standard Type of RAD test Sens Saudi Arabia n=355 Adults and children Culture (horse blood agar) Detector Strep A Direct 88% Children aged 4 to 14 Adults aged >15 Araujo Filho et al Single-gate50 Forw ard et al Single-gate51 Brazil Canada n=81 Adults over 18 years Culture (5% goat blood agar) Culture (5% sheep blood agar) n=818 overall OIA MAX Step A Rapid Test Device (SARTD) n=328 adults n=490 children Humair et al Single-gate52 Shaheen and Hamdan Single-gate53 PPV NPV LR+ LR- 91% 70% 97% 10 (95%CI 6.90, 15) 0.13 (95%CI 0.07, 0.25) 81% 86% 67% 93% 5.93 (95%CI 3.33, 11) 93% 93% 73% 98% 14 (95%CI 8.22, 23) 93.9% 68.7% 67.4% 94.2% 3.01 (1.96, 4.61) 0.09 (0.02, 0.34) 18.9% 25.2% 16.1% 40.7% 19.6% 71.9% 94.3% 76.9% 92.7% 11 (95%CI 7.92, 14) 67.8% 93.8% 77.7% 90.2% 11 (95%CI 7.24, 17) 0.34 (95%CI 0.26, 0.45) 81.1% 94.9% 75.4% 96.3% 16 (95%CI 9.41, 27) 0.20 (95%CI 0.11, 0.35) 24.1% 16.2% 37.6% n=372 Patients age >15 years Culture (blood agar) Amman n=200 Adults 20 to 42 years (mean 28.3 years) Culture (blood agar) Latex particle agglutination 90.00% 98.22% USA n=150 Adults over 18 years Culture Acceava 92.1% 100% Sw itzerland 0.21 (95%CI 0.10, 0.48) 0.08 (95%CI 0.03, 0.24) 0.25 (95%CI 0.19, 0.33) Testpack Plus Strep A w /OBC[On Board Controls] II (Abbott Laboratories) Atlas et al Single-gate54 Children w ere <16 years Spec 91.4% 95.3% 92.1% 0.09 (95%CI 0.05, 0.16) 94.9% 19.3 (95%CI 11, 34) 90.00% 98.22% 50.70 (95%CI 16.41, 156.61) 0.10 (0.03, 0.30) 100% 98% Not estimable 0.08 (95%CI 0.03, 0.24) 15.1% Management of Streptococcal A Sore Throat 22 18.4% Reference (study design) Country Participants Age Reference standard Type of RAD test Ezike et al Single-gate55 USA n=363 Children 5 to 18 years Culture (5% sheep blood agar) OIA MAX Culture (Columbia agar w ith horse blood) TestPack Plus 96% 86% 79.7% Culture (5% blood agar) TestPack 73% 94% 85% Lindbaek et al Single-gate56 Norw ay n=306 Adults and children (<10 years) Santos et al Single-gate57 Brazil n=50 Children age 1 to 12 years Nerbrand et al Single-gate58 Sw eden Culture (6% defibrinised horse blood) n=536 All ages n=615 All ages Culture (6% defibrinised horse blood) Chapin et al Single-gate59 USA n=520 Children (age not specified) Culture (5% sheep blood agar). Gieseker et al Single-gate60 USA n=302 Children (age not specified) Culture Prevalence Canada n=126 All ages Culture (5% sheep blood agar) 94.7% Spec PPV NPV LR+ LR- 100% 100% 96.2% Not estimable 0.05 (95%CI 0.020.14)* 97.7% 7.0 (95%CI 4.92,9.95) 0.04 (95%CI 0.02,0.11) 88% 12 (95%CI 3.14, 14.49) 0.28 (95%CI 0.12, 0.66) 0.30 (95%CI 0.21, 0.43) 42.4% 36% 73.9% 86.8% 59.4% 92.7% 5.60 (95%CI 4.28, 7.32) TestPack 82.8% 96.1% 92.7% 94.2% 21 (95%CI 14, 33) 0.18 (95%CI 1.02, 0.26) Thermo Biostar OIA 86.1% 97.1% 93.7% 93.4% 28 (95%CI 15, 52) 0.13 (95%CI 0.09, 0.18) 97% 92% 82% 98% 12 (95%CI 7.4, 18) 0.04 (95%CI 0.01, 0.11) 79% 95% 84% 92% 15 (95%CI 8.29, 25) 0.252 (95%CI 0.14, 0.34) 75% 99% 96% 92% 71(95%CI 9.93, 500) 0.25 (95%CI 0.14, 0.46) OSOM Testpack 34% 15.3% QuickVue OIA Max Rosenberg et al Single-gate61 Sens Management of Streptococcal A Sore Throat 23 21.1% 37.9% 28.8% 27.2% 25.4% Reference (study design) Country Participants Age Reference standard Type of RAD test Sens Spec PPV NPV LR+ LR- Keahey et al Single-gate62 Canada n=165 Children age 5 to 16 years Culture (Sheep blood agar) PathoDx Strep A Kit 86.7% 80.1% 78.3% 87.8% 4.33 (95%CI 2.84, 6.61) 0.17 (95%CI 0.09, 0.30) Gieseker et al Single-gate63 USA n=887 Children (age not specified) Culture (no details) OSOM 87.6% 96.2% 87.6% 96.2% 22.81 (95%CI 15.60, 33.37) 0.13 (95%CI 0.09, 0.18) Sheeler et al Tw o-gate64 USA n=211 cases All ages Testpack Plus 91% 96% 96% 90% 9.92 (95%CI 5.5, 18) 0.04 (95%CI 0.02, 0.11) n=232 controls All ages Testpack Plus 70% 98% 92% 90% 8.88 (95%CI 5.75, 14) 0.09 (95%CI 0.04, 0.24) Accustrip 52.6% 98.2% 52.6% 98.2% 28.9 (95%CI 13, 63) 0.48 (95%CI 0.30, 0.78) 80% 92.7% 83.1% 91.1% 10.89 (6.38, 18.59) 0.22 (95%CI 0.14, 0.34) Overall 94.12% 89.45% 60.38% 98.89% 8.92 (95%CI 5.90, 13) 0.07 (95%CI 0.02, 0.25) Testpack Plus 93.3% 94.7% 73.7% 98.9% 18 (95%CI 7.4, 42) Kodak SureCell 94.7% 84.8% 52.9% 98.9% 6.22 (95%CI 3.91, 9.88) Culture (5% sheep blood agar) Culture (5% sheep blood agar) Wong and Chung Single-gate65 Hong Kong n=1491 All ages Culture (5% horse blood agar) Kurtz et al Single-gate66 USA n=537 Children age 4 to 15 years Culture (5% standard) Alesna et al Single-gate67 Philippines n=233 All ages >3 years Culture (5% sheep blood agar) Prevalence Testpac Plus 0.07 (95%CI 0.01, 0.47) 0.06 (95%CI 0.01, 0.42) Sens = sensitivity; Spec = specificity; PPV = positive predictive value; NPV = negative predictive value; LR+ = positive likelihood ratio; LR- = negative likelihood ratio Management of Streptococcal A Sore Throat 24 45.5% 23.7% 50.2% 20.7% 37% 31.1% 14.6% 13.8% 15.3% Quality of included studies The overall methodological quality is summarised in Figures 2.1 and 2.2. Most studies reported representative spectrums of patients and explained selection criteria. Two studies did not recruit a representative spectrum of patients:55, 61 both studies used a convenience sample based on the availability of the lead investigator. Two studies did not clearly describe selection criteria.4.9, 53 Almost all the included studies reported avoidance of partial verification and differential verification, and all reported avoidance of incorporation bias. Only one study did not adequately describe the details or execution of the RAD test or culture.44 Blinding was not well reported, approximately 75% of studies reported blinding of the index test, but less than half of the included studies reported blinding of the reference standard. In one study it was unclear whether the same clinical information would be available in practice.64 Withdrawals were not explained in three studies: in one study67 233/269 patients who completed both RAD test and culture were reported with no reason for withdrawals given, in another study54 two patients did not receive culture and in the third study45 it was not clear how many participants were included. Overall, the studies included were of high quality. Management of Streptococcal A Sore Throat 25 Figure 2.1 Methodological quality of individual studies Management of Streptococcal A Sore Throat 26 Figure 2.2 Summary of methodological quality Overall results The forest plots of sensitivities and specificities from all 31 studies are shown in Figure 2.3. Sensitivities of all tests ranged from 53% to 96%, specificities from 69% to 100%. Of the 31 included studies, 26 reported specificities greater than 90%. Eight of the 31 studies reported sensitivities greater than 80%. The pooled average sensitivity and specificity were 84.5% (95%CI 83.4 to 85.6) and 94.7% (95%CI 94.2 to 95.1), respectively, but significant heterogeneity was noted between studies with I2 tests of 89.1% and 89.8%, respectively. Figure 2.4 shows the spread of studies on a ROC plane. Management of Streptococcal A Sore Throat 27 Figure 2.3 Forest plot of overall study results (sensitivity and specificity) Study TP FP FN Abu Sabbah 2006 59 25 8 263 0.88 [0.78, 0.95] 0.91 [0.87, 0.94] Al Najjar 2008 68 3 3 422 0.96 [0.88, 0.99] 0.99 [0.98, 1.00] Alesna 2000 14 5 1 89 0.93 [0.68, 1.00] 0.95 [0.88, 0.98] Araujo Filho 2006 31 15 2 33 0.94 [0.80, 0.99] 0.69 [0.54, 0.81] Atlas 2005 38 0 3 112 0.93 [0.80, 0.98] 1.00 [0.97, 1.00] Camurdan 2008 427 22 49 751 0.90 [0.87, 0.92] 0.97 [0.96, 0.98] Chapin 2002 173 10 24 313 0.88 [0.82, 0.92] 0.97 [0.94, 0.99] Ezike 2005 71 0 4 102 0.95 [0.87, 0.99] 1.00 [0.96, 1.00] Fontes 2007 49 19 5 156 0.91 [0.80, 0.97] 0.89 [0.84, 0.93] 123 48 37 610 0.77 [0.70, 0.83] 0.93 [0.90, 0.95] Gieseker 2002 84 18 3 197 0.97 [0.90, 0.99] 0.92 [0.87, 0.95] Gieseker 2003 184 26 26 651 0.88 [0.82, 0.92] 0.96 [0.94, 0.97] 51 12 28 362 0.65 [0.53, 0.75] 0.97 [0.94, 0.98] Humair 2006 128 11 12 221 0.91 [0.86, 0.95] 0.95 [0.92, 0.98] Keahey 2002 65 18 10 72 0.87 [0.77, 0.93] 0.80 [0.70, 0.88] 187 8 8 90 0.96 [0.92, 0.98] 0.92 [0.85, 0.96] 64 13 16 164 0.80 [0.70, 0.88] 0.93 [0.88, 0.96] 106 27 4 169 0.96 [0.91, 0.99] 0.86 [0.81, 0.91] 52 14 3 153 0.95 [0.85, 0.99] 0.92 [0.86, 0.95] Maltezou 2008 121 21 25 284 0.83 [0.76, 0.89] 0.93 [0.90, 0.96] Nerbrand 2002 107 19 22 466 0.83 [0.75, 0.89] 0.96 [0.94, 0.98] Rimoin 2010 561 136 Forward 2006 Gurol 2010 Kim 2009 Kurtz 2000 Lindbaek 2004 Llor 2009 TN Sensitivity Specificity Sensitivity Specificity 0 0.2 0.4 0.6 0.8 1 0 0.2 0.4 0.6 0.8 1 149 1626 0.79 [0.76, 0.82] 0.92 [0.91, 0.93] Rogo 2011 65 1 1 161 0.98 [0.92, 1.00] 0.99 [0.97, 1.00] Rosenberg 2002 24 1 8 93 0.75 [0.57, 0.89] 0.99 [0.94, 1.00] Santos 2003 11 2 4 32 0.73 [0.45, 0.92] 0.94 [0.80, 0.99] Sarikaya 2010 15 8 7 70 0.68 [0.45, 0.86] 0.90 [0.81, 0.95] Shaheen 2006 27 3 3 166 0.90 [0.73, 0.98] 0.98 [0.95, 1.00] Sheeler 2002 165 19 4 44 0.98 [0.94, 0.99] 0.70 [0.57, 0.81] Tanz 2009 395 36 158 1259 0.71 [0.67, 0.75] 0.97 [0.96, 0.98] Wong 2002 10 9 9 486 0.53 [0.29, 0.76] 0.98 [0.97, 0.99] Wright 2007 71 7 12 248 0.86 [0.76, 0.92] 0.97 [0.94, 0.99] TP = true positive; TN – true negative; FP = false positive; FN = false negative Management of Streptococcal A Sore Throat 28 Figure 2.4 ROC of RAD tests Sensitivity analysis excluding the two-gate study design did not significantly alter the pooled average sensitivity or specificity (84.0% [95%CI 82.8 to 85.1] and 94.8% [95%CI 94.4 to 95.2], respectively). Post-hoc sensitivity analysis excluding any study that scored a ‘no’ on the QUADAS checklist did not significantly alter the pooled average sensitivity or specificity (82.8% [95%CI 81.4% to 84.1%] and 94.5% [95%CI 94.0% to 95.0%], respectively). Significant heterogeneity was noted for all summary measures. Chromatographic immunoassay tests The most commonly-reported rapid antigen tests were chromatographic immunoassay tests of which nine different types were identified in the included studies. The forest plots of sensitivities and specificities are shown for 26 comparisons (21 studies) in Figure 2.5. Sensitivities of all tests ranged from 53% to 98%, specificities from 70% to 100% with all but one study reporting specificity of more than 85% (Figure 2.6). The pooled overall sensitivity and specificity were 83.9% (95%CI 82.3 to 85.4) and 94.4% (95%CI 93.8 to 95.0), respectively. Tests of homogeneity for sensitivity and specificity reported I2 tests of 90.6% and 89.0%, respectively; indicating significant heterogeneity. Sensitivity analysis excluding the two-gate study design did not significantly alter the pooled average sensitivity or specificity (82.5% [95%CI 80.8 to 84.1] and 94.6% [95%CI 94.0 to 95.2], respectively). Figure 2.5: Forest plot of study results (sensitivity and specificity) for chromatographic immunoassay tests QuickVue Study TP FP FN TN Gurol 2010 51 12 28 362 0.65 [0.53, 0.75] 0.97 [0.94, 0.98] Nerbrand 2002 61 60 21 394 0.74 [0.64, 0.83] 0.87 [0.83, 0.90] Rogo 2011 60 6 5 157 0.92 [0.83, 0.97] 0.96 [0.92, 0.99] Sarikaya 2010 15 8 7 70 0.68 [0.45, 0.86] 0.90 [0.81, 0.95] 395 36 158 1259 0.71 [0.67, 0.75] 0.97 [0.96, 0.98] 66 12 17 243 0.80 [0.69, 0.88] 0.95 [0.92, 0.98] Tanz 2009 Wright 2007 Sensitivity Specificity Sensitivity Specificity 0 0.2 0.4 0.6 0.8 1 0 0.2 0.4 0.6 0.8 1 Sensitivity Specificity 0 0.2 0.4 0.6 0.8 1 0 0.2 0.4 0.6 0.8 1 Sensitivity Specificity 0 0.2 0.4 0.6 0.8 1 0 0.2 0.4 0.6 0.8 1 Sensitivity Specificity 0 0.2 0.4 0.6 0.8 1 0 0.2 0.4 0.6 0.8 1 Sensitivity Specificity 0 0.2 0.4 0.6 0.8 1 0 0.2 0.4 0.6 0.8 1 Sensitivity Specificity 0 0.2 0.4 0.6 0.8 1 0 0.2 0.4 0.6 0.8 1 Sensitivity Specificity 0 0.2 0.4 0.6 0.8 1 0 0.2 0.4 0.6 0.8 1 Sensitivity Specificity 0 0.2 0.4 0.6 0.8 1 0 0.2 0.4 0.6 0.8 1 Sensitivity Specificity 0 0.2 0.4 0.6 0.8 1 0 0.2 0.4 0.6 0.8 1 Acceava Study TP FP FN TN Atlas 2005 38 0 3 112 0.93 [0.80, 0.98] Sensitivity 1.00 [0.97, 1.00] Specificity Rogo 2011 63 2 1 162 0.98 [0.92, 1.00] 0.99 [0.96, 1.00] OSOM Study TP FP FN TN Sensitivity Specificity Gieseker 2002 84 18 3 197 0.97 [0.90, 0.99] 0.92 [0.87, 0.95] Gieseker 2003 184 26 26 651 0.88 [0.82, 0.92] 0.96 [0.94, 0.97] Llor 2009 52 14 3 153 0.95 [0.85, 0.99] 0.92 [0.86, 0.95] Rogo 2011 65 1 1 161 0.98 [0.92, 1.00] 0.99 [0.97, 1.00] Wright 2007 71 7 12 248 0.86 [0.76, 0.92] 0.97 [0.94, 0.99] Detector Strep A Direct Kit Study TP FP FN TN Abu Sabbah 2006 59 25 8 263 Sensitivity 0.88 [0.78, 0.95] Specificity 0.91 [0.87, 0.94] Abbott Test Pack Study TP FP FN TN Alesna 2000 14 5 1 89 0.93 [0.68, 1.00] 0.95 [0.88, 0.98] Humair 2006 128 11 12 221 0.91 [0.86, 0.95] 0.95 [0.92, 0.98] 64 13 16 164 0.80 [0.70, 0.88] 0.93 [0.88, 0.96] Lindbaek 2004 106 27 4 169 0.96 [0.91, 0.99] 0.86 [0.81, 0.91] Nerbrand 2002 107 19 22 466 0.83 [0.75, 0.89] 0.96 [0.94, 0.98] Rosenberg 2002 24 1 8 93 0.75 [0.57, 0.89] 0.99 [0.94, 1.00] Santos 2003 11 2 4 32 0.73 [0.45, 0.92] 0.94 [0.80, 0.99] 165 19 4 44 0.98 [0.94, 0.99] 0.70 [0.57, 0.81] Kurtz 2000 Sheeler 2002 Sensitivity Specificity Strep A Rapid Test device Study Forward 2006 TP FP FN TN Sensitivity Specificity 123 48 37 610 0.77 [0.70, 0.83] 0.93 [0.90, 0.95] SD Bioline Strep A RAT Study Kim 2009 TP FP 187 8 FN TN 8 90 Sensitivity Specificity 0.96 [0.92, 0.98] 0.92 [0.85, 0.96] Link 2 Strep A Rapid Test Study Maltezou 2008 TP FP FN TN Sensitivity Specificity 121 21 25 284 0.83 [0.76, 0.89] 0.93 [0.90, 0.96] Accustrip Study TP FP FN TN Wong 2002 10 9 9 486 Sensitivity 0.53 [0.29, 0.76] Specificity 0.98 [0.97, 0.99] TP = true positive; TN – true negative; FP = false positive; FN = false negative The pattern of the points on the summary ROC (sROC) in Figure 2.6 do not show a threshold effect and the Spearman correlation coefficient was 0.410 (p=0.065) indicating borderline, but not significant presence of a threshold effect. The area under the sROC curve was 0.9672. Table 2.2 shows summary measures for chromatographic immunoassay tests in children and adults; the tests appear to be good at ruling in streptococcal A sore throat in both groups. The test appears to be better at ruling out streptococcal A sore throat in adults, however, significant heterogeneity was present in all summary measures. Figure 2.6 Summary ROC plot for chromatographic immunoassay tests* Sensitivity 1 sROC Curve Symmetric sROC AUC = 0.9672 SE(AUC) = 0.0058 Q* = 0.9153 SE(Q*) = 0.0090 0.9 0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0 0 0.2 0.4 0.6 0.8 1 1-specificity *Red circles indicate children, yellow circles indicate adults, green circles indicate studies that included all age groups. Management of Streptococcal A Sore Throat 31 Table 2.2 Summary measures for children and adults Total children Total adults Total mixed population (adults and children) Total Number of participants (number of studies) n=5444 (11 studies) n=1153 (5 studies) n=1517 (5 studies) Pooled sensitivity (95%CI) Heterogeneity 2 (I ) Pooled specificity (95%CI) Heterogeneity 2 (I ) 81.1 (79.1, 83.0) 91.4% 95.4 (94.7, 96.0) 73.0% 92.1 (88.9, 94.7) 72.4% 92.4 (90.3, 94.1) 86.8% 86.4 (82.2, 90.0) 92.1% 92.2 (90.5, 93.6) 95.4% n=8131 (21 studies) 83.9 (82.3, 85.4) 90.6% 94.4 (93.8, 95.0) 89.0% Pooled results for the most common chromatographic immunoassay tests were similar; the pooled sensitivity and specificity for the Quickvue test (n=3503, 6 studies), the OSOM test (n=1977, 5 studies) the Abbott test (n=2065, 8 studies) and the Acceava test (n=381, 2 studies) were comparable (Table 2.3). Sensitivity analysis excluding the two-gate study design from the Abbott test did not alter results. Table 2.3 Summary measures by test brand Name of test QuickVue Acceava OSOM Detector Strep A Direct Abbott Strep A Rapid test device SD Bioline Link 2 Accustrip Total Number of participants (number of studies) Pooled sensitivity n=3503 (6 studies) n=381 (2 studies) n=1977 (5 studies) n=355 (1 study) 73.3 (70.3, 76.2) 76.4% 94.9 (94.0, 95.7) 92.7% 96.2 (90.5, 99.0) 55% 99.3 (97.4, 99.9) 52.2% 91.0 (88.2, 93.4) 76.6% 95.5 (94.3, 96.5) 82.2% 88 (78–95) - 91 (87, 94) - n=2065 (8 studies) n=818 (1 study) 89.7 (87.2, 91.9) 84.3% 92.9 (91.5, 94.2) 88.3% 77 (70–83) - 93 (90–95) - n=293 (1 study) n=451 (1 study) n=514 (1 study) n=8131 (21 studies) 96 (92, 98) - 92 (85–96) - 83 (76–89) - 93 (90–96) - 53 (29–76) - 98 (97–99) - 83.9 (82.3, 85.4) 90.6% 94.4 (93.8, 95.0) 89.0% (95%CI) Heterogeneity (I2) Pooled specificity Heterogeneity (I2) (95%CI) Management of Streptococcal A Sore Throat 32 Double sandwich immunoassay tests Three different types of double sandwich immunoassay tests were reported in three different studies. The forest plots of sensitivities and specificities are shown in Figure 2.7. Tests of homogeneity for sensitivity and specificity reported I2 tests of 45.0% and 94.9%, respectively; indicating no heterogeneity for sensitivity, and significant heterogeneity for specificity. Sensitivities ranged from 90% to 96%, specificities from 85% to 99% (Figure 2.8). The pooled sensitivity and specificity were 90.6% (95%CI 87.9 to 92.9) and 96.9% (95%CI 95.8 to 97.7), respectively. The area under the ROC curve was 0.9802. There are too few studies of double sandwich immunoassay tests to draw conclusions about their accuracy. Figure 2.7 Forest plot of study results (sensitivity and specificity) for double sandwich immunoassay tests Diaquick Study TP Al Najjar 2008 68 FP FN 3 TN Sensitivity Specificity Sensitivity Specificity 0 0.2 0.4 0.6 0.8 1 0 0.2 0.4 0.6 0.8 1 Sensitivity Specificity 0 0.2 0.4 0.6 0.8 1 0 0.2 0.4 0.6 0.8 1 Sensitivity Specificity 0 0.2 0.4 0.6 0.8 1 0 0.2 0.4 0.6 0.8 1 3 422 0.96 [0.88, 0.99] 0.99 [0.98, 1.00] INTEX Strep A test II Study TP Camurdan 2008 427 FP FN 22 TN Sensitivity Specificity 49 751 0.90 [0.87, 0.92] 0.97 [0.96, 0.98] Kodak Surecell Study TP FP FN TN Alesna 2000 18 16 1 Sensitivity Specificity 89 0.95 [0.74, 1.00] 0.85 [0.76, 0.91] TP = true positive; TN – true negative; FP = false positive; FN = false negative The pattern of the points on the summary ROC in Figure 2.8 do not represent a threshold effect, and the Spearman correlation coefficient was -0.500 (p=0.667) indicating that a threshold effect is not present. Management of Streptococcal A Sore Throat 33 Figure 2.8 Summary ROC plot for double sandwich immunoassay tests Sensitivity 1 sROC Curve Symmetric sROC AUC = 0.9802 SE(AUC) = 0.0166 Q* = 0.9376 SE(Q*) = 0.0313 0.9 0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0 0 0.2 0.4 0.6 0.8 1 1-specificity Pooled results for the double sandwich immunoassay tests were similar; the sensitivity and specificity for the Diaquick test, the INTEX Strep A test and the Kodak Surecell were comparable (Table 2.4). Table 2.4 Study results by test brand Name of test Diaquick Number of participants (number of studies) Sensitivity (95%CI) n=496 (1 study in 96 (88, 99) children) INTEX Strep n=1249 (1 study in 90 (87, 92) A test II children) Kodak n=124 (1 study in mixed 95 (74, 100) Surecell population) Pooled total n=1869 (3 studies) 90.6 (87.9, 92.9) TP = true positive; TN – true negative; FP = false positive; FN = false Specificity (95%CI) 99 (98, 100) 97 (96, 98) 85 (76, 91) 96.9 (95.8, 97.7) negative Optical immunoassay One optical immunoassay test was reported in five different studies. The forest plots of sensitivities and specificities are shown in Figure 2.9. Tests of homogeneity for sensitivity and specificity reported I2 tests of 83.5% and 92.2% respectively, indicating significant heterogeneity for both sensitivity and specificity. Sensitivities ranged from 79% to 95%, specificities from 69% to 100% (Figure 2.9). The pooled sensitivity and specificity were 82.1% (95%CI 79.7 to 84.4) and 93.0% (95%CI 91.9% to 93.9%), respectively. Management of Streptococcal A Sore Throat 34 Figure 2.9 Summary ROC plot for optical immunoassay tests Study TP FP 31 15 2 33 0.94 [0.80, 0.99] 0.69 [0.54, 0.81] 173 10 24 313 0.88 [0.82, 0.92] 0.97 [0.94, 0.99] Araujo Filho 2006 Chapin 2002 FN TN Sensitivity Specificity Ezike 2005 71 0 4 102 0.95 [0.87, 0.99] 1.00 [0.96, 1.00] Gieseker 2002 65 12 17 208 0.79 [0.69, 0.87] 0.95 [0.91, 0.97] Rimoin 2010 Sensitivity Specificity 561 136 149 1626 0.79 [0.76, 0.82] 0.92 [0.91, 0.93] 0 0.2 0.4 0.6 0.8 1 0 0.2 0.4 0.6 0.8 1 TP = true positive; TN – true negative; FP = false positive; FN = false negative The pattern of the points on the summary ROC in Figure 12.10 do not represent a threshold effect, and the Spearman correlation coefficient was -0.400 (p=0.505) indicating that a threshold effect is not present. The area under the ROC curve was 0.9462. Figure 2.10 Summary ROC plot for optical immunoassay tests Sensitivity 1 sROC Curve Symmetric sROC AUC = 0.9462 SE(AUC) = 0.0244 Q* = 0.8854 SE(Q*) = 0.0321 0.9 0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0 0 0.2 0.4 0.6 0.8 1 1-specificity Table 2.5 shows summary measures for optical immunoassay tests in children and adults; only one study was conducted in adults with a small number of participants. In children, optical immunoassay tests appear to be good at both ruling in and ruling out Streptococcal A sore throat, but are better at ruling in disease. Significant heterogeneity was present in all summary measures. Management of Streptococcal A Sore Throat 35 Table 2.5 Optical immunoassay tests by adults/children Total children Total adults Total Number of participants (number of studies) n=3471 (4 studies) n=81 (1 study) Pooled sensitivity (95%CI) Heterogeneity 2 (I ) Pooled specificity (95%CI) Heterogeneity 2 (I ) 81.8 (79.3, 84.0) 85.1% 93.4 (92.4, 94.4) 88.3% 94 (90, 99) - 69 (54, 81) - n=3552 (5 studies) 82.1 (79.9, 84.4) 83.5% 93.0 (91.9, 93.9) 92.2% Regression analysis Possible sources of heterogeneity across the included studies, other than the threshold effect, were investigated using regression analysis using the co-variates listed below as predictor variables: study population (less than, or greater than 200 participants) prevalence of Streptococcal A throat infection (greater or less than 35%) age (children or adults) technique of taking swab (described or not described). Results are shown in Table 2.6, and suggest that none of the variables investigated are significantly associated with accuracy. Table 2.6 Results of meta-regression analysis for predicting the presence or absence of streptococcal A throat infection Meta-Regression (inverse variance weights) Var Cte. S <200 prev children swab Coeff. 5.214 -0.073 -0.981 0.322 -0.212 -0.551 Std. Err. 0.4211 0.1382 0.5865 0.4667 0.4350 0.4178 p - value 0.0000 0.6037 0.1069 0.4965 0.6307 0.1994 rdOR ------0.37 1.38 0.81 0.58 [95%CI] ------(0.11; 1.25) (0.53; 3.61) (0.33; 1.98) (0.24; 1.36) Var = variance; Coeff. = coefficient; std. err. = standard error; rdOR = relative diagnostic odds ratio; prev = prevalence Discussion Summary of main results All tests had high diagnostic accuracy. Overall, sensitivities of all tests ranged from 53% to 96%, specificities from 69% to 100% with pooled sensitivity and specificity outcomes of 84.5% (83.4 to 85.6) and 94.7% (94.2 to 95.1), respectively. The quality of the included studies was good. Significant heterogeneity was observed overall, and for most subgroups. The pooled estimates of each test are shown in Table 2.7. Management of Streptococcal A Sore Throat 36 Table 2.7 Pooled estimates of each test Pooled sens (95%CI) 83.9% (82.3 to 85.4) 2 I 90.6% Chromatographic immunoassay Double sandwich 90.6% (87.9 to 92.9) 45.0% immunoassay Optical 82.1% (95%CI 79.7 to 83.5% immunoassay 84.4) 2 sens = sensitivity; spec = specificity; I = heterogeneity 2 Pooled spec (95%CI) 94.4% (93.8 to 95.0) I 89.0% 96.9% (95.8 to 97.7) 94.9% 93.0% (95%CI 91.9 to 93.9) 92.2% The most common tests in the included studies were chromatographic immunoassays and showed good diagnostic performance despite significant heterogeneity. Double sandwich immunoassays, optical and latex particle agglutination were limited because of the small number of studies. Although the diagnostic outcomes appear promising, only three studies investigating double sandwich immunoassays and five studies investigating optical immunoassays were identified; too few to draw reliable conclusions about their ability to discriminate between those with and without streptococcal A throat infection. We included latex particle agglutination in this review, even though it has most likely been superseded by more modern methods of rapid antigen testing and requires greater input from the primary care physician than other methods. Sensitivity analysis excluding the three studies investigating latex particle agglutination in the overall summary of studies did not alter the results. We did not report the individual results of latex particle agglutination alone. Limitations Significant heterogeneity was present in almost all of the analyses conducted. Regression analysis revealed that studies with lower numbers (less than 200 participants), studies with a higher prevalence of streptococcal A throat infection (greater than 35%), subgroups of children and adults, and studies in which the swabbing method was explicitly described, did not explain the heterogeneity observed. Potential causes of heterogeneity The technique used in obtaining swabs is likely an important source of heterogeneity. Many authors of the included studies claimed to have followed the directions on the test kit, but there is no way to control the quality of the swab samples. If the swab comes into contact with other parts of the mouth (for example the tongue or cheek) it can contaminate the sample. The only thing we were able to do was conduct regression analysis on the studies providing an explicit description of the swab method used; however, this does not represent an adequate exploration of swab quality. Another possible cause of heterogeneity may have been the differences in prevalence. In children the prevalence ranged from 14.3% to 66.5% (mean 31.2%) and in adults ranged from 13.4% to 40.7% (mean 25.1%). Comparison with other reports We identified one systematic review and meta-analysis published in Spanish, and after confirming that it had not been published in English we translated the review.68 The review included 24 studies, some of which we excluded because the authors only confirmed results of negative rapid antigen tests with culture, and 2x2 contingency Management of Streptococcal A Sore Throat 37 tables could not be constructed. The review concluded that rapid tests offer good accuracy for use as a diagnostic method; however, the rapid test devices have to be complemented with culture because of false positive and negative results. We located a second meta-analysis published in 1999, in abstract form only.69 We could not locate a full text copy of the published report, nor were we able to contact the author. The review concluded that variation in test sensitivity is much greater than that of specificity in reported studies. sROC results indicate that overall test accuracy is good and that selection of sensitivity thresholds should play a role in determining the use of the rapid test in the management of sore throat. The American Heart Association guidelines on acute rheumatic fever and Kawasaki disease recommends that treatment is indicated for children with acute pharyngitis who have a positive RAD test, but that a negative test doesn’t necessarily rule out infection and children with a negative test should have a throat culture.70 The guideline points out that there are insufficient studies to make recommendations on which rapid antigen tests perform better than others. For their recommendations in adults, the guideline suggests that because of the epidemiological features of acute pharyngitis in adults (eg, low incidence of GAS infections and low risk of acute rheumatic fever), diagnosis of GAS pharyngitis in most adults on the basis of an RADT alone, without confirmation of negative RADT results by a negative throat culture, is reasonable and an acceptable alternative to diagnosis on the basis of throat culture results. Implications for practice The key question is whether the number of false positives and false negatives are acceptable if rapid antigen tests are to be used as a first-line test in detecting streptococcal A throat infection. Table 2.8 shows the implications of different scenarios; the sensitivities and specificities represent the pooled estimates derived from the included studies in this review on a hypothetical population of 100 children and 100 adults with suspected GAS throat infection. The prevalences in Table 2.8 are derived from the median prevalences in the included studies in this review. In a hypothetical population of 100 children with suspected streptococcal A throat infection, three children without the disease would be prescribed antibiotics, potentially unnecessarily, and five with streptococcal A throat infection would be missed. Rapid antigen testing would reduce the number of children receiving unnecessary empiric antibiotics by 71%. Management of Streptococcal A Sore Throat 38 In a hypothetical population of 100 adults with suspected streptococcal A throat infection, five without streptococcal A throat infection would be prescribed antibiotics, potentially unnecessarily, and four with streptococcal A throat infection would be missed. Rapid antigen testing would reduce the number of adults receiving unnecessary empiric antibiotics by 71%. The populations included in this review are likely to be inherently different from New Zealand populations in high risk areas. The included studies spanned a variety of countries and socioeconomic positions and for most of these regions, the prevalence of GAS throat infection is unknown. There is very little data on the prevalence of streptococcal A throat infection in New Zealand. Interim results from a school-based sore-throat study in Opotiki, an area with a high prevalence of rheumatic fever, showed a GAS prevalence of 8% in children presenting with sore throats. In a population of 100 children, we would expect to see five children prescribed unnecessary antibiotics and one child missed using the rapid antigen tests, and we would expect a reduction in empiric antibiotic use by 88%. Although the populations in the included studies and the New Zealand high risk populations are likely to be different, the review showed that the rapid antigen tests performed fairly consistently. It seems reasonable to assume that the tests would perform similarly in New Zealand as they have in other countries. Table 2.8 Consequences of pooled diagnostic outcomes on a theoretical sample Children Adults Children in Opotiki Influence on patient outcome Prevalence 31% 28% 8% - Sensitivity 85% 85% 85% - Specificity 95% 92% 95% - True positive 26 21 7 True negative 66 69 87 False positive 3 6 5 False negative 5 4 1 Benefit from no delay in treatment Benefit from avoiding unnecessary antibiotics Detriment from unnecessary antibiotics Detriment from delayed diagnosis Conclusions Despite the limitations of this review and the heterogeneity present in many of the comparisons, rapid antigen tests appear to be a useful tool for basing initial treatment decisions about streptococcal A throat infection. Specificity was consistently reported at more than 90% (26 of 31 studies) indicating that rapid antigen tests are useful for identifying true cases of infection; in cases of a false positive, the detriment to the patient is an unnecessary course of antibiotics. Sensitivity was consistently reported to be lower than specificity with a pooled value of 84.5% indicating that rapid antigen tests Management of Streptococcal A Sore Throat 39 are useful for ruling out disease, but are better at ruling in disease. To this end, it seems reasonable to confirm the results of negative tests with culture. In the example, if empiric treatment was withheld until culture results were available, unnecessary antibiotics could be avoided in at least 70% of cases overall. However, the pooled sensitivity and specificity should be interpreted with caution. Despite a strict selection of studies based on proper patient recruitment and study design, heterogeneity was considerable and we could not find adequate causes for the variability between studies. Expert advisory group discussion The group discussed the practicalities of swabbing children’s throats in school-based clinics and decided that it was too difficult to recommend in the school clinic setting, but may work better in a general practice setting. Practicality and cost were considered to be the most important factors in considering RADTs. Some group members said they would not use them because they did not have 10 minutes to wait for the test to work and would find using different reagents fiddly. There was also discussion about whether follow-up culture (for negative results on RADT) was worthwhile since it would double the cost. Prevalence was discussed, in that the different prevalence’s in the included studies in the review were varied; some from school-based populations, some from primary care etc. The group acknowledged that prevalence is an important issue and makes a difference to the sensitivity and specificity of a test. The group did not reach firm conclusions on the usefulness of the RAD tests. Some felt that empiric antibiotic use would be decreased if an RADT was used in primary care; some thought that the time it would take to do the test (approximately 10 minutes) was too difficult in the busy practice environment and they would rather prescribe empiric antibiotics. There was discussion about whether the RADTs should be recommended differently in high- and low-risk populations, and whether the addition of risk criteria could increase diagnostic accuracy. The group also discussed the issue of swabbing family members and the need for culture to undertake such swabbing. Rapid Antigen Diagnostic Test in people with a resolved sore throat Research question: In children and adults presenting with a resolved sore throat, what is the accuracy of the RADT compared to culture to confirm GAS? Body of evidence We did not identify any evidence to answer this question. Management of Streptococcal A Sore Throat 40 Timing of testing Research question: In children and adults presenting with a current sore throat is immediate RADT and/or Culture more effective than delayed in ensuring diagnostic accuracy? Body of evidence We did not identify any evidence to answer this question. Management of Streptococcal A Sore Throat 41 3 Antibiotic treatment This chapter addresses antibiotic treatment for people with GAS infection and covers: antibiotic type antibiotic dose antibiotic duration (delayed vs. immediate treatment). Compliance and adverse events are reported for each comparison. Antibiotic type Research question: What is the antibiotic of choice for treatment of children and/or adults diagnosed with GAS throat infection? Body of evidence Systematic reviews Two systematic reviews were identified that compared different types of antibiotic therapies for the treatment of GAS throat infection. One review was of good quality71 and the other was of average quality.72 The reviews compared penicillin with other types of antibiotics (cephalosporins, macrolides and carbacephem). Primary studies Four randomised control trials (RCTs) were identified that compared different types of antibiotic therapies for the treatment of GAS throat infection. All RCTs were of average quality.73-76 The RCTs either compared oral amoxicillin (either short or long course) with oral penicillin or penicillin injection or clindamycin with a combination of amoxicillin and clavulanic acid. Review findings Bacteriological success (microbial eradication)/failure Bacteriological eradication was measured by one average quality systematic review comparing cephalosporins and penicillin72 in adults and children. Two RCTs were non inferiority trials in children comparing amoxicillin with penicillin. 75, 76 One RCT compared clindamycin with amoxicillin/clavulanic acid in adolescents and adults, 74 and the fourth RCT was a non inferiority trial comparing amoxicillin with penicillin measured bacteriological failure of therapy in children.73 Details are provided in Tables 3.1 and 3.2. Cephalosporins (4 to 5 days or 10 days) versus penicillin (10 days): ERADICATION: The systematic review stratified results according to whether the trials were undertaken in the USA or Europe, whether participants were adults or children and according to duration of cephalosporins (4 to 5 days or 10 days). 72 With shortened doses of cephalosporins (4 to 5 days), bacteriological eradication was significantly more likely in children, but not in adults (Europe: odds ratio (OR) 1.34 [95%CI 1.04 to Management of Streptococcal A Sore Throat 42 1.72]; USA: OR 2.94 [95%CI 1.99 to 4.33]). Cephalosporin therapy given for 10 days was significantly more effective in children (no adult trials) (Europe: OR 4.27 [95%CI 3.13 to 5.83]; USA: OR 2.7 [95%CI 2.15 to 3.37]). It was not reported when the outcome was measured. Amoxicillin versus penicillin: ERADICATION: Two non inferiority trials found no difference in the rates of bacteriological eradication between amoxicillin and penicillin (using a pre-specified margin of 10% difference) when measured 14 to 45 days after initiation of treatment in children aged up to 12 years.75, 76 Route of administration varied in the two trials; one compared oral amoxicillin suspension with a single dose of intramuscular benzathine penicillin and the other compared amoxicillin sprinkle (sachets of powder for sprinkling on food) with penicillin VK suspension. FAILURE: One non inferiority trial found no evidence of a difference in bacteriological failure rates when measured at various time points (3 to 6 days, 12 to 16 days or 26 to 36 days) between oral amoxicillin and oral penicillin given for 10 days in children aged 5 to 12 years.73 The rates ranged from 6% to 13%. Another non inferiority RCT found no evidence of a difference in bacteriologic failure with treatments (amoxicillin sprinkle 475 mg to 775 mg for seven days versus penicillin suspension, maximum dose 250 mg QID for 10 days) on days 14 to 18 or 38 to 45.75 Rates of failure were much higher than those reported by Lennon; 73 they ranged from 32% to 44%. Clindamycin versus amoxicillin/clavulanic acid: ERADICATION: One large multicentre trial found high rates of bacteriological eradication and no evidence of a difference between oral clindamycin and oral amoxicillin/clavulanic acid in adults and adolescents (97.9% and 94.4% at day 12, and 99.2% and 99.6% at 3 months).74 Summary: The mixed quality review found substantial benefits for cephalosporin when compared with penicillin in rates of bacteriological eradication in children, both for shortened courses of 4 to 5 days and 10 days of cephalosporin versus 10 days of penicillin in trials conducted both in the USA and Europe. The Cochrane review did not measure this outcome. Although the benefits were substantial, these findings should be interpreted with caution, because potential bias arising from lack of blinding, inadequate follow-up and unexplained heterogeneity cannot be excluded. Amoxicillin, combined amoxicillin and clavulanic acid, clindamycin and penicillin appeared to have comparable rates, although the rates varied substantially between trials. Management of Streptococcal A Sore Throat 43 Table 3.1 Type of antibiotic – Bacteriologic success/eradication Trial and setting Participants Treatment 1 SYSTEMATIC REVIEWS Pichichero Children and Oral and Casey 72 adults – cephalosporins separate (doses not Setting not analyses reported) for: defined – 1. four days studies from Also stratified 2. five days USA and according to 3. 10 days Europe w hether USA trials or European trials RANDOMISED CONTROLLED TRIALS Pichichero et Children <12 Oral amoxicillin al 75 years sprinkle (475 – 775 mg once Multicentre daily for seven days) Rimoin et al76 Children 2 – 12 years Low resource setting in Croatia and Egypt Mahakit et al74 26 centres in Asia and three in Venezuela Adolescents and adults, aged 12 to 60 years Oral amoxicillin suspension (750 mg once daily) Oral clindamycin (300 mg BID for 10 days) Treatment 2 Results Oral penicillin for 10 days Cephalosporins (10 days) vs. penicillin (10 days): All w ere analyses of children: Europe: OR 4.27 (95%CI 3.13 to 5.83) USA: OR 2.70 (95%CI 2.15 to 3.37) Cephalosporins (4–5 days) vs. penicillin (10 days): Children Europe: OR 1.34 (95%CI 1.04 to 1.72) Children USA: OR 2.94 (95%CI 1.99 to 4.33) Adults Europe: OR 1.09 (95%CI 0.58 to 2.02) NS Adults USA: OR 1.65 (95%CI 0.97 to 2.82) NS Oral penicillin suspension (maximum dose of 250 mg four times a day for 10 days) Penicillin injection (600,000 to 1.2 million units, according to body w eight Oral amoxicillin/clavulanic acid 1g (875 mg amoxicillin/125 mg clavulanic acid BID for 10 days) Days 14 to 18: Amoxicillin: 65.3% Penicillin: 68% Rx difference: 95%CI -12 to 6.6%, NS Days 14 to 18 plus 38 to 45: Amoxicillin: 55.4% Penicillin: 56.9% Rx difference: 95%CI not reported ITT analysis: Croatia: MD 2.5% (95%CI -13.8 to 18.9), NS Egypt: MD -15.1% (-26.6 to 18.5), NS PP analysis: Croatia: MD 1.1% (95%CI -16.2 to 18.5) NS Egypt: -9.3% (95%CI -26.3 to 7.8) NS Day 12: Clindamycin: 97.9% Amoxicillin/clavulanic acid: 94.4% NS 3 months: Clindamycin: 99.2% Amoxicillin/clavulanic acid: 99.6% NS OR = odds ratio; CI = confidence interval; NS = not significant; ITT = intention to treat; Rx = treatment/therapy; BID = tw ice daily; MD = mean difference; PP analysis = per protocol analysis Management of Streptococcal A Sore Throat 44 Table 3.2 Type of antibiotic – Bacteriologic failure Trial and setting Participants Treatment 1 RANDOMISED CONTROLLED TRIALS Pichichero et Children <12 Oral amoxicillin al 75 years sprinkle (475 to 775 mg once Multicentre daily for seven days) Lennon et al73 Sore throat clinic at primary school in New Zealand Children 5 to 12 years Oral amoxicillin (750 to 1500 mg QD for 10 days) Treatment 2 Results Oral penicillin suspension (maximum dose of 250 mg four times a day for 10 days) Days 14 to 18: Amoxicillin: 34.7% Penicillin: 32.0% Rx difference not reported Oral penicillin V (250 to 500 mg BID for 10 days) Days 38 to 45: Amoxicillin: 43.6% Penicillin: 40.3% Rx difference not reported Days 3 to 6: Amoxicillin: 5.8% Penicillin: 6.2% Rx difference: 0.3% (upper 95% confidence limit 4.9%) Days 12 to 16: Amoxicillin: 12.7% Penicillin: 11.9% Rx difference: (upper 95% confidence limit 6.5%) Days 26 to 36: Amoxicillin: 10.7% Penicillin: 11.3% Rx difference: 1.9% (upper 95% confidence limit 8.5%) Rx = treatment/therapy; BID = tw ice daily; QD = once a day Clinical success (microbial eradication and complete or substantial resolution of symptoms)/failure Clinical success (defined in different ways) was measured by five of the six studies. The Cochrane systematic review compared clinical success in three different comparisons: cephalosporins versus penicillin, macrolides versus penicillin and carbacepham versus penicillin, stratified by children and adults. 71 The other systematic review compared cephalosporins with penicillin.72 Two non-inferiority RCTs compared amoxicillin with penicillin73, 75 and one RCT compared clindamycin with amoxicillin/clavulanic acid.74 Details are provided in Table 3.3. Cephalosporins versus penicillin: The good quality Cochrane systematic review found no evidence of a difference in symptom resolution in adults and children in intention to treat (ITT) analysis (OR 0.79, 95%CI 0.55 to 1.22) (or in their separate subgroups) but a significant difference was reported overall in the per protocol analysis.71 The average quality systematic review comparing 10 days of cephalosporins with 10 days of penicillin found improved clinical cure in children taking cephalosporins (Europe: OR 2.38, 95%CI 1.68 to 3.35; USA: OR 2.46, 95%CI 2.02 to 2.98) but more variable results with 4 to 5 days of cephalosporins according to subgroup (Children: Europe: OR 1.75, 95%CI 1.18 to 2.61; US: no evidence of a difference; Adults: Europe: no evidence of a difference; US: OR 1.78, 95%CI 1.0 to 3.17).72 Management of Streptococcal A Sore Throat 45 Macrolides versus penicillin: The good quality Cochrane systematic review found no evidence of a difference in symptom resolution between treatments.71 Carbacephem versus pencillin: The good quality Cochrane systematic review found a significant benefit for carbacephem in children (OR 0.57, 95%CI 0.33 to 0.99). 71 Amoxicillin versus penicillin: The two non-inferiority trials found no evidence of a difference between amoxicillin and penicillin between treatments in the resolution of symptoms in children aged up to 12 years.73, 75 Clindamycin versus amoxicillin/clavulanic acid: Clindamycin was associated with improved clinical cure at day 12 in a mixed group of adolescents and adults (92.6% vs. 85.2%; p<0.003) but not at three months after the initiation of treatment (95.4% vs. 95.7%).74 Summary: There appears to be some evidence that cephalosporins and carbacephem have benefits over penicillin in terms of resolution of symptoms or clinical cure, mostly in children. However, the Cochrane review found that the findings were inconsistent across analysis methods (ITT and per protocol) and the numbers needed to treat for benefit were substantial. The lower quality review confirmed the Cochrane review findings on clinical cure with cephalosporins but the benefits were more consistent (and larger) when 10 day courses were compared. The magnitude of the benefit in clinical cure or resolution of symptoms differed substantially between these two reviews and may have been caused by differences in quality. The Cochrane systematic review had strict inclusion criteria and included only double blind trials to minimise the likelihood of bias in the measurement of outcomes. By contrast, blinding was not a criterion of inclusion for the average quality review, follow-up time was not reported and many of the meta-analyses had substantial heterogeneity. Assessment of clinical cure is subjective and bias as a result of lack of blinding in many of the studies cannot be excluded. There was no evidence of a benefit for macrolides when compared with penicillin and amoxicillin and penicillin appeared to have comparable effects, although clindamycin was superior to combination treatment with amoxicillin at the completion of treatment in adults and adolescents. Management of Streptococcal A Sore Throat 46 Table 3.3 Type of antibiotic – Clinical success rates Trial and setting Participants SYSTEMATIC REVIEWS Van Driel et Children and al71 adults – separate Mostly high analyses resource countries Treatment 1 Treatment 2 Results Non penicillin antibiotic class Penicillin ITT analyses: (1) Cephalosporins vs. penicillin Adults and children: OR 0.79 (95%CI 0.55 to 1.12) NS (subgroups of adults and children NS) (2) Macrolides vs. penicillin: Adults and children: OR 1.11 (95%CI 0.92 to 1.35) NS (subgroups of adults and children NS) Pichichero and Casey 72 Setting not defined – studies from USA and Europe Children and adults – separate analyses Also stratified according to w hether USA trials or European trials Oral cephalosporins (doses not reported) for: 1. four days 2. five days 3. 10 days RANDOMISED CONTROLLED TRIALS Lennon et al Children 5 to 12 Oral amoxicillin 73 years (750 to 1500 mg QD for 10 days) Sore throat clinic at primary school in NZ Mahakit et al 74 Adolescents and adults, aged 12 to 60 years 26 centres in Asia and three in Venezuela Pichichero et al 75 Children <12 years Oral clindamycin (300 mg BID for 10 days) Oral penicillin for 10 days (3) Carbacephem vs. penicillin: Adults and children: OR 0.70 (95%CI 0.49 to 0.99) Children: OR 0.57 (95%CI 0.33 to 0.99) Adults: OR 0.75 (95%CI 0.46 to 1.22) Cephalosporins (10 days) vs. penicillin (10 days): All w ere analyses of children: Europe: OR 2.38 (95%CI 1.68 to 3.35) USA: OR 2.46 (95%CI 2.02 to 2.98) Cephalosporins (4 to 5 days) vs. penicillin (10 days): Children Europe: OR 1.75 (95%CI 1.18 to 2.61) Children USA: OR 0.97 (95%CI 0.60 to 1.57) NS Adults Europe: OR 1.32 (95%CI 0.67 to 2.63) NS Adults USA: OR 1.78 (95%CI 1.0 to 3.17) Oral penicillin V (250 to 500 mg BID for 10 days) Days 3 to 6: Figures not reported. Days 12 to 16: Figures not reported Oral amoxicillin/clavulanic acid 1 g (875 mg amoxicillin/125 mg clavulanic acid BID for 10 days) Days 26 to 36: Figures not reported Day 12: Clindamycin: 92.6% Amoxicillin/clavulanic acid: 85.2% P<0.003 3 months: Clindamycin: 95.4% Amoxicillin/clavulanic acid: 95.7% NS Days 14 to 18: Amoxicillin: 86.1% Penicillin: 91.9% Rx difference: 95%CI -11.6 to -0.4% Oral amoxicillin Oral penicillin sprinkle (475 to suspension (maximum 775 mg once dose of 250 mg four Multicentre daily for seven times a day for 10 days) days) OR = odds ratio; CI = confidence interval; NS = not significant; ITT = intention to treat; Rx = treatment/therapy; BID = tw ice daily; QD = once a day Management of Streptococcal A Sore Throat 47 Bacteriological relapse Relapse was measured in two studies, one systematic review of good quality 71 and one RCT of mixed quality.73 The Cochrane systematic review measured incidence of relapse only in evaluable participants as the authors considered that ITT analysis would seriously overestimate the importance of relapse. Details are provided in Table 3.4. Cephalosporin versus penicillin: The systematic review found that cephalosporin was associated with a significant reduction in the rate of relapse in adults (OR 0.42, 95%CI 0.2 to 0.88; numbers needed to benefit [NNTB] 33) but not in children.71 Macrolides versus penicillin and carbacephem versus penicillin: There was no evidence of significant differences in relapse rates between treatments when macrolides or carbacephem were compared with penicillin. 71 Amoxicillin versus penicillin: Relapse rates were similar between treatments in one non inferiority RCT; they ranged from 7% to 9% up to 36 days after the initiation of treatment.73 Summary: The incidence of relapse in evaluable adult participants seems to be lower in those treated with cephalosporins compared with penicillin, but the event rate is low (approximately 3.5%) and the numbers needed to benefit are quite high (NNTB 33). There were no differences in the relapse rate between other antibiotics and penicillin. Table 3.4 Type of antibiotic – Bacteriologic relapse Trial and setting Participants SYSTEMATIC REVIEW Van Driel et Children and al71 adults – subgroup Mostly high analyses resource countries Treatment 1 Treatment 2 Results Non penicillin antibiotic class Penicillin 1. Cephalosporins vs. penicillin Adults and children: OR 0.55 (95%CI 0.31 to 0.99), NNTB 50 Children: OR 0.89 (95%CI 0.33 to 2.43) NS Adults: OR 0.42 (95%CI 0.20 to 0.88), NNTB 33 2. Macrolides vs. penicillin: NS in any analyses 3. Carbacephem vs. penicillin: NS in any analyses RANDOMISED CONTROLLED TRIALS Lennon et al73 Children 5 to 12 Oral amoxicillin years (750 to 1500 mg Sore throat QD for 10 days) clinic at primary school in NZ Oral penicillin V (250 to 500 mg BID for 10 days) Days 12 to 16: Amoxicillin: 7.6% Penicillin: 7.6% Days 26 to 36: Amoxicillin: 8.8% Penicillin: 9.4% Rx difference not reported. OR = odds ratio; CI = confidence interval; NS = not significant; NNTB = number needed to benefit; Rx = treatment/therapy; BID = tw ice daily; QD = once a day Management of Streptococcal A Sore Throat 48 Compliance One RCT of average quality, undertaken in two countries with low resource settings, reported on compliance separately in each country. 76 Oral amoxicillin was compared with a single dose of intramuscular penicillin. Compliance in the amoxicillin group was 84.4% in Croatia but only 30.1% in Egypt (the comparative arm had penicillin injection so compliance could not be compared), leading the authors to conclude that a single dose of intramuscular penicillin may be preferable for treatment where compliance is a major issue. No other studies were identified that compared compliance between treatments, but a number of studies only analysed participants who had a pre-specified level of compliance with therapy. Details are provided in Table 3.5. Summary: There was insufficient evidence to compare rates of compliance between treatments. Table 3.5 Type of antibiotic – Compliance Trial and setting Participants Treatment 1 RANDOMISED CONTROLLED TRIALS Rimoin et al76 Children 2 to 12 Oral amoxicillin years suspension Low resource (750 mg once setting in daily) Croatia and Egypt Treatment 2 Results Penicillin injection (600,000 to 1.2 million units, according to body w eight Croatia: 84.4% Egypt: 30.1% No comparison made w ith treatment tw o as compliance w as 100% for this treatment. Adverse events Adverse events were measured in one systematic review of good quality71 and two RCTs of average quality.74, 76 Details are provided in Table 3.6. Cephalosporins versus pencillin: There was no evidence of a difference in the rates of adverse events (sore throat, fever or any adverse event) between treatments in the Cochrane high quality systematic review.71 Macrolides versus penicillin: Macrolide therapy caused more adverse events in children in one trial in the Cochrane systematic review (OR 2.33, 95%CI 1.06 to 5.15; numbers needed to harm [NNTH] 17.2) but there was no evidence of significant differences in these events in adults. 71 Carbacephem versus penicillin: There was no evidence of a difference in the rates of adverse events between treatments in the Cochrane high quality systematic review. 71 Amoxicillin versus penicillin: In one RCT where oral amoxicillin was compared with intramuscular injection of penicillin, 67.4% of children receiving penicillin had discomfort at the site of the injection and 5.3% of children taking oral amoxicillin had rashes and gastrointestinal Management of Streptococcal A Sore Throat 49 symptoms, although no statistical tests were performed. 76 No serious adverse events were reported. Clindamycin versus amoxicillin/clavulanic acid: There was no evidence of a difference between treatments in the rate of adverse events, either overall or by body system; overall rates ranged from 11% to 14% and were mostly gastrointestinal.74 Summary: There were no clinically important differences in the occurrence of adverse events between different types of antibiotics, except for an increased rate in children taking macrolides. These findings are based on a limited number of studies. Table 3.6 Type of antibiotic – Adverse events Trial and setting Participants SYSTEMATIC REVIEWS Van Driel et al Children and 71 adults – separate Mostly high analyses resource countries Treatment 1 Treatment 2 Results Non penicillin antibiotic class Penicillin 1. Cephalosporins vs. penicillin NS: rates of sore throat, fever or any adverse events betw een treatments 2. Macrolides vs. penicillin: NS: rates of sore throat and fever. Also NS: rates of any adverse events in adults. Any adverse events: Children: OR 2.33 (95%CI 1.06 to 5.15), NNTH 17.2 3. Carbacephem vs. penicillin: NS: rates of any adverse events RANDOMISED CONTROLLED TRIALS Rimoin et al 76 Children 2 to 12 Oral amoxicillin years suspension Low resource (750 mg once setting in daily) Croatia and Egypt Mahakit et al74 26 centres in Asia and three in Venezuela Adolescents and adults, aged 12 to 60 years Oral clindamycin (300 mg BID for 10 days) Penicillin injection (600,000 to 1.2 million units, according to body w eight Amoxicillin: 5.3% (skin rash, diarrhoea, vomiting, sw eating, itching, nausea) IM penicillin: 67.4% (discomfort at the site of injection) No statistical comparison made. Oral amoxicillin/clavulanic acid 1 g (875 mg amoxicillin/125 mg clavulanic acid BID for 10 days) ≥1 adverse event: Clindamycin: 13.8% Amoxicillin/clavulanic acid: 10.5% NS Also NS for specific adverse events by body system OR = odds ratio; CI = confidence interval; NS = not signif icant; NNTH = number needed to harm; BID = tw ice daily Summary of findings The evidence base includes primary studies which compared oral amoxicillin (in either short or long courses) with oral penicillin or pencillin injection, clindamycin with a combination of amoxicillin and clavulanic acid and systematic reviews which mostly compared cephalosporins with penicillin, but also included comparisons of macrolides and carbacephem with penicillin. In sum, in spite of the marginal benefits found for cephalosporins and carbacephem (both antibiotics with a wider spectrum) when compared to penicillin, the Cochrane Management of Streptococcal A Sore Throat 50 authors concluded that there is insufficiently convincing evidence to alter current guideline recommendations for the treatment of patients with GAS throat infection. Choice of treatment for GAS throat infection needs to take into account prevention of complications, adverse events, costs and microbial resistance patterns, as well as efficacy and the evidence for these outcomes is still limited. The limited number of studies, with non-inferiority designs, comparing amoxicillin with penicillin reported mostly comparable outcomes. Antibiotic dose Research question: What is the efficacy and safety of different doses of antibiotics for treatment of children and/or adults diagnosed with GAS throat infection? Body of evidence Systematic reviews One systematic review of poor quality was identified.77 It compared azithromycin given over a period of 3 to 5 days at a dose of 30 mg/kg or 60 mg/kg with a 10 day comparator antibiotic (mostly penicillin); analyses were stratified for adults and children and by dose and duration of azithromycin, but not the comparator antibiotic. Primary studies Two RCTs of good quality were identified, each of which compared different doses of the same drug. 78, 79 Jorgensen compared an oral single dose (2 g) of azithromycin with oral immediate release azithromycin given for 3 days (500 g/day) in adolescents and adults (≥13 years).79 Clegg et al compared once daily penicillin (750 mg or 1000 mg) with twice daily amoxicillin (2 doses of 375 mg or 500 mg) for 10 days in children and adolescents (3 to18 years).78 Three RCTs of average quality were identified which compared doses of different drugs for treatment of GAS tonsillopharyngitis.73, 75, 76 Pichichero et al compared amoxicillin sprinkle (475 mg once a day (QD) for ages 6 months to 4 years and 775 mg QD for ages 5 to 12 years) for seven days with penicillin VK suspension (10 mg/kg of body weight four times a day (QID), maximum dose 250 mg QID) for 10 days in children aged six months to 12 years.75 Rimoin et al compared oral amoxicillin suspension (750 mg QD for all weight categories) for 10 days with a single dose of intramuscularly administered benzathine penicillin G (IM BPG) (600,000 units if body weight <27 kg; 1.2 million units if body weight ≥27 kg).76 Lennon et al compared amoxicillin 1500mg (or 750 mg for children with body weight ≤30k g) orally QD for 10 days with penicillin V 500mg (or 250 mg for children with body weight ≤20 kg) orally twice a day for 10 days.73 Management of Streptococcal A Sore Throat 51 Review findings Bacteriological success (microbial eradication)/failure One poor quality systematic review 77 and four RCTs , (two of good quality78, 79 and three of average quality73,75, 76) assessed bacteriological success/eradication or bacteriological failure. Details are provided in Tables 3.7 and 3.8. Azithromycin (3 to 5 days) versus comparator antibiotics (10 days): ERADICATION: Casey and Pichichero77 found that 3 to 5 days of azithromycin administered at the rate of 30 mg/kg was inferior to the 10 day courses of comparator antibiotics (mostly penicillin) (OR 0.47, 95%CI 0.24 to 0.91) but was superior to 10 day courses when administered at the rate of 60 mg/kg (OR 5.27, 95%CI 3.34 to 8.32) in children. There was no evidence of a difference in the bacteriological cure rates in the adult studies (which all used doses of 30 mg/kg). In children, five day administration of azithromycin was superior when compared to 10 day comparator antibiotics (OR 4.37, 95%CI 1.70 to 11.27) but not three day courses (OR 0.62, 95%CI 0.30 to 1.27). In adults, five day administration of amoxicillin was inferior to 10 day comparator antibiotics (OR 0.41, 95%CI 0.22 to 0.75). Azithromycin (single dose of 2 g) versus azithromycin (three day dose of 500 mg/day): ERADICATION: One non inferiority RCT did not find evidence of a difference between treatments, at the pre-specified level of 10%, either at the test of cure visit (days 24 to 28) or the long-term follow-up visit (days 38 to 45).79 Amoxicillin versus penicillin: ERADICATION: One non inferiority RCT found no evidence of a difference in treatments (amoxicillin suspension 750 mg once daily vs. penicillin injection – 600,000 to 1.2 million units) for bacteriological success in either the intention to treat or evaluable populations of children, at the pre-specified level of 10% on days 21 to 28.76 Another non inferiority RCT found no evidence of a difference in treatments (amoxicillin sprinkle 475 mg–775mg for seven days vs. penicillin suspension, maximum dose 250 mg QID for 10 days) in children on days 14 to 18 or 38 to 45. 75 FAILURE: One non inferiority RCT found no evidence of a difference in treatments (oral amoxicillin 750-1500 mg QD for 10 days vs. oral penicillin 250-500 mg twice a day for 10 days) in children at the pre-specified level of 10% on days three to six, 12 to 16 or 26 to 36.73 Another non inferiority RCT found no evidence of a difference in treatments (amoxicillin sprinkle 475 mg-775 mg for seven days vs. penicillin suspension, maximum dose 250 mg QID for 10 days) in the rates of failure on days 14 to 18 or 38 to 45.75 Amoxicillin once daily (750 to 1000 mg) versus amoxicillin twice daily (375 to 500 mg): FAILURE: One non inferiority RCT found no evidence of a difference in the rates of bacteriological failure at the pre-specified level of 10% at days 14 to 21.78 Failure rates ranged from 16% to 20% and included bacteriological persistence (as well as clinical recurrence). When measured at days 28 to 35, bacteriological failure was significantly lower (2.8%) in the once daily treatment group when compared with the twice daily group (7.1%) (mean difference (MD) -4.33, 90%CI -7.7 to -1.0). This statistical difference was no longer apparent when data from both visits were combined. Management of Streptococcal A Sore Throat 52 Table 3.7 Antibiotic dose – Bacteriological success Trial and setting Participants SYSTEMATIC REVIEWS Casey and Children and Pichichero 77 adults – separate Setting not analyses specified – trials undertaken in the USA and Europe Treatment 1 Treatment 2 Results Oral azithromycin (3 to 5 days) administered at dosages of 30 mg/kg and 60 mg/kg Comparator antibiotics (10 days) – dosage not specified (mostly penicillin) Children: 30 mg/kg: OR 0.47 (95%CI 0.24 to 0.91) 60 mg/kg: OR 5.27 (95%CI 3.34 to 8.32) 3 days: OR 0.62 (95%CI 0.30 to 1.27) NS 5 days: OR 4.37 (95%CI 1.70 to 11.27) Adults: 30 mg/kg: OR 0.86 (95%CI 0.37 to 1.99) NS 3 days: OR 1.87 (95%CI 0.81 to 4.27) NS 5 days: OR 0.41 (95%CI 0.22 to 0.75) RANDOMISED CONTROLLED TRIALS Jorgensen79 Adolescents and Oral adults azithromycin Multicentre – (single dose 2 g) outpatients extended release (AZ-ER) Rimoin et al76 Children 2 to 12 years Low resource setting in Croatia and Egypt Pichichero et al75 Children <12 years Multicentre Oral amoxicillin suspension (750 mg once daily) Oral amoxicillin sprinkle (475 to 775 mg once daily for seven days) Oral azithromycin (500 mg/day for three days) immediate release (AZ-IR) Penicillin injection (600,000 to 1.2 million units, according to body w eight Oral penicillin suspension (maximum dose of 250 mg four times a day for 10 days) Days 24 to 28 follow -up: AZ-ER: 85.4% AZ-IR: 81.4% No difference Days 34 to 45 follow -up: AZ-ER: 94.5% AZ-IR: 92.3% No difference ITT analysis: Croatia: MD 2.5% (95%CI -13.8 to 18.9), NS Egypt: MD -15.1% (-26.6 to 18.5), NS PP analysis: Croatia: MD 1.1% (95%CI -16.2 to 18.5) NS Egypt: -9.3% (95%CI -26.3 to 7.8) NS Days 14 to 18: Amoxicillin: 65.3% Penicillin: 68% Rx difference: 95%CI -12 to 6.6%, NS Days 14 to 18 plus 38 to 45: Amoxicillin: 55.4% Penicillin: 56.9% Rx difference: 95%CI not reported OR = odds ratio; CI = confidence interval; NS = not significant; ITT = intention to treat; Rx = treatment/therapy; MD = mean difference; PP analysis = per protocol analysis Table 3.8 Antibiotic dose - Bacteriological failure Trial and setting Participants Treatment 1 RANDOMISED CONTROLLED TRIALS Clegg et al78 Children and Oral amoxicillin adolescents, (750 to1000 mg, Single aged 3 to 18 once daily) paediatric years clinic in USA Treatment 2 Results Oral amoxicillin (375 to 500 mg tw ice daily) Days 14 to 21: Amoxocillin once daily: 20.1% Amoxocillin tw ice daily: 15.5% Rx difference 4.53 (90% CI -0.6 to 9.7) NS Days 28 to 35: Amoxocillin once daily: 2.8% Amoxocillin tw ice daily: 7.1% Rx difference -4.33 (90% CI -7.7 to -1.0) Management of Streptococcal A Sore Throat 53 Trial and setting Participants Treatment 1 Treatment 2 Results Lennon et al73 Children 5 to 12 years Oral amoxicillin (750 to 1500 mg QD for 10 days) Oral penicillin V (250 to 500 mg BID for 10 days) Days 3 to 6: Amoxicillin: 5.8% Penicillin: 6.2% Rx difference: 0.3% (upper 95% confidence limit 4.9%) Sore throat clinic at primary school in NZ Days 12 to 16: Amoxicillin: 12.7% Penicillin: 11.9% Rx difference: (upper 95% confidence limit 6.5%) Pichichero et al 75 Multicentre Children <12 years Oral amoxicillin sprinkle (475 to 775 mg once daily for seven days) Oral penicillin suspension (maximum dose of 250 mg four times a day for 10 days) Days 26 to 36: Amoxicillin: 10.7% Penicillin: 11.3% Rx difference: 1.9% (upper 95% confidence limit 8.5%) Days 14 to 18: Amoxicillin: 34.7% Penicillin: 32% Rx difference not reported. Days 14 to 18 plus 38 to 45: Amoxicillin: 43.6% Penicillin: 40.3% Rx difference not reported CI = confidence interval; NS = not significant; Rx = treatment/therapy ; QD = once a day Summary The systematic review found that azithromycin administered at a dosage of 60 mg/kg in children for 3 to 5 days was more effective than other antibiotic regimens (mostly penicillin) administered for 10 days. In this study, dosages of the comparator regimens were not reported so it is difficult to make reliable comparisons. Heterogeneity in the pooled analyses was substantial; when the authors performed a sensitivity analysis with the inclusion only of trials where the comparative regimen was penicillin, there was no longer a difference between treatments, although heterogeneity persisted. Moreover, adverse events and compliance were not measured. The reliability of these results is not clear and they should be considered tentative. There was no evidence of statistical differences in bacteriological eradication or failure in the other dosage comparisons in the studies, except for a lower rate of failure in the once-daily amoxicillin regimen when compared with twice-daily. All but Jorgensen were non inferiority trials, with the goals of establishing whether treatments are comparable in terms of outcomes. Amoxicillin is often given only once a day when compared with penicillin; since efficacy appears to be at least as good as penicillin, other outcomes such as compliance, cost and adverse events need to be considered. Clinical success (microbial eradication and complete or substantial resolution of symptoms)/failure One poor quality systematic review 77 and three RCTs , were identified which assessed clinical success (one of good quality79 and two of average quality73, 75). Clinical success Management of Streptococcal A Sore Throat 54 was defined mostly as resolution of or improvement in the presenting signs and symptoms of GAS infection and the absence of GAS on throat culture). Details are provided in Table 3.9. Short-course azithromycin versus long-course comparator antibiotics: The systematic review77 found that clinical success was significantly increased with short-course azithromycin when given at a dosage of 60 mg/kg in children (OR 7.51, 95%CI 3.66 to 15.39) but not at a dosage of 30 mg/kg. There was no evidence of a difference in treatments in adults. Azithromycin extended release (single dose of 2 g) versus azithromycin immediate release (500 mg for three days): There was no evidence of a difference in the rates of clinical success between different doses of azithromycin, either at days 24 to 28 or days 34 to 45 follow-up.79 Rates varied at these time points from 92% to 99%. Amoxicillin versus penicillin: There was no evidence of a difference in clinical success in two non-inferiority RCTs; one compared oral amoxicillin (75 to 1500 mg once daily for 10 days) with oral penicillin (250 to 500 mg twice daily for 10 days) 73 and the other compared amoxicillin sprinkle (475 to 775 mg once daily for seven days) with penicillin suspension (maximum dose of 250 mg QID for 10 days).75 Where rates were reported, they ranged from 86% to 92%. Table 3.9 Antibiotic dose – Clinical success Trial and Participants setting SYSTEMATIC REVIEW Casey and Children and Pichichero 77 adults – separate Setting not analyses specified – trials undertaken in the USA and Europe Treatment 1 Oral azithromycin (3 to 5 days) administered in children at dosages of: a. 30 mg/kg b. 60 mg/kg Adults received only doses of 30 mg/kg RANDOMISED CONTROLLED TRIALS Jorgensen79 Adolescents and Oral adults, aged ≥13 azithromycin Multicentre – years (single dose 2 g) outpatients extended release (AZ-ER) Treatment 2 Results Comparator antibiotics (10 days) – dosage not specified (mostly penicillin) Children: 30 mg/kg: OR 0.92 (95%CI 0.46 to 1.83) NS 60 mg/kg: OR 7.51 (95%CI 3.66 to 15.39) 3 days: OR 1.04 (95%CI 0.51 to 2.13) NS 5 days: OR 6.80 (95%CI 3.30 to 14.01) Adults: 30 mg/kg: OR 0.86 (95%CI 0.37 to 1.99) NS 3 days: OR 0.56 (95%CI 0.22 to 1.46) NS 5 days: OR 1.53 (95%CI 0.69 to 3.38) NS Oral azithromycin (500 mg/day for three days) immediate release (AZ-IR) Days 24 to 28 follow -up: AZ-ER: 99% AZ-IR: 96.7% Rx difference: 95%CI -1.7 to 8.3 Days 34 to 45 follow -up: AZ-ER: 92.1% AZ-IR: 95.2% Rx difference not reported Level of 10%. Management of Streptococcal A Sore Throat 55 Trial and setting Lennon et al73 Participants Treatment 1 Treatment 2 Results Children 5 to 12 years Oral amoxicillin (750 to 1500 mg QD for 10 days) Oral penicillin V (250 to 500 mg BID for 10 days) Days 3 to 6: Figures not reported Sore throat clinic at primary school in NZ Pichichero et al 75 Days 12 to 16: Figures not reported Children <12 years Multicentre Oral amoxicillin sprinkle (475 to 775 mg once daily for seven days) Oral penicillin suspension (maximum dose of 250 mg four times a day for 10 days) Days 26 to 36: Figures not reported Days 14 to 18: Amoxicillin: 86.1% Penicillin: 91.9% Rx difference: 95%CI -11.6 to -0.4% OR = odds ratio; CI = confidence interval; NS = not significant; Rx = treatment/therapy ; BID = tw ice daily; QD = once a day Summary: Clinical success was significantly increased in children, but not adults, with the use of short-course azithromycin when given at a dosage of 60 mg/kg when compared with 10 day comparator antibiotics (mostly penicillin). The systematic review reporting these findings was of poor quality with significant flaws (see above) and the findings should be regarded with caution. There was no evidence of improved clinical response with any of the other comparisons made: different doses of azithromycin and amoxicillin versus penicillin. The amoxicillin versus penicillin trials had a non inferiority design and clinical success appeared to be comparable. Bacteriological relapse One good quality RCT78 and one average quality RCT73 were identified that assessed bacteriological relapse. This outcome was defined as eradication of GAS by culture after treatment followed by recovery in culture of the same M type of GAS as initially cultured at baseline. Details are provided in Table 3.10s. Amoxicillin (750 to 1000 mg once daily vs. 375 to 500 mg twice daily): Bacteriological relapse was significantly reduced with amoxicillin once daily compared to amoxicillin twice daily (MD -4.37%, 95%CI -7.4 to -1.3) at days 28 to 35.78 Rates were 1.9% for amoxicillin once daily and 6.2% for amoxicillin twice daily. Amoxicillin versus penicillin: There was no evidence of a difference in the rates of bacteriological relapse between treatments.73 Bacteriological relapse was 7.6% for both treatments at days 12 to 16 and ranged from 8.8% to 9.4% at days 26 to 36. Management of Streptococcal A Sore Throat 56 Table 3.10 Antibiotic dose – Bacteriological relapse Trial and setting Participants Treatment 1 RANDOMISED CONTROLLED TRIALS Clegg et al78 Children and Oral amoxicillin adolescents, (750 to 1000 Single aged 3 to 18 mg, once daily) paediatric years clinic in USA Lennon et al73 Children 5 to 12 Oral amoxicillin years (750 to 1500mg Sore throat QD for 10 days) clinic at primary school in NZ Treatment 2 Results Oral amoxicillin (375 to 500 mg tw ice daily) Visit 3 (28 to 35 days): Amoxocillin once daily: 1.9% Amoxocillin tw ice daily: 6.2% Rx difference -4.37 (90% CI -7.4 to -1.3) Oral penicillin V (250 to 500 mg BID for 10 days) Days 12 to 16: Amoxicillin: 7.6% Penicillin: 7.6% Days 26 to 36: Amoxicillin: 8.8% Penicillin: 9.4% Rx difference not reported CI = confidence interval; Rx = treatment/therapy; BID = tw ice daily; QD = once a day Summary: Bacteriological relapse was less likely with once-daily amoxicillin compared with twice-daily amoxicillin in one trial. One other trial confirmed that amoxicillin was not inferior to penicillin in the rates of relapse. Clinical recurrence One good quality78 RCT was identified that assessed clinical recurrence. This outcome was defined as clinical cure followed by recurrence of symptoms and signs of GAS pharyngitis associated with recovery from throat culture of the same M type of GAS as initially cultured at baseline. Details are provided in Table 3.11. Amoxicillin (750 to 1000 mg once daily vs. 375 to 500 mg twice daily): There was no evidence of a difference in the rates of clinical recurrence between treatments at either of two time points. Clinical recurrence ranged from 7.1% to 9.2% at 14 to 21 days and was 0.9% at 28 to 35 days. Table 3.11 Antibiotic dose – Clinical recurrence Trial and setting Participants Treatment 1 RANDOMISED CONTROLLED TRIALS Clegg et al78 Children and Oral amoxicillin adolescents, (750 to1000 mg, Single aged 3 to 18 once daily) paediatric years clinic in USA Treatment 2 Results Oral amoxicillin (375– 500 mg tw ice daily) Visit tw o (14 to 21 days): Amoxocillin once daily: 9.2% Amoxocillin tw ice daily: 7.1% Rx difference 2.09 (90% CI -1.6 to 5.8) Visit three (28 to 35 days): Amoxocillin once daily: 0.9% Amoxocillin tw ice daily: 0.9% Rx difference 0.04 (90% CI -1.4 to 1.5) CI = confidence interval; Rx = treatment/therapy Summary: Clinical recurrence did not differ significantly with different doses of amoxicillin and was minimal after 35 days from the start of treatment. Management of Streptococcal A Sore Throat 57 Compliance Compliance was measured by two good quality RCTs 78, 79 and one average quality RCT.76 Details are provided in Table 3.12. Azithromycin (single dose 2 g extended release) versus azithromycin (500 mg/day for three days): There was no evidence of a difference in the rates of compliance between treatments in one RCT.79 Compliance was high and ranged from 98% to 100%. Amoxicillin (750 to 1000 mg once daily vs. 375 to 500 mg twice daily): There was no evidence of a difference in the rates of compliance between treatments in one RCT.78 Compliance was high and ranged from 92% to 93%. Amoxicillin versus penicillin: Compliance varied substantially in the two low resource settings in one RCT. 76 Compliance was not directly compared with penicillin, which was administered by a single intramuscular injection (100% compliance). Compliance with the oral dose of amoxicillin was 84.4% in Croatia and 30.1% in Egypt; low compliance in Egypt was associated with lower rates of treatment success. Table 3.12 Antibiotic dose – Compliance Trial and setting Participants Treatment 1 RANDOMISED CONTROLLED TRIALS Jorgensen79 Adolescents Oral and adults, azithromycin Multicentre – aged ≥13 (single dose 2 g) outpatients years extended release (AZ-ER) Clegg et al78 Children and Oral amoxicillin adolescents, (750 to 1000 Single aged 3 to 18 mg, once daily) paediatric years clinic in USA Rimoin et al76 Children 2 to Oral amoxicillin 12 years suspension (750 Low resource mg once daily) setting in Croatia and Egypt Rx = treatment/therapy Treatment 2 Results Oral azithromycin (500 mg/day for three days) immediate release (AZ-IR) Oral amoxicillin (375 to 500 mg tw ice daily) Days 34 to 45 follow -up: AZ-ER: 100% AZ-IR: 98% Rx difference not reported Penicillin injection (600,000 to 1.2 million units, according to body w eight Amoxicillin: Croatia: 84.4% Egypt: 30.1% Compliance w as not statistically compared w ith penicillin injection as compliance is 100% w ith this treatment Visit tw o (14 to 21 days): Amoxocillin once daily: 92% Amoxocillin tw ice daily: 93% Rx difference figures not reported Summary: There was limited evidence on compliance. Compliance rates varied in the limited number of trials that assessed this outcome. In one country with a low resource setting, compliance was very poor with an oral regimen of treatment. It is feasible that compliance in well-monitored RCTs is likely to be superior to the normal practice setting and so rates may not be generalisable. Management of Streptococcal A Sore Throat 58 Adverse events Two RCTs of good quality78, 79 and one RCT of average quality76 were identified that measured adverse events. Details are provided in Table 3.13. Azithromycin (single dose 2 g extended release) versus azithromycin (500 mg/day for three days): There was no evidence of a difference in the rate of overall adverse events between treatments in adults and adolescents in one RCT.79 Mild to moderate adverse events, the majority of which were gastrointestinal, were experienced by 20% of participants in each treatment group. Amoxicillin (750 to 1000 mg once daily) versus amoxicillin (375 to 500 mg twice daily): There was no evidence of a difference in the rate of one of more adverse events between treatments in children and adolescents in a non-inferiority RCT.78 The rate of any adverse events ranged from 14% to 17%. Amoxicillin (750 mg once daily) versus penicillin injection (600,000 to 1.2 million units): Rates of adverse events were not statistically compared between treatment groups in children. Of participants having penicillin injections, 67.4% had discomfort at the site of the injection and 5.3% of participants taking oral amoxicillin had rash or gastrointestional symptoms.76 Table 3.13 Antibiotic dose – Adverse events Trial and setting Participants Treatment 1 RANDOMISED CONTROLLED TRIALS Jorgensen79 Adolescents and Oral adults, aged ≥13 azithromycin Multicentre – years (single dose 2 g) outpatients extended release (AZ-ER) Clegg et al78 Children and Oral amoxicillin adolescents, (750 to1000 mg, Single aged 3 to 18 once daily) paediatric years clinic in USA Rimoin et al76 Children 2 to 12 Oral amoxicillin years suspension (750 Low resource mg once daily) setting in Croatia and Egypt Rx = treatment/therapy; IM = intramuscular Treatment 2 Results Oral azithromycin (500 mg/day for three days) immediate release (AZ-IR) Overall rates days 34 to 45 follow -up: AZ-ER: 20.3% AZ-IR: 19.5% Rx difference not reported Oral amoxicillin (375 to 500 mg tw ice daily) Any adverse event after day 3: Amoxocillin once daily: 17% Amoxocillin tw ice daily: 14% Rx difference: 2.2% (90% CI -3.0 to 7.3) Penicillin injection (600,000 to 1.2 million units, according to body w eight Amoxicillin: 5.3% (skin rash, diarrhoea, vomiting, sw eating, itching, nausea) IM penicillin: 67.4% (discomfort at the site of injection) Summary: There was limited evidence on adverse events. There was no evidence of a difference either in the rates of any adverse events or when specific adverse events were compared. The majority of these events were gastrointestinal and mild to moderate in nature. Management of Streptococcal A Sore Throat 59 Summary of findings The evidence base includes a systematic review which compared short-course azithromycin (3 to 5 days) with a 10 day course of comparator antibiotics with variable doses.77 One RCT compared azithromycin given as a single dose as extended release or over three days as immediate release.79 One RCT compared once-daily with twicedaily amoxicillin.78 Three other RCTs compared amoxicillin with penicillin, given in various doses and delivery methods.73, 75, 76 In sum, a poor quality systematic review found benefits for bacteriologic eradication and clinical success with a 60 mg/kg dose of azithromycin when compared with comparator antibiotics (with variable doses) over 10 days in children, but not in adults. Many of the comparator antibiotics were penicillin, but they also included erythromycin, clarithromycin, amoxicillin-clavulanate, ceflacor and roxithromycin. The outcomes were reported at variable follow-up times, from three days to 25 days, few studies were blinded and they were mostly of poor quality. Substantial heterogeneity in the analyses means that we should treat these findings with caution. Trials with non-inferiority designs confirmed that different doses of azithromycin in adults and adolescents and amoxicillin in children and adolescents were comparable. Outcomes were also comparable in three trials comparing different doses and delivery methods of amoxicillin when compared with penicillin in children. Where treatments appear to be comparable, choice of treatment for GAS throat infection should consider other factors such as cost, potential for resistance, compliance and convenience. Antibiotic duration Research question: What is the optimal duration of antibiotic therapy for GAS throat infection? Body of evidence Systematic reviews Five systematic reviews were identified that had compared different durations of antibiotic therapies for the treatment of GAS throat infection: two systematic reviews were identified that were considered to be of good quality80, 81 two systematic reviews were identified that were considered to be of mixed quality72, 82 one systematic review was considered to be of poor quality.77 Primary studies Three randomised trials were identified that that had compared different durations of antibiotic therapies for the treatment of GAS throat infection. All of the identified randomised trials were considered to be of mixed quality.75, 76, 83 Management of Streptococcal A Sore Throat 60 Summary of findings Bacteriological success/failure (Microbial eradication) Bacteriological success/failure was reported in five systematic reviews and three randomised trials. Short-course oral antibiotic therapy (5 to 7 days) was associated with inferior microbial eradication rates compared with long course (10 day) oral antibiotic therapy in a metaanalysis of 11 RCTs.81 The same effect was also observed in six RCTs (n=1258) involving mainly children or adolescents <18 years. Microbial eradication was significantly less likely for short-course regimens (OR 0.63, 95%CI 0.40 to 0.98).81 Altamimi et al reported no statistically significant differences between orally administered short- (3 to 6 days) and long-course (10 day) antibiotic regimens for early bacteriological failure (within two days after completion of therapy) in a meta-analysis of 20 RCTs (OR 1.08, 95%CI 0.97 to 1.20).80 The authors concluded that the efficacy of short- and long-course antibiotics were comparable. However, short-course regimens may be satisfactory in countries with low rates of rheumatic fever, but in countries where there is a high prevalence of rheumatic heart disease the results should be interpreted with caution.80 Pichichero and Casey conducted a meta-analysis comparing four or five days of oral antibiotics with 10 day oral antibiotic regimens in Europe and the USA. 72 There were no overall pooled data. Nine trials (n=3175) in Europe (OR 1.30, 95%CI 1.03 to 1.64, p=0.03) favoured the short-course regimen for bacterial success. Three USA trials also favoured the short-course regimen (OR 2.41, 95%CI 1.76 to 3.30, p<0.00001) of five days versus 10 days. Bacterial eradication was also found to be more pronounced in paediatric trials compared to adult trials.72 Casey and Pichichero reported on bacteriological success in a meta-analysis of 14 paediatric and five adult trials administering three to five days of oral antibiotics (shortcourse) compared with ten days of oral antibiotics (long-course).77 Overall there was no statistically significant difference between short-course and long-course groups for bacterial success rate (OR 0.97, 95%CI 0.44 to 2.14). Sub-group analysis examining differences between three day versus ten day regimens found no statistical differences between the regimens (OR 0.62, 95%CI 0.30 to 1.27, p=0.19). For five days versus 10 day regimens the bacterial success rate was significantly higher in the short-course (five day) regimen (OR 4.37, 95%CI 1.70 to 11.27, p=0.002).77 In the adult trials, there was no inferiority of short-course (three day) regimens compared with long-course (10 day) regimens (OR 1.87, 95%CI 0.81 to 4.27). Bacterial success rate was significantly higher in the long-course regimen compared with the five day regimen (OR 0.41, 95%CI 0.22 to 0.78, p=0.006).77 The same authors found no benefit of short-course (4 to 5) oral antibiotic regimens over long-course (10 day regimens) in a meta-analysis of macrolides and cephalosporin.82 Sakata identified no statistically significant differences between orally administered short-course (five days) and long-course (10 day) antibiotic regimens in early Management of Streptococcal A Sore Throat 61 bacteriological success as reported at three days after completion of the therapy (93.8% for short-course and 92.8% for long-course).83 Rimoin et al compared a 10 day oral antibiotic regimen with a single dose intramuscular antibiotic therapy in Croatia and Egypt.76 There was no pooled analysis of the data. Bacteriological treatment success varied between the two countries. In Croatia there were no differences between the two regimens based on age or gender. In Egypt, the 10 day oral antibiotic regimen was found to be inferior to intra-muscular antibiotic therapy after controlling for age and gender (-15.1% difference, 95%CI -26.6 to 3.5). Eradication of GAS bacteria at 14 to 18 days after treatment was commenced was 65.3% in the short-course (seven days) regimen (n=202) and 68% in the long-course (10 days) regimen (n=194). There were no statistically significant differences between the intervention groups.75 At 38 to 45 days follow-up bacterial eradication was still observed in 55.4% of the short-course regimen (n=195) and 56.9% of the long course regimen (n=56.9%). There were no statistically significant differences between the intervention groups.75 Neither intervention met the criteria for ≥85% bacteriological eradication at test of cure visit.75 Overall, the evidence suggests that short-course antibiotics are at least equivalent to long-course antibiotic regimens in terms of eradication of GAS bacteria after completion of therapy. One of the systematic reviews did advise caution in the use of short-course antibiotic therapy in regions where RHD had a high prevalence. Clinical success/failure (microbial eradication and complete or substantial resolution of symptoms) Clinical success/failure was reported in five systematic reviews and two randomised trials. Clinical success was significantly less likely in the short-course (≤7 days) compared with the long-course (at least two days longer than short-course) regimens (five RCTs, n=1217; OR 0.49; 95%CI 0.25 to 0.96).81 Early clinical treatment failure (within two weeks of completion of therapy) was significantly lower in the short-course antibiotic regimens (OR 0.80, 95%CI 0.67 to 0.94; p=0.0078) as reported in a meta-analysis of 19 RCTs.80 There was no statistically-significant difference between short- and long-course antibiotic regimens for late clinical recurrence (beyond two weeks from completion of therapy) in a metaanalysis of 13 RCTs (OR 0.95, 95%CI 0.83 to 1.08).80 Clinical success rates reported by Pichichero and Casey reflected bacteriologic success rates. There were significant differences favouring shorter regimens in a metaanalysis of five European paediatric trials (p=0.006) and one USA trial (p=0.05).72 There were no statistically significant differences between short-course (three or five days) and long-course (10 days) oral antibiotic regimens in adults for clinical success (3 days, OR 0.56, 95%CI 0.22 to 1.46, p=0.23 vs. five days, OR 1.53, 95%CI 0.69 to Management of Streptococcal A Sore Throat 62 3.38, p=0.29).77 In paediatric trials there were no differences between three day and 10 day regimens (OR 1.04, 95%CI 0.51 to 2.13, p= 0.91). For five days versus 10 day regimens; the clinical cure rate was found to be significantly higher in the five day course compared with 10 day oral antibiotic therapy (OR 6.80, 95%CI 3.30 to 14.01, p<0.0001)77. Casey and Pichichero also reported an inferior result for short duration (4 to 5 days) compared with long duration (10 days) oral penicillin regimens in terms of clinical success rates.82 Sakata reported 100% clinical success at three days for both five and 10 day courses of antibiotics.83 Pichichero et al reported clinical success (resolution of signs/symptoms and no new signs/symptoms) in 86.1% of the short-course (seven day) regimen and 91.9% of the long-course (10 day) regimen. There were no statistically significant differences between the intervention groups.75 Overall, the evidence indicates that short-course antibiotics are at least equivalent to long-course antibiotics for clinical success rates. The exception is for penicillin, for which a long-course (10 day) regimen would be advised. Bacteriological relapse Bacterial relapse was reported in one systematic review and one randomised control trial. A meta-analysis found no statistically significant differences in this outcome between short- (≤7 days) or long-course (at least two days longer than short-course) antibiotic regimens (five RCTs, n=981; OR 1.74; 95%CI 0.88 to 3.46).81 Sakata also reported no statistically significant differences in relapse after treatment between five day, shortcourse (1.3%) and 10 day, long-course (3.45%) antibiotic regimens.83 The evidence indicates that there is no difference in bacteriological relapse between short- and long-course antibiotic therapy. Bacteriological recurrence Bacteriological recurrence was reported in two systematic reviews. A meta-analysis found bacteriological recurrence was significantly more likely in shortcourse (≤7 days) regimens compared with long-course (at least two days longer than short-course) regimens (three RCTs, n=698; OR 3.02, 95%CI 1.06 to 8.56).81 Altamimi et al also reported that later bacteriological recurrence (beyond two weeks of completion of therapy) was significantly worse in short-course regimens (OR 1.31, 95%CI 1.16 to 1.48, p=0.00002, I2 74%), although significant heterogeneity was observed. Subgroup analysis removing low dose azithromycin (10 mg/kg) resulted in no statistically significant differences between short-and long-course antibiotic regimens (OR 1.06, 95%CI 0.92 to 1.22).80 Management of Streptococcal A Sore Throat 63 For those studies that had explored long-term outcomes, bacteriological recurrence was found to be more likely to occur following short-course antibiotic therapy. Compliance Compliance was reported in two systematic reviews and two randomised trials. In a meta-analysis of five RCTs, Altamimi et al reported that compliance was significantly higher in the orally administered short-course (3 to 6 days) compared with long-course (10 days) antibiotic regimens (OR 0.21, 95%CI 0.16 to 0.29, p <0.00001, I2=72%), although significant heterogeneity was observed.80 Casey and Pichichero reported overall compliance in 16 trials that also favoured short-course regimens (OR 3.10, 95%CI 2.22 to 4.32, p < 0.00001).82 Compliance to a 10 day oral antibiotic regimen varied between the two study sites in a randomised trial reported by Rimoin et al. In Croatia compliance was 84.4% and in Egypt compliance was 30.1%. Compliance with a single dose intra-muscular administration of antibiotics was 100%. The authors concluded that in areas where compliance may be an issue, a single dose of intra-muscularly administered antibiotic therapy may be a preferable treatment for GAS throat infection.76 Pichichero et al compared a seven day (short-course) oral antibiotic (in a sprinkle formulation) with a10 day oral antibiotic regimen (long-course).75 In the intention-totreat/safety analysis 100% compliance in the first three days was achieved in 97.2% in the short-course regimen (n=284) and 83.7% in the long-course regimen (n= 282). Over the whole study period 80% compliance was achieved by 95.4% in the shortcourse regimen and 90.4% in the long-course regimen.75 Overall, the evidence suggests that compliance rates are higher with short-course regimens and 100% compliance can be achieved through intra-muscular administration. Expert advisory group discussion The group discussed amoxicillin and penicillin V in terms of first-choice intervention. Once daily amoxicillin is the first choice for antibiotic treatment for a GAS throat infection. Studies comparing amoxicillin with penicillin V report comparable outcomes. Amoxicillin is likely to achieve better compliance because of its daily dosing and ability to be taken with food compared with penicillin V’s more frequent dosing and the requirement to take it on an empty stomach (see Table 3.14). There was also discussion around the dosing of amoxicillin and some felt this should be updated based on reviews and guidelines from the USA. The group also agreed that IM penicillin was acceptable in situations of poor compliance but would likely not be good as a standard treatment because children are unlikely to report that they have a sore throat if the outcome is an injection. Management of Streptococcal A Sore Throat 64 There was discussion about inclusion of a Cochrane review comparing azithromycin with amoxicillin. This Cochrane review did not meet the inclusion criteria because it was in patients with lower respiratory tract infection (no mention of GAS) and also because the majority of included studies were conducted in adults. There was also discussion of emm typing; some group members felt studies that did not complete emm typing were flawed as any relapse or recurrence events may be due to different emm proteins. The group discussed erythromycin and agreed that is should be reviewed by PHARMAC and replaced with something that has fewer side effects and improves compliance (for example, roxithromycin). Management of Streptococcal A Sore Throat 65 Table 3.14 Routine antibiotics Antibiotic Dose Duration Amoxycillin Weight <30kg: 750 mg once daily Weight >30kg: 1500 mg once daily 10 days Penicillin V Children: 20 mg/kg/day 2–3 times/day (max 500 mg (250 mg) 3 times/day) Adults: 500 mg twice daily On empty stomach 10 days Benzathine penicillin G Children <20 kg: 600,000U Adults and children >20 kg: 1,200,000U Single dose Erythromycin Children: 40 mg/kg/day in 2 to 4 divided doses (max 1 g/day) Adults: 400 mg twice daily 10 days Delaying antibiotic treatment Research question: When should antibiotic therapy be administered in children or adults with GAS to prevent progression to rheumatic fever, reduce likelihood of antibiotic resistance and ensure compliance? Body of evidence Systematic reviews We identified one Cochrane systematic review of average quality. 84 Primary studies We identified four RCTs 85-88 all of which were included in the Cochrane review. None of these RCTs were appraised as they were assessed for quality and their outcomes were synthesised in the systematic review. Management of Streptococcal A Sore Throat 66 A cohort study was identified which compared persistence of positive throat culture and occurrence of rheumatic fever in participants being treated immediately with sulfadiazine, after nine days with penicillin or no treatment (control). Participants were young airmen admitted to hospital.89 Review findings The systematic review compared delayed antibiotic therapy (defined as therapy initiated more than 48 hours after consultation) with immediate antibiotic therapy (defined as therapy initiated at the time of consultation) in people with acute respiratory tract infections (ARTI). Where possible, subgroup analysis was undertaken according to type of ARTI: sore throat, acute otitis media, cough or common cold. Primary outcomes were clinical symptoms (relief of GAS symptoms), antibiotic use, patient satisfaction (as these are all patient-oriented outcomes); secondary outcomes included adverse effects, complications of disease, re-consultation and use of alternative therapies.84 The systematic review identified four studies which assessed outcomes in a subgroup of participants with sore throat. Outcomes were measured on day three and day seven. Small differences were found in the reduction of GAS symptoms (pain, malaise or fever) for immediate as compared with delayed antibiotics in some trials but results were not consistent and no definitive conclusions could be reached. When all trials were pooled together (all ARTI participants), there was no evidence of differences in safety outcomes between treatments. When all trials were pooled together (all ARTI participants), significantly less antibiotic use was found with delayed treatment when compared with immediate treatment and patient satisfaction was significantly greater with immediate compared with delayed treatment. Re-consultation rate, recurrence, relapse and incidence of rheumatic fever and other complications was not measured. The individual RCTs within the systematic review assessed other outcomes which were not included in the systematic review. Two double blind RCTs 85, 88 and one trial without blinding86 also assessed rates of recurrence and relapse. Relapse was defined as a positive throat culture and symptoms suggestive of GAS throat infection at the three week visit. Early recurrence was defined as any recurrence (signs and symptoms of GAS throat infection and a positive throat culture) within one month following a three week follow-up negative culture, and late recurrence was defined as any recurrence after one month following a three week follow-up negative culture. El Daher et al (n=306)85 found a reduced relapse rate with delayed treatment compared with immediate treatment (2% vs. 7%, p=0.04), reduced early recurrence (5% vs. 16%, p=0.006) and reduced late recurrence (3% vs. 13%, p=0.009). Pichichero et al (n=142)88 found a reduced late recurrence rate (2% vs. 14%) and reduced combined early and late recurrence rate (16% vs. 37%) with delayed treatment compared to immediate treatment, but found no evidence of a difference in relapse or early recurrence rates. By contrast, Gerber et al86 found no evidence of a difference in positive follow-up throat cultures, recurrences (14% vs. 12%) or new acquisitions (27% vs. 24%) between treatments at various time points: 4 days to 2 months, 2 to 4 months, 4 to 5 months. The inconsistency in rates of relapse and/or recurrence could be as a result of lack of serotyping data on the strains of GAS throat infection isolated. Both El- Management of Streptococcal A Sore Throat 67 Daher et al85 and Pichichero et al88 did not perform serotyping on GAS throat infection isolates and thus they could not make the distinction between recurrences and new acquisitions with different strains. Thus, it is not possible to reach definitive conclusions on rates of relapse and/or recurrence as a result of delaying antibiotic treatment. The 1954 RCT compared treatment failure (persistence of positive throat culture) and incidence of rheumatic fever in groups receiving penicillin on days nine, 11 and 13 after the onset of hospitalisation for tonsillitis or pharyngitis, sulfadiazine at the time of admission to hospital and placebo (control).89 Treatment failure was measured on day nine (penicillin: 94%; sulfadiazine 71%; control 95%), day 13 (penicillin: 1%; sulfadiazine 88%; control 96%), day 21 (penicillin 9%; sulfadiazine 81%; control 85%) and day 35 (penicillin 9%; sulfadiazine 59%; control 64%). Participants taking penicillin appeared to have reduced rates of treatment failure after treatment was started compared to other groups, although no statistical testing was performed. Incidence of rheumatic fever was measured from onset of pharyngitis to onset of illness. On day nine, there appeared to be similar rates between groups (penicillin: 1.2%; sulfadiazine: 0.9%; control: 1.4%). Incidence between days nine and days 45 were as follows: penicillin 0.7%; sulfadiazine 5.2%; control 3.6%. The authors concluded that treatment of GAS with penicillin nine days after the onset of illness was effective in bacteriologic eradication and significantly reduced the rate of rheumatic fever. 89 However, no direct comparison was made with patients having immediate antibiotic therapy. Summary of findings When comparing immediate with delayed antibiotic therapy for GAS, immediate therapy appears to be more effective in reducing GAS symptoms when compared to therapy that has been delayed for at least 48 hours. With regards to preventing relapse and/or recurrence, the limited evidence is inconsistent and no definitive conclusions can be reached. There is no direct evidence to determine whether incidence of rheumatic fever is influenced by the timing of antibiotic therapy and likelihood of antibiotic resistance and compliance have not been studied. Expert advisory group discussion The group discussed the lack of evidence for delaying antibiotic treatment based on the studies presented in the review. Discussion focussed on the fact that one study conducted in 1954, which suggested that patients were effectively treated after nine days, did not make the correct comparisons to draw this conclusion. The group agreed that there is no evidence to support a delay in treatment. Some group members referred to a RCT published by Lennon et al where anecdotal evidence showed that some children developed ARF at four days. There was disagreement around the use of the data in this study to support a recommendation due to the lack of direct comparisons and lack of statistical significance. Management of Streptococcal A Sore Throat 68 There was also discussion of emm typing; some group members felt studies that did not complete emm typing were flawed as any relapse or recurrence events may be due to different emm proteins. Management of Streptococcal A Sore Throat 69 4 Asymptomatic GAS infection This chapter addresses the prevalence of asymptomatic Group A Streptococcus (GAS) throat infection in the community. It also addresses whether there is any relationship between the rate of asymptomatic carriage of GAS throat infection and rates of rheumatic fever. Studies published between 2005 and the present were identified. As stated in the methodology these questions were not answered using a systematic review given that the literature in relation to this area of research is primarily epidemiological and observational in nature. 4.1 Prevalence of GAS sore throat Research question: At what rate does asymptomatic GAS throat infection occur in the community? Body of evidence Systematic reviews One meta-analysis was identified that was considered to be of mixed quality.90 Primary studies Fifteen epidemiological studies addressing the prevalence of asymptomatic GAS in healthy populations were identified.91-106 These studies were summarised but were not appraised with a formal appraisal tool due to their study design (see Table 4.1). Summary of findings The meta-analysis was of 18 studies of asymptomatic children with no signs or symptoms of pharyngitis.90 No details were provided on the study designs and there was significant (p<0.001), unexplained, statistical heterogeneity. The prevalence of carriage of GAS was lower in pre-school children (<5 years). For all children the prevalence rate was 12% (95%CI 9 to 14%) in 18 studies of 9662 children, age range 0.5 to 18 years. For children < 5 years the prevalence was 3.8% (95%CI 1 to 7%) in 4 studies of 1036 children. One study reported on adults 97 and one study did not specify the ages of the population.93 The remaining studies reported on the incidence of asymptomatic GAS throat infection in children. The ages of the children ranged from >094 to 16 years.103 Almost all of the studies reporting on asymptomatic GAS throat infection in children recruited the populations from schools. The exceptions were Dhakal et al94 who recruited children attending as in-patients or out-patients in a medical centre, Kohler et al99 recruited children attending community centres for screening and Sevinc and Enoz 104 recruited children attending day care centres. Management of Streptococcal A Sore Throat 70 Data were reported from 10 different countries, Hawaii,96 American Samoa,96 Nepal,95, 103 Fiji,107 India,92, 94, 100, 101 Micronesia,99 Korea,98 China,93 Turkey97, 104, 106 and Ethiopia.91 The prevalence of asymptomatic GAS throat infection ranged from 1.3% (defined in the study as carriers), in a Northern Indian study of 3591 healthy schoolchildren (aged 5 to 15 years)100 to 22.9% in a study of 266 healthy school children in Korea (aged 7 to 12 years).98 In adults the asymptomatic GAS rate in a Turkish population was reported as 5.6% by Gϋçlϋ et al.97 Refer to Table 4.1 for further details. Table 4.1 Prevalence of asymptomatic GAS throat infection in the community Reference Country Year data relates to SYSTEMATIC REVIEW Shaikh et Spain, Korea, Not al90 Iran, Turkey, stated United States, Canada, Sw eden, Australia, Kuw ait and India EPIDEMIOLOGICAL STUDIES Erdem et Oahu, Haw aii 2003 al96 Num ber of participants Source of population Age range Asym ptomatic GAS infection rate 18 studies Clinics, schools and emergency departments <5 years Overall 3.8% 12% 955 13 schools representing a cross section of ethnicity and socioeconomic groups 5 to 15 years 3.4% 11 schools from Oahu, in Haw aii and 2 schools from Pago Pago in American Samoa Schools (number not stated) in Pokhara, Nepal 5 to 15 years 13% 5 to 8 years 9 to 12 years 13 to 16 years Overall 5 to 8 years 9 to 12 years 13 to 15 years Overall 5 to 9 years 10 to 14 years Overall >0 to 3 years 4 to 6 years 7 to 9 years 10 to 12 years Overall 5 to 15 years 11.8% 7.8% 8.2% 9.2% 10.9% 12% 9.6% 10.9% 7.8% 4.1% 6.0% 3.8% NA 5.6% 8% 4.5% 1.3% 5 to 17 years 8.4% Pago Pago, American Samoa Nepal 2006 106 2008 487 Dumre et al95 Nepal 2007 350 Four schools at different locations in the Kathmandu valley Steer et al107 Fiji 2006 665 Four schools in Fiji representing urban and rural populations Dhakal et al94 India 2007 200 Children attending as in-patients or out-patients at the Jaw aharial Institute of Postgraduate Medical Education and Research. Kumar et al100 Lloyd et al101 India 2000 to 2002 2004 3591 Schools in 25 to 257 villages in Haryana District, Northern India Schools in five locations in Chennai, India to try and represent different residential areas Rijal et al103 India 1173 Management of Streptococcal A Sore Throat 71 Reference Country Year data relates to EPIDEMIOLOGICAL STUDIES Bramhachari India 2006 to et al92 2008 Kohler et al99 Micronesia 2009 Kim and Lee98 Korea Chang et al93 China Sevinc and Enoz 104 Yildirim et al106 Gϋçlϋ et al97 Turkey Abdissa et al91 Ethiopia Turkey Turkey Num ber of participants Source of population Age range Asym ptomatic GAS infection rate 1504 Seven municipal schools in Mumbai, India Children presenting to community centres for screening. Elementary schools (number not stated) in Seoul, Korea School children in Beijing and Chonqing in China. No other details 13 Day care centres 5 to 15 years 1.5% 5 to 15 years 12.4% 7 to 12 years 22.9% Not stated 2.3% 1 to 7 years 2.4% A primary school in Dϋzce, Turkey Medical students attending Ducze University in Turkey 6 to 14 years 6% Adults (age range not specified) 6 to 14 years 5.6% 667 Not stated 2007 to 2008 266 2003 to 2005 Not stated Not stated 1893 2004 to 2005 937 4087 484 179 Seven schools in three cities in Ethiopia. 8.7% Expert advisory group discussion The group discussed the importance of prevalence measures in terms of asymptomatic carriage rates and agreed that if an intervention was planned, then all children should be swabbed pre-and post-intervention to establish a rate. Relationship between prevalence of asymptomatic GAS throat infection and rheumatic fever Research questions: This section answered two research questions. Does asymptomatic GAS throat infection occur at a higher rate in communities with higher rates of rheumatic fever? Is there an association between the carriage rate and rate of rheumatic fever in communities? Body of evidence Systematic reviews Two systematic reviews of multi-country epidemiological data relating to the prevalence of asymptomatic GAS and rheumatic fever were identified, and both were considered to be of good quality.18, 108 Management of Streptococcal A Sore Throat 72 Primary studies Ten studies reported on asymptomatic GAS rates 91, 92, 94-96, 99-101, 103, 107 and six studies reported multi-country rheumatic fever rates from the same countries.91, 96, 99, 102, 107, 109, 110 These studies were summarised but were not appraised with a formal appraisal tool due to their study design (see Appendix 1). Summary of findings Data on the incidence of rheumatic fever were more widely published than data on the prevalence of asymptomatic GAS throat infection. There was a lack of published evidence that matched the incidence of rheumatic fever and the prevalence of asymptomatic GAS throat infection in the same country. We attempted to match the incidence of rheumatic fever in the countries for which asymptomatic GAS throat infection had been identified (Table 4.2). There was no published incidence data for rheumatic fever identified for Turkey, Korea or China. Only two studies were identified that reported both asymptomatic GAS throat infection rates and rheumatic fever rates within the same country. 91, 99 Kohler reported on 667 school children, aged five to 15 years from Micronesia. The prevalence of asymptomatic GAS was reported as 12.4% and the incidence of rheumatic fever in Micronesia ranged between 50 and 134/100,000 population.99 In the second study, Abdissa reported an asymptomatic GAS rate in 937 school children in Ethiopia, aged six to 14 years, of 8.7%. The rheumatic fever incidence rate for children (age not specified) was 4.6 to 7.1/1000.91 For a further eight studies of asymptomatic GAS prevalence, data for rheumatic fever incidence rates were identified. It should be noted that the years for which the data were reported do not necessarily coincide. Five countries had asymptomatic GAS prevalence rates of less than 10% (Ethiopia, Hawaii, India, Fiji and Nepal) and three countries had rates greater than 10%. There was no obvious relationship between the two rates. The incidence rates of rheumatic fever varied, even when reported in the same country over similar time frames and similar age groups (Fiji, India) and data were often reported as ranges rather than averages. Based on the available published evidence it is not possible to draw any inference between asymptomatic GAS throat infection prevalence and rheumatic fever incidence. Management of Streptococcal A Sore Throat 73 Table 4.2 Relationship between GAS throat infection rate and rheumatic fever by country Country Oahu, Haw aii Reference Year data relates to Age range GAS throat infection Erdem et al96 2003 GAS throat infection rate 3.4% 2006 Reference Year data relates to Age range Rheumatic fever rate Rheum atic fever Jackson et 2003 and al108 2006 5 to 15 years Pacific Islander 9.5 to 12.4/ 100,000 13% American Samoa Micronesia Kohler et al99 2009 5 to 15 years 12.4% Kohler et al99 2009 5 to 15 years 50 to134/ 100,000 India Dhakal et al94 2007 >0 to 12 years 4.5% Jackson et al108 2003 and 2006 5 to 15 years 54/100,000 2000 to 2002 5 to 15 years 1.3% Tibazarwa et al18 1988 to 1991 Kumar et al100 51/100,000 5 to 18 years Lloyd et al101 2004 Bramhachari et al92 8.4% 2006 to 2008 5 to 17 years 1.5% Fiji Steer et al107 2006 5 to 15 years 5 to 14 years 6.0% Parks et al102 Cuboni et al109 2003 to 2008 4 to 20 years 24.9/ 100,000 1996 to 2000 2.3/100,000 All ages 2005 to 2007 Steer et al107 9.8/100,000 5 to 14 years 15.2/100,000 Nepal Rijal et al103 2008 5 to 16 years 9.2% Limbu and Maskey 110 Not stated Abdissa et al91 2004 to 2005 Dumre et al95 2007 10.9% 5 to 15 years School children (ages not specified) 1.2 to 1.3/ 1000 5 to 15 years Ethiopia Abdissa et al91 2004 to 2005 6 to 14 years 8.7% Children (age not specified) Management of Streptococcal A Sore Throat 4.6 to 7.1/ 1000 74 5 Community swabbing This chapter addresses what constitutes an outbreak of ARF. It also considers whether swabbing for GAS throat infection in asymptomatic community members following an outbreak impacts on rates of ARF. These questions have been scoped broadly in terms of outbreaks (ARF, GAS, GAS-induced invasive disease), population (contacts including family members, school, residential community, workplace) and outcomes (ARF, eradication of GAS). Note that consideration of swabbing asymptomatic contacts does not relate to the well-established approach of prophylactic treatment of people with a history of ARF (known as secondary prevention) although such people may be swabbed in an outbreak of ARF. As these questions are informed by research published over several decades, no date restriction was applied to searching. The questions were addressed narratively, drawing on epidemiological sources and published accounts of attempts to manage outbreaks, with an emphasis on those occurring in the developed world. Rheumatic fever outbreaks Research question: What defines an outbreak of Rheumatic Fever? Body of evidence Factors associated with an outbreak Outbreaks of ARF have been described from widely separated areas of the world, and continue to be rampant in the developing world. It also persists in socially and economically disadvantaged subpopulations within developed countries, including indigenous Māori and Pacific Islanders descendant in New Zealand and indigenous Aborigines in Australia. In addition, there have been several outbreaks in the developed world in closed or semi-closed environments including warships, nursing homes, military centres, youth detention centres, child care centres, and specific geographical areas. Acute rheumatic fever was a major problem in the USA until the 1960s, then largely disappeared as a major cause of illness, arguably due to improved socioeconomic status, reduced crowding, the advent of antibiotics, and the widespread treatment of streptococcal throat infections.111 A resurgence of rheumatic fever occurred in the mid1980s among children in less crowded communities, middle-class suburbs, and people with good access to health care, such as areas of Utah and Ohio in the USA, and training centres for the Armed Forces. This is in stark contrast with the developing world where socioeconomic issues are thought to be responsible for rheumatic fever outbreaks.111 Management of Streptococcal A Sore Throat 75 These temporally-related but geographically separated outbreaks of acute rheumatic fever in the USA cannot be explained by host factors alone and it has been suggested that the infecting streptococci are somehow unique.112 Group A streptococci are highly transmissible and spread rapidly in families and communities, with the predominant M types are constantly changing. However in reports of the outbreaks, including those in the US in the 1980s, only a limited number of streptococcal M serotypes were obtained from the throat cultures of children in affected communities.113 It has been conjectured that if these streptococci have enhanced rheumatogenic potential, this characteristic appears not to be related simply to serotype, but is probably expressed by specific strains within several serotypes often equated with enhanced virulence.112 Determining an outbreak An outbreak of rheumatic fever can be defined epidemiologically as a significant increase in the incidence of newly diagnosed cases of acute rheumatic fever in a defined geographical area over a defined period of time.114 According to the Manual for Public Health Surveillance in New Zealand115 the threshold for reporting an outbreak may include any of the following circumstances: two or more cases linked to a common source a community-wide or person-to-person outbreak (except when the source has become well-established as a national epidemic) any other situation where outbreak investigation or control measures are undertaken or considered. Outbreak reporting is not required in New Zealand for single cases caused by a specific contaminated source, and secondary cases, with the exception of secondary cases in an institution. In 2010 there was one outbreak of rheumatic fever reported. The outbreak occurred at a school and involved two cases. In practical terms, establishing whether an outbreak has occurred is more an art than a science and several sources of information can be brought to bear on this decision. In countries where rheumatic fever is endemic such as New Zealand, it is crucial to establish whether new cases represent a significant increase over the ‘background’ rate. Other factors can be considered to determine whether an increase in case incidence is unlikely to be a chance event. An example of this process is the appearance of seven cases of invasive streptococcal disease occurring in three adjacent counties in south-eastern Minnesota caused by a single clone of invasive GAS infection.116 The authors argued that the seven cases represented an outbreak for the reasons below: cases caused by a single clone of GAS were clustered temporally and geographically the incidence rate of outbreak-associated cases within the outbreak area was substantially higher than expected Management of Streptococcal A Sore Throat 76 four of the seven outbreak-associated cases were epidemiologically linked to children attending one elementary school. The prevalence of streptococcal pharyngeal carriage of the outbreak clone was substantially higher among students attending that school than among students attending three other comparison schools outside the outbreak area. Summary of findings Defined epidemiologically, an outbreak of ARF is a significant increase in the incidence of newly diagnosed cases within a defined geographical area and over a defined time period. However, practically applying this definition requires some detective work drawing on several sources of information. These include the following: the incidence of Rheumatic Fever and GAS relative to the usual background rate, the proximity of cases geographically and socially to each other, the timing of cases, commonality of the strain of GAS infection, and pattern of contact between people who are GAS positive. Swabbing asymptomatic community members and households in areas of outbreak Research Question: Where there is an outbreak, does swabbing of asymptomatic community members and household reduce rates of rheumatic fever? In New Zealand, the existing guidelines recommend that where there are three or more cases of GAS pharyngitis confirmed within a household in a three month period, household members should be swabbed and those found positive for GAS treated with antibiotics, regardless of symptoms.28 This approach is consistent with recommendations from the Infectious Disease Society of America26 and The American Academy of Pediatrics.117 The latter does not recommend asymptomatic GAS carrier treatment except in certain situations. Those relevant to the current research question include the following: when there is an outbreak of rheumatic fever or post streptococcal glomerulonephritis when there is an outbreak of GAS in a closed or semi-closed community where there is an outbreak within families of multiple episodes of documented symptomatic GAS pharyngitis which continue to occur over a period of many weeks despite appropriate treatment. This research question concerns whether such intervention for asymptomatic members of an affected household or community is effective in reducing rates for rheumatic fever. Management of Streptococcal A Sore Throat 77 Limitations of treating symptomatic cases only Primary prevention of rheumatic fever involves treating people who have a confirmed GAS infection and who are symptomatic, usually presenting with sore throat. A recent meta-analysis of controlled studies of GAS infection treatment following sore throat found a 60% reduction in rheumatic fever (RR 0.41 [95%CI 0.23 to 0.70, p=0.001]), supporting a mixture of community and school-based programmes.118 However, relying on symptoms such as sore throat to target people for swabbing has limitations, as described in the following paragraphs. Most sore throats are viral. No microbiological test is able to differentiate between acutely infected patients and asymptomatic carriers of GAS with viral pharyngitis.26 A person may present with a sore throat, be swabbed as culture-positive for GAS and treated by antibiotics, but be unresponsive to antibiotics as their sore throat is not bacterial. Many people who develop rheumatic fever never report having a prior sore throat and therefore never seek medical attention. For example, in a study of an outbreak of rheumatic fever in the inter-mountain area of Utah,119 only 46 patients (17%) sought medical attention for a preceding sore throat. Most significantly, symptomatic household or community members may be carriers of GAS and able to infect or re-infect those around them, thus prolonging an outbreak and hampering efforts to control infection. For example, it has been suggested that a cluster of invasive streptococcal disease arising in Minnesota was related to a single virulent clone becoming prevalent among asymptomatic carriers.116 Patterns of cross-infection Group A streptococcal sore throat is highly infectious. It appears to be spread by droplets, saliva, nasal secretions, food preparation, and water and is more infectious in crowded settings.120 A systematic review120 reports on the 'ping-ponging' of infection between members of a household. Studies suggest that where a patient has been infected with GAS pharyngitis, the chance of another household member becoming infected in the ensuing month is up to one in three,121 with each household member estimated to have a 5% to 6% chance per month of contracting it from the index case.122 Given the infectious nature of GAS pharyngitis and its potentially dangerous and debilitating sequelae, it has been suggested that swabbing of members of households and communities during an outbreak of GAS and treating those with positive cultures may assist in preventing rheumatic fever. This applies to members who are symptomatic for GAS or asymptomatic. The presence of GAS in the upper respiratory tract (throat, nasal passage) may reflect either true infection or a carrier state. In either state, the patient harbours the organism, but only in the case of a true infection does the patient show a rising antibody response. In the carrier state there is no rising Management of Streptococcal A Sore Throat 78 antibody response.113 The carrier state for GAS is not clearly understood, but it has been suggested that when screened and appropriately treated with antibiotics, carriers can be prevented from spreading streptococcal infections in the community. Preventing the ping-ponging of cross infections is aimed at reducing the incidence of life-threatening sequelae including rheumatic fever. Key studies attempting to control outbreaks of rheumatic fever or eradicate GAS to prevent rheumatic fever are discussed below. Early studies In the early 1950s, entire regiments of US navy recruits were given courses of oral prophylactic penicillin 123 aimed to prevent rheumatic fever. Following the administration of 500,000U of penicillin per day there were no new cases of streptococcal infection, with a marked reduction in the proportion of men carrying GAS in the throat, and no more cases of ARF. However concerns about increased resistance to antibiotics, and the resources and practical barriers associated with such intensive approaches led to calls to investigate more targeted approaches. In the late 1950s, a trial 124 was conducted of an intensive approach to managing GAS infection in three Philadelphian schools. Over the school year, monthly throat swabs were obtained from each child, from children upon presentation with upper respiratory infections, and from family contacts of all positive cases. In one school, penicillin was given to all positive cases (children and family members), whether GAS carriers or cases with overt infections. In this small, preliminary study, the authors questioned whether such an intensive therapeutic measure was justified given the high carrier rates found generally (half the children being GAS positive at some time over the year) and low incidence of infection. The disruption from exclusion from school of all carriers was also problematic. In 1960, an epidemiologic study of GAS cross-infection was conducted of families in Cleveland, Ohio.125 Acquisition rates for GAS were highest among young schoolchildren, and were symptomatic in 40%, with no cases of rheumatic fever. Schoolchildren most commonly introduced a GAS into the family unit – six times as frequently as their parents. The GAS carrier rate was 25% in families when the index carrier was symptomatic but was only 9% when the index case was an asymptomatic carrier. Three and four year olds had the highest risk of becoming secondary carriers (50%). The spread of streptococci in the family unit often occurred quite slowly, and the carrier state frequently persisted for a long time. The authors concluded that it is desirable to administer penicillin to all members of a family once an initial streptococcal illness is recognised. Management of Streptococcal A Sore Throat 79 Junior detention centre An epidemic of streptococcal infection (40%) was the subject of intervention in a closed community, junior detention centre in the north of England in the mid-1970s 126. The centre received 15 to 17 year old boys for six to eight week periods, reflecting a changing population of adolescent boys from relatively socially-deprived backgrounds. Throats were swabbed for GAS upon entry (4% carrier rate). In an early phase of intervention, symptomatic cases and carriers were given a course of penicillin. The carriage-rate for GAS was reduced from 31.0% to 13.4% over several months, however concerns about persistently high rates of acute tonsillitis (21%) and an outbreak of rheumatic fever (three cases in two years) led to a new prophylaxis phase being implemented. In this phase, penicillin was instituted for all boys on admission to the centre (0.25 g orally four times per day for 10 days) before GAS status was known. The attack rate for acute tonsillitis fell gradually over 18 months from 21.0% to 4.7% although it was six months before any reduction occurred. The incidence of reported sore throat fell from 67% to 3.2% over two years. As there was no control group/centre without a programme it is not possible to observe the natural history of the epidemic and to ascertain the degree to which the prophylaxis intervention contributed to its management. A follow-up investigation of the same centre 127 reported that as full prophylaxis was difficult to administer and the epidemic seemed under control the intervention was ceased. High rates of acute tonsillitis (over 30%) returned almost at once and prophylaxis was recommenced for boys upon entry. Various doses were trialled over a two-year period and fixed at 0.5 g of oral penicillin once per day for 10 days (ie, instead of 0.25 g four times per day as previously). The attack rate for acute tonsillitis reduced very gradually to 2.1%. The authors suggest that rates may have been reduced more quickly if all residents had been administered the course of penicillin instead of just new admissions. Another limitation of this study is that staff or other potential contacts were not assessed or treated for GAS. Navajo Indians A three-year programme targeting ARF was administered among Navajo schoolchildren in the USA.128 Throat swabs for GAS were taken monthly from asymptomatic children, and upon presentation of a sore throat for any child, although schools participated intermittently. Antibiotic treatment of GAS positive cases and carriers was undertaken. The ARF rate in the area covered by the programme was 39% lower in the three years post-programme than the two years prior (13.5 cf 8.2 per 100,000, respectively) whereas rates in the uncovered comparison area were largely unchanged at 9.5 before and 10.1 after. However a confounding factor in the study was that there were substantially higher attack rates of ARF in the covered areas compared with the uncovered areas at baseline (13.5 cf 9.5, respectively). As the programme did not have an adequate control group, any effect on ARF incidence remains uncertain.16 Management of Streptococcal A Sore Throat 80 Child care centre in Sweden In Sweden, day child care centres (DCC) in the county of Halland (population: 240,000) were involved in an outbreak of erythromycin-resistant GAS (ERGAS) between 1984 and 1985, erythromycin being an antibiotic used for patients who are allergic to penicillin.129 This represented a localised outbreak after not having had any significant spread in the population of ERGAS before. A prevention programme was instituted in seven DCCs where ERGAS had been isolated and where there was more than one suspected case. Throat swabs were taken from all children and employees at day one. On days 5 to 7, swabs were taken from those absent on day one, from those who were culture negative on day one, and from parents and siblings of ERGAS culture-positive subjects. All subjects with positive swabs were treated with antibiotics and were then followed up at days 21 to 33 and retreated if still ERGAS-positive. Half (49%, 112/230) the children attending the seven DCCs involved in the outbreak were infected with ERGAS, as well as 8% of employees (7/93), 23% of parents to ERGAS children (37/163) and 36% (22/61) of siblings to ERGAS children. In addition, 21 children also had erythromycin-sensitive GAS. It should be noted that asymptomatic ERGAS-positive children had as many ERGAS-positive relatives as symptomatic children, suggesting rates of infection were similar between cases and carriers for ERGAS. However, asymptomatic children’s relatives were less likely to be symptomatic than the relatives of symptomatic ERGAS-infected children. The authors suggest that this may be because the symptomatic children and their symptomatic relatives were more recently infected. Antibiotic treatment eradicated ERGAS in 75% of cases after an initial 10-day course and 48% of the remaining cases after a second 10-day course, leaving 13% (22/165) still ERGAS positive. A third course was also used in one town where the outbreak began. Treatment compliance was not assessed. None of the ERGAS-infected patients developed clinically obvious glomerulonephritis. Over two-year follow-up, only sporadic isolations of ERGAS arose in Halland and no case of acute glomerulonephritis provoked by ERGAS was diagnosed. The authors suggest that child care centres can act as epicenters for the spread of GAS with children acting as ‘primary transmitters’, particularly as infants are known to be ‘saliva promiscuous’. This study suggests that where a virulent strain has been identified in a community, particularly one involving close contact of children, and where an intervention is practical, an intensive prophylaxis programme of swabbing close community and family contacts can be successfully managed. However it should be cautioned that there was no comparison observation of the natural history of the infection without an intervention programme, or a control population observed without swabbing of asymptomatic contacts. Therefore what specific effect the programme, or aspects of it, had on the outcomes cannot be clearly quantified. Management of Streptococcal A Sore Throat 81 Nursing home Following nine outbreaks of GAS in nursing homes in Atlanta over two years, an investigation was performed of one outbreak in the winter of 1989/1990.130 Over a sixweek period, 20% (16/80) of residents and 7% (3/45) of staff, were infected with GAS. Eleven of the residents developed invasive disease and four died. Matched casecontrol and retrospective cohort studies were performed to determine risk factors for infection. Strong spatial clustering of cases was observed with having a roommate with prior infection the most important risk factor. No evidence was found for commonsource transmission of infection. Following improved infection control practices and administration of prophylactic antimicrobials to all residents and staff, no further cases occurred. The authors conclude that in such an outbreak of a virulent GAS strain, adherence to infection control can prevent or control GAS outbreaks. They further suggest that prophylactic antimicrobials may be an effective adjunct to control severe or ongoing outbreaks. A limitation of this study is that it is not possible to determine the relative contribution of infection control practices versus prophylactic antimicrobials in the management of this outbreak. Summary of findings Several studies were identified that were published since the 1950s describing attempts to manage outbreaks of GAS rheumatic fever through an intensive prophylaxis programme of swabbing close community and/or household contacts. Studies varied across factors including location, settings, population, background infection and disease rates, strains of GAS, swabbing and GAS confirmation techniques, treatment approaches, compliance and ability to control compliance, and follow-up. Despite these variations, results are largely consistent. They suggest that programmes which swab and treat GAS-positive carriers and cases are associated with reductions in GAS infection rates and potentially rates of rheumatic fever, although these were too small to be statistically tested. Epidemiological studies also support the ability of carriers as well as cases to infect contacts with GAS, though it appears that symptomatic cases are more likely to arise after contact with symptomatic index cases. Limitations of the evidence base include that whilst some studies had the ultimate aim of reducing incidence of rheumatic fever, study samples were too small to investigate rheumatic fever rates as a primary outcome. Further, most studies were uncontrolled making it difficult to isolate the contribution to reductions in infection and GAS-sequelae of swabbing of asymptomatic carriers, as well as cases versus swabbing cases alone. An exception was the small study (80 residents) based in a nursing home130 where a case control design was employed. Prophylactic treatment of cases and carriers for GAS requires practical and financial resources, cooperation from participants and their community contacts, as well as the careful administration and monitoring by programme staff to ensure good programme fidelity and compliance with treatment. Such well-coordinated primary prevention programmes may be less likely to be practical, affordable and cost-effective in developing countries or larger communities.16 However, at least in the developed world, Management of Streptococcal A Sore Throat 82 the investment of resources is more likely to be cost-effective when dealing with severe or persistent outbreaks of virulent strains within a household or community, and within closed or semi-closed communities such as schools or nursing homes following an outbreak of GAS. Given the small number and methodological limitations of the studies considered here, there is limited evidence. It is suggested that approaches involving prophylaxis of carriers for GAS are likely to be most effective when applied in closed or semi-closed communities where severe or persistent outbreaks of new virulent strains of GAS occur or within households where an outbreak has occurred. Management of Streptococcal A Sore Throat 83 Appendix 1: Methods This appendix describes the process undertaken by NZGG to determine the research questions and review the evidence. Contributors Expert Advisory Group Jim Vause New Zealand College of General Practitioners Norman Sharpe National Heart Foundation Louisa Ryan Pacific Health Manager, National Heart Foundation Lance O’Sullivan New Zealand College of General Practitioners Jim Miller NZ College of Public Health Medicine Phil Shoemack NZ College of Public Health Medicine Dianna Lennon Royal Australasian College of Physicians David Jensen Te Ohu Rata o Aotearoa: Maori Medical Practitioners Association Elizabeth Farrell KidzFirst, CMDHB Maxine Shortland Ngati Hine Health Trust Helen Herbert Te Runanga o Kaikohe Teuila Percival Pasifika Medical Association Management of Streptococcal A Sore Throat 84 Melissa Kerdemelidis Primary Health Registrar Christchurch Bruce Arroll University of Auckland, Department of General Practice & Primary Health Care New Zealand Guidelines Group team Jessica Berentson-Shaw Research Manager Anita Fitzgerald Anne Lethaby Assistant Research Manager and lead researcher Researcher Catherine Coop Julie Brown Researcher Senior Researcher Marita Broadstock Margaret Paterson Senior Researcher Information Specialist Leonie Brunt Publications Manager Declarations of competing interest No competing interests were declared. Research process This section provides an overview of the research methodology utilised during the development of this evidence review. It describes how the research questions were developed and how the systematic and narrative reviews were undertaken. The evidence review aimed to cover both children and adults with GAS throat infection clinically managed within primary healthcare settings. Research questions The Ministry of Health suggested a list of questions, initially revised and then agreed to by NZGG. The questions were then circulated among a specialist group, most of whom were invited to be part of the Expert Advisory Group (EAG). Following final agreement on the research questions, the research team prepared the questions in the PICO (Patient, Intervention, Comparison, Outcome) format to ensure effective and focused searches and reviews could be undertaken. Some of the research questions were able to be subject to a formal systematic review while for the remaining questions, literature reviews were undertaken. Management of Streptococcal A Sore Throat 85 Research Question PICO Type of evidence review Chapter 1 – Introduction and context 1. When do sore throats N/A occur in the natural course of Streptococcal Pharyngitis? Chapter 2 - Rapid Antigen Diagnostic Tests 2. In children and adults P: Children and Adults with sore throats with sore throats, what is Index test: RADT the accuracy of the Rapid Ref standard: culture Antigen Diagnostic Test Outcomes: Diagnostic accuracy, adverse (RADT) compared to events culture to confirm GAS? Subgroups: low and high risk kids 3. In children and adults P: Children and Adults with resolved sore presenting with a resolved throats sore what is the accuracy I (index test): RADT of the Rapid Antigen C (ref standard): culture Diagnostic Test (RADT) Outcomes: Diagnostic accuracy, adverse compared to culture to events confirm GAS? Subgroups: low and high risk kids 4. In children and adults P: Children and adults with sore throats presenting with a current I (index test): immediate RADT/culture sore throat is immediate C (ref standard): delayed RADT/culture RADT and/or Culture more O: Diagnostic accuracy, adverse events effective than delayed in Subgroups: low and high risk kids ensuring diagnostic accuracy? Chapter 3 – Antibiotic Treatment 5. What is the antibiotic of P: Children and adults with confirmed choice for treatment of GAS infection children and adults I: Antibiotics diagnosed GAS, when C: No treatment, placebo, other antibiotic should it be administered, O: Clinical and bacteriological resolution, for how long and in what recurrence, re-infection, dose, duration, dose to prevent compliance, resistance progression to rheumatic fever, reduce likelihood of antibiotic resistance and ensure compliance? Literature review. No date restriction. Systematic review of diagnostic studies. No date restriction. Systematic review of diagnostic studies. No date restriction. Systematic review of diagnostic studies. No date restriction. Systematic review of intervention studies. Date restriction: 2005 to May 2011. Management of Streptococcal A Sore Throat 86 Research Question PICO 6. In children presenting P: Children and adults with sore throats with a current sore throat is I: Immediate antibiotic treatment immediate antibiotic C: Delayed antibiotic treatment treatment compared with O: Eliminating GAS infection, progression delayed antibiotic to ARF, resistance. treatment more effective in eliminating a GAS infection and preventing progression to rheumatic fever? Chapter 4 - Asymptomatic Carriers 7. At what rate does N/A asymptomatic GAS occur in the community? 8. Does asymptomatic N/A GAS occur at a higher rate in communities with higher rates of rheumatic fever? 9. Is there an association N/A between the carriage rate and rate of rheumatic fever in communities? Chapter 5 - Community swabbing 10. What defines an N/A outbreak of rheumatic fever? 11. Where there is an N/A outbreak does swabbing of asymptotic community members and households reduce rates of rheumatic fever? Type of evidence review Systematic review of intervention studies. Date restriction: 2005 to May 2011. Literature review. No date restriction. Literature review. No date restriction. Literature review. No date restriction. Literature review. Literature review. Reviewing the literature Search strategy Search strategies for most research questions were conducted without restrictions on date. The questions regarding antibiotics (Chapter 3) were limited to 2005 onwards because existing good quality systematic reviews covered the studies published prior to 2005. Searches were completed in May 2011. The NZGG research team in consultation with the Ministry of Health, set the inclusion and exclusion criteria for the searches. For the questions answered by systematic review, systematic literature searches relating to each PICO question were designed in consultation with an information specialist. For the questions answered by literature review, searches were also designed in consultation with an information specialist. Management of Streptococcal A Sore Throat 87 Studies investigating cost-effectiveness were not included. Reviewing international guidelines NZGG often includes the findings of international guidelines in research reports. For the epidemiological chapters of this report, such guidelines and their findings are referenced and described and were assessed for quality using the AGREE II tool. For the systematic review chapters of this report, it was agreed that reporting such guidelines would not be helpful. A study published in 2011 analysed the different recommendations in 12 international guidelines for the management of acute pharyngitis in children and adults.131 The study found several discrepancies in the recommendations between countries with regard to the use of rapid antigen tests, culture and the indications for antibiotic treatment. Most agreed that narrow-spectrum penicillin is the first choice of antibiotic for the treatment of streptococcal pharyngitis and that treatment should last for 10 days to eradicate the microorganism. Given the obvious differences in recommendations, and likely differences in the evidence used to make these decisions, NZGG has included only systematic reviews and comparative intervention or diagnostic studies in the systematic reviews included in this evidence review. Search databases The systematic review searches were conducted for the research questions noted above. The following bibliographic, HTA and Guideline databases were included in the search: 1. MEDLINE 2. EMBASE 3. CINAHL 4. Cochrane Library 5. Web of Science 6. DARE Database 7. HTA Database 8. CCTR 9. Current Controlled Trials (CCTR) 10. ClinicalTrials.gov 11. Web of Science The literature review searches were conducted for the research questions noted above using the same databases as for the systematic reviews. Other references (eg, text book chapters, studies referenced in bibliographies) were also included where appropriate. Management of Streptococcal A Sore Throat 88 Evidence appraisal Where literature reviews were carried out (Chapters 1, 4 and 5), comparative studies were appraised for quality and included in evidence tables. Where studies were epidemiological (or non-comparative), no formal appraisals were carried out. Where systematic reviews were carried out, the steps below were followed in appraising the evidence. Step 1: Assigning a level of evidence Following the completion of searches, retrieved studies meeting the inclusion criteria for each question were assigned a level of evidence. The level of evidence indicates how well the study eliminates bias based on its design. NZGG uses a published evidence hierarchy, designed by the National Health and Medical Research Council of Australia (NHMRC).132 The levels of evidence are presented in Table A2.1. Step 2: Appraising the quality of included studies Intervention studies Intervention study designs (systematic reviews, randomised controlled trials) that met the inclusion criteria for each research question were appraised using an adapted version of the GATE (Graphic Appraisal Tool for Epidemiology), which has been validated by NZGG researchers.133 In brief, the GATE checklists are comprised of slightly different criteria depending on the study design but all broadly address each part of the PICO framework. The case is slightly different for systematic reviews and meta-analyses where additional criteria are included to assess the appropriateness of combining and analysing multiple studies. However, in general the checklists help the researcher to assess study quality in three main areas: 1. study validity (steps made to minimise bias) 2. 3. study results (size of effect and precision) study relevance (containing applicability/generalisability). The researcher indicates whether the criteria for quality has been met (+), is unmet (x) or, where there is not enough information to make a judgment, is unknown (?) for each checklist item. Researchers then assign the same quality criteria to each of three summary sections which assess the accuracy, relevance and applicability of the findings. Here, the researcher indicates whether the study has any major flaws that could affect the validity of the findings and whether the study is relevant to clinical practice. The three summary sections include: internal validity – potential sources of bias precision of results applicability of results/external validity – relevance to key questions and clinical practice. Management of Streptococcal A Sore Throat 89 Table A2.1 Level NHMRC levels of evidence Intervention1 Diagnostic accuracy2 Aetiology3 Prognosis I4 A systematic review of level II studies A systematic review of level II studies II A randomised controlled trial A study of test accuracy with: an A prospective cohort study independent, blinded comparison with a valid reference standard,5 among non-consecutive persons with a defined clinical presentation 6 III-1 III-2 A systematic review of level II studies Screening intervention A systematic review of level II studies A systematic review of level II studies A prospective cohort study A randomised controlled trial A pseudorandomised controlled A study of test accuracy with: an All or none 8 trail (ie, alternate allocation or some independent, blinded comparison other method) with a valid reference standard,5 among non-consecutive persons with a defined clinical presentation 6 All or none 8 A pseudorandomised controlled trial (ie, alternate allocation or some other method) A comparative study with concurrent controls: A retrospective cohort study A comparative study with concurrent controls: 7 Non-randomised, experimental trial 9 A comparison with reference standard that does not meet the criteria required for Level II and III-1 evidence Analysis of prognostic factors amongst persons in a single arm of a randomised controlled trial Non-randomised, experimental trial Cohort study Cohort study Case-control study Case-control study Interrupted time series with a control group III-3 Diagnostic case-control study5 A comparative study without concurrent controls: A retrospective cohort study A case-control study Historical control study A comparative study without concurrent controls: Historical control study 10 Two or more single arm study Two or more single arm study Interrupted time series without a parallel control group IV Case series with either post-test or pre-test/post-test outcomes Study of diagnostic yield (no reference standard)11 Case series, or cohort study of A cross-sectional study or persons at different stages of case series disease Management of Streptococcal A Sore Throat 90 Case series Finally, researchers assign an overall assessment of the study quality based on a summary of the checklist criteria, these are + good; x not ok, poor; ? unclear. Scores for each of the three summary domains, and the overall score are presented as part of the evidence tables. Diagnostic studies Diagnostic accuracy studies are appraised using the QUADAS tool, an internationally recognised and validated tool.30 The QUADAS tool, developed by the NHS Centre for Reviews and Dissemination at the University of York, aims to evaluate the presence of spectrum bias, bias associated with the choice of reference standard, disease progression bias, verification bias, review bias, clinical review bias, incorporation bias, and bias associated with study withdrawals and indeterminate results. Summary scores estimating the overall quality of a diagnostic accuracy article were not applied since the interpretation of such summary scores is problematic and potentially misleading.32 Guidelines Where NZGG identified existing national and international guidelines, these were appraised for quality using the second iteration of the Appraisal of Guidelines for Research and Evaluation (AGREE II)134 instrument and are summarised at the beginning of each chapter. The AGREE II tool evaluates the process of practice guideline development and the quality of reporting. The AGREE II is the currently accepted international tool for the assessment of practice guidelines. The AGREE II is both valid and reliable and comprises 23 items organised into six quality domains. Evidence tables Following the appraisal of study quality, using the different methods above, evidence tables were developed to present the key characteristics of each of the included studies. Different forms of the template are used for each of the different study designs. Step 3: Expert discussion A one-day, face-to-face meeting was held where the EAG considered the evidence. They were unable to agree recommendations and so none are presented in this review. Instead, key points arising from the review are provided at the start of the document. Management of Streptococcal A Sore Throat 91 Appendix 2: Abbreviations and glossary Abbreviations AGREE Appraisal of Guidelines for Research and Evaluation ARF Acute rheumatic fever ARTI Acute respiratory tract infections AUC Area under the curve BID Twice a day CI Confidence interval Coeff. Coefficient DCC Day childcare centres dOR Diagnostic odds ratio EAG Expert Advisory Group ERGAS Erythromycin-resistant GAS FP False positive FN False negative 2 I Heterogeneity IM intramuscular ITT analys. Intention to treat analysis LR+ Positive likelihood ratio LR – Negative likelihood ratio MD Mean difference NHMRC National Health and Medical Research Council (Australia) NICE National Institute for Clinical and Health Excellence NNTB Number needed to benefit NNTH Number needed to harm NPV Negative predictive value NS Not significant NZGG New Zealand Guidelines Group OR Odds ratio PCR assay Polymerase chain reaction PP analys Per protocol analysis PPV Positive predictive value Prev Prevalence Q* Cochrane Q statistic QD Once a day QID Four times a day Management of Streptococcal A Sore Throat 92 RCT Randomised controlled trial rdOR Relative diagnostic odds ratio RHD Rheumatic heart disease ROC Receiver operator curve RR Relative risk Rx Therapy/treatment SE (AUC) Standard error (Area under curve) SIGN Scottish Intercollegiate Guideline Network sROC Summary receiver operator curve Std. Err. Standard error, same as SE above TP True positive TN True negative Var Variance Management of Streptococcal A Sore Throat 93 Glossary Acute rheumatic fever Disease involving inflammation of joints and damage to heart valves that follows streptococcal infection and is believed to be autoimmune Chronic Persisting over a long period of time Concurrent Occurring at the same time Heterogeneous Having a large number of variants Holistic care Care that provides for the psychological as well as the physical requirements of the individual Mana Power, respect, status Morbidity A diseased condition or state Mortality Death Noa Free from tapu or any other restriction Ora Health, life, vitality Primary care Services provided in community settings with which patients usually have first contact (eg, general practice) Prognosis A prediction of the likely outcome or course of a disease; the chance of recovery or recurrence Prognostic factors Patient or disease characteristics (eg, age and disease stage) that influence the course of the disease under study Prophylactic A medication or treatment designed and used to prevent a disease Regimen A plan or regulated course of treatment Sequential One treatment following another Systemic therapy/treatment Treatment, usually given by mouth or injection, that reaches and affects tumour cells throughout the body rather than targeting one specific area Tapu Sacred, taboo Whānau Family, community Whānau ora The health of an extended family or community of related families Management of Streptococcal A Sore Throat 94 References 1. 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