The Journal of Pain, Vol 9, No 1 (January), Supplement 1, 2008: pp S19-S30 Available online at www.sciencedirect.com An Update on the Treatment of Postherpetic Neuralgia Christopher L. Wu and Srinivasa N. Raja Department of Anesthesiology and Critical Care Medicine, The Johns Hopkins University School of Medicine, Baltimore, Maryland. Abstract: Like other types of neuropathic pain, postherpetic neuralgia (PHN) can be resistant to many types of pharmacologic and interventional therapies. Although many analgesic agents have been used for the treatment of other types of neuropathic pain, tricyclic antidepressants, antiepileptic drugs, opioids, and lidocaine patch appear to demonstrate relative analgesic efficacy for the treatment of pain from PHN. There are fewer studies on the use of interventional options for the treatment of pain from PHN. The majority of interventional therapies show equivocal analgesic efficacy although some data indicate that intrathecal methylprednisolone may be effective. Further randomized, controlled trials will be needed to confirm the analgesic efficacy of analgesic and interventional therapies to determine their role in the overall treatment of patients with PHN. Perspective: This article reviews the analgesic options for the treatment of PHN and suggests that tricyclic antidepressants, membrane stabilizers, opioids, and lidocaine patch may demonstrate analgesic efficacy in this group of patients. These data may potentially help clinicians who attempt to provide analgesia in patients with PHN. © 2008 by the American Pain Society Key words: Neuropathic pain, zoster, pharmacotherapy. Introduction P ostherpetic neuralgia (PHN), a sequel of acute herpes zoster, may be associated with severe pain and sensory abnormalities that adversely affect a patient’s quality of life.17 Like other types of neuropathic pain, PHN can be resistant to many types of pharmacologic and interventional therapies. Nevertheless, more recent data, including systematic reviews/meta-analyses and randomized, controlled trials (RCTs), provide evidence for the analgesic efficacy of a number of pharmacologic therapies. We provide an overview on the efficacy of pharmacologic and interventional strategies for the treatment of PHN. Pharmacologic Therapies A number of pharmacologic agents have been used for the treatment of PHN. Many of these agents are also generally used for the treatment of other types of neuSupported in part by grants NIH P01 HD 33990 and NS-26363 (SNR). SNR has received research support, consulting fees, or honoraria in the past year from US Public Health Service, US Food and Drug Administration, Allergan, and Fralex. CLW has no relevant conflicts to report. Address reprint requests to Dr. Srinivasa N. Raja, The Johns Hopkins Hospital, Carnegie 292, 600 North Wolfe Street, Baltimore, MD 21287. E-mail: [email protected] 1526-5900/$34.00 © 2008 by the American Pain Society doi:10.1016/j.jpain.2007.10.006 ropathic pain. We focus on the more commonly used pharmacologic agents with evidence for analgesic efficacy in the treatment of PHN (Table 1). Systemic Drugs Tricyclic Antidepressants Tricyclic antidepressants (TCAs), which are used widely for the treatment of numerous neuropathic pain states, including PHN, have a number of presumptive mechanisms of action, including blocking of norepinephrine and serotonin reuptake and local anesthetic-like sodium channel blockade.21 There have been several RCTs and a meta-analysis of available RCTs examining the efficacy of TCAs for the treatment of PHN. In a meta-analysis of 4 RCTs, use of TCAs (including amitriptyline, nortriptyline, and desipramine) resulted in significant analgesic benefit for the treatment of PHN pain, with the pooled data showing a number needed to treat (NNT) of 2.6 (95% confidence interval [CI], 2.1–3.5) (Figs 1 and 3).38 Earlier meta-analyses examining the efficacy of TCAs for the treatment of PHN pain also provided similar results with an NNT of 2.1 to 2.3.15,70 With regard to individual RCTs, 1 double-blinded, crossover trial of TCAs and opioids in patients with PHN noted a higher NNT of 4.0 for TCAs, and there was a lack of correlation in the analgesic responsiveness between TCAs and opioids where some patients who did not have analgesia with TCA treatment S19 Therapeutic Agents for the Management of PHN: Suggested Dose Titration, Side Effects, and Clinical Comments23,28,46,77 MEDICATION CLASS TCAs* Nortriptyline Desipramine Amitriptyline Antiepileptics Gabapentin STARTING DOSE DOSE-ESCALATION SCHEME COMMON SIDE EFFECTS CONTRAINDICATIONS/CAUTION COMMENTS Increase by 10–25 mg weekly with a target dose of 75–150 mg Sedation, dry mouth, blurred vision, weight gain, urinary retention, constipation, sexual dysfunction Cardiac disease, glaucoma, suicide risk, seizure disorder Concomitant use of tramadol, SSRI, or SNRIs The lower starting dose may be more appropriate in the elderly. Amitriptyline has the most anticholinergic effects and hence less well tolerated by the elderly. Obtain baseline ECG in patients with hx of cardiac disease. 100–300 mg Start qhs and increase to tid dosing; increase by 100–300 mg every 3 days to total dose of 1800–2400 mg/d 300–600 mg in 1 wk Somnolence, dizziness, ataxia, peripheral edema and weight gain, myalgia, fatigue Decrease dose in patients with renal impairment No clinically significant drug interactions, improved sleep. Avoid sudden discontinuation. Ataxia, dizziness, somnolence, peripheral edema and weight gain, blurred vision, euphoria Decrease dose in patients with renal impairment by 50% or more based on CL creatinine Known hypersensitivity to amide local anesthetics Caution in patients receiving class I antiarrhythmic drugs (eg, tocainide and mexiletine) Caution with concomitant use of ACE inhibitors-angioedema; Increased risk for weight gain and peripheral edema in patients on thiazolidinedione antidiabetic agents. No significant systemic side effects. Pregabalin 50 mg tid OR 75 mg bid Topical lidocaine 5%, 1–2 patches Can use up to 3 patches 12 h/d Local erythema, rash, blisters Topical capsaicin* 0.025–0.075% Cream Apply 3–4 times a day over affected region Stinging or burning at application site Coughing, sneezing, or other signs of respiratory irritation if dry residue inhaled 15–30 mg 10 –20 mg 5–15 mg 0.5–1 mg Titrate at weekly intervals balancing analgesia and side effects. Average dose: 90 mg morphine or its equivalent Total daily dose: 150 – 400 mg Extended-release dosing once a day Nausea/vomiting, constipation, drowsiness, dizziness, itching History of substance abuse, suicide risk, driving impairment during treatment initiation Gradual titration monitoring G.I. and CNS side effects. Nausea/vomiting, constipation, drowsiness, dizziness, seizures, hallucinations, pruritus History of substance abuse, suicide risk, driving impairment during treatment initiation, seizure disorder, concomitant use of SSRI, SSNRI, TCA Caution if TCA, SSRI, or SNRI are also being used. Caution with reduced dose in patients with hepatic or renal disease. Opioid agonists Morphine Oxycodone Methadone Levorphanol Tramadol 50 mg bid or tid Care to avoid contact with eye or mucosa, use gloves for application. Pretreatment with topical 5% lidocaine may decrease burning associated with its use. Update on the Treatment of Postherpetic Neuralgia 10 –25 mg 10 –25 mg 10 –25 mg (once a day, qhs) S20 Table 1. S21 Vertigo, headache, somnolence, weight gain, alopecia, abdominal pain, hepatotoxicity, teratogenicity, pancreatitis, thrombocytopenia Avoid in patients with hepatic disease or dysfunction Avoid in women of child-bearing age and patients and urea cycle disorder. Drug interaction with lamotrigine. experienced significant pain relief with opioids and vice versa.61 As with other neuropathic pain states, amitriptyline is probably the most commonly studied TCA for the treatment of PHN pain, but other similar TCAs (eg, nortriptyline) appear to be equally effective.38,75 A recent study noted that desipramine may also provide clinically meaningful pain relief in antidepressantnaïve PHN patients.65 The addition of fluphenazine to amitriptyline does not seem to provide superior pain relief for PHN pain compared with amitriptyline alone.35 A limiting factor in the clinical use of TCAs is their side effects, including dry mouth, fatigue, dizziness, sedation, constipation, urinary retention, and palpitations. Other side effects include orthostatic hypotension, weight gain, blurred vision, and QT prolongation. These side effects may be of particular concern in the older population and in patients with a history of cardiac arrhythmia or ischemic heart disease. Although there is no standard or guideline for ECG screening prior to TCA administration, TCAs may cause ECG changes (eg, prolonged QT) and it may be prudent to obtain a baseline ECG in patients with cardiac disease.68,73 As PHN is a disease of the elderly and co-existing cardiac abnormalities are not uncommon in this age group, a baseline ECG may be beneficial. For minor harm, the number needed to harm (NNH) for TCAs (vs placebo) has been reported as 5.7 (95% CI, 3.3–18.6) (Fig 4). For major harm, the NNH for TCAs is 16.9 (95% CI, 8.9 –178).38 Antiepileptic Drugs *Not FDA approved for this indication. Titrate to 1000 mg/d 250 mg bid (extended release) Other drugs Divalproex sodium* STARTING DOSE MEDICATION CLASS Table 1. Continued DOSE-ESCALATION SCHEME COMMON SIDE EFFECTS CONTRAINDICATIONS/CAUTION COMMENTS ORIGINAL REPORT/Wu and Raja Antiepileptic drugs such as gabapentin and pregabalin have been used for the treatment of many types of neuropathic pain, including PHN. Although the precise mechanism of analgesic action of gabapentin is uncertain, it is believed that gabapentin acts at the ␣2␦-1 subunits of voltage-dependent Ca2⫹ channel to decrease calcium influx, which in turn inhibits the release of neurotransmitters (such as glutamate) from the central terminals of primary afferent fibers in the spinal cord.8,49 Several RCTs and a few meta-analyses have established the analgesic efficacy of gabapentin for the treatment of PHN pain (Figs 2 and 3). A meta-analysis of 2 RCTs revealed that the pooled NNT for gabapentin for the treatment of PHN was approximately 4.4 (95% CI, 3.3– 6.1).38 The daily dose of gabapentin ranged from 1800 mg to 2400 mg. One study looked at gabapentin dosages up to 3600 mg/d or placebo over a 4-week titration period in 229 patients with PHN.63 This study found that those who received gabapentin had a significant reduction in average daily pain score (from 6.3– 4.2 points), compared with a smaller decrease (6.5– 6.0 points) for placebo; however, patients receiving gabapentin experienced a higher incidence of somnolence, dizziness, ataxia, peripheral edema, and infection. In another RCT with a total of 334 patients with PHN,62 those who received gabapentin (1800 or 2400 mg/d) had a significantly greater improvement in pain scores from week 1 than those receiving placebo. The most common side effects S22 Update on the Treatment of Postherpetic Neuralgia Figure 1. Responder rates for tricyclic antidepressants (TCA) in the treatment of postherpetic neuralgia. (Modified with permission from Hempenstall K, Nurmikko TJ, Johnson RW, A’Hern RP, Rice AS. PLoS Med. 2005;2:e164.) noted over the 7-week study period were dizziness and somnolence. The optimal dosing schedule for gabapentin in patients with PHN is uncertain, but a systematic review4 suggested that gabapentin treatment should be started at a dosage of 900 mg/d by initiating 300 mg/d on the first day, administering 600 mg/d on day 2, and 900 mg/d on day 3, with titration up to 1800 mg/d over approximately 2 weeks (and occasionally dosages up to 3600 mg/d needed for some patients) recommended for greater efficacy. The dose should be reduced in patients with altered renal function and titrated slowly in the elderly. Administration of gabapentin with an opioid may provide superior analgesia at lower doses compared with either administered as a single agent.33 A newer gabapentinoid, pregabalin, provides analgesia presumably by a mechanism of action similar to that of gabapentin. Although there are no meta-analyses examining the analgesic efficacy of pregabalin in PHN, there are a few RCTs. Pregabalin at a dose of 150 to 600 mg/d provided superior pain relief to placebo and improved pain-related sleep interference in 3 doubleblinded RCTs in 776 patients with PHN.28 Common side effects of pregabalin include dizziness, somnolence, and peripheral edema.24,28,29 Although the optimal dosing regimen for pregabalin is unclear, patients may notice a reduction in pain even after the first full day of treatment, and flexible and fixed-dose pregabalin regimens both appear to be effective for PHN.24,29 Generally, the gabapentinoids are well tolerated. The most frequently reported side effects are somnolence, dizziness, peripheral edema, fatigue, headache, and dry mouth. For minor harm, the NNH for gabapentinoids (vs placebo) has been reported as 4.1 (95% CI, 3.2–5.7) (Fig 4). For major harm, the NNH for gabapentinoids is 17.3 (95% CI, 7.7–30.2).38 Figure 2. Responder rates for gabapentin and pregabalin in the treatment of postherpetic neuralgia. (Modified with permission from Hempenstall K, Nurmikko TJ, Johnson RW, A’Hern RP, Rice AS. PLoS Med. 2005;2:e164.) ORIGINAL REPORT/Wu and Raja S23 Figure 3. Meta-analysis of the number needed to treat to provide a significant analgesic benefit for the treatment of postherpetic neuralgic pain. (Adapted from Hempenstall K, Nurmikko TJ, Johnson RW, A’Hern RP, Rice AS. PLoS Med. 2005;2:e164; Davies PS, Galer BS. Drugs. 2004;64:937-947.) Tramadol The analgesic effects of tramadol are centrally mediated and related to its weak opioid agonist (-receptor) action and monoamine (norepinephrine and serotonin) reuptake inhibition. Earlier placebo-controlled studies have demonstrated the efficacy of tramadol in treating diabetic neuropathic pain and polyneuropathies.36,69 A more recent RCT in 127 patients with PHN10 suggested that 6 weeks of treatment with sustained-release tramadol (100 – 400 mg/d; average dose ⫽ 275 mg) was associated with a reduction in pain and improved quality of life compared with placebo. The NNT was 4.8 (95% CI, 3.5– 6.0), and the drug was relatively safe (Fig 3). Adverse effects of tramadol include nausea, vomiting, constipation, and dizziness. Less common side effects in- clude vertigo, urinary retention, pruritus, somnolence, and headache. For minor harm, the NNH for tramadol (vs placebo) has been reported as 7.2 (Fig 4). For major harm, the NNH for tramadol is 10.8.38 About 7% of the population exhibit a reduced activity of the CYP2D6 isoenzyme of cytochrome P-450. In these individuals (poor metabolizers), concentrations of tramadol were approximately 20% higher versus “extensive metabolizers.” In addition, concomitant therapy with inhibitors of CYP2D6 such as SSRIs (eg, fluoxetine, paroxetine), SNRIs (venlafaxine, duloxetine), and TCAs (amitriptyline, nortriptyline) could result in increases in tramadol concentrations due to varying degrees of inhibition of the metabolism of tramadol. Concomitant use of SSRIs and MAO inhibitors may enhance the risk of adverse events, including seizures and serotonin syndrome. *NNH for major harm could not be calculated from available data. Figure 4. Meta-analysis of the number needed to harm to elicit significant adverse effects associated with analgesic therapy. (Adapted with permission from Hempenstall K, Nurmikko TJ, Johnson RW, A’Hern RP, Rice AS. PLoS Med. 2005;2:e164.) S24 Opioid Analgesics Although opioid analgesics are accepted as a cornerstone for the treatment of nociceptive and cancer pain, their role in the management of neuropathic pain such as PHN has been intensely debated. Some clinicians consider neuropathic pain to be resistant to the analgesic effects of opioids. The controversy of efficacy in relieving neuropathic pain reflects the use of multiple definitions and pain assessments of neuropathic pain in both clinical and experimental trials, methodologic issues in available RCTs, and interindividual differences in opioid responsiveness. In addition, many other factors, such as opioidrelated side effects, development of tolerance, exaggerated fear of addiction, and government health policies, contribute to the controversy regarding the use of opioids for nonmalignant neuropathic pain. Efficacy of Opioids for Neuropathic Pain Despite previous clinical uncertainty regarding the analgesic efficacy of opioids for the treatment of neuropathic pain, a number of high quality studies demonstrate that opioids are effective in relieving neuropathic pain (Fig 3).26,28,66,79,82 Guidelines and consensus statements2,25,54 have indicated that opioid analgesics are a recognized option for the treatment of neuropathic pain including PHN. Although the efficacy of opioids for neuropathic pain, derived from NNTs, is comparable to TCAs and better than antiepileptics, their side effects, concerns of misuse and abuse, and tolerance have, however, led to the recommendation by the IASP Neuropathic Pain Special Interest group, the European and Canadian consensus panels that this class of drugs be considered as second or third line analgesics.2,25,54 Initial proof of principle of the effectiveness of opioids for neuropathic pain was achieved using brief intravenous infusion studies of morphine, lidocaine, and placebo in PHN.66 In a double-blinded, placebo-controlled RCT, the analgesic effect of a short-acting intravenous opioid, fentanyl, was compared with an active (diazepam) and inert (saline) placebo in 53 patients with various types of neuropathic pain including 3 with PHN. Compared with the 2 control phases, patients had significantly superior average and maximum pain relief while receiving placebo, and the analgesic effect was independent of the degree of sedation.20 In another doubleblinded, placebo-controlled RCT of an intravenous opioid in neuropathic pain,82 phantom limb pain was significantly diminished by morphine but not by lidocaine or active control (diphenhydramine). Another double-blinded RCT evaluating the analgesic efficacy of oral levorphanol (a potent -opioid agonist) for the treatment of a variety of neuropathic pains refractory to conventional therapy67 demonstrated that patients randomized to receive a high-strength/dose of levorphanol had a greater decrease in pain compared with a lowstrength/dose of levorphanol. Long-term treatment of chronic noncancer pain (neuropathic in 51% of patients) with transdermal fentanyl53 provided a stable degree of Update on the Treatment of Postherpetic Neuralgia pain control and was generally well-tolerated with a low incidence of serious side effects such as drug abuse and respiratory depression. A recently published meta-analysis26 also indicates that opioids demonstrate significant efficacy versus placebo in treatment of neuropathic pain in intermediate-term studies. It is possible that opioid responsiveness of neuropathic pain is in part related to dosage as higher doses of opioids may be necessary to decrease neuropathic pain compared with nociceptive pain.7 Efficacy of Opioids for Postherpetic Neuralgia Both intravenous and oral opioids have been shown to provide significant pain relief for patients with neuropathic pain.66,75,76 The analgesic efficacy of oral oxycodone for PHN pain was evaluated in a double-blinded, crossover RCT.75 Patients were randomly assigned to receive either placebo or sustained-release oxycodone 10 mg every 12 hours over a period of 4 weeks. Treatment with oxycodone resulted in a significant reduction in allodynia, steady pain, and paroxysmal spontaneous pain, while providing significantly improved pain relief.75 Oxycodone treatment also resulted in superior scores for global effectiveness, disability, and masked patient preference relative to placebo. A randomized, doubleblinded, crossover trial in patients with PHN61 found an NNT of 2.7 for opioids. Therefore, RCTs suggest that PHN pain responds to opioid therapy. However, questions remain as to whether the beneficial effects persist with longterm therapy. Further studies are needed to determine the beneficial effects of prolonged treatment with opioids.27 For the treatment of PHN and other neuropathic pain, opioids may be considered as part of a comprehensive plan that includes pharmacologic and nonpharmacologic options.12 Opioids may be considered if the pain is moderate to severe and has a significant impact on function or quality of life, and reasonable and conservative therapy has already been tried. There are several general principles of chronic opioid therapy that may facilitate effective PHN pain control. The dose of opioid should be titrated to optimize efficacy and minimize side effects. In general, a fixed-dose regimen using a long-acting or sustained-release formulation opioid with prn (on an asneeded basis) administration of short-acting opioids for breakthrough pain is preferable over a prn-only analgesic regimen. The clinician should document the treatment plan and outcomes. Some clinicians use an “opioid contract” to describe treatment parameters, the mutually agreed-on treatment plan, and informed consent.5,55 Patients may exhibit opioid-related side effects including endocrine dysfunction,18 loss of libido, and immunosuppression.6 Clinicians should also consider prophylactic bulk laxative when commencing opioid treatment. Finally, possible cognitive and neuropsychological side effects associated with chronic use of opioids remain a major concern and area of controversy. Several trials indicate that long-term use of opioids does not have a detrimental effect on cognitive function— on the contrary, some aspects of cognitive functioning actually im- ORIGINAL REPORT/Wu and Raja prove because of a decrease in pain and improvement in mood.6,71 Patients receiving long-term treatment with opioids (up to 12 months) did not demonstrate any decrease in neuropsychological tests or experimental assessments of driving ability.6,71 Constipation, nausea, and sedation are common adverse effects associated with opioid use. A significant side effect with chronic opioid use is hormonal change that may result in sexual dysfunction. More recently, issues related to drug diversion or aberrant drug-seeking behavior in the use of opioids for chronic noncancer pain have been of concern, but it is less likely to be a significant issue in the elderly population most affected by PHN. For minor harm, the NNH for opioids (vs placebo) has been reported as 3.6 (95% CI, 2.2–10.2) (Fig 4). For major harm, the NNH for opioids is 6.3 (95% CI, 4.2–12.8).38 The successful long-term administration of opioids for the treatment of chronic pain, including that of neuropathic origin, has been reported in several studies; however, there are several tangentially related issues (eg, dose escalation, adverse events, quality of life, use in persons with a history of chemical dependency) with long-term use that are discussed elsewhere.43,60,78,79 Topical Therapies Topical Local Anesthetics Local anesthetic may provide analgesia in neuropathic pain states where an accumulation of neuronal-specific sodium channels may contribute to pain, including that of PHN.50 A topical adhesive patch containing 5% lidocaine (700 mg) has been used for the treatment of PHN pain.16 A randomized, controlled crossover trial demonstrated that lidocaine patch was strongly preferred over a placebo patch (78.1% vs 9.4%) with no significant difference noted between the active and placebo treatments in the incidence of side effects.31 Two open-label, nonrandomized, prospective studies19,32 showed that the lidocaine patch 5% (applied over the area of maximal pain) reduced the intensity of moderate-to-severe PHN pain and improved quality of life.19 Although there are few studies, the available clinical trials in PHN patients with allodynia suggest that the lidocaine patch is effective in providing pain relief from PHN with minimal systemic absorption and few side effects, the most frequent being mild skin irritation at the site of application.30,31,64 Another study suggested that the NNT (for more than 50% relief of ongoing pain) was 4.4.51 Patients may respond well to topical lidocaine even if the skin is completely deprived of nociceptors.74 Topical Capsaicin Capsaicin, the pungent ingredient in hot chili pepper, results in excitation of nociceptive afferents when applied topically. However, repeated applications of capsaicin results in desensitization of unmyelinated epidermal nerve fibers and hypalgesia.57 A 6-week, blinded, parallel-group study, followed by a 2-year, open-label fol- S25 low-up period, indicated that a 0.075% topical capsaicin cream was effective in relieving pain in 64% of patients at 6 weeks, compared with 25% in patients receiving placebo.77 An earlier study in a small group of patients showed similar efficacy.9 The topical application has to be used 3 to 4 times a day and is often associated with local irritation and an unpleasant burning sensation that may decrease with repeated applications. The pooled NNT was 3.3 (Fig 3). For minor harm, the NNH for capsaicin (vs placebo) has been reported as 3.9 (95% CI, 2.5– 8.6) (Fig 4); for major harm, the NNH for capsaicin is 4.7 (95% CI, 3.1–9.2).38 Other Therapies A number of other oral therapies, such as NMDA receptor antagonists (dextromethorphan, memantine), ketamine, topical NSAIDs and TCAs, vincristine iontophoresis, homeopathy, and acupuncture have been explored. However, there is little scientific evidence to make recommendations about the efficacy of these therapies. More recently, some promising data indicates that divalproex sodium (valproic acid and sodium valproate) may provide significant pain relief in PHN with a relatively low incidence of side effects.46 Consensus Recommendations/Guidelines and Combination Therapies Recent guidelines of evidence-based treatment of neuropathic pain (including PHN) includes the recommendation of the first-, second-, and third-line options of pharmacotherapy.2,25,54 Consensus panels have generally considered TCAs, antiepileptics, and topical lidocaine as first-line analgesics for PHN. Opioids and tramadol are recommended as second-line treatments that can be considered for first-line under certain select circumstances.25 Topical capsaicin and valproate are considered as third-line therapies. Although we discuss drugs individually, combination therapy of more than 1 drug class may be useful in providing additive if not synergistic analgesia although there is a lack of good evidence for which combinations may be superior (or harmful). The benefits of combination therapies are supported by a recent study indicating that in patients with PHN and diabetic neuropathy, the combination of gabapentin and morphine achieved better analgesia at lower doses of each drug than either of the 2 drugs as a single agent.33 Psychological Interventions Neuropathic pain reduces quality of life, including mood, physical, and social functioning. Depression and pain coping strategies such as catastrophizing and social support predict pain severity in chronic pain states. Investigation of cognitive-behavioral factors affecting the adaptation of elderly individuals experiencing PHN suggest that catastrophizing predicts the level of pain, an effect that is independent of depressive symptoms.39 Although S26 controlled trials have examined the role of cognitive behavioral therapy in many chronic pain states, we are not aware of any studies specific to patients with PHN. The importance of psychosocial support and long-term follow-up for severe cases should, however, not be overlooked as sometimes it is the final thing that remains for the most intractable cases. Interventional Strategies A wide variety of interventional options, such as sympathetic and other nerve blocks, intrathecal injections (eg, methylprednisolone), and spinal cord stimulation have been examined as potential treatments for PHN. Interventional options are part of a comprehensive (invasive and noninvasive) strategy for the treatment of PHN. The analgesic efficacy of some interventional strategies (eg, sympathetic nerve blocks) is uncertain; however, studies indicate that some interventional options (ie, intrathecal methylprednisolone) may be more effective than others. Sympathetic Nerve Blocks Selective sympathetic nerve blocks have traditionally been used for the treatment of many chronic pain conditions. Sympathetic nerve blocks have been one of the more common interventional strategies used for pain relief for both acute herpes zoster and PHN. Although the precise mechanisms by which the sympathetic nervous system contributes to neuropathic pain are unclear, experimental data indicate that abnormal activation of the ␣-adrenergic receptors in primary afferent neurons, direct interactions between primary afferent neurons and efferent sympathetic nerves resulting from neuronal regeneration and sprouting after nerve injury and tissue trauma may all contribute to sympathetically mediated pain.42,81 Some data suggest a link between sympathetic activity and pain in PHN, as patients with PHN demonstrate increased levels of pain and worsening of their allodynia after local administration of adrenergic agonists.11 Thus, administration of sympathetic nerve blocks may theoretically interrupt the sympathetic-sensory interactions that may contribute to the pain of herpes zoster and PHN. Regional sympathetic blockade with local anesthetics can be achieved by trained pain management specialists. The incidence of severe complications from sympathetic nerve blocks is extremely low, and, depending on the location of the nerve block, may consist of local anesthetic toxicity (eg, seizures), pneumothorax, intraspinal/neuraxial injection, or neurologic injury. Sympathetic Nerve Blocks for Postherpetic Neuralgia Sympathetic nerve blocks have also been used in patients with PHN, although with much less analgesic effectiveness compared with that used for acute herpes zoster.81 Early retrospective studies seemed to indicate that sympathetic nerve blocks might provide transient pain relief: 41% to 50% of patients with longstanding PHN who received sympathetic nerve blocks noted Update on the Treatment of Postherpetic Neuralgia marked improvement or complete relief,13,14 but longterm follow-up revealed that far fewer patients actually obtained significant prolonged pain relief. Only 14% of patients who received sympathetic nerve blocks later than 2 months after rash onset became pain free, compared with 92% of those who received sympathetic nerve blocks within 2 months of rash onset.80 Despite the apparent effectiveness of sympathetic nerve blocks in decreasing the pain of acute herpes zoster and possibly PHN, there are significant methodologic issues in the evaluation of the analgesic efficacy of sympathetic nerve blocks for relief of PHN.40,45,81 One of the most glaring problems is the lack of double-blinded RCTs. Such trials are particularly necessary in this disease state, because the natural course of acute herpes zoster for a majority of patients is complete resolution of pain within a few weeks. In addition, inadequate assessments of pain severity, lack of control for other important covariates (eg, age, rash severity, acute pain severity, concurrent use of antiviral agents), varying definitions of acute herpes zoster and PHN, and systemic effects of local anesthetics all contribute to the controversy of the analgesic efficacy of sympathetic nerve blocks for both acute herpes zoster and PHN.81 Despite these methodologic issues in examining the effectiveness of sympathetic nerve blocks for acute herpes zoster and PHN, it does appear that there may be a role for sympathetic nerve blocks in the treatment of pain from acute herpes zoster, as it may diminish pain and theoretically prevent the development of PHN. The role of sympathetic nerve blocks for established PHN is controversial, as the longterm analgesic efficacy is marginal. Other Nerve Blocks Use of epidural block has been reported for the treatment of acute herpes zoster.1,41 Several prospective observational trials1,41 suggest that epidural blockade in combination with an antiviral agent, is a very effective treatment modality for acute herpes zoster that shortens the total duration and severity of pain. High thoracic epidural block was shown to be as effective as sympathetic stellate ganglion block in relieving moderate to severe acute herpes zoster pain. Other nerve blocks, such as intercostal nerve blocks, have been reported to provide long lasting pain relief for PHN.22 However, the quality of many of these studies is questionable. A preliminary study44 randomly assigned patients with intractable PHN of longer than 1 year’s duration to receive 60 mg methylprednisolone acetate administered either epidurally or intrathecally. Patients randomly assigned to receive intrathecal methylprednisolone had significantly superior pain relief and lower levels of interleukin-8 within the cerebrospinal fluid. A subsequent study47 by the same group of investigators randomized 277 patients with long-lasting PHN pain refractory to conventional therapy to receive an intrathecal injection of either methylprednisolone and lidocaine, lidocaine alone, or no treatment (no injection/control). Over a follow-up period of 2 years after injection, patients who received the intrathecal methylprednisolone-lidocaine ORIGINAL REPORT/Wu and Raja combination showed a significant improvement in global pain relief (vs the control group) and mean pain scores for both burning and lacinating pain, with a decrease in diclofenac use within 4 weeks of injection (vs the lidocainealone group and the control group). Compared with the other 2 groups, the methylprednisolone-lidocaine group had significantly lower areas of maximal pain and allodynia. Despite the potential of intrathecal methylprednisolone in relieving pain from PHN, clinicians should recognize that intrathecal injection of methylprednisolone acetate has not been approved for the treatment of PHN with the methylprednisolone acetate containing benzyl alcohol and polyethylene glycol preservatives. Moreover, the safety of intrathecal administration of methylprednisolone has been debated and hence caution is advised in the use of this therapy. Finally, a single epidural injection of steroids and local anesthetics in the acute phase of herpes zoster may have a modest effect in reducing zoster-associated pain for 1 month after injection but is not effective for prevention of long-term postherpetic neuralgia.72 Other Interventional Strategies Spinal Cord Stimulation Spinal cord stimulation (SCS) has been used for the treatment of chronic neuropathic pain.37,48 The mechanism of action of SCS is unclear; postulated mechanisms are based on the gate-control theory of pain, in which stimulation of large myelinated A- fibers would interfere at the dorsal horn with transmission of nociceptive information carried by the small unmyelinated C and myelinated A-␦ fibers from the periphery. According to this model, SCS blocks pain of neuropathic origin by producing an electrical field over the spinal cord. The electrical pulse is transmitted to the spinal cord from a subcutaneously implanted generator via implanted electrodes placed directly into the epidural space.48 Other proposed mechanisms of SCS-mediated analgesia include suppression of sympathetic overdrive and inhibition of nociceptive processing via GABA-ergic interneurons.37,48 Although there are limitations in the quality and quantity of data available, current evidence from the literature suggests that SCS is effective in the management of certain types of neuropathic pain.34 In appropriate patients, SCS may provide long-term pain relief (2 years) in up to 60% to 80% of patients with chronic pain.48 Some PHN patients obtained relief with temporary percutaneous SCS.37 References 1. Ahn HJ, Lim HK, Lee YB, Hwang SM, Lee WS, Ahn SK, Choi EH: The effects of famciclovir and epidural block in the treatment of herpes zoster. J Dermatol 28:208-216, 2001 2. Attal N, Cruccu G, Haanpää M, Hansson P, Jensen TS, Nurmikko T, Sampaio C, Sindrup S, Wiffen P, EFNS Task Force: EFNS guidelines on pharmacological treatment of neuropathic pain. Eur J Neurol 13:1153-1169, 2006 3. Angel IF, Gould HJ Jr, Carey ME: Intrathecal morphine S27 Other Surgical Options Continuous infusions of analgesic agents (typically an opioid or local anesthetic) via an externalized intrathecal catheter or internalized intrathecal pump may also be used for the treatment of PHN, although no controlled trials examining the analgesic efficacy of these modalities are available.3,56 Initial reports of skin excision corresponding to an area of PHN pain as a treatment option to reduce pain, eliminate tactile allodynia, and significantly reduce the use of analgesic medication up to 1 year after surgery appeared promising58 but subsequent follow-up revealed a steady increase in pain ultimately exceeding presurgery levels and as such, the authors concluded that skin resection cannot be recommended as a treatment for PHN.59 The results of this procedure suggest that afferents near the skin surface contribute to the pain and allodynia of PHN.58 Other reported surgical options for PHN treatment include trigeminal or spinal peripheral neurectomy, deep brain stimulation, dorsal root entry zone lesions, cordotomy, and mesencephalotomy. Microsurgical DREZotomy or dorsal root entry zone lesions may interrupt small nociceptive fibers and neurons in the dorsal horn of the spinal cord. General indications for this procedure include well-localized pain, neuropathic pain including PHN, and excessive spasticity associated with severe pain.52 The role of these invasive surgical treatments in the management of PHN is uncertain, as there are no controlled studies to date. Conclusions Treatment of PHN is often difficult and frustrating for both the patient and the clinician. Although many have believed PHN to be resistant to the analgesic effects of opioids, RCTs indicate that some pharmacologic therapy, including opioids, TCAs, antiepileptic drugs, and lidocaine patch, may result in significant pain relief for patients with PHN, although some may not experience sufficient pain relief, or find that the adverse effects of the medication outweigh its benefits. 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