Infections in Oncology

Infections in Oncology
SUCCESSFUL THERAPY OF POSTNEUROSURGICAL MENINGITIS CAUSED BY A
RESISTANT STRAIN OF ENTEROBACTER AEROGENES
Ted N. Fotopoulos, MD, John N. Greene, MD,
Ramon L. Sandin, MD, and Albert L. Vincent, PhD
H. Lee Moffitt Cancer Center & Research Institute
Introduction
Gram-negative bacillary meningitis (GNBM) is commonly seen in infants and neonates. However, GNBM can cause severe meningitis in adults, although
rarely.1,2 It usually occurs after central nervous system trauma and neurosurgical procedures. The immunocompromised, the elderly, or patients with
chronic diseases are at high risk.1,3 Numerous antibiotics have been tried in the treatment of GNBM, but overall, the therapeutic results have been largely
unsatisfactory, and mortality as high as 70% has been reported.4
We present a patient who was successfully treated with trimethoprim-sulfamethoxazole (TMP-SMX) and gentamicin with Enterobacter aerogenes meningitis
following neurosurgery. Recent literature has focused on the successful treatment of GNBM with newer agents such as third generation cephalosporins and
aztreonam. However, with increasing resistance of Gram-negative bacteria to beta-lactam antibiotics, alternative regimens need consideration based on the
individual institution's antibiogram, as our case illustrates.
Case Report
A 39-year-old man presented with an 11-month history of progressive visual loss and headaches. Computed tomography of the head revealed a 7 x 8-cm
frontal-sella turcica mass invading the maxillary, ethmoid, and sphenoid sinuses (Fig 1). Physical examination demonstrated exophthalmos and bilateral
diminished vision.
The arterial supply of the mass was embolized. The tumor was resected via bifrontal craniotomy and was a meningioma. Prophylactic clindamycin and
nafcillin were administered postoperatively. Six days following the operation, he developed a fever of 105 degrees Fahrenheit with agitation, lethargy, and
combativeness. A cerebral spinal fluid leak with rhinorrhea was noted.
Cerebral spinal fluid (CSF) obtained by a lumbar puncture revealed glucose of 20 mg/dL, protein of 222 mg/dL, and a white blood cell count of 3100/cc3 .
The Gram stain showed 2+ white blood cell count but no organisms. CSF cultures grew E aerogenes with two different morphologies of colony growth (Fig
2). Organisms from one of the colony types were susceptible to all antibiotics tested, and the other was resistant to ceftazidime and piperacillin but sensitive
to ciprofloxacin, TMP-SMX, and aminoglycosides by the automated Vitek system. TMP-SMX was substituted for ceftazidime, and gentamicin was added.
The patient's fever resolved promptly, and his mental status improved. Repeat CSF analysis demonstrated protein of 221 mg/dL, glucose of 38 mg/dL, a
white blood cell count of 990/cc3 with 91% neutrophils, and a red blood cell count of 50/cc3 . The CSF cultures were negative. Additional CSF analyses at
one and four weeks later remained sterile. After 21 days of intravenous administration of TMP-SMX followed by 14 days of oral TMP-SMX, the patient
remained asymptomatic.
The CSF leak required placement of a lumbar drain. However, the leak recurred after removal of the drain, and a ventriculo-peritoneal (V-P) shunt was
placed with resolution of the leak. Since the placement of the V-P shunt, all subsequent CSF analyses have been negative for any infection. After six
months, the patient had no sensory or motor deficits but remained legally blind.
Discussion
Meningitis caused by Gram-negative enteric bacteria is rare in adults but can be found most often after disruption of the dura-arachnoid barrier secondary
to trauma or neurosurgery.1 It may also occur spontaneously in patients who are elderly, immunocompromised, or chronically debilitated.3 It occasionally
spreads directly from an adjacent focus of infection as in the case of mastoiditis or sinusitis.4 The most common organisms involved are Klebsiella sp,
Pseudomonas sp, Escherichia coli, and Haemophilus influenzae. Enterobacter sp are rarely the causative agents.5
Over the last decade, the choice of antibiotics for GNBM has varied greatly. Overall unsatisfactory results and mortality rates as high as 70% have been
reported.4 For years, chloramphenicol was the standard therapy for GNBM. Chloramphenicol offered not only in vitro inhibitory activity against most of
the offending organisms except Pseudomonas aeruginosa, but also the ability to enter the CSF when given intravenously. However, its action against
aerobic Gram-negative organisms is only bacteriostatic at levels obtainable in the CSF.6 In vivo resistance during therapy can occur,7 and antagonism
when used in combination with gentamicin or cefotaxime has been reported.8,9 Aminoglycosides, which have been frequently used, are associated with low
systemic therapeutic-toxic ratio, diminished effectiveness in actively infected CSF, and difficulty in obtaining bactericidal levels in the CSF.10 The third
generation cephalosporins, including moxalactam, ceftriaxone, cefotaxime, and ceftazidime are effective against GNBM11-14 and enter the CSF in high
bactericidal concentrations.14 Treatment failures have been reported,15 and several agents in this group have been associated with hypoprothrombinemia
and platelet dysfunction with increased risk of hemorrhage.16 Aztreonam, which covers a broad range of Gram-negative bacteria,17 has been shown to
reach therapeutic levels in the CSF regardless of inflamed or noninflamed meninges.18 Investigators have documented high microbiologic cure rates with
aztreonam,19,20 so it must be regarded as one of the front-line agents in the treatment of GNBM.
The combination of TMP-SMX, which became available for intravenous use in the mid 1970s, has long been known to be active against many Gramnegative bacilli. It quickly enters the CSF to establish bactericidal levels. The use of TMP-SMX to treat GNBM in neonates and infants was reported in
1969,21 followed by later reports of TMP-SMX use in the treatment of a bacterial brain abscess with documentation of bactericidal levels in the abscess
cavity22 and the successful treatment of five patients with meningitis.23 In 1982, successful treatment of a patient with Klebsiella pneumonia meningitis
using TMP-SMX was reported.24 In a worldwide review of the literature in 1984 for cases of meningitis treated with TMP-SMX, Levitz and Quintiliani25
obtained data on 33 patients with GNBM treated with TMP-SMX. Seventeen of the cases were from published reports, and 16 were unpublished cases
reported to pharmaceutical companies. Bacteriologic cure was achieved in 26 of the 33 patients. In two of these cases, the causative agent was
Enterobacter cloacae, which generally is only moderately sensitive to third-generation cephalosporins. Treatment with TMP-SMX in both patients resulted
in clinical and bacteriologic cure. A similar successful outcome using TMP-SMX was obtained in a postoperative patient with E cloacae meningitis.26 The
organism demonstrated both an inducible beta-lactamase and a constitutive beta-lactamase that resulted in a poor response to cephalosporin therapy.26
Clinical trials have not yet been performed to determine the value of TMP-SMX in the treatment of GNBM. However, Wolff et al27 reported a 100% (5/5)
cure rate of Enterobacter sp meningitis with TMP-SMX alone. Faced with a multiple drug resistance strain of E aerogenes, we chose to treat the patient
with TMP-SMX and gentamicin intravenously with a successful outcome. Despite the recognition that intrathecal gentamicin is necessary to obtain
bacteriocidal levels in CSF, we used intravenous gentamicin for synergy with TMP-SMX in serum and possibly in CSF. Imipenem/cilastatin and
ciprofloxacin are alternatives to treat Gram-negative bacterial meningitis. However, the risk of seizures and mental status changes with the former and
poor CSF penetration (10% of peak serum concentration) with the latter make these options less desirable. Meropenem, a new carbapenem, has been used
successfully to treat resistant pseudomonas aeruginosa meningitis and probably would be effective against enterobacter with less risk of seizures.28 We
agree with previous reports that in a select group of patients with GNBM with multiple-drug resistance and in vitro susceptibility to TMP-SMX and
aminoglycosides, this combination should be considered as a viable and potentially successful treatment option.
Appreciation is expressed to Catherine Hearn and Debbie Brickner for their assistance in the preparation of this manuscript.
References
1. Gower DJ, Barrows AA 3d, Kelly DL Jr, et al. Gram negative bacillary meningitis in the adult: review of 39 cases. South Med J. 1986;79:1499-1502.
2. Mancebo J, Domingo P, Blanch L, et al. Post-neurosurgical and spontaneous gram- negative bacillary meningitis in adults. Scand J Infect Dis.
1986;18:533-538.
3. Crane LR, Lerner AM. Non-traumatic gram-negative bacillary meningitis in the Detroit Medical Center, 1964-1974 (with special mention of cases due
to Escherichia coli). Medicine (Baltimore). 1978;57:197-209.
4. Mangi RJ, Quintiliani R, Andriole VT, et al. Gram-negative bacillary meningitis. Am J Med. 1975;59:829-836.
5. de Champs C, Guelon D, Joyon D, et al. Treatment of a meningitis due to an Enterobacter aerogenes producing a derepressed cephalosporinase and
a Klebsiella pneumoniae producing an extended-spectrum beta-lactamase. Infection. 1991;19:181-183.
6. Rahal JJ Jr, Simberkoff MS. Bactericidal and bacteriostatic action of chloramphenicol against meningeal pathogens. Antimicrob Agents Chemother.
1979;16:13-18.
7. McGee ZA, Kaiser AB, et al. Emergence of chloramphenicol resistance during chloramphenicol therapy of gram-negative bacillary meningitis. In:
Proceedings and Abstracts of the 17th Interscience Conference of Antimicrobial Agents and Chemotherapy, New York, 1977. Washington, DC:
American Society for Microbiology, 1977, Abstract No. 4.
8. Strausbaugh LJ, Sande MA. Factors influencing the therapy of experimental Proteus mirabilis meningitis in rabbits. J Infect Dis. 1978;137:251-260.
9. Brown TH, Alford RH. Failure of chloramphenicol and cefotaxime therapy in Klebsiella meningitis: possible role of antibiotic antagonism. South Med
J. 1985;78:869-871.
10. Kaiser AB, McGee ZA. Aminoglycoside therapy of gram-negative bacillary meningitis: possible role of antibiotic antagonism. N Engl J Med.
1975;293:1215-1220.
11. Cherubin CE, Corrado ML, Nair SR, et al. Treatment of gram-negative bacillary meningitis: role of the new cephalosporin antibiotics. Rev Infect Dis.
1982;4:S453-S464.
12. Norrby SR. Role of cephalosporins in the treatment of bacterial meningitis in adults: overview with special emphasis on ceftazidime. Am J Med.
1985;79:56-61.
13. Cherubin CE, Eng RH. Experience with the use of cefotaxime in the treatment of bacterial meningitis. Am J Med. 1986;80:398-404.
14. Landesman SH, Corrado ML, Shah PM, et al. Past and current roles for cephalosporin antibiotics in treatment of meningitis: emphasis on use in
gram-negative bacillary meningitis. Am J Med. 1981:71:693-703.
15. Neu HC. Mechanisms of bacterial resistance to antimicrobial agents, with particular reference to cefotaxime and other beta-lactam compounds. Rev
Infect Dis. 1982;4:S288-S299.
16. Quintiliani R. Bleeding disorders associated with newer cephalosporins. Clin Pharm. 1983;2:360-361.
17. Barry AL, Thornsberry C, et al. Aztreonam: antibacterial activity, beta-lactamase stability and interpretive standards and quality control guidelines
for disk-diffusion susceptibility tests. Rev Infect Dis. 1985;7:S594-S604.
18. Modai J, Vittecoq D, Decazes JM, et al. Penetration of aztreonam into cerebrospinal fluid of patients with bacterial meningitis. Antimicrob Agents
Chemother. 1986;29:281- 283.
19. Lentnek AL, Williams RR. Aztreonam in the treatment of gram-negative bacterial meningitis. Rev Infect Dis. 1991;13:S586-S590.
20. Kilpatrick M, Girgis N, Farid Z, et al. Aztreonam for treating meningitis caused by gram-negative rods. Scand J Infect Dis. 1991;23:125-126.
21. Morzaria RN, Walton IG, Pickering D. Neonatal meningitis treated with trimethoprim and sulfamethoxazole. Br Med J. 1969;2:511-512.
22. Greene BM, Thomas FE Jr, Alford RH. Trimethoprim-sulfamethoxazole and brain abscess. Ann Intern Med. 1975;82:812-813.
23. Farid Z, Girgis NI, Yassin W, et al. Trimethoprim-sulfamethoxazole and bacterial meningitis. Ann Intern Med. 1976;84:50-51.
24. Hickstein DD, Dillon JT. Klebsiella pneumoniae meningitis: intravenous trimethoprim-sulfamethoxazole treatment. JAMA. 1982;248:1212-1213.
25. Levitz RE, Quintiliani R. Trimethoprim-sulfamethoxazole for bacterial meningitis. Ann Intern Med. 1984;100:881-890.
26. Ralph ED, Behme RJ. Enterobacter meningitis: treatment complicated by emergence of mutants resistant to cefotaxime. Scand J Infect Dis.
1987;19:577-579.
27. Wolff MA, Young CL, Ramphal R. Antibiotic therapy for enterobacter meningitis: a retrospective review of 13 episodes and review of the literature.
Clin Infect Dis. 1993;16:772-777.
28. Klugman KP, Dagan R. Carbapenem treatment of meningitis. Scand J Infect Dis. 1995;96:45-48.