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Efficacy of intravenous plus intrathecal/intracerebral ventricle injection of polymyxin B for post-neurosurgical intracranial infections due to MDR/XDR Acinectobacter baumannii: a retrospective cohort study
- Sijun Pan†1, 2,
- Xiaofang Huang†1,
- Yesong Wang†1,
- Li Li3,
- Changyun Zhao3,
- Zhongxiang Yao2,
- Wei Cui1 and
- Gensheng Zhang1Email author
© The Author(s). 2018
- Received: 22 August 2017
- Accepted: 15 January 2018
- Published: 19 January 2018
The Correction to this article has been published in Antimicrobial Resistance & Infection Control 2019 8:11
Post-neurosurgical intracranial infections caused by multidrug-resistant or extensively drug-resistant Acinetobacter baumannii are difficult to treat and associated with high mortality. In this study, we analyzed the therapeutic efficacy of intravenous combined with intrathecal/intracerebral ventricle injection of polymyxin B for this type of intracranial infection.
This retrospective study was conducted from January 2013 to September 2017 at the Second Affiliated Hospital, Zhejiang University School of Medicine (Hangzhou,China) and included 61 cases for which cerebrospinal fluid (CSF) cultures were positive for multidrug-resistant or extensively drug-resistant A. baumannii after a neurosurgical operation. Patients treated with intravenous and intrathecal/intracerebral ventricle injection of polymyxin B were assigned to the intrathecal/intracerebral group, and patients treated with other antibiotics without intrathecal/intracerebral injection were assigned to the intravenous group. Data for general information, treatment history, and the results of routine tests and biochemistry indicators in CSF, clinical efficiency, microbiological clearance rate, and the 28-day mortality were collected and analyzed.
The rate of multidrug-resistant or extensively drug-resistant A. baumannii infection among patients who experienced an intracranial infection after a neurosurgical operation was 33.64% in our hospital. The isolated A. baumannii were resistant to various antibiotics, and most seriously to carbapenems (100.00% resistance rate to imipenem and meropenem), cephalosporins (resistance rates of 98.38% to cefazolin, 100.00% to ceftazidime, 100.00% to cefatriaxone, and 98.39% to cefepime). However, the isolated A. baumannii were completely sensitive to polymyxin B (sensitivity rate of 100.00%), followed by tigecycline (60.66%) and amikacin (49.18%). No significant differences in basic clinical data were observed between the two groups. Compared with the intravenous group, the intrathecal/intracerebral group had a significantly lower 28-day mortality (55.26% vs. 8.70%, P = 0.01) and higher rates of clinical efficacy and microbiological clearance (95.65% vs. 23.68%, P < 0.001; 91.30% vs. 18.42%, P < 0.001, respectively).
Intravenous plus intrathecal/intracerebral ventricle injection of polymyxin B is an effective regimen for treating intracranial infections caused by multidrug-resistant or extensively drug-resistant A. baumannii.
- Acinetobacter Baumannii
- Polymyxin B
- Intrathecal injection
- Intracerebral ventricle injection
- Multidrug resistance
Postoperative nervous system infection is a common complication of neurosurgery and accounts for 0.8–7% of intracranial infections . The most common pathogens are Gram-negative Bacilli and Staphylococcus aureus, but the percentage of post-neurosurgical intracranial infections caused by Acinetobacter baumannii is still high at 15–21.74% [2, 3] with a high associated mortality rate ranging from 20 to 40% [4, 5]. A previous study reported a frequency of nosocomial, post-neurosurgical meningitis caused by A. baumannii as high as 10.9% with a mortality rate of 33.3% . An urgent clinical problem that has arisen in recent years is the high prevalence of intracranial infections with multidrug-resistant (MDR)/extensively drug-resistant (XDR) A. baumannii (MDR/XDR-Ab) due to the widespread use of broad-spectrum antibiotics. Thus, effective treatments for MDR/XDR-Ab intracranial infections are needed.
Although MDR/XDR-Ab is resistant to multiple antibiotics, it is still currently susceptible to polymyxins. The high molecular weight of polymyxins and the existence of the blood–brain barrier have forced the use of "intravenous combined with intrathecal/intracerebral ventricle injection" in order to achieve an effective therapeutic concentration [7, 8]. This method has been used clinically to treat intracranial infections caused by MDR/XDR-Ab, but the outcomes have been described in mostly case reports or case series [9, 10]. To further confirm the efficacy of this treatment strategy and provide more solid evidence, we retrospectively analyzed the effects of intravenous antibiotics without polymyxin B and intravenous plus intrathecal/intraventricular injection of polymyxin B in 61 cases of intracranial infection with MDR/XDR-Ab after neurosurgery.
The patients treated with intravenous and intrathecal/intracerebral ventricle injection of polymyxin B (Fresenius Kabi USA) were assigned to the intrathecal/intracerebral group, and patients treated with intravenous antibiotics only were assigned to the intravenous group. In the intrathecal/intracerebral group, 450,000 units per 12 h were administered intravenously and 50,000 units/day were simultaneously administered via the lumbar cistern drainage tube or ventricular drainage tube twice daily [9–11]. The drainage tube was removed and replaced upon diagnosis of infection. The process of intrathecal/intracerebral injection was as follows: we withdrew 2 mL CSF via the tube and discarded it; then we injected 50,000 units/day of polymyxin B; and then we kept the tube closed for 2 h [9, 11]. In the intravenous group, patients were treated with other antibiotics without intrathecal/intracerebral injection.
Baseline characteristics of patients enrolled in the study
ITV group (n = 38)
ITV + ITC group (n = 23)
Sex (male) (n, %)
53.50 ± 15.17
55.00 ± 15.08
Primary disease (n, %)
Benign Intracranial tumor
Comorbidities (n, %)
Nervous system disease
Surgeries (n, %)
Craniotomy evacuation of hematoma + decompressivecraniectomy
Intracranial tumor resection
Craniotomy aneurysm clipping
Drainage of intracranial hematoma
Ventricle peritoneal shunt
Lumbar cistern drainage
Coinfection (n, %)
5.34 ± 3.02
5.08 ± 2.23
APACHE II score
18.55 ± 5.62
17.65 ± 4.90
39.02 ± 0.53
39.17 ± 0.48
Statistical analysis was performed with SPSS 19.0 (SPSS, IBM Company, Chicago, IL) software. Continuous variables are presented as mean ± standard deviation if normally distributed, and as median and interquartile range if non-normally distributed. The Student’s t-test was performed for comparison of continuous variables, and chi-square test for categorical variables. A two-tailed P < 0.05 was considered statistically significant.
Study participants and demographic characteristics
A total of 428 cases with positive CSF cultures were retrospectively reviewed, including infections by A. baumannii (n = 145, 33.88%), Klebsiella pneumonia (n = 81, 18.93%), Staphylococcus epidermidis (n = 33, 7.71%), Staphylococcus aureus (n = 16, 3.74%), Pseudomonas aeruginosa (n = 11, 2.57%), and others such as Klebsiella oxytoca, Cryptococcus neoformans. Among the 145 cases with A. baumannii-positive CSF cultures, 84 subjects were excluded, and a total of 61 patients with intracranial infection due to MDR/XDR-Ab after neurosurgery were finally enrolled. There were 38 cases in the intravenous group and 23 cases in the intrathecal/intracerebral group. The baseline characteristics of these patients according to the two groups are summarized in Table 1, and no significant differences were observed in characteristics including age, sex, underlying disease, surgical history, use of external CSF drainage tube, APACHE II score, or SOFA score.
Susceptibility testing and antimicrobial therapies
Susceptibility testing results for isolated A. baumannii
ITV + ITC group
(n = 61)
(n = 38)
(n = 23)
Antibiotic resistance (n, %)
R ≥ 32
R ≥ 8
R ≥ 8
R ≥ 8
R ≥ 32
R ≥ 32
R ≥ 64
R ≥ 32
R ≥ 4
The initially applied empirical antimicrobial therapies
Total (n = 61)
ITV group (n = 38)
ITV + ITC group (n = 23)
Before infection (n, %)
M/I + vancomycin
M/I + linezolid
M/I + cefperazone-sulbactam
Tigecycline + cefperazone-sulbactam
Cefperazone-sulbactam + vancomycin
After infection (n, %)
M/I + amikacin
M/I + tigecycline
M/I + cefperazone-sulbactam
Cefperazone-sulbactam + amikacin
Microbiological clearance and biochemistry indicators of CSF
Among the 61 patients with A. baumannii infection, the earliest death occurred on day two, and the total mortality rate was 37.70%. In the intravenous group, the mortality rate was 55.26% (21/38), while in the intrathecal/intracerebral group, the mortality rate was 8.70% (2/23; P = 0.01).
As renal function impairment is one of the side effects of polymyxin B treatment, we analyzed the changes in serum creatinine from before to after polymyxin B treatment. The mean creatinine level was 41.09 ± 11.46 μmol/L at 48 h after polymyxin B injection, which did not differ significantly from the baseline level (41.09 ± 11.46 μmol/L; P = 0.799).
A. baumannii is an opportunistic pathogen. The CHINET surveillance of bacterial resistance (2005–2014)  reported that A. baumannii accounts for 8.7–12.1% of clinical isolates in China, with the total number of bacterial isolates was ranging from 22,774–84,572 annually. In the current study, A. baumannii accounted for 33.88% of all isolates, which was considerably higher than the frequency noted in the 2005–2014 CHINET surveillance report. The reasons might be as follows: first, the incidence of A. baumannii infection is increasing; second, most of the patients recovering from neurosurgery were in an immune compromised state. Some had acquired artificial devices such as an external ventricular drain or intraventricular catheter, and some had hospitalized for a long time and had already received broad-spectrum antibiotics. All of these conditions are known risk factors for developing A. baumannii infection .
A. baumannii tends to quickly develop resistance to multiple antimicrobial agents through various mechanisms, such as through degrading enzymes targeting β-lactams, modifying enzymes targeting aminoglycosides, and alteration to the binding sites for quinolones . A report from the SENTRY antimicrobial surveillance program (2001–2004)  showed that the resistance rates of A. baumannii exceeded 25% for imipenem and meropenem, 40% for cefepime and ceftazidime, 35% for amikacin, and 45% for ciprofloxacin. The CHINET surveillance report (2005–2014) from China  showed the resistance rate of A. baumannii for imipenem approximately doubled from 31% in 2005 to 62.4% in 2014, while that for meropenem increased from 39% in 2005 to 66.7% in 2014. Cefepime and ceftazidime resistance levels ranged from 54.8%–67.6% and 52.4%–71.9%, respectively, and amikacin and ciprofloxacin resistance levels ranged from 40.2%–61% and 60%–68.3%, respectively. In the present study, we found that 49.36% of A. baumannii isolates were MDR and 28.47% were XDR, with resistance to carbapenems (resistance rate of 100% for both imipenem and meropenem), cephalosporins (98.38% for cefazolin, 100% for ceftazidime, 100% for cefatriaxone, and 98.38% for cefepime). In comparison to the findings of the SENTRY antimicrobial surveillance report (2001–2004) and CHINET surveillance report (2005–2014), we observed major increases in the resistance of A. baumannii to these antibiotics. These results suggest that the treatment of A. baumannii is becoming more complicated, especially in the intensive care unit (ICU) where broad spectrum antimicrobials are commonly used.
For the initial empirical antimicrobial therapy, carbapenems, as broad-spectrum β-lactam antibiotics, have remained the first-line agents for patients who are immunocompromised or have had a prolonged period of hospitalization even though the prevalence of carbapenem-resistant bacteria is increasing . Meropenem/imipenem is active against carbapenemase-negative A. baumannii isolates, but inactive against A. baumannii isolates that express plasmid-mediated carbapenemases . Sulbactam is a β-lactamase inhibitor with intrinsic antibacterial activity against many Acinectobacter isolates, which is related to its affinity for penicillin-binding proteins . It can be effective against infections caused by moderately imipenem-resistant isolates . Because the combination of sulbactam and carbapenems showed better results than carbapenems alone for MDR-Ab infections , the combination of meropenem/imipenem and other antibiotics have been used as initial empirical therapy in our hospital. Considering that polymyxins are expensive and not easily accessible in China, after confirmation of MDR/XDR-Ab, most of the patients in the intravenous group received tigecycline together with cefperazone-sulbactam or meropenem/imipenem, but this did not effectively reduce mortality, which we attribute to the weak dispersion of tigecycline in CSF .
Consistent with the results of the CHINET report , the results of the present study demonstrate that A. baumannii is highly sensitive to polymyxins (100.00%), tigecycline (60.66%), and amikacin (49.18%). Thus, polymyxins may be an ideal antibiotic for the treatment of MDR/XDR-Ab, as they effectively and rapidly kill most Gram-negative microorganisms. The 2017 Infectious Diseases Society of America (IDSA) Clinical Practice Guide recommends that colistin or polymyxin B be administered intravenously and intraventricularly for the treatment of intracranial infections caused by carbapenem-resistant Acinetobacter species , but the quality of evidence is moderate as is mentioned in the Guide. In a retrospective study, Moon et al.  found that colistimethate-containing regimens could cure post-neurosurgical meningitis caused by carbapenem-resistant A. baumannii. Fotakopoulos et al.  reported that the combination of intravenous and intraventricular colistin may improve outcomes in patients with meningitis/ventriculitis due to multidrug resistance infections, especially that attributed to A. baumannii. Guardado et al.  studied intracranial infections caused by MDR/XDR-Ab after neurosurgery and found that intravenous injection along with intrathecal/intraventricular injection of polymyxin resulted in a significant reduction in mortality [0 vs. 80%, P = 0.04, odds ratio [OR]: 1.69 (1.32–2.16)]. Although a satisfactory result was achieved by intrathecal/intracerebral ventricle injection of polymyxins, the evidence remains rather weak as it stems from clinical studies or case series with small sample numbers. To our knowledge, our current study is the largest cohort study to date to compare the efficacy of intravenous combined with intrathecal/intracerebral ventricle injection of polymyxin B for intracranial infection due to MDR/XDR-Ab in post-neurosurgical patients. The intrathecal/intraventricular group showed significant improvement in microbiological eradication, biochemistry indicators of CSF, clinical efficiency, and 28-day mortality compared with the intravenous group. A retrospective case-control study analyzed the efficacy of intravenous plus intrathecal injection of colistin in 18 cases with XDR-Ab meningitis in the past 11 years . It showed that the CSF sterilization rate was only 33.3% after treatment with intravenous administration of colistin alone, but reached complete sterilization with a rate of 100% after combination treatment with intravenous plus intraventricular injection of colistin (P = 0.009). These sterilization rates were similar to ours calculated in the present study. In Karaiskos’ study , the all-cause mortality rate of patients with intracranial infection caused by MDR/XDR-Ab was 71%, while the all-cause mortality rate in our study was only 47.54% (29/61). This could partially explain why intrathecal/intraventricular injection of polymyxin B significantly improved the survival rate, although it is impossible to discern the definitive cause of mortality. Evidence has revealed that the level of colistin in CSF is only 5–10% of that in blood when using intravenous administration only . Moreover, the administration of polymyxin with direct intrathecal/intraventricular injection could increase the penetration of polymyxins into the central nervous system. Together with our study, all these findings suggest that a combination treatment with intravenous and intrathecal/intraventricular polymyxins be superior to routine intravenous antibiotics for the treatment of patients with an intracranial infection due to MDR/XDR-Ab.
A last-line treatment for infections that are resistant to other available antibiotics, the polymyxins antibiotics (including colistin and polymyxin B) are potentially nephrotoxic, but the relative risk of this adverse effect is still unclear . Early reports revealed that use of more than the recommended dosage of colistin (2.5–5 mg/kg/day) was associated with an adverse renal reaction [29–31]. Additional research suggested that the incidence of nephrotoxic effects is higher with colistimethate than with polymyxin B . In the present study, 61 patients received polymyxin B at a dose of 450,000 units per 12 h intravenously and at the same time received intrathecal/intraventricular injection of polymyxin B at 50,000 units/day. No cases of acute kidney injury were observed among the study participants according to the KDIGO guidelines , and several studies have shown that intravenous polymyxins is not associated with serious renal toxicity if the dosage is proper [34, 35]. Thus, the method of polymyxin B administration in the current study might be relatively safe for renal function. Notably, since the kidney is the primary route of elimination for polymyxins, the dosage must be carefully monitored .
Intravenous along with intrathecal/intracerebral injection of polymyxins might not only be effective for MDR/XDR-Ab but also have significant effects on other multidrug-resistant gram-negative bacteria. Macedo et al.  reported that intraventricular therapy with polymyxins improved outcomes in patients presenting with meningoencephalitis due to multidrug-resistant Gram-negative bacteria infections (A. baumannii, P. aeruginosa, etc.), with no cases of neurotoxicity and nephrotoxicity. In the study by Falagas et al. , intraventricular and intrathecal polymyxins (alone or with systemic antibiotics) were effective for Gram-negative meningitis (P. aeruginosa, A. baumannii, etc), and that toxicity is not uncommon but is usually dose-dependent and reversible. Therefore, taken together, these results suggest that intrathecal/intracerebral of polymyxins is an effective treatment strategy against intracranial infection by MDR/XDR-Ab or other MDR/XDR gram-negative bacteria without toxicity.
There were some limitations in this study. (1) This was a single-center retrospective study, and thus, further multicenter randomized controlled studies (prospective or retrospective) are needed. (2) The sample size in our current study (n = 61) was still small and needs to be expanded. (3) The most significant adverse effects of intraventricular or intrathecal injection that have been reported are chemical ventriculitis and meningitis. This study did not evaluate the neurotoxicity of polymyxin B nor obtain any dynamic records on changes in consciousness (such as the Glasgow Coma Scale score) and other clinical indicators due to the retrospective nature of the study. (4) Polymyxins must be bought from outside China, and they are too expensive for some patients.
Intravenous plus intrathecal/intraventricular injection of polymyxin B can effectively improve levels of CSF indicators and support clinical efficiency, microbiologic eradication, and 28-day mortality without adverse effects, which might be a promising strategy to treat intracranial infections due to MDR/XDR-Ab.
This work was supported in part by grants from the National Natural Science Foundation of China (No. 81570017 to GS Zhang), the Medical and Health Research Program of Zhejiang Province (Core Talents Plan) of Zhejiang Province (No. 2016RCA014 to GS Zhang), and the Medical and Health Research Program of Zhejiang Province (No. 2017KY371 to GS Zhang).
Availability of data and materials
All data generated or analyzed during this study are included in this manuscript.
SJ, XF and YS contributed to the acquisition and analysis of the data and writing the initial draft of this paper. LL, CY, ZX and CW contributed to the collection and interpretation of data. GS contributed to the concept of the study, the revision of this paper, and the final approval of the version to be published. SJ, XF and YS contributed equally to this work. All authors read and approved the final manuscript.
Ethics approval and consent to participate
This study was approved by the Ethics Committee of the 2nd Affiliated Hospital, School of Medicine, Zhejiang University (NO. 2017–048). The requirement of patient consent to participate is not applicable due to the retrospective nature of the study.
Consent for publication
The authors declare that they have no competing interests.
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- Ruan L, Wu D, Li X, et al. Analysis of microbial community composition and diversity in postoperative intracranial infection using high-throughput sequencing. Mol Med Rep. 2017;16(4):3938–46.View ArticleGoogle Scholar
- Dettenkofer M, Ebner W, Els T, Babikir R, Lucking C, Pelz K, Ruden H, Daschner F. Surveillance of nosocomial infections in a neurology intensive care unit. J Neurol. 2001;248(11):959–64.View ArticleGoogle Scholar
- Jiang L, Guo L, Li R, Wang S. Targeted surveillance and infection-related risk factors of nosocomial infection in patients after neurosurgical operation. Pak J Pharm Sci. 2017;30(3(Special)):1053–6.PubMedGoogle Scholar
- Kasiakou SK, Rafailidis PI, Liaropoulos K, Falagas ME. Cure of post-traumatic recurrent multiresistant gram-negative rod meningitis with intraventricular colistin. J Inf Secur. 2005;50(4):348–52.Google Scholar
- Bergogne-Berezin E, Towner KJ. Acinetobacter spp. as nosocomial pathogens: microbiological, clinical, and epidemiological features. Clin Microbiol Rev. 1996;9(2):148–65.View ArticleGoogle Scholar
- Rodriguez Guardado A, Blanco A, Asensi V, Perez F, Rial JC, Pintado V, Bustillo E, Lantero M, Tenza E, Alvarez M, et al. Multidrug-resistant Acinetobacter meningitis in neurosurgical patients with intraventricular catheters: assessment of different treatments. J Antimicrob Chemother. 2008;61(4):908–13.View ArticleGoogle Scholar
- Imberti R, Cusato M, Accetta G, Marino V, Procaccio F, Del Gaudio A, Iotti GA, Regazzi M. Pharmacokinetics of colistin in cerebrospinal fluid after intraventricular administration of colistin methanesulfonate. Antimicrob Agents Chemother. 2012;56(8):4416–21.View ArticleGoogle Scholar
- Lonsdale DO, Udy AA, Roberts JA, Lipman J. Antibacterial therapeutic drug monitoring in cerebrospinal fluid: difficulty in achieving adequate drug concentrations. J Neurosurg. 2013;118(2):297–301.View ArticleGoogle Scholar
- De Bonis P, Lofrese G, Scoppettuolo G, Spanu T, Cultrera R, Labonia M, Cavallo MA, Mangiola A, Anile C, Pompucci A. Intraventricular versus intravenous colistin for the treatment of extensively drug resistant Acinetobacter Baumannii meningitis. Eur J Neurol. 2016;23(1):68–75.View ArticleGoogle Scholar
- Sandri AM, Landersdorfer CB, Jacob J, et al. Population pharmacokinetics of intravenous polymyxin B in critically ill patients: implications for selection of dosage regimens. Clin Infect Dis. 2013;57(4):524–31.View ArticleGoogle Scholar
- Tunkel AR, Hasbun R, Bhimraj A, Byers K, Kaplan SL, Michael Scheld W, van de Beek D, Bleck TP, Garton HJ, Zunt JR. Infectious Diseases Society of America's clinical practice guidelines for healthcare-associated Ventriculitis and meningitis. Clin Infect Dis. 2017; https://doi.org/10.1093/cid/ciw861. Epub ahead of print.
- Durand ML, Calderwood SB, Weber DJ, Miller SI, Southwick FS, Caviness VS Jr, Swartz MN. Acute bacterial meningitis in adults. A review of 493 episodes. N Engl J Med. 1993;328(1):21–8.View ArticleGoogle Scholar
- Magiorakos AP, Srinivasan A, Carey RB, Carmeli Y, Falagas ME, Giske CG, Harbarth S, Hindler JF, Kahlmeter G, Olsson-Liljequist B, et al. Multidrug-resistant, extensively drug-resistant and pandrug-resistant bacteria: an international expert proposal for interim standard definitions for acquired resistance. Clin Microbiol Infect. 2012;18(3):268–81.View ArticleGoogle Scholar
- Clinical and Laboratory Standards Institute. Performance standards for antimicrobial susceptibility testing: 26st informational supplement M100–S26. Wayne: CLSI; 2016.Google Scholar
- Hu FP, Guo Y, Zhu DM, Wang F, Jiang XF, Xu YC, Zhang XJ, Zhang CX, Ji P, Xie Y, et al. Resistance trends among clinical isolates in China reported from CHINET surveillance of bacterial resistance, 2005-2014. Clin Microbiol Infect. 2016;22(Suppl 1):S9–14.View ArticleGoogle Scholar
- Howard A, O’Donoghue M, Feeney A, Sleator RD. Acinetobacter Baumannii: an emerging opportunistic pathogen. Virulence. 2012;3(3):243–50.View ArticleGoogle Scholar
- Peleg AY, Seifert H, Paterson DL. Acinetobacter Baumannii: emergence of a successful pathogen. Clin Microbial Rev. 2008;21(3):538–82.View ArticleGoogle Scholar
- Gales AC, Jones RN, Sader HS. Global assessment of the antimicrobial activity of polymyxin B against 54 731 clinical isolates of gram-negative bacilli: report from the SENTRY antimicrobial surveillance programme (2001-2004). Clin Microbiol Infect. 2006;12(4):315–21.View ArticleGoogle Scholar
- Jones RN, Huynh HK, Biedenbach DJ. Activities of doripenem (S-4661) against drug-resistant clinical pathogens. Antimicrob Agents Chemother. 2004;48(8):3136–40.View ArticleGoogle Scholar
- Bassetti M, Righi E, Esposito S, Petrosillo N, Nicolini L. Drug treatment for multidrug-resistant Acinetobacter Baumannii infections. Future Microbiol. 2008;3(6):649–60.View ArticleGoogle Scholar
- Corbella X, Ariza J, Ardanuy C, Vuelta M, Tubau F, Sora M, Pujol M, Gudiol F. Efficacy of sulbactam alone and in combination with ampicillin in nosocomial infections caused by multiresistant Acinetobacter Baumannii. J Antimicrob Chemother. 1998;42(6):793–802.View ArticleGoogle Scholar
- Lee NY, Wang CL, Chuang YC, Yu WL, Lee HC, Chang CM, Wang LR, Ko WC. Combination carbapenem-sulbactam therapy for critically ill patients with multidrug-resistant Acinetobacter Baumannii bacteremia: four case reports and an in vitro combination synergy study. Pharmacotherapy. 2007;27(11):1506–11.View ArticleGoogle Scholar
- Ceylan B, Arslan F, Sipahi OR, et al. Variables determining mortality in patients with Acinetobacter Baumannii meningitis/ventriculitis treated with intrathecal colistin. Clin Neurol Neurosurg. 2017;153:43–9.View ArticleGoogle Scholar
- Moon C, Kwak YG, Kim BN, Kim ES, Lee CS. Implications of postneurosurgical meningitis caused by carbapenem-resistant Acinetobacter Baumannii. J Infect Chemother. 2013;19(5):916–9.View ArticleGoogle Scholar
- Fotakopoulos G, Makris D, Chatzi M, Tsimitrea E, Zakynthinos E, Fountas K. Outcomes in meningitis/ventriculitis treated with intravenous or intraventricular plus intravenous colistin. Acta Neurochir. 2016;158(3):603–10. discussion 610View ArticleGoogle Scholar
- Karaiskos I, Galani L, Baziaka F, Giamarellou H. Intraventricular and intrathecal colistin as the last therapeutic resort for the treatment of multidrug-resistant and extensively drug-resistant Acinetobacter Baumannii ventriculitis and meningitis: a literature review. Int J Antimicrob Agents. 2013;41(6):499–508.View ArticleGoogle Scholar
- Markantonis SL, Markou N, Fousteri M, Sakellaridis N, Karatzas S, Alamanos I, Dimopoulou E, Baltopoulos G. Penetration of colistin into cerebrospinal fluid. Antimicrob Agents Chemother. 2009;53(11):4907–10.View ArticleGoogle Scholar
- Nation RL, Li J, Cars O, et al. Framework for optimisation of the clinical use of colistin and polymyxin B: the Prato polymyxin consensus. Lancet Infect Dis. 2015;15(2):225–34.View ArticleGoogle Scholar
- Randall RE, Bridi GS, Setter JG, Brackett NC. Recovery from colistimethate nephrotoxicity. Ann Intern Med. 1970;73(3):491–2.View ArticleGoogle Scholar
- Price DJ, Graham DI. Effects of large doses of colistin sulphomethate sodium on renal function. Br Med J. 1970;4(5734):525–7.View ArticleGoogle Scholar
- Koch-Weser J, Sidel VW, Federman EB, Kanarek P, Finer DC, Eaton AE. Adverse effects of sodium colistimethate. Manifestations and specific reaction rates during 317 courses of therapy. Ann Intern Med. 1970;72(6):857–68.View ArticleGoogle Scholar
- Akajagbor DS, Wilson SL, Shere-Wolfe KD, Dakum P, Charurat ME, Gilliam BL. Higher incidence of acute kidney injury with intravenous colistimethate sodium compared with polymyxin b in critically ill patients at a tertiary care medical center. Clin Infect Dis. 2013;57(9):1300–3.View ArticleGoogle Scholar
- Khwaja A. KDIGO clinical practice guidelines for acute kidney injury. Nephron Clin Pract. 2012;120(4):c179–84.Google Scholar
- Reina R, Estenssoro E, Saenz G, Canales HS, Gonzalvo R, Vidal G, Martins G, Das Neves A, Santander O, Ramos C. Safety and efficacy of colistin in Acinetobacter and pseudomonas infections: a prospective cohort study. Intensive Care Med. 2005;31(8):1058–65.View ArticleGoogle Scholar
- Falagas ME, Rizos M, Bliziotis IA, Rellos K, Kasiakou SK, Michalopoulos A. Toxicity after prolonged (more than four weeks) administration of intravenous colistin. BMC Infect Dis. 2005;5:1.View ArticleGoogle Scholar
- Evans ME, Feola DJ, Rapp RP. Polymyxin B sulfate and colistin: old antibiotics for emerging multiresistant gram-negative bacteria. Ann Pharmacother. 1999;33(9):960–7.View ArticleGoogle Scholar
- Macedo S, Gonçalves I, Bispo G, et al. Intrathecal (intraventricular) polymyxin B in the treatment of patients with meningoencephalitis by Acinetobacter baumanii and Pseudomonas Aeruginosa. Crit Care. 2011;15(S1):P235.View ArticleGoogle Scholar