Abstract
Background
Cerebrospinal fluid (CSF) drainage or intracranial pressure (ICP) monitoring devices are life-saving devices. We examined the risk factors for infections related to them and assessed the effect of an infection control (IC) intervention.
Methods
A prospective observational study was conducted in the Neurosurgical Department of our hospital between 2014 and 2017. We included all consecutive patients undergoing CSF catheter insertions, including external ventricular drainage (EVD), lumbar drainage (LD), and ICP catheters. An IC intervention was implemented between March and August 2016. We examined risk factors for meningitis or ventriculitis, defined according to Healthcare-associated infections surveillance definitions, on univariate and multivariate analysis.
Results
A total of 232 patients with 437 drains (212 EVDs, 92 LDs, and 133 ICPs) were included. On univariate and multivariate analysis, the infection incidence was 13.7 per 1000 drain days (17.3/1000 before IC intervention, 7.9/1000 during, and 9.2/1000 after the intervention). Most episodes were caused by Gram-negative bacteria, and the most common pathogen was Acinetobacter baumanii. Risk factors for infection per patient included diabetes mellitus (p = 0.017), CSF leak (p = 0.032), drain opening (p = 0.027), and the duration of the drain in days (p = 0.035). Risk factors per catheter included drain opening (p < 0.001), drain days (p = 0.001), and the IC intervention period compared to before the intervention period (p = 0.037). When restricting the analysis to EVDs, drain days (p = 0.001) was the only significant risk factor.
Conclusions
Strict adherence to IC, shortening drain duration, and avoiding unnecessary opening and manipulation of the drains are crucial to preventing neurosurgical drain infections.
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Background
Devices such as external ventricular drain (EVD), intracranial pressure (ICP), and lumbar drain (LD) are crucial for the management of elevated ICP, hemorrhage, and monitoring in neurosurgical patients [18]. These devices, while lifesaving, also carry significant complications, including hemorrhage, misplacement, blockage and, most significantly, infections. EVD-related infections may arise from catheter colonization by inoculation of skin flora during insertion or from the manipulation of the drainage system during the postoperative period [34].
The estimated ventriculostomy-related infection incidence rates range between 0 and 27% [9, 12, 22, 26, 28], the wide range being both real and artefactual due to differences in infection definitions. A few previous studies have addressed LD-related infection and rates ranging from 3 to 10% [28, 29]. Device-related infections present typically as meningitis caused by pathogens common to other post-neurosurgical meningitis [31] and infrequently as other central nervous system (CNS) infections. These infections are associated with high rates of morbidity and mortality, significantly prolonging hospital stay, increasing costs, and often negatively affecting the overall prognosis [20, 23, 34].
The aims of our study were to examine the risk factors for central nervous system (CNS) infections among patients with CSF drains by type of drain (EVD, ICP, LD) and to assess the effects on an infection control intervention targeting improved management of CSF drains.
Methods
Design and study participants
We conducted a prospective observational cohort study including all consecutive adult patients undergoing insertion of EVD, ICP monitor, and LD in the neurosurgical intensive care unit (ICU) at Rambam Health Care Campus between October 2014 and June 2017. The hospital serves as a primary and referral center for the north of Israel. The Neurosurgery Department at Rambam has 1630 admissions and 1240 surgical procedures yearly, with 12 ICU beds. Follow-up started at the time of catheter insertion and continued until discharge from the neurosurgical ICU or death.
Exposure
Between March and August 2016, the Infection Control Unit conducted an intervention, starting with the publication and implementation of local guidelines for CNS device insertion and maintenance (Supplement 1). In addition, contact isolation of multidrug-resistant (MDR) bacteria was revised, introducing cohorting of MDR carriers in one section of the neurosurgical ICU and a physical separation between MDR carriers and all other patients. The intervention included educational sessions delivered in staff meetings and daily observation of staff adherence to the guidelines, hand hygiene, isolation precaution, and environmental cleanliness. Feedback was sent daily to the nursing and medical department heads.
Outcome (dependent variable)
The outcome assessed was device-related infection. Since there are no universally accepted definitions of CNS device-related infections, for the purposes of our study, it was defined as meningitis/ventriculitis in the presence of EVD/LD/ICP, or within 30 days after its removal if no intervening surgical procedure was performed. Meningitis/ventriculitis was defined using the CDC/NHSN surveillance definition for healthcare-associated infections, which is based on positive cultures, clinical symptoms, and laboratory findings [11]. In the case of Staphylococcus epidermidis, the diagnosis was made if there were at least two positive separate cultures. The incidence of device-related infection was expressed per catheter day, as previously reported [2, 8, 29], applying similar rules regarding multiple drains, such as the CDC/NHSN’s Central Line-Associated Bloodstream Infection surveillance definitions [14].
Independent risk factors
Data were collected on risk factors for infection, including the following:
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1.
Baseline patient characteristics: age, gender, admission neurosurgical diagnosis, previous hospitalization in the 90 days before current admission, home vs. long-term care facility dwell, previous neurosurgery, underlying diseases, Charlson’s score [7], CSF leak, presence of CNS foreign body or VP shunt prior to catheter insertion, previous CNS drain, presence of permanent urinary catheter prior to admission, presence of other catheters, and length of stay before drain insertion
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2.
Procedure characteristics: reason for device insertion, place and date of insertion, antimicrobial prophylaxis, length of procedure, type of catheter, and incision closure type
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3.
Device management: use of a closed system, type of drainage bag, number of CSF samplings from the catheter, date of catheter removal, and reason for catheter removal
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4.
Infection control: Adherence to the infection control guidelines for device insertion and maintenance, hand hygiene, standard precautions, and contact isolation
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5.
Device-related infection and other outcomes: CSF findings including Gram stain and culture, systemic symptoms at time of infection diagnosis, systemic and intrathecal antibiotic treatment, and type and days of antibiotic treatment. In addition, we documented the total length of hospital stay and all-cause in-hospital mortality.
Patient management and data collection
Data were collected prospectively by an infection control nurse and as part of the infection control activities in the department and were complemented by a review of patients’ computerized charts. EVDs and ICPs were inserted in the operating room, while most LDs were inserted on the ward at bedside. Meningitis was managed according to published and local guidelines, the latter considering the local epidemiology [13, 35].
Statistical analysis
We calculated the incidence of device-related infections as the number of device-related infections per catheter-day for the study period overall and per catheter type (EVD, LD, ICP), and before, during, and after the infection control intervention. We assessed risk factors for device-related infection, comprising the exposure coded as the period before the intervention, the intervention period, and after the intervention. In the primary analysis, the counting unit was the patient, assessing the first catheter insertion per patient. In a secondary analysis, the counting unit was catheters, assessing separately each catheter per patient, overall and for EVDs alone. In the catheter-based analysis, for patients having concomitantly two catheters, we counted the highest risk catheter, ranked as EVD > LD > ICP. Normally distributed continuous variables were expressed as means ± SD and compared by Student’s t test; skewed variables were expressed as medians with IQRs and compared using the Mann–Whitney U test. Categorical data were compared using the chi-square test or Fisher’s exact test as appropriate. We entered variables found significant on univariate analysis and non-correlated statistically and clinically to a backward stepwise logistic regression model to define variables associated independently with device-related infections. Adjusted odds ratios (OR) with 95% confidence intervals (CI) are reported. Data were analyzed using SPSS V23.
Results
During the study period, 232 patients were included, 167 (72%) of whom were males. Mean age was 50 ± 20 years. The causes of admission were trauma (126, 54.3%), infection (13, 5.6%), and other causes (93, 40.1%), including spontaneous hemorrhage, brain tumors, and hydrocephalus.
The patients received 437 drains. Of these, 212 were EVDs, 92 were LDs, and 133 were ICPs. Indications for drain insertion included hydrocephalus/increased ICP (124, 28.4%), trauma (167, 38.2%), intracerebral hemorrhage (55, 12.6%), subarachnoid hemorrhage (45, 10.3%), infection (29, 6.6%), and CSF leak (17/437, 3.9%). Fifty-three episodes (12%) of meningitis (in 38 patients) were identified with a rate of 13.7 episodes per 1000 drain days. In the period preceding the IC intervention, the rate was 17.3 per 1000 drain days; during the intervention, the rate dropped to 7.9/1000, increasing slightly after the intervention to 9.2/1000 drain days. A microbiological diagnosis was confirmed in 34 (64%) of the cases. The majority of cases (24, 70.5%) were due to Gram-negative bacteria including carbapenem-resistant Acinetobacter baumannii (13, 38.2%), Klebsiella pneumoniae (9, 26.5%), and Pseudomonas aeruginosa (2, 5.9%). Three of the episodes with Acinetobacter baumannii were polymicrobial (Enterobacter sp., Enterococcus faecalis and Staphylococcus epidermidis). Other pathogens included Staphylococcus epidermidis (4, 11.8%), Candida sp. (3, 8.8%), Staphylococcus aureus (1 MSSA, 1 MRSA, 5.9%), and Enterococcus faecalis (1, 2.9%). The 30-day mortality rate 7.5% (4/53).
Analysis per patient
In the analysis of the first catheter insertion per patient (25 patients with meningitis), risk factors for infection on univariate analysis included diabetes mellitus (p = 0.006), Charlson’s score > 2 (p = 0.045), CSF leak present before catheter insertion (p = 0.029), drain type (EVD > LD > ICP, p = 0.007), drain opening (p < 0.005), and drain days (p < 0.005) (Table 1). Variables remaining significant on multivariate analysis included diabetes mellitus, CSF leak, drain opening, and drain days (Table 2).
Analysis per catheter, all catheters
On univariate analysis, taking the catheter as the observation unit (53 episodes of meningitis), risk factors for device-related infection included diabetes mellitus (p = 0.016), hospitalization in the 90 days before current admission (p = 0.021), length of stay before drain insertion (p = 0.045), drain type (EVD > ICP and LD, p = 0.002), drain opening (p < 0.005), and the study period (before intervention, intervention period, and after intervention, p = 0.024) (Table 3). On multivariate analysis, the significant risk factors retained in the final model were drain days, drain opening, and the infection control intervention period compared to before the intervention (OR 0.3, 95% CI 0.09–0.93). The odds for meningitis were non-significantly lower in the period after the intervention compared to the baseline period before (OR 0.57, 95% CI 0.24–1.33) (Table 2).
Analysis per catheter, EVD only
Restricting the analysis to EVDs, infection incidence decreased from 18.7/1000 EVD days (29 cases) before the intervention to 9.5/1000 EVD days (4 cases) during the intervention and 8.6/1000 EVD days (4 cases) post-intervention. On univariate analysis, diabetes mellitus (0.028), drain number (0.047), drain insertion in the first three hospitalization days (0.044), drain opening (< 0.005), and drain days (< 0.005) were associated with the occurrence of meningitis (Supplementary Table 1). In the adjusted analysis, drain days was the only statistically significant risk factor. The odds for meningitis were non-significantly lower during (OR 0.38, 95% CI 0.11–1.29) and after (OR 0.38, 95% CI 0.12–1.26) the IC intervention.
Discussion
In this study, we assessed risk factors for neurosurgical drain infections. In all analyses, drain days and drain opening were significant risk factors. When assessing the first catheter inserted per patient, diabetes mellitus and CSF leak were significantly related to infection. Taking into account all drains, the IC intervention was significantly associated with the risk for drain-related infections.
Several previous studies assessed risk factors for infections related to neurosurgical drains, mainly for EVD, and a few assessed LD or ICP also [1, 2, 5, 6, 9, 10, 24, 25, 30, 33, 37]. Most studies are retrospective and limited by a small number of outcome events, limiting complete adjustment of multiple risk factors. Risk factors for EVD-related infection included the duration of the drain [1, 2, 9, 10, 22, 25, 28, 30, 33], intracerebral hemorrhage with intraventricular hemorrhage [22], concurrent systemic infections [6, 33], multiple drains [25], drain type (LD in a study assessing EVDs and LDs) [29], neurosurgical procedures after drain insertion [37], previous meningo-ventriculitis [29], neoplasm [29], drain insertion outside operation room [6], CSF leakage [28], and frequent manipulation of the EVD system [22]. As for LDs, risk factors for infection included site leakage, drain blockage, and drain duration [19, 28]. Our study was prospective and assessed all three types of drains. We did not attempt to assess the effect of a single intervention but assessed a bundle of interventions, recognizing that single manipulations in catheter management cannot reduce infection rates. We show that a coordinated effort, addressing catheter insertion, opening, and replacement and IC was associated with lower infection rates, adjusting to other risk factors.
The association between drain duration and infection was observed in many of the previous studies [1, 2, 9, 10, 22, 25, 28, 30, 33]. The cutoff defining an increased risk for infection is debated. EVD duration > 10 days was the time point identified for an increased risk in a recent retrospective matched case-control study [33]. In earlier studies, including a review summarizing 17 studies [20], the authors observed a gradual daily increase in infection rate, peaking at 9–11 days [20]. Similarly, Holloway et al. found that the risk increased in the first 10 days but decreased significantly thereafter [10]. In a study that included EVD and LD drains, duration > 15 days increased the risk for infection seven times compared to drains with a shorter duration [28]. Other studies pointed at 5–6-day duration as the cutoff for increased risk for infection [10, 22]. A precise cutoff probably does not exist, as the risk increases from day to day. Variations between studies may reflect local practices in each center and the timing of infection inoculation: during EVD insertion or during daily handling and maintenance.
During an IC intervention to improve staff adherence to IC practices, we observed that the infection rate decreased from 17.3 per 1000 drain days before the intervention to 7.9/1000 after the intervention. Our rate of EVD-related meningitis specifically, during and following the intervention period (9.5–8.6/1000 EVD days), was in the low range of rates in previous studies reporting on EVD-related meningitis per catheter day (4.8–17.2/1000 EVD days) in the UK and Ireland [12], Russia [27], and Switzerland [32]. In the analysis per patient, patient-related factors dominated, while the effect of the IC intervention was observed in the analysis per catheter. Improvement of adherence to EVD insertion and management protocols or bundles to lower drain-related complications have been shown previously to reduce infection rates [2, 3, 16, 17, 21]. As for all bundle interventions, it is difficult to point at the precise component/s of the bundle that were effective. The IC intervention included two of the dominant risk factors in our study, attention to drain duration and reduction of unnecessary drain openings and replacements. However, since the study period was associated with lower infection rates independent of these risk factors, additional components of the bundle must have contributed to lowering the infection rates. A trend towards increasing infection rates after the intervention, if true, might be due to relaxation of the monitoring and education activities and points at the need for continued intense efforts to maintain infection control achievements.
Previous studies showed Gram-positive bacteria, mainly coagulase negative Staphylococci, to be the main pathogens causing neurosurgical drain-related infection [8, 15, 19, 28, 29, 33, 36, 37]. In the current study, there was a predominance of Gram-negative bacteria, especially carbapenem-resistant Acinetobacter baumannii. The emergence of Gram-negative pathogens as the main pathogen was reported in post-neurosurgical meningitis [2, 4]. It reflects the changing epidemiology of nosocomial infections and the emergence of MDR Gram-negative pathogens as a major threat for healthcare institutions. We show that an IC intervention can affect infection rates when infections are caused by MDR Gram-negative bacteria.
The main limitation of our study is that it was conducted in a single center. The methodologically correct analysis is per patient. However, the analysis by catheter, counting patients more than once in the analysis, allowed us to better inspect variables related the individual catheter insertion and maintenance. We did not adjust for clustering in the catheter-based analysis. We did not perform a time series analysis, due to low outcome event-rates; however, the cohort design allowed us to adjust the study period to important risk factors for device-related meningitis. Other healthcare-associated infections, including central-venous catheter infections and ventilator-associated pneumonia, were not surveilled during the study period.
In conclusion, strict adherence to infection control is mandatory to prevent neurosurgical drain infections. Shortening drain duration and avoiding unnecessary opening and manipulation of the drains are crucial to preventing drain-related infections. This requires coordination and collaboration of the neurosurgical and IC teams.
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All procedures performed in studies involving human participants were in accordance with the ethical standards of the institutional and/or national research committee (Helsinki Committee, Rambam Medical Center) and with the 1964 Helsinki declaration and its later amendments or comparable ethical standards. For this type of study formal consent was not required.
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This is a well performed prospective study of the infectious complications of CNS externalized catheters and monitoring devices. The authors identified already known risk factors such as diabetes, duration of catheter presence, and device sampling rates as the prime culprits in increasing infection rates. The favourable effect of simple infection control interventions is an important observation and mirrors the effectiveness of similar protocols in other invasive monitoring procedures as reported in the literature. The health and economic burden of increasingly multi-drug resistant infections due to CNS drains makes the implementation of infection control protocols a no brainer for health care institutions.
Zvi Harry Rappaport
Petah Tiqvah, Israel
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Hussein, K., Rabino, G., Feder, O. et al. Risk factors for meningitis in neurosurgical patients with cerebrospinal fluid drains: prospective observational cohort study. Acta Neurochir 161, 517–524 (2019). https://doi.org/10.1007/s00701-019-03801-y
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DOI: https://doi.org/10.1007/s00701-019-03801-y