To identify risk factors for short-term percutaneously inserted central venous catheter-related infections in children and to evaluate the accuracy of a mortality score in predicting the risk of infection.
METHODAfter reviewing the charts of patients who developed catheter-related infection in a university hospital's pediatric intensive care unit, we conducted a case-controlled study with 51 pairs. Variables related to patients and to catheter insertion and use were analyzed. Risk factors were defined by logistic regression analysis. The accuracy of the Pediatric Risk of Mortality score to discriminate the risk for infection was tested using the Receiver Operating Characteristic curve.
RESULTSInfection was associated with respiratory failure, patient's length of stay, duration of tracheal intubation, insertion of catheter in the intensive care unit and parenteral nutrition. Insertion site (femoral or internal jugular) was unimportant. Multivariate logistic regression analysis identified the following variables. Risk factors included more than one catheter placement (p=0.014) and duration of catheter use (p=0.0013), and protective factors included concomitant antibiotic use (p=0.0005) and an intermittent infusion regimen followed by heparin filling compared to continuous infusion without heparin (p=0.0002). Pediatric Risk of Mortality did not discriminate the risk of infection.
CONCLUSIONSCentral parenteral nutrition and central venous catheters should be withdrawn as soon as possible. Femoral vein catheterization carries a risk of infection similar to internal jugular catheterization. The Pediatric Risk of Mortality score should not be used to predict the risk of central catheter-related infections.
Bloodstream infection (BSI) related to intravenous therapy is an important factor in morbidity, mortality and hospital costs, especially in intensive care. Most hospital-acquired BSIs are associated with the use of a central venous catheter (CVC). Catheter-related bloodstream infection (CRBSI) rates are influenced by patient-related parameters, such as severity of illness, and by catheter–related parameters, such as the material comprising the device. Additionally, utilization conditions should be considered, including insertion techniques, catheter care and solutions infused,1 along with unique considerations of pediatric patients.2
Some studies aimed at prevention and surveillance have estimated the risk for this and other nosocomial infections. Low specificity was obtained when using risk scores like Pediatric Risk of Mortality (PRISM) values.3,4
From January 2002 through December 2003, 875 patients were admitted to the Pediatric Intensive Care Unit (PICU) of this university hospital, with 17.8 central line-associated BSIs per 1000 central line-days in 2002 and 25.8 in 2003.
Such rates motivated this study, which aims to identify risk factors for the development of short-term percutaneously inserted central venous catheter-related infection (CRI) in children and to evaluate the accuracy of a pediatric mortality score in predicting the risk of infection.
MATERIALS AND METHODSSample selectionIn the two years of study, the PICU used catheters from the same manufacturer (Arrow International Inc, USA). There were no changes in the standards of care, including aseptic insertion technique, catheter site dressing, access to ports or filling the lumen with a heparin solution, when receiving intermittent infusion.
Patients reported as having CRI, according to the criteria of Pearson and HICPAC,5 were identified in the files of the hospital infection control committee, and their charts were reviewed. A retrospective 1:1 case-control study was conducted, where controls were defined by catheter placement close in time to the cases. A previous observation was that infection was always diagnosed 4 or more days after catheter insertion, in 10 randomly selected cases. For that reason, the minimum length of stay accepted for controls was 4 days.
VariablesVariables included in the case-control study were related to both patients and technical aspects of catheter insertion and utilization. Patients were evaluated for age, gender, Z-score of weight for age and gender, length of stay in the PICU, underlying conditions, reason for admission, duration of tracheal intubation, previous antibiotic therapy, PRISM on admission, and exit (discharge or death). Catheter variables included scene, operator, site and order of insertion, as well as the length of time it remained in place. Other variables were concomitant antibiotic therapy, use of CVC for administration of blood products, infusion of parenteral nutrition through CVC and regimen of infusion, which could be continuous or intermittent, alternating with heparin. Catheters without continuous infusion were filled with a 50U/mL heparin solution, after administration of intermittent medications (e.g., antibiotics, sedatives). Catheters with continuous infusion (e.g., hydration, parenteral nutrition, vasoactive drugs) were not filled or flushed with heparin.
Statistical analysisSAS® 8.2 for Windows was used for statistical analysis, with a level of significance of 5%.
With the aim to select variables associated with infection that could act as risk factors, preliminary statistical analysis compared cases and controls by Chi-square analysis, Fisher exact test for proportions and Mann-Whitney test for continuous and ordinal variables.
Variables associated with infection in the preliminary tests were then analyzed by univariate logistic regression in order to identify risk factors for infection. The most important set of risk factors was then selected by stepwise multivariate logistic regression analysis. The Receiver Operating Characteristic (ROC) curve was used to test discriminatory power of the PRISM score.
Ethical aspectsThe medical science faculty research ethics committee approved this study.
RESULTSIn 27 cases, the same microorganism was isolated from cultures of both the peripheral blood and the catheter tip. Thirteen other cases had BSIs with positive blood culture but negative or contaminated catheter tip culture. These 13 patients experienced a decrease in fever after removal of the catheter and initiation of empirical antibiotic therapy for CRBSI. Six additional cases had clinical sepsis with negative blood culture and experienced a decrease in of fever after removal of the catheter and initiation of antibiotic therapy. Five patients had exit-site infection.
Table 1 shows general characteristics of the study sample.
Demographic and clinical characteristics.
Characteristics | Cases | Controls | p |
---|---|---|---|
Number | 51 | 51 | |
PRISM | |||
≤ 10 | 32 | 33 | |
de 10 a 30 | 16 | 13 | |
> 30 | 2 | 4 | |
Age in months (median) | 13,5 | 7,8 | |
Age | |||
< 1 year | 23 | 29 | |
1 to 2 years | 17 | 6 | 0,032 |
> 2 years | 11 | 16 | |
Gender | |||
Female | 20 | 27 | |
Male | 31 | 24 | |
Weight | |||
Low (Z-score < -2) | 27 | 22 | |
Appropriate (Z-score ≥ -2) | 24 | 29 | |
Underlying conditions | |||
Chronic lung disease | 12 | 5 | |
Cardiac disease | 10 | 4 | |
Chronic renal failure | 3 | 8 | |
Steroid therapy | 6 | 7 | |
Reason for admission | |||
Elective operation | 4 | 13 | |
Sepsis | 4 | 9 | |
Respiratory failure | 36 | 21 | 0,013 |
Cardiac failure | 4 | 12 | |
Other | 3 | 6 | |
Length of stay in the PICU | |||
≤ 7 | 9 | 19 | |
de 8 a 14 | 20 | 24 | |
≥ 15 | 22 | 8 | 0,005 |
Tracheal intubation | |||
No | 1 | 3 | |
<24 hours | 2 | 6 | |
1 to 7 days | 7 | 19 | |
> 7 days | 41 | 23 | 0,001 |
Death | 9 | 3 | |
Catheter insertion scene | |||
PICU | 48 | 38 | 0,009 |
operating room | 2 | 11 | |
other | 1 | 2 | |
Catheter insertion operator | |||
PICU staff doctor | 13 | 16 | |
PICU resident doctor | 31 | 21 | 0,049 |
Anesthesiologist | 2 | 10 | |
Other | 5 | 4 | |
Catheter insertion site (vein) | |||
internal jugular | 31 | 35 | |
femoral | 19 | 11 | 0,097 |
external jugular and subclavian | 1 | 5 |
Blood cultures were positive in 40 cases, and catheter segment cultures were positive or considered contaminated by laboratory standards in 45 cases. The most frequent microorganisms in blood samples were Staphylococcus aureus (34.1%), Staphylococcus epidermidis (11.4%), Klebsiella pneumoniae (9.0%) and Enterobacter sp (9.0%). Candida tropicalis was present in two blood cultures (4.5%).
Preliminary statistical analysisUsing Chi-square analysis, infection was associated with age 1 to 2 years (p=0.032), PICU stays longer than 15 days (p=0.005), more than one CVC placement (p=0.009), no antibiotic therapy (p<0,0001), parenteral nutrition (p=0.016) and continuous infusion regimen without heparin filling (p=0.0001). Fisher exact test identified an association between infection and admission for respiratory failure (p=0.013), tracheal intubation for more than 7 days (p=0.001), catheter insertion in the PICU (p=0.009) and insertion performed by the PICU-resident doctor (p=0.049). Mann-Whitney test revealed an association with length of time the catheter remained in place (p=0.018).
Risk factorsRisk factors for CRI defined by univariate logistic regression analysis are shown in Table 2. Significant variables on multivariate logistic regression were also significant after adjusting for age categories (Table 3). Furthermore, the analysis of the infection risk related to the reason for admission, by age adjusted multivariate logistic regression, showed that respiratory failure carried a higher risk for CRI (p=0.0051; OR=6.843; CI=1.779-26.314).
Analysis of risk factors for catheter-related infection by univariate logistic regression analysis.
Variable | p-value | Odds-ratio | CI 95% |
---|---|---|---|
Age | |||
<1 year versus >2 years | 0.7664 | 1.154 | 0.449 ; 2.961 |
1 to 2 years versus >2 years | 0.0214 | 4.121 | 1.233 ; 13.771 |
Underlying conditions: chronic lung disease | 0.0704 | 2.831 | 0.917 ; 8.738 |
Previous antibiotic therapya | 0.1066 | 1.944 | 0.867 ; 4.360 |
Reason for admission | |||
Sepsisbversus post-operative | 0.6575 | 1.444 | 0.284 ; 7.341 |
Respiratory failure versus post-operative | 0.0068 | 5.571 | 1.607 ; 19.314 |
Cardiac disease versus post-operative | 0.0713 | 6.500 | 0.850 ; 49.687 |
Accident, shock and other versus post-operative | 0.5934 | 1.625 | 0.273 ; 9.658 |
Tracheal intubation | |||
>7 days versus <1 day or not-intubated | 0.0192 | 5.348 | 1.315 ; 21.749 |
1 day to 7 days versus <1 day or not-intubated | 0.9004 | 1.105 | 0.230 ; 5.301 |
Insertion scene PICU versus operating room | 0.0152 | 6.945 | 1.452 ; 33.231 |
Operator | |||
PICU resident-doctor versus PICU staff-doctor | 0.2023 | 1.817 | 0.726 ; 4.549 |
Anesthesiologist versus PICU staff-doctor | 0.1031 | 0.246 | 0.046 ; 1.328 |
Other versus PICU staff-doctor | 0.5747 | 1.538 | 0.342 ; 6.928 |
Insertion site (vein) | |||
Femoral versus internal jugular | 0.1396 | 1.950 | 0.804 ; 4.730 |
Number of catheter placements: >1 versus 1 | 0.0120 | 3.750 | 1.336 ; 10.523 |
Catheter length of stayc (median) | 0.0218 | 1.144 | 1.020 ; 1.283 |
>7 days versus ≤7 days | 0.2336 | 1.612 | 0.735 ; 3.537 |
Concomitant antibiotic therapy | 0.0002 | 0.132 | 0.045 ; 0.388 |
Blood products administered by CVC | 0.2336 | 1.612 | 0.735 ; 3.537 |
Parenteral nutrition | 0.0230 | 4.020 | 1.211 ; 13.339 |
Intermittent infusion + heparin filling versus continuous infusion without heparin | 0.0004 | 0.143 | 0.049 ; 0.420 |
Analysis of risk factors for catheter-related infections using multivariate logistic regression, adjusted for age.
Variable | p-value | Odds-ratio | CI 95% |
---|---|---|---|
Number of catheter placements: >1 versus 1 | 0.0278 | 5.630 | 1.208 ; 26.251 |
Catheter length of stay > 7 days versus ≤ 7 days | 0.0155 | 4.121 | 1.310 ; 12.965 |
Concomitant antibiotic therapy | 0.0003 | 0.068 | 0.016 ; 0.292 |
Intermittent infusion + heparin filling versus continuous infusion without heparin | 0.0008 | 0.082 | 0.019 ; 0.354 |
There was no significant difference between admission PRISM values of cases (average ± SD = 9.21% ± 9.26) and controls (average ± SD = 11.39% ± 13.85), even after stratification in <10%, 10 to 30% and >30% ranges. Subsequently, every PRISM value found was tested as a potential cutoff value to predict appearance of infection. Their sensitivities and specificities were plotted to obtain an ROC curve (Figure 1). Considering that an area under the curve Az=0.5 corresponds to a random performance and that Az=1 corresponds to a perfect prediction, PRISM score showed a non-discriminating performance for the appearance of catheter-related infections.
DISCUSSIONWe should emphasize that some measures, such as adherence to aseptic technique during catheter insertion as well as hand hygiene and cleansing of injection ports before catheter manipulation, are necessary for infection control. These and other simple methods must be stressed in continuing education programs because they are essential for reducing infections 1.
However, in a retrospective study, it may not be possible to examine important variables like catheter insertion conditions, catheter site care and access to ports due to lack of records. Consequently, important risk factors may be hidden. Nevertheless, relevant conclusions can be drawn from the results.
AgeCRBSI rates in pediatric intensive care units are comparatively high, surpassed only by burn and trauma units 6. Multi-center hospital-acquired infection studies, especially in the PICU, have found either a higher incidence (p<0.001) of primary BSI in children less than 2 months old7 or no significant difference in the point-prevalence of nosocomial infections among pediatric age ranges.8 In Brazil, one investigation reported a higher frequency of nosocomial infections in children younger than 2 years admitted to a PICU.9
In this study, there was no significant difference between the average ages of cases and controls. However, when categorizing age into three ranges, there was a higher incidence of cases in one to two year old children. This result may have been biased by other factors because CRI risk factors that were found by multivariate logistic regression did not include age range and were the same when adjusted for age (Table 3). A biasing factor could be connected to reason for admission because the risk of infection related to respiratory failure was significantly higher with age-adjusted logistic regression.
Reason for admissionConditions related to respiratory disease, like repeated access to CVC ports for bolus sedation of patients on mechanical ventilation, may have contributed to the association between respiratory failure as a reason for admission and infection. In support of this hypothesis, we observed that patients admitted after eletive operations, who usually require less frequent handling of ports, were significantly more frequent (p=0.005) among controls than cases.
Patients with CRI had significantly large duration of intubation and longer PICU stays, similar to other authors’ results,8,10,11 which reflects patient's critical condition, exposure to invasive devices and procedures, repeated access to central lines, selection for resistant bacteria and colonization by nosocomial microorganisms.
Insertion scene, operator and siteCRIs occurred significantly more often when the catheter was inserted in the PICU (Table 2). However, most of the catheters were inserted in the PICU, and the others were usually inserted in the operating room (OR). PICU-placed CVCs may be associated with a higher incidence of infection due to factors linked to the patients, like their physiopathological condition. In shock and hypoxic-ischemic states, vascular collapse or vasoconstriction complicates percutaneous needle puncture of veins, resulting in hematomas and necrotic tissue, which favor colonization. In addition, critically ill patients need frequent access to CVC ports and invasive procedures. Generally, insertion in the OR occurs in ideal asepctic conditions, anesthesia and hemodynamic control. Furthermore, elective surgical patients have less need for access to CVC ports and shorter durations of device placement than critically ill patients.
Resident doctors generally have less experience in catheter insertion techniques than PICU staff doctors and anesthesiologists. Insertion by a physician with an accumulated experience of 50 or more catheterizations is half as likely to result in a mechanical complication as compared to an insertion by a less skilled doctor.12 On preliminary analysis, there was an association between insertion by resident doctor and CRI. Insertion of half of the catheters in the study by resident doctors and more than half of the remaining devices in the OR must have influenced such an association. Furthermore, logistic regression did not identify this variable as a risk factor, suggesting that aseptic techniques and adequate supervision make up for lack of ability.13
A randomized study in adults14 found that subclavian venous catheterization was associated with a significantly lower rate of total infectious complications than femoral venous catheterization, in which overall mechanical complications are more likely. In a non-randomized study, subclavian vein catheterization resulted in a smaller incidence of CRI than internal jugular vein catheterization.15 However, catheterization of the subclavian vein in children is not recommended due to risks of mechanical complications16, and there are no consistent reports comparing the risks of infection between the femoral vein and jugular internal vein. In this investigation, there was no association between insertion site and infection, when comparing femoral, internal jugular, external jugular and subclavian veins. Furthermore, logistic regression analysis demonstrated no significant difference in the incidence of infection comparing femoral venous catheterization to internal jugular, although the other sites were used too infrequently to be evaluated.
Catheter useCatheter placement for more than 7 days was a risk factor for CRI according to multivariate logistic regression analysis, which agrees with Maki and coworkers’ finding that the cumulative risk for CRBSI rises with the length of time the catheter remains in place.17 Furthermore, more than one CVC placement resulted in a higher risk of infection in the multivariate analysis. The need for a new CVC could be related to severity of illness, longer PICU stay, number of invasive procedures and frequency of infusions. These are all factors associated with CRBSI. In addition, the presence of multiple intravascular access devices and the total duration of intravascular access device use are associated with an increase in the rate and risk of developing CRBSI.18
In this study, the use of antibiotics was a protective factor against CRI. Other authors have reported the efficacy of prophylactic vancomicin in preventing Gram-positive infections in low birth weight neonates,19,20 but the emergence of resistant bacteria has discouraged this practice.21
In this investigation, blood product transfusion was not associated with CRI, suggesting that colonization was not significant even though transfusion could have favored thrombosis. Additionally sepsis caused by blood products contaminated with bacteria has been reported as a rare incident.22
While parenteral nutrition was associated with CRI, it was not statistically identified as a risk factor in the multivariate logistic regression. probably because of the short administration period; the relationship between parenteral nutrition and infection is stronger when parenteral nutrition lasts for more than 7 days.23 Moreover, the practice of designating one port to exclusively administer parenteral nutrition was observed when a multilumen catheter was in place.1
In a meta-analysis, the use of either intra-luminal conventional or subcutaneous low weight heparin reduced the risk of thrombosis, but neither substantially changed the CRBSI rate.24 Because the majority of heparin solutions contain preservatives with antimicrobial activity, it is unclear whether the observed decrease in the rate of CRBSI was a result of reduced thrombus formation or an effect of preservatives. In this survey, catheters receiving continuous infusion flow had a higher risk of CRI when compared to catheters that remained in intermittent use, alternating with heparin flush, in the multivariate logistic regression analysis. One could conclude that heparin had a protective action against infection, but it is necessary to emphasize that continuous infusion was administered to severely ill patients who needed intravenous maintenance fluids, parenteral nutrition and continuous infusion drugs like inotropes, vasopressors, vasodilators and sedatives, as well as intermittent medications. On the other hand, CVCs with intermittent infusions followed by heparin flush were used in less critical situations, when patients received enteral nutrition and probably fewer medications, with less chance for contamination.
Pediatric Risk of MortalityAlthough the PRISM score was designed to predict the mortality of populations, it has also been used to predict morbidity, including nosocomial infections.3,4 However, the results of this study do not support the use of PRISM to evaluate the risk for CVC-related infections. PRISM is composed strictly of physiological and laboratory variables25, variables directy related to the appearance of infections (c.g. the use of invasive devices). The inclusion and the other risk factors identified in this study would allow for the development of more adequate scores for nasocomial infections.26
CONCLUSIONSIn conclusion, enteral nutrition should substitute parenteral nutrition, and catheters should be withdrawn as soon as possible because it is relatively easy to reduce these risk factors. The relative safety of femoral vein catheterization suggested by these results, in which its risk for infection is comparable to jugular vein catheterization, should be investigated in a controlled trial. Adequate supervision and respect to aseptic techniques may compensate for resident doctors’ lack of skill in catheter insertion. The Pediatric Risk of Mortality score should not be used to predict the risk for central catheter-related infections. A more specific score that includes variables clearly related to the development of nosocomial bloodstream infection, like the use of invasive devices, should be available to predict the risk of central venous catheter-related infections in children.
We thank Dr. Sônia R. P. E. Dantas, for clarifying concepts of hospital infection surveillance, Dr. Plínio Trabasso, president of the hospital infection control committee, for the open doors and files, and Dr. Carlos Eduardo Lopes for his contributions regarding pediatric intensive care medicine.