Background
In recent years, the incidence and drug resistance of multi-drug resistant infections (MDRI) have shown a rapid growth trend [
1]. Particularly, the emergence of a large number of pan-drug resistant strains poses great difficulties for treatment of pediatric patients [
2]. The intensive care unit has become a high-risk area for hospital-acquired infections and drug-resistant strains regarding its large number of special susceptible populations and its special diagnosis and treatment environment, especially in the pediatric intensive care unit (PICU) [
3]. PICU patients are particularly susceptible to nosocomial infections, the potential reasons may include that the use of invasive devices and procedures in this critically ill patient group, and the children’s immune function is relatively incompletely developed [
4]. Although a serious infection may prompt the entry to PICU, MDRI may be a post-hospital complication, potentially life threatening for children [
5]. Many previous studies [
6‐
8] have indicated that the incidence of nosocomial infections caused by antibiotic-resistant organisms is increasing. The prevalence of hospital-acquired or nosocomial infections in pediatric patients ranges from 10 to 25% in PICU [
9,
10]. Therefore, the control of infection in PICU is very important.
Understanding the reasons behind that is very essential. Certain risk factors are associated with nosocomial infections caused by drug-resistant organisms. In adult patients with interstitial transfer, long-term hospitalization, gastrointestinal surgery and transplantation, as well as exposure to all types of invasive devices and exposure to previous antimicrobial agents are closely associated with MDRI in ICU [
11]. It’s been reported [
12] that
Staphylococcus aureus (MRSA), vancomycin-resistant Enterococcus (VRE), Carbapenem-based antibacterial drug Acinetobacter baumannii (CR-AB) are the three commonly-seen multi-drug resistant bacteria. In PICU, considering that the low immunity, serious condition, long hospitalization, mechanical ventilation, invasive examination and other factors related to the treatment of children, the incidence of MDRIs increases significantly, posing a great threat to children [
4,
13].
Therefore, it is necessary to analyze the risk factors for MDRIs in PICU, to understand characteristics of MDRIs in PICU, thereby providing a basis for developing related treatment and nursing strategies for the prophylaxis and management of MDRIs in PICU.
Methods
Study design
A cases and controls study.
Setting
Three PICUs of one tertiary children’ hospital were included, of which the microbial identification results are homogeneous and are regulatory accepted by each other. Nine hundred six patients who were hospitalized in ICU during the period of July 1st 2018 to June 30th 2019 were identified, of which 79 Children were diagnosed as MDRI. Therefore, we included those 79 children with MDRI as participants in the present study, and repeated strains isolated from the same patient in the same part of the specimen were excluded. In the same period, 80 children in PICU without MDRI were selected as the control group, we have included the children with the same diagnosis with the cases as controls.
We used following methods to control the quality of sputum samples: when being under laboratory microscope, the squamous epithelial cells in the low fold field of vision < 10 and the white blood cells > 25 were defined as qualified samples. And all the specimens were sent to the laboratory room for bacteria analysis.
Definitions
MDRI was defined as having an isolate resistant to more than three kinds of the following antimicrobial or antimicrobial groups: ampicillin/sulbactam, aztreonam, ceftazidime, ciprofloxacin, gentamicin, piperacillin, trimethoprim/sulfamethoxazole, carbapenem and amikacin [
14,
15]. Bacterial isolation and antimicrobial susceptibility testing were performed according to the method of the Clinical and Laboratory Standards Institute [
16].
Invasive operation was defined as having inserted or indwelling catheters or tubes, such as the status of mechanic ventilation.
Drug sensitivities was conditions which exist due to the natural variation in patients’ metabolism of drugs. Some people may react to them faster than others, and some people may have a lower threshold to the effects of drugs than others. The effects caused by this lower threshold was defined as drug sensitivities, which was performed in the laboratory room in our hospital.
Data collection
The cases were reviewed in the microbiology and inspection laboratory database by searching for at least 2 positive cultures. And the medical records of the cases were obtained from the medical record archives. The demographics-related information, regarding clinical care, microbiologic data, treatments provided, and outcomes of the patients with were reviewed and collected. Main contents including the name, gender, age, the length of ICU stays, infection site, operation, invasive operation, antibiotic use, and drug sensitivity were collected. All the data were analyzed after double-entry check.
Statistical analysis
All of the statistical analyses were conducted using SPSS 21.0 (SPSS Inc., Chicago, USA). Categorical variables were analyzed using the χ2 test or Fisher’s exact test, and continuous variables were analyzed using Student’s t test or Mann-Whitney U test, and were generally presented as means and standard deviation. Multivariate logistic regression analyses were performed using the forward likelihood ratio selection method to identify independent factors of MDRI and it is presented with an odds ratio (95% confidence intervals, CI). Potential candidate variables were those with P < 0.05 in univariate analyses. All of the P values were 2 tailed, and P < 0.05 was considered as being statistically significant.
Discussion
In this present study, the incidence of MDRIs in the three PICUs was 8.72% (79/906), which is significantly lower than that of previous reports with incidence of MDRIs ranging from 10 to 25% in PICU [
9,
10]. Previous studies [
17‐
19] have reported that the patients with MDRI were hospitalized and treated in the ICU for considerably longer stay and had lower survival rates compared to other patient groups. Identifying risk factors for infection development caused by multidrug-resistant bacteria can help health care providers prevent nosocomial infections. This becomes even more important if we consider the slow drug development of new effective anti-bacteria and the rising prevalence of MDRI, especially in the PICU. The results of this present study have revealed that coma, parenteral nutrition, 2 or more antibiotics use and the duration of mechanical ventilation > 5 d are independent risk factors associated with MDRIs in PICU. To the best of our knowledge, very few studies focus on the MDRIs in PICU, so we believe that the present study can provide some evidences for the prophylaxis of MDRIs.
Infected patients are mainly concentrated in the coma population of children. Coma patients have higher risk of infection due to more basic diseases and low immunity [
20]. There are many types of diseases in the ICU, the coma children in PICU are usually seriously ill and the treatment periods are longer [
2,
21]. The extension of the ICU stay increases the use of antibiotics, invasive operation and cross-infection between patients. Besides, the body’s own pathogens may shift to other tissues and organs, leading to endogenous infections [
22]. As the hospitalization period is extended, the patient’s medical expenses will also increase, and the human-borne pathogens can invade the body, causing exogenous infections, thus the risk of MDRI can increase [
23]. Usually, the beds in the ICU are very few, and the increase of MDRI makes the medical resources not properly configured. Previous studies [
24,
25] have concluded that the hospitalization time of patient needs to be strictly controlled, which is one of the effective measures to prevent MDRI.
Mechanical ventilation can significantly increase the chance of respiratory infection [
26,
27]. The establishment of an artificial airway in an ICU patient results in the disappearance of the natural barrier of the upper respiratory tract and direct communication of the lower respiratory tract with the outside air. Various invasive medical procedures potentially increase the risk of infection in the lower respiratory tract [
28]. The establishment of the artificial airway opens the respiratory pathway for the patient, but long-term mechanical ventilation and open-ended invasive procedures such as suction and fiberoptic bronchoscopy increase the incidence of VAP [
29]. Additionally, resistant bacteria can easily enter the bloodstream through the damaged blood gas barrier, causing blood sepsis [
30]. Besides, it is often the case that the maintenance and care of the ventilator tube is not standardized, or the equipment is not properly disinfected, which provides a shortcut for the invasion of the drug-resistant bacteria, which is one of the important reasons for the MDRI in ICU [
31,
32]. In clinical setting, special attention should be paid to the patient in comatose state and with mechanical ventilation length > 5 days. Patients who have been in bed for a long time are prone to pneumonia.
The use of antibacterial drugs is a key factor related to bacterial resistance [
33,
34]. The selective pressure of bacteria comes from the use of antibiotic dose [
35]. When the antibiotic used by the patient reaches or is about to reach the sublethal dose, the selective pressure of the antibiotic can force the change of body’s behavior, physiology and biochemistry [
36]. The gene and protein expression of the resistant bacteria will change, the protective defense and immunity of the body will gradually weaken, and the risk of MDRI elevates [
37]. China is a large country with massive use of antibiotics, and the frequency of antibiotics use is very high [
38,
39]. It’s been reported [
40,
41] that almost 80% hospitalized patients in China have been prescribed antibacterial drugs, and the use of broad-spectrum antibiotics is 28% higher than the average antibiotics use globally. There is a close correlation between the amount of antibiotics used and bacterial resistance. ICU has higher pathogen composition ratio and bacterial resistance [
34], thus it’s necessary to fully grasp the basic information of bacterial epidemiology in ICU, and control the resistance of various drug-resistant bacteria with different antibiotics, to provide basis for MDRI treatment and strategies.
It must be mentioned that the findings of our study should be interpreted with the consideration of potential limitations. Firstly, it should be acknowledged that, due to the innate limitations of retrospective studies, a significant proportion of the children had more than one incidence of infection, but only one incidence per patient was analyzed. Secondly, there is ample room for improvement in the explanation of the rationale to include cases, and specially, for the justification of choosing a case: control ratio of 1:1, when the customary ratio is to have at least 2 controls for each case. The relatively limited number of cases included in this present analysis may not be powered enough to detect the potential risk factors for MDRIs, future studies with larger sample and broader areas are needed to identify the MDRIs risks. Despite these shortcomings in this study, the results of this study may still lend some inspiration for clinical health workers, as this is the first analysis of the risk factors for the development MDRI in PICU.
In conclusion, this present study has revealed that coma, parenteral nutrition, 2 or more antibiotics use and the duration of mechanical ventilation > 5 days are independent risk factors associated with MDRIs in PICU. Based on the evidence provided in this study, specific actions can be taken to improve prevention of MDRIs, such implementing the post of infection control nurses et al. [
42], which may significantly reduce the MDRIs. The evidences provided can help critical care providers in PICU determine the extent to which they can modify their treatment strategies to achieve optimal clinical outcomes.
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