Factors associated with mortality of pediatric sepsis patients at the pediatric intensive care unit in a low-resource setting

We retrospectively collected patients’ data from 1st January 2014 to 31st December 2019 who had been diagnosed with sepsis and admitted to the PICU in our tertiary hospital (Dr. Sardjito Hospital, Yogyakarta, Indonesia). We defined sepsis using the Goldstein 2005 criteria which stated sepsis as SIRS followed by infection. All patients were screened during admission at the PICU for sepsis using the Goldstein 2015 definition. The definition of SIRS included a body temperature of > 38.5 °C or < 36.0 °C, tachycardia, mean respiratory rate > 2 SD above normal for age, and a leukocyte count elevated or depressed for age or >  10% immature neutrophils [2]. All PICU sepsis management algorithms were based on Indonesian Pediatric Society guidelines which referred to ACCM/PALS haemodynamic support guidelines. Included patients were those who were admitted to the PICU with sepsis as one of the diagnoses or who were diagnosed with sepsis later during their stay in the PICU. We assumed that all patients who were diagnosed with sepsis later during their stay in PICU had hospital acquired sepsis. All patients were followed up until they reached death as an outcome or date of PICU discharge. Patients with missing medical records or incomplete data related with sepsis criteria and evaluated factors were excluded from the analysis (Table 1). From 678 patients admitted to PICU with sepsis in 2014–2019, 665 patients were enrolled to the study and 13 patients were excluded. The data lock was done on December 31, 2019 (Fig. 1).

We recorded demographic and clinical data of all patients during their admission in the PICU. We searched medical record data since 1st January 2014 to 31st December 2019 in our Central Medical Record Unit using keywords: sepsis diagnosis and pediatric patients. We used keywords through electronic medical records database which only include the diagnosis and age category of the patient to make it easier to search for manual medical record numbers. Then we recorded and opened every medical record to collect the data. The demographic data that we evaluated were age and gender, while the clinical data included nutritional status, morbidity, referred from other hospital (yes/no), post-operative patients (yes/no), the need of mechanical ventilation or vasoactive drugs (yes/no), bacteremia, and occurrence of fluid overload.

Patient’s nutritional status was classified according to the World Health Organization (WHO) growth charts: Weight-for-Height curve for children younger than 5 years old or body mass index (BMI)-for-age curve for children 5 years old or older. Children were categorized into having good nutritional status (− 2 ≤ z < 2 SD), being under-nourished (z < − 2 SD) or overweight (z > 2 SD) [9]. Post-operative patients were patients that had undergone surgery before admitted to the PICU. Comorbidity was defined as any chronic condition that has been diagnosed and treated before the patient was diagnosed with sepsis, such as congenital and acquired heart disease, cerebral palsy, malignancy, kidney disease, autoimmune disease and congenital anomaly. All patient’s comorbidties including cerebral palsy in this study were previously diagnosed by an expert in our setting and have had routinely treatment in our pediatric outpatient and also underwent comprehensive treatment with other departments before admission to the PICU.

For children who needed invasive mechanical ventilation or advanced circulatory supports, administrations of both interventions were recorded. The ventilator duration was defined as the total duration of ventilator use during PICU admission (in days). Patients were classified as having septic shock if hemodynamic instability occurred, as indicated by one or more of the following signs: a decrease or change in consciousness, prolonged capillary filling time (> 2 s), decreased strength of peripheral pulses, cold extremities, or bounding pulses, wide pulse pressure differences, or decreased urinary output (< 1 ml/kg/hour), or hypotension [4, 6, 7]. We defined bacteremia as the positive growth of blood culture taken at the first time sepsis diagnosis was established after confirmation that the bacterial isolate was the true pathogen. We performed blood culture testing when the patient met the criteria of sepsis or the doctor in charge had been declared that the patient having sepsis. Standard culture techniques were used, which had been validated using BACTEC® 9120 (BD Diagnostics, Sparks, MD, USA). Clinical Pathology standard procedures were followed for bacterial isolation and antibiotic susceptibility testing [10]. To determine whether a positive culture result was a contaminant, the type of isolated organism, time to positivity, and number of positive culture sites were taken into consideration. We assessed the Pediatric Logistic Organ Dysfunction (PELOD) score using PELOD-2 criteria. The PELOD-2 score criteria consist of 5 system organ dysfunction assessments (range 0–30), including neurologic, cardiovascular, renal, respiratory, and hematologic systems [11].

Fluid overload percentage was calculated based on the total fluid input (in milliliter) minus total fluid output (in milliliter) divided by body weight at hospital admission (in kilogram) and multiplied by 100% [12]. Fluid overload percentage was calculated from the first 24 h after PICU admission until discharge or until the seventh day at PICU if the length of stay exceeded 7 days.

For every patient, the follow-up period ended when the outcome, death or PICU discharge was reached. In our PICU, we held routine death conferences to conclude the cause of death of every death case, that was attended by experts and hospital representatives. From the result of it, we concluded that all death cases in this study were due to sepsis. The mortality rate of sepsis was defined as the proportion of patients who died during PICU stay in all children with sepsis who were admitted to the PICU within the study period.

This study was approved by the Medical and Health Research Ethics Committee of the Faculty of Medicine, Public Health and Nursing, Universitas Gadjah Mada, Yogyakarta, Indonesia KE/FK/ 0860/EC/2019. As a teaching hospital, all patients or guardians are required to sign an informed consent form related to data usage for education and research purposes at patients’ admission time.

Demographic characteristics of the patients are shown in Table 2. Overall, there were 364 (54.7%) boys and 301 (46.3%) girls. The median age of patients admitted to PICU was 1.8 with interquartile range (IQR) ±8.36 years old and the median length of stay was 144 h (1–1896 h). From 665 patients, more than half 391 patients (58.8%) had good nutritional status, 216 patients (32.4%) were undernourished and only 58 patients (8.8%) were overweight. As many as 277 patients (41.7%) had chronic disease comorbidity, and multiple comorbidities were quite common. The most common comorbidities were heart diseases (105 patients) and kidney diseases (65 patients). Other reported comorbidities were congenital anomalies in 64 patients (9.6%), malignancy in 52 patients (7.8%), cerebral palsy in 36 patients (5.4%) and autoimmune disorders in 15 patients (2.3%). As many as 486 patients (73.1%) were referred from other primary or secondary care hospitals.

Some interventions were commonly performed in our patients. About 570 patients (85.7%) who were admitted to the PICU needed mechanical ventilation support, with median duration of 4.00 days (0.00–65.00 days). About two-thirds of all patients (67.7%) needed vasoactive drugs during the treatment and 147 patients (22.1%) were post-operative patients. As many as 490 patients (73.7%) progressed to septic shock. From all patients, 29% had fluid overload percentage >  10%.

A total of 134 patients (20.2%) in our study had a positive blood culture. The most common organism found was Staphylococcus sp. The duration of stay in the PICU ranged from 1 to 1896 h with median time of 264 h. Three hundred and eighty five patients (57.9%) died during this study period. We found that the presence of chronic disease comorbidities, the need of invasive mechanical ventilation support and vasoactive drugs, septic shock, post-operative patient and fluid overload percentage > 10% to be significantly different between those that died and those that survived.

Overall, the survival rates of patients in our study at 12 h, 24 h and 48 h were 91.6, 80.6 and 72.4%. Between 48 h (2 days) until 216 h (9 days) of admission, the survival rate was above 50%. Meanwhile, at 240 h (10 days) of admission, the survival rate became 47.8% and it worsened with each additional day. The length of stay of all patients in this study was 433 ± 45 h (18 days) (Fig. 2).

Table 3 shows the demographic and clinical characteristics with survival of PICU patients. Multivariable Cox proportional hazards modeling showed that mortality was associated with the following factors: presence of congenital anomaly (HR 1.4, 95% CI: 1.0–1.9), fluid overload percentage (HR 9.6, 95% CI: 7.4–12.6), the need of invasive mechanical ventilation support (HR 2.7, 95% CI 1.6–4.6), vasoactive drugs (HR 1.5, 95% CI 1.2–2.0) and PELOD score (HR 1.13, 95% CI: 1.10–1.16 and 1.06 95% CI: 1.03–1.09 adjusted). On the contrary, we found that cerebral palsy was associated with lower mortality (HR 0.3, 95% CI: 0.1–0.5). Similarly, post-operative patients showed lower mortality (HR 0.4, 95% CI: 0.3–0.6).

We found that the survival of patients who needed mechanical ventilation support or vasoactive drug to be significantly lower as compared to those without (HR 2.7, 95% CI 1.6–4.6, p <  0.001) for mechanical ventilation and (HR 1.5 95% CI: 1.2–2.0, p <  0.001) for vasoactive drug use.