Acute kidney injury in COVID-19 pediatric patients in North America: Analysis of the virtual pediatric systems data

Rupesh Raina; Isabelle Mawby; Ronith Chakraborty; Sidharth Kumar Sethi; Kashin Mathur; Shefali Mahesh; Michael Forbes

doi:10.1371/journal.pone.0266737

. 2022 Apr 26;17(4):e0266737. doi: 10.1371/journal.pone.0266737

Acute kidney injury in COVID-19 pediatric patients in North America: Analysis of the virtual pediatric systems data

Rupesh Raina ^1,^2,^*, Isabelle Mawby ³, Ronith Chakraborty ^1,², Sidharth Kumar Sethi ⁴, Kashin Mathur ⁵, Shefali Mahesh ¹, Michael Forbes ⁶

Editor: Zhanjun Jia⁷

PMCID: PMC9041802 PMID: 35472149

Abstract

Background

Despite extensive research into acute kidney injury (AKI) in adults, research into the epidemiology, associated risk factors, treatment, and mortality of AKI in pediatric COVID-19 patients is understudied. Advancing understanding of this disease is crucial to further developing treatment and preventative care strategies to reduce morbidity and mortality.

Methods

This is a retrospective analysis of 2,546 COVID-19 pediatric patients (age ≤ 21 years) who were admitted the ICU in North America. Analysis of the Virtual Pediatric Systems (VPS) COVID-19 database was conducted between January 1, 2020, and June 30, 2021.

Results

Out of a total of 2,546 COVID positive pediatric patients, 10.8% (n = 274) were diagnosed with AKI. Significantly higher continuous and categorical outcomes in the AKI subset compared to the non-AKI cohort included: length of stay at the hospital (LOS) [9.04 (5.11–16.66) vs. 5.09 (2.58–9.94) days], Pediatric Index of Mortality (PIM) 2 probability of death [1.20 (0.86–3.83) vs. 0.96 (0.79–1.72)], PIM 3 probability of death [0.98 (0.72–2.93) vs. 0.78 (0.69–1.26)], mortality [crude OR (95% CI): 5.01 (2.89–8.70)], airway and respiratory support [1.63 (1.27–2.10)], cardio-respiratory support [3.57 (1.55–8.23)], kidney support [12.52 (5.30–29.58)], and vascular access [4.84 (3.70–6.32)].

Conclusions

This is one of the first large scale studies to analyze AKI among pediatric COVID-19 patients admitted to the ICU in North America. Although the course of the COVID-19 virus appears milder in the pediatric population, renal complications may result, increasing the risk of disease complication and mortality.

Introduction

Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) is responsible for the 2019 coronavirus pandemic (COVID-19). According to The World Health Organization, over 182,319,261 cases and almost 4 million deaths have been reported worldwide as of July 2021 [1]. Kidney manifestations from COVID-19 are becoming increasingly prevalent, with acute kidney injury (AKI) contributing to high mortality rates. [2, 3].

Previously, we performed a meta-analysis assessing AKI incidence and outcomes among both pediatric and adult COVID-19 patients. Among 1,247 COVID-19 positive (+) pediatric patients, 30.51% developed AKI. Among the COVID-19+ patients with AKI, 0.56% received kidney replacement therapy (KRT). In comparison, among the studied adult COVID-19 population (n = 42,591), 15.90% developed AKI. The overall mortality rates in children and adults were 2.55% and 14.60%, respectively [4]. However, despite this age-related discrepancy, COVID-19’s renal association has been a consistent, negative, prognostic factor [4–7].

Throughout the world, preliminary studies are starting to assess the epidemiology of AKI in pediatric population affected by COVID-19, with reported incidents ranging from 0.8% to 80% [8–21]. However, there are no large-scale studies examining this association in North America. This study uses the Virtual Pediatric Systems database (VPS) to identify the epidemiology, associated risk factors, treatments, and mortality of AKI in pediatric COVID-19 patients admitted to the pediatric intensive care unit (PICU) in North America.

Methods

Study design and population

A retrospective analysis of 2,597 COVID-19 pediatric patients (age ≤ 21 years) in the ICU within North America was performed by analyzing the VPS COVID-19 database, which includes data from over 200 pediatric critical care hospital units, between January 1, 2020 and June 30, 2021. Male and female patients <21 years old with AKI were analyzed (determined by Kidney Disease Improving Global Outcomes (KDIGO) staging of stage 1 or worse), along with patients with current or recent SARS-CoV-2 infection (determined by RT-PCR, serology, or antigen test), and ICU admission. Excluded from the study were patients >21 years old and patients with a negative SARS-CoV-2 status.

Data collection

Data regarding pediatric patients < 21 years old with a primary diagnosis of COVID-19 and AKI diagnosis was recorded. Patients with COVID-19 were identified using ICD-10, which also identified any presenting underlying conditions. Patients negative for COVID-19 were excluded from the study. Variables utilized in the study included COVID-19 positivity, confirmed deaths, PICU days, therapies used, comorbidities of patients, cumulative COVID-19 positive PICU admission, COVID-19 positive PICU admissions per day, average LOS by age group, average LOS by period comorbidities, and organ support. S1B Table in S1 File provides the definition of these variables. In order to investigate epidemiology, risk factors associated with AKI, results on treatment, and associated mortality in the pediatric population, the following variables were necessary: patient demographics (age, sex, race, ethnicity (White, Black, Hispanic, Asian/Pacific Islander, etc.), diagnosis (primary and secondary), lab order/results (hematology and chemistry tests), image order/results, respiratory support modality, kidney replacement therapy modality (if utilized), medications, interventions and procedures, pediatric index of mortality (PIM) 2 and 3, discharge status, length of stay, and mortality. PIM 2 and 3 are severity scoring systems consisting of 10 variables which are used for predicting outcome of patients admitted to intensive care units (ICUs). It provides predicted % of mortality rate, where higher indicates greater probability of death [22]. The patients were separated into an AKI group and a non-AKI group. In the AKI group, patients were subcategorized based on staging of AKI severity by KDIGO guidelines. PIM3, KRT, and mortality data was used when urine output and serum creatinine level data were not available. If KRT was utilized, the patient was graded as AKI stage 2. Patients with the presence of mortality status were graded as AKI stage 3. The baseline parameters among AKI and non-AKI patients are provided in Table 1. The Pediatric Overall Performance Category (POPC) and the Pediatric Cerebral Performance Category (PCPC) scales are included as baseline parameters. Both the POPC and the PCP are qualitative assessments of performance, conducted by observers, based on the Glasgow Outcome Scale. Scores include 1 for good, 2 for mild disability, 3 for moderate disability, 4 for severe disability, and 5 for vegetative state or coma (6 indicates death, but was not included in the study) [23, 24].

Table 1. Baseline parameters among AKI and non-AKI group.

Variables		AKI	Non-AKI	p value
Variables		N (%)	N (%)	p value
Age	Neonate Birth to 29 days	2 (0.7%)	44 (1.9%)	<0.001
	Infant 29 days to < 2 years	18 (6.6%)	340 (15.0%)
	Child 2 to < 6 years	21 (7.7%)	319 (14.0%)
	Child 6 to < 12 years	59 (21.5%)	476 (21.0%)
	Adolescent 12 to < 18 years	152 (55.5%)	943 (41.5%)
	Adolescent (late) 18 to < 21 years	22 (8.0%)	150 (6.6%)
Age in median (IQR) [years]		5 (4–5)	4 (3–5)	<0.001
Gender	Male [vs. female]	142 (51.8%)	1248 (54.9%)	0.33
Race	White [vs. non-white]	59 (25.2%)	543 (27.6%)	0.433
Ethnicity	Hispanic / Latino [vs. non Hispanic / Latino]	88 (37.6%)	746 (38%)	0.915
Readmission patient	Yes [vs. No]	70 (25.5%)	612 (26.9%)	0.624
Co-morbidities	Cardiovascular [vs. No]	161 (58.8%)	721 (31.7%)	<0.001
	Endocrine [vs. No]	81 (29.6%)	389 (17.1%)	<0.001
	Gastrointestinal [vs. No]	64 (23.4%)	428 (18.8%)	0.073
	Haematology [vs. No]	124 (45.3%)	514 (22.6%)	<0.001
	Neurologic [vs. No]	87 (31.8%)	761 (33.5%)	0.563
	Oncology [vs. No]	8 (6.8%)	50 (5.3%)	0.495
	Respiratory [vs. No]	176 (64.2%)	1257 (55.3%)	0.005
	Obesity [vs. No]	79 (54.1%)	653 (58.1%)	0.353
Baseline Paediatric Cerebral Performance Category	Normal	27 (84.4%)	287 (70.3%)	0.527
	Mild disability	2 (6.2%)	46 (11.3%)
	Moderate disability	2 (6.2%)	33 (8.1%)
	Severe disability	1 (3.1%)	41 (10%)
	Coma or vegetative state	0 (0%)	1 (0.2%)
Baseline Paediatric Overall Performance Category	Normal	23 (71.9%)	240 (58.8%)	0.491
	Mild disability	5 (15.6%)	63 (15.4%)
	Moderate disability	3 (9.4%)	62 (15.2%)
	Severe disability	1 (3.1%)	42 (10.3%)
	Coma or vegetative state	0 (0%)	1 (0.2%)

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AKI: Acute Kidney Injury

The laboratory profile of patients among the AKI and non-AKI group are included in Table 2. EGFR was calculated using IDMS-Traceable Schwartz Equation [eGFR = (0.41 x height in cm) ÷ serum Cr]. Systolic and Diastolic blood pressure Z score was calculated using the equation provided in National High Blood Pressure Education Program Working Group on High Blood Pressure in Children and Adolescents [25]. In Table 1, BMI z score was calculated based upon the CDC’s definition. Obesity is defined as BMI z score > 1.64 [18]. The association of different outcomes among AKI patients across different AKI stages are included in Table 4. The continuous outcome variables include hospital length of stay, PIM 2 probability of death and PIM 3 probability of death. Categorical outcomes include mortality, airway and respiratory support, cardiorespiratory support, kidney support, and vascular access. Vascular access included arterial catheter; Hemodialysis/ Plasmapheresis catheters; ECMO cannula; venous catheter (peripherally inserted central catheter; and percutaneous central venous catheter). Airway/respiratory support included endotracheal intubation (and duration of intubation); tracheostomy tube insertion (includes duration of intubation); invasive ventilation [mechanical ventilation, conventional (including CPAP plus pressure support); CPAP (invasive); HFOV (high frequency oscillator ventilation); Jet Ventilation]; Non-Invasive Respiratory Support or Ventilation [BiPAP (non-invasive); Mechanical Ventilation (Non-Invasive); CPAP (Non-Invasive); and Humidified High Flow Oxygen. Cardio-respiratory support included ECMO. Kidney support included Intermittent Hemodialysis (IHD).

Table 2. Laboratory profile of patients among AKI and non-AKI group.

Variables	AKI		Non-AKI		p value
Variables	N	Median (IQR)	N	Median (IQR)	p value
BMI z score	146	1.9 (0.4–3.3)	1123	2.2 (0.4–3.7)	0.425
SBP (mmHg)	118	118.5 (106–133.3)	941	117 (105–128.5)	0.267
SBP z score^{^}	64	2 (0.9–3.1)	441	1.9 (0.9–3.1)	0.986
DBP (mmHg)	118	71 (61.8–85)	942	72 (62–82)	0.929
DBP z score^{^}	64	1.5 (0.5–2.8)	441	1.7 (0.9–2.8)	0.109
Heart Rate (bpm)	118	128 (114.8–148)	947	127 (107–147)	0.107
Respiratory Rate (bpm)	118	36.5 (26.8–47)	939	34 (26–44)	0.092
Temperature (°C)	118	37.2 (36.8–38.5)	932	37.2 (36.8–37.8)	0.361
pH	76	7.3 (7.2–7.4)	345	7.4 (7.3–7.4)	<0.001
pCO2 (mmHg)	78	37.3 (30.4–46.2)	336	39.5 (33.6–47)	0.079
Haemoglobin (g/dL)	71	12.1 (10.4–14.3)	399	11.9 (10.5–13.5)	0.411
WBC (10⁹/L)	66	15.9 (9–23.5)	334	9.4 (6.3–13.6)	<0.001
Platelet Count (10⁹/L)	58	168 (110.3–273.5)	326	216.5 (149–289.5)	0.07
PT (Seconds)	49	15.2 (13.4–17.4)	237	14.5 (13.1–16.2)	0.278
PTT (Seconds)	45	30.9 (27.1–44.9)	226	32 (28.8–37)	0.919
Sodium (Serum) (mmol/L)	99	143 (137–148)	495	141 (137–145)	0.064
Potassium (Serum) (mmol/L)	100	4.6 (3.9–5.7)	481	4.3 (3.8–4.9)	0.008
Bicarbonate (mmol/L)	77	19 (14–22.3)	430	21.1 (18–24.2)	<0.001
Blood Urea Nitrogen (mmol/L)	91	9.3 (5.4–15.7)	452	3.9 (2.9–5.4)	<0.001
Creatinine (mg/dL)	91	1.3 (0.8–2.4)	451	0.5 (0.3–0.7)	<0.001
eGFR (ml/min/1.73m²)^*	51	41.7 (23.7–68.2)	218	107.6 (82–146.3)	<0.001
Glucose (Serum) (mg/dL)	100	157 (125–260)	505	128 (106–192)	<0.001
Total Calcium (mg/dL)	75	8.4 (7.8–9.4)	404	8.6 (8.1–9.2)	0.325
Total Bilirubin (mg/dL)	57	0.5 (0.3–1.3)	296	0.5 (0.3–0.8)	0.322
Albumin (g/dL)	53	3 (2.6–3.8)	310	3.5 (2.8–4)	0.062

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AKI: Acute Kidney Injury; mmHg: millimeter of mercury; bpm: beat per minute; °C: degree Celsius; pCO2: partial pressure of carbon dioxide; g: gram; dl: deciliter; WBC: White blood cells; L: liter; PT: prothrombin time; PTT: partial thromboplastin time; mmol/L: millimoles per liter; mg: milligram; IQR: Interquartile range

^calculated only for children with height data availability

*calculated only for children with height and creatinine data availability

Table 4. Association of different outcomes among AKI patients across different AKI stage.

Continuous outcome
Outcomes	AKI stage 1		AKI stage 2		AKI stage 3		p value
Outcomes	N	Median (IQR)	N	Median (IQR)	N	Median (IQR)	p value
Hospital LOS (days)	168	8.24 (4.90–13.6)	40	8.78 (4.64–16.05)	62	11.93 (7.40–24.33)	0.009
PIM 2 Probability of Death (%)	172	1.15 (0.89–3.36)	40	1.22 (0.82–5.24)	62	1.28 (0.85–4.42)	0.606
PIM 3 Probability of Death (%)	172	0.96 (0.73–2.34)	40	1.04 (0.38–2.97)	62	1.12 (0.7–4.7)	0.484
Categorical outcome
Outcomes	N (%)		N (%)		N (%)		p value
Airway / Respiratory support	86 (50.0%)		22 (55.0%)		44 (71.0%)		0.019
Cardio-respiratory support	5 (2.9%)		0 (0%)		3 (4.8%)		0.375
Vascular access	102 (59.3%)		28 (70.0%)		54 (87.1%)		<0.001

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AKI: Acute Kidney Injury; LOS: Length of stay; PIM: Pediatric index of mortality; IQR: Interquartile range

The mortality status and kidney support has been used in the classification of AKI stage, therefore these outcomes have not been considered for analysis.

This study has been approved by the Akron Children’s Health Centers IRB Committee. The project approval number is 1632930-AKHC. This is a retrospective study of medical records, and the IRB committee waived the requirement for informed consent. All data was fully anonymized before being accessed.

Statistical analysis

All the variables were tested for normality using Kolmogorov-Smirnov test. Categorical variables were summarized as frequencies and percentages, while continuous variables were summarized as medians and inter-quartile range (IQR; 25th to 75th percentiles). Univariate analysis (using the chi-square or Fischer exact test for categorical variables and Mann Whitney U test for continuous variables) was carried out to assess the unadjusted relationship between the variables / different outcomes in the two groups. The multivariate linear or logistic regression was conducted to assess the association of different outcomes in the two groups after adjusting for variables observed to be significant in the univariate analysis. The difference in outcomes across three AKI staging group was assessed using Kruskal Wallis test for continuous variables and chi-square or Fischer exact test for categorical variables. A two-sided p value <0.05 was statistically significant. Statistical software (SPSS version 20) was used to perform the statistical analyses.

Results

A total of 2,546 COVID+ patients were included in our analysis where 10.8% (n = 274) had a diagnosis of AKI. In this subset, 62.8% (n = 172) had stage 1 AKI, 14.6% (n = 40) had stage 2 AKI, and 22.6% (n = 62) had stage 3 AKI. The median (IQR) age (years) of the patients with AKI was observed to be significantly higher versus without AKI [5 (4–5) vs. 4 (3–5)]. Associated co-morbidities with AKI—according to the VPS database–include respiratory [64.2% vs. 55.3%; p = 0.005], cardiovascular [58.8% vs. 31.7%; p<0.001], endocrinal [29.6% vs. 17.1%; p<0.001], and hematology [45.3% vs. 22.6%; p<0.001] dysfunctions when compared with non-AKI cohort. Notably, the gender, race, ethnicity, baseline pediatric cerebral performance category, and baseline pediatric overall performance category were not statistically significant between the two groups (Table 1).

Clinical lab values which were higher in the AKI subset compared to the non-AKI cohort are reported as ‘median (IQR)’and include: white blood cells count, serum potassium, blood urea nitrogen, creatinine, eGFR, and serum glucose. pH and bicarbonate levels were significantly lower in the AKI subset compared to the non-AKI cohort (Table 2).

Significantly higher continuous and categorical outcomes in the AKI subset compared to the non-AKI cohort included: length of stay at the hospital (LOS) [9.04 (5.11–16.66) vs. 5.09 (2.58–9.94) days; p<0.001], PIM 2 probability of death [1.20 (0.86–3.83) vs. 0.96 (0.79–1.72)%; p<0.001], PIM 3 probability of death [0.98 (0.72–2.93) vs. 0.78 (0.69–1.26)%; p<0.001], mortality [crude OR (95% CI): 5.01 (2.89–8.70)], airway and respiratory support [1.63 (1.27–2.10)], cardio-respiratory support [3.57 (1.55–8.23)], kidney support [12.52 (5.30–29.58)], and vascular access [4.84 (3.70–6.32)] (S1A and S1B Figs in S1 File).

The continuous and categorical outcomes remained greater in the AKI versus non-AKI cohort even after adjusting for variables significant in the uni-variate analysis (such as age (continuous), presence of cardiovascular, endocrine, hematology, and respiratory co-morbidities) and included: LOS [6.29 (3.95–8.64) days], the adjusted odds (95% CI) of mortality [2.69 (1.48–4.88)], of airway and respiratory support [1.61 (1.16–2.24)], of kidney support [5.34 (2.15–13.25)], and of vascular access [3.51 (2.63–4.70)] (Table 3). The adjusted association of other variables with the outcomes is shown in S1C Table in S1 File.

Table 3. Univariate (crude) and adjusted association of different outcomes among patients with versus without AKI.

Univariate Association
Continuous outcome
Outcomes		AKI			Non-AKI					p value
Outcomes		N	Median (IQR)		N		Median (IQR)			p value
Hospital LOS (days)		270	9.04 (5.11–16.66)		2,228		5.09 (2.58–9.94)			<0.001
PIM 2 Probability of Death (%)		274	1.20 (0.86–3.83)		2,272		0.96 (0.79–1.72)			<0.001
PIM 3 Probability of Death (%)		274	0.98 (0.72–2.93)		2,272		0.78 (0.69–1.26)			<0.001
Categorical outcome
Outcomes	AKI [N (%)]			Non-AKI [N (%)]		p value		Crude Odds ratio (95% CI)
Mortality	21 (7.7%)			37 (1.6%)		<0.001		5.01 (2.89–8.70)
Airway / Respiratory support	152 (55.5%)			983 (43.3%)		<0.001		1.63 (1.27–2.10)
Cardio-respiratory support	8 (2.9%)			19 (0.8%)		0.006		3.57 (1.55–8.23)
Kidney support	13 (4.7%)			9 (0.4%)		<0.001		12.52 (5.30–29.58)
Vascular access	184 (67.2%)			675 (29.7%)		<0.001		4.84 (3.70–6.32)
Adjusted Association ^*
Continuous outcome
Outcomes		Un-standardized Coefficients (95% CI)^{^}							p value
Hospital LOS (days)		6.29 (3.95–8.64)							<0.001
PIM 2 Probability of Death (%)		0.81 (-0.11–1.72)							0.083
PIM 3 Probability of Death (%)		0.61 (-0.30–1.51)							0.187
Categorical outcome
Outcomes		Adjusted odds ratio (95% CI)^{^}							p value
Mortality		2.69 (1.48–4.88)							0.001
Airway / Respiratory support		1.61 (1.16–2.24)							0.005
Cardio-respiratory support		1.88 (0.77–4.56)							0.165
Kidney support		5.34 (2.15–13.25)							<0.001
Vascular access		3.51 (2.63–4.70)							<0.001

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AKI: Acute Kidney Injury; LOS: Length of stay; PIM: Pediatric index of mortality; IQR: Interquartile range; CI: Confidence Interval

^AKI versus non-AKI

*Adjusted for variables significant in the uni-variate analysis “Table 1” such as age (continuous in years), presence of cardiovascular, endocrine, hematology, and respiratory co-morbidities (categorical). The clinical and laboratory variables significant in the uni-variate analysis “Table 2” were not considered because for those variables the data was available for <25% of the children [which was leading to decrease in the sample size for adjusted analysis to a greater extent]

When comparing the continuous outcomes to the stages of AKI, the values increased statistically significantly for LOS [stage 1: 8.24 (4.90–13.6); stage 2: 8.78 (4.64–16.05); and stage 3: 11.93 (7.40–24.33) days; p = 0.009], but not for PIM 2 [1.15 (0.89–3.36) vs. 1.22 (0.82–5.24) vs. 1.28 (0.85–4.42)%; p = 0.606], and PIM 3 [0.96 (0.73–2.34) vs. 1.04 (0.38–2.97) vs. 1.12 (0.7–4.7)%; p = 0.484]. However, when comparing the categorical outcomes to the stages of AKI, airway and respiratory support reported statistically significant data [stage 1: 50.0%; stage 2: 55.0%; and stage 3: 71.0%; p = 0.019] and need of vascular access [59.3% vs. 70.0% vs. 87.1%; p<0.001]. The mortality status and kidney support has been used in the classification of AKI stage; therefore these outcomes have not been considered for analysis (Table 4) A multivariate analysis for these outcomes based on AKI staging was not conducted due to the limited sample size.

Discussion

As of July 2021, the public, online VPS dashboard reported 2,596 pediatric patients with COVID-19 admitted to North American PICUs, of which approximately 3.04% required KRT. Within this subset, 86.4% were successfully discharged afterwards but 13.6% eventually died. From the patients that received KRT, 84.8% reported respiratory dysfunction, 81.2% reported circulatory dysfunction, and 42.4% reported vascular dysfunction. Notably, 14.0% of the total cohort reported kidney/urinary organ dysfunction, of which 88.8% were discharged and 11.2% died.

Among 2,546 COVID-19+ children, 10.8% of patients developed AKI. This coincides with the incidence reported by Derespina et al. in a study at New York City PICUs; Among 70 children admitted, 12.9% developed AKI [21]. Separate studies from Saudi Arabia, Iran, England, and France found much higher incidences of AKI at 21%, 22%, 29%, 19%, and 70% respectively [13, 15–17, 26] (S1A Table in S1 File). Contrarily, studies from Italy, Spain, and two from China all reported AKI incidences significantly lower at 1.2%, 0.8%, 1.3%, and 2.7%, respectively [8, 9, 11, 27] (S1A Table in S1 File). A recent study by Basu et al. reported an AKI incidence of 37.5% among 311 pediatric patients with COVID-19 [28]. However, only 51.4% of the patients had a confirmed SARS-CoV-2 infection, while the rest of the population were suspected cases. The authors acknowledge the presence of a possible selection bias, as provides may have been more likely to suspect SARS-CoV-2 with a negative test result in more severely ill patients than those who were less severely ill. Kari et al. hypothesized that some discrepancy between AKI incidences may also be attributed to differences in the AKI definitions used [13]. Some studies used the KDIGO definition to define AKI; however, an English study by Stewart et al. analyzed the British Association of Pediatric Nephrology’s (BAPN) and found a higher incidence of 29% [26].

The VPS data showed that patients in the AKI group have a much higher rate of mortality [crude OR (95% CI): 5.01 (2.89–8.70)]. Likewise, a study from Saudi Arabia found a mortality rate of 42% among AKI patients and 0% among non-AKI patients [13]. The VPS results deviate from Bjornstad et al’s multicenter study throughout the United States, Eastern Europe, and Russia, where a mortality rate of 6% was found among AKI COVID-19 pediatric patients and 5% among pediatric COVID-19 patients without AKI. However, data may be underestimated as the authors note that they used creatinine instead of urine output to define AKI [12].

The most common clinical features of COVID-19 among children include fever, dry cough, and pneumonia, along with an increasing prevalence of multisystem dysfunction [26]. Within the 2,596 pediatric COVID-19 cohort from the VPS data from North American PICU’s, several additional organ systems were reportedly involved including 49.3% of patients with respiratory symptoms, 33.1% with circulatory symptoms, 21.6% with digestive/excretory symptom, 17.6% with hematologic symptoms, 12.3% with neurologic symptoms, and 11.7% with kidney/urinary symptom. Correspondingly, comorbidities that were reported to be significantly higher among the VPS AKI-group as opposed to the non-AKI group included respiratory [64.2% vs. 55.3%], cardiovascular [58.8% vs. 31.7%], endocrinal [29.6% vs. 17.1%], and hematologic [45.3% vs. 22.6%]. In many COVID-19 cases, residual renal impairment may be attributed to the systemic effects of decreased tissue perfusion from hypoxia or transient periods of hypotension, fluctuations in electrolyte levels or hypernatremia, and/or associated comorbidities [13]. Consequently, physicians ought to be aware of such factors that may precipitate renal complications in COVID-19 patients. Ultimately, research aims to improve short-term outcomes as measured by hospital LOS along with overall long-term outcomes in quality of life.

Despite COVID-19’s potential severity, studies have suggested that children are less susceptible than adults. Lee et al. theorizes that this is because children have a more active innate immune response, are generally more protected by parents, engage in fewer outdoor activities, are less likely to travel internationally, and have relatively less comorbidities [29]. Biochemically, ACE2 demographics differ from its distribution, maturation, and function–ultimately affecting its association with the receptor binding domain of the COVID-19 spike-protein and reducing susceptibility and severity [6, 29, 30]. However, more studies are needed to fully elucidate why children are less susceptible than the adult population to severe COVID-19 infections.

Due to the retrospective database design of this study, there are notable limitations. This study is limited to data from a select number of pediatric ICUs across only North America, therefore limiting our ability to apply our results globally. Additionally, as COVID-19 continues to progress and new viral variants being to emerge, new advances in data and research will emerge, which will allow for better understanding of the virus.

Conclusion

Overall, AKI incidence among pediatric ICU patients was 10.8%, which is higher than multiple previous large-scale studies had described. AKI severity among children with COVID-19 has additionally been shown to be associated with an increased risk of mortality. Despite the reduced susceptibility of severe disease in children, it is crucial to continue to develop the knowledge base surrounding all manifestations of COVID-19 among children across the world. A greater understanding of COVID-19 among the pediatric population may reduce the potential for exponentially increasing rates of morbidity and mortality through this highly transmissible virus.

Supporting information

S1 File. Supporting information.

(DOCX)

Click here for additional data file.^{(48.7KB, docx)}

S2 File. Data set.

(XLSX)

Click here for additional data file.^{(1,002.9KB, xlsx)}

Acknowledgments

We would like to acknowledge Nina Vijayvargiya for her help with manuscript revision.

Data Availability

All relevant data are within the manuscript and its Supporting Information files.

Funding Statement

The authors received no specific funding work.

References

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PLoS One. doi: 10.1371/journal.pone.0266737.r001

Decision Letter 0

Zhanjun Jia

17 Jan 2022

PONE-D-21-39403Acute Kidney Injury in COVID-19 Pediatric Patients in North America: Analysis of the Virtual Pediatric Systems DataPLOS ONE

Dear Dr. raina,

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Reviewer #1: Yes

Reviewer #2: Yes

**********

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Reviewer #1: Yes

Reviewer #2: I Don't Know

**********

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Reviewer #1: Yes

Reviewer #2: Yes

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Reviewer #1: Dear Authors,

I have reviewed your manuscript titled "Acute Kidney Injury in COVID-19 Pediatric Patients in North America: Analysis of the Virtual Pediatric Systems Data" with keen interest.

I have very few comments.

1. It is usually best to leave continuous variables uncategorized, except where such categorization are standard e.g categorizing blood sugar levels according to diabetes defining cut-off values. It seems arbitrary that in some of the analyses, age is categorized as <12 years or >12 years (line 116) while in other instances it is categorized as <2 years or >2 years (line 146 and Table 1). The <2 years or >2 years categorization lumps up individuals with different anatomic/developmental and physiologic profiles. The group >2 years would comprise for instance 3-5 year olds, 6-10 year olds, young adolescents and late adolescents, given the cut off age in the study of <21 years.

If the age is left as a continuous variable, you could then assess what the odds ratios would be for different ages with incremental age and this would provide more clinically applicable and relevant deductions.Kindly have a look at this.

2. In line 168, you mention "circulatory dysfunction" and "vascular dysfunction". In reading through the manuscript I did not come across where these entities had been clearly defined and distinguished.

Overall, it is a nicely written, straight-to-the-point manuscript.

Thank you.

Reviewer #2: Thank you for your submission. I am curious to know why pediatric age rage was unto 21-years? It may be important to know that the studies that you have refereed/compared to have used the similar upper age. In line 15 PIM abbreviation is used for the first time. without its full name kindly correct.

**********

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Reviewer #1: No

Reviewer #2: Yes: Aasim Ahmad

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PLoS One. 2022 Apr 26;17(4):e0266737. doi: 10.1371/journal.pone.0266737.r002

Author response to Decision Letter 0

8 Feb 2022

Review’s Comments:

Reviewer 1

Reviewer Comment: It is usually best to leave continuous variables uncategorized, except where such categorization are standard e.g categorizing blood sugar levels according to diabetes defining cut-off values. It seems arbitrary that in some of the analyses, age is categorized as <12 years or >12 years (line 116) while in other instances it is categorized as <2 years or >2 years (line 146 and Table 1). The <2 years or >2 years categorization lumps up individuals with different anatomic/developmental and physiologic profiles. The group >2 years would comprise for instance 3-5 year olds, 6-10 year olds, young adolescents and late adolescents, given the cut off age in the study of <21 years. If the age is left as a continuous variable, you could then assess what the odds ratios would be for different ages with incremental age and this would provide more clinically applicable and relevant deductions. Kindly have a look at this.

Response: We thank the reviewer very much for their suggestion. We have re-done our data analysis as suggested so that age may be analyzed as a continuous variable with odds ratios. Kindly view the changes in the statistical analysis portion of the methods section, the results section, Table 1, and Table 3 of the manuscript. We have included S3 Table under supporting information entitled “Adjusted association of different variables on the outcomes” so that the adjusted association of age as a continuous variable with the different outcomes is shown.

Reviewer Comment: In line 168, you mention "circulatory dysfunction" and "vascular dysfunction". In reading through the manuscript I did not come across where these entities had been clearly defined and distinguished.

Response: We thank the reviewer for pointing out this issue. By using the terms ‘circulatory’ and ‘vascular’ dysfunction, we are using the terminology set forth by the Virtual Pediatric Systems (VPS) database and do not have any further information on how these terms were distinguished. According to the VPS data set, the organ systems involved by COVID-19 identifies organ specific symptoms a patient in the database was reported to have.

Reviewer 2

Comment: Thank you for your submission. I am curious to know why pediatric age rage was unto 21-years? It may be important to know that the studies that you have refereed/compared to have used the similar upper age. In line 15 PIM abbreviation is used for the first time without its full name kindly correct.

Response: We thank the reviewer for their comment. According to a 2017 policy statement from the American Academy of Pediatrics (AAP) entitled “Age Limit of Pediatrics,” by Amy Hardin and Jesse Hackell, the AAP acknowledges the upper age limit of pediatrics to be 21 years of age. In accordance to this statement, the US Department of Health and the Food and Drug Administration (FDA) reference approximate age ranges for late adolescence to be 18-21 years old. One very similar study we have referenced and cited as reference 38 in our manuscript entitled “Acute Kidney Injury in Critically Ill children and young adults with suspected SARS-CoV2 infection” by authors Basu et al., utilized an even broader age range of >1 week and <25 years of age. Ultimately, we chose the age of 21 due to the AAP, US Department of Health, and FDA guidelines.

Additionally, we thank the reviewer for pointing out the oversight in line 15. The abbreviation has been defined in the manuscript.

Attachment

Submitted filename: Response to Reviewers.docx

Click here for additional data file.^{(18.4KB, docx)}

PLoS One. doi: 10.1371/journal.pone.0266737.r003

Decision Letter 1

Zhanjun Jia

28 Mar 2022

Acute Kidney Injury in COVID-19 Pediatric Patients in North America: Analysis of the Virtual Pediatric Systems Data

PONE-D-21-39403R1

Dear Dr. Raina,

We’re pleased to inform you that your manuscript has been judged scientifically suitable for publication and will be formally accepted for publication once it meets all outstanding technical requirements.

Within one week, you’ll receive an e-mail detailing the required amendments. When these have been addressed, you’ll receive a formal acceptance letter and your manuscript will be scheduled for publication.

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Zhanjun Jia

Academic Editor

PLOS ONE

Additional Editor Comments (optional):

Reviewers' comments:

Reviewer's Responses to Questions

Comments to the Author

1. If the authors have adequately addressed your comments raised in a previous round of review and you feel that this manuscript is now acceptable for publication, you may indicate that here to bypass the “Comments to the Author” section, enter your conflict of interest statement in the “Confidential to Editor” section, and submit your "Accept" recommendation.

Reviewer #1: All comments have been addressed

Reviewer #2: All comments have been addressed

**********

2. Is the manuscript technically sound, and do the data support the conclusions?

Reviewer #1: Yes

Reviewer #2: (No Response)

**********

3. Has the statistical analysis been performed appropriately and rigorously?

Reviewer #1: Yes

Reviewer #2: (No Response)

**********

4. Have the authors made all data underlying the findings in their manuscript fully available?

Reviewer #1: Yes

Reviewer #2: (No Response)

**********

5. Is the manuscript presented in an intelligible fashion and written in standard English?

Reviewer #1: Yes

Reviewer #2: (No Response)

**********

6. Review Comments to the Author

Reviewer #1: Dear Authors,

Thank you for your responses to my comments.

They have adequately addressed all that had been raised by me.

Kind regards.

Reviewer #2: (No Response)

**********

7. PLOS authors have the option to publish the peer review history of their article (what does this mean?). If published, this will include your full peer review and any attached files.

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Reviewer #1: No

Reviewer #2: Yes: Aasim Ahmad

PLoS One. doi: 10.1371/journal.pone.0266737.r004

Acceptance letter

Zhanjun Jia

4 Apr 2022

PONE-D-21-39403R1

Acute kidney injury in COVID-19 pediatric patients in North America: analysis of the Virtual Pediatric Systems data

Dear Dr. Raina:

I'm pleased to inform you that your manuscript has been deemed suitable for publication in PLOS ONE. Congratulations! Your manuscript is now with our production department.

If your institution or institutions have a press office, please let them know about your upcoming paper now to help maximize its impact. If they'll be preparing press materials, please inform our press team within the next 48 hours. Your manuscript will remain under strict press embargo until 2 pm Eastern Time on the date of publication. For more information please contact onepress@plos.org.

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Thank you for submitting your work to PLOS ONE and supporting open access.

Kind regards,

PLOS ONE Editorial Office Staff

on behalf of

Dr. Zhanjun Jia

Academic Editor

PLOS ONE

Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

S1 File. Supporting information.

(DOCX)

Click here for additional data file.^{(48.7KB, docx)}

S2 File. Data set.

(XLSX)

Click here for additional data file.^{(1,002.9KB, xlsx)}

Attachment

Submitted filename: Response to Reviewers.docx

Click here for additional data file.^{(18.4KB, docx)}

Data Availability Statement

All relevant data are within the manuscript and its Supporting Information files.

[pone.0266737.ref001] 1.WHO Coronavirus Disease (COVID-19) Dashboard. World Health Organization. https://covid19.who.int. Published July 2, 2021. Accessed July 3, 2021.

[pone.0266737.ref002] 2.Gao YD, Ding M, Dong X, et al. Risk factors for severe and critically ill COVID-19 patients: A review. Allergy. 2021;76(2):428–455. doi: 10.1111/all.14657 [DOI] [PubMed] [Google Scholar]

[pone.0266737.ref003] 3.Chan L, Chaudhary K, Saha A, et al. AKI in Hospitalized Patients with COVID-19. J Am Soc Nephrol. 2021;32(1):151–160. doi: 10.1681/ASN.2020050615 [DOI] [PMC free article] [PubMed] [Google Scholar]

[pone.0266737.ref004] 4.Raina R, Chakraborty R, Mawby I, Agarwal N, Sethi S, Forbes M. Critical analysis of acute kidney injury in pediatric COVID-19 patients in the intensive care unit. Pediatr Nephrol. 2021. Apr 29. doi: 10.1007/s00467-021-05084-x Epub ahead of print. . [DOI] [PMC free article] [PubMed] [Google Scholar]

[pone.0266737.ref005] 5.Coronavirus Disease 2019 in Children—United States, February 12–April 2, 2020. MMWR Morb Mortal Wkly Rep 2020;69:422–426. doi: 10.15585/mmwr.mm6914e4 [DOI] [PMC free article] [PubMed] [Google Scholar]

[pone.0266737.ref006] 6.Deep A, Bansal M, Ricci Z. Acute Kidney Injury and Special Considerations during Renal Replacement Therapy in Children with Coronavirus Disease-19: Perspective from the Critical Care Nephrology Section of the European Society of Paediatric and Neonatal Intensive Care [published online ahead of print, 2020 Jul 14]. Blood Purif. 2020;1–11. doi: 10.1159/000509677 [DOI] [PMC free article] [PubMed] [Google Scholar]

[pone.0266737.ref007] 7.Wu Z, McGoogan JM. Characteristics of and Important Lessons From the Coronavirus Disease 2019 (COVID-19) Outbreak in China: Summary of a Report of 72 314 Cases [DOI] [PubMed]

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PERMALINK

Acute kidney injury in COVID-19 pediatric patients in North America: Analysis of the virtual pediatric systems data

Rupesh Raina

Isabelle Mawby

Ronith Chakraborty

Sidharth Kumar Sethi

Kashin Mathur

Shefali Mahesh

Michael Forbes

Roles

Abstract

Background

Methods

Results

Conclusions

Introduction

Methods

Study design and population

Data collection

Table 1. Baseline parameters among AKI and non-AKI group.

Table 2. Laboratory profile of patients among AKI and non-AKI group.

Table 4. Association of different outcomes among AKI patients across different AKI stage.

Statistical analysis

Results

Table 3. Univariate (crude) and adjusted association of different outcomes among patients with versus without AKI.

Discussion

Conclusion

Supporting information

Acknowledgments

Data Availability

Funding Statement

References

Decision Letter 0

Zhanjun Jia

Roles

Author response to Decision Letter 0

Decision Letter 1

Zhanjun Jia

Roles

Acceptance letter

Zhanjun Jia

Roles

Associated Data

Supplementary Materials

Data Availability Statement

ACTIONS

PERMALINK

RESOURCES

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