All issues > Volume 66(10); 2023
Kidney complications associated with COVID-19 infection and vaccination in children and adolescents: a brief review
- Corresponding author: Min Hyun Cho. Department of Pediatrics, School of Medicine, Kyungpook National University, 680 Gukchaebosang-ro, Jung-gu, Daegu 41944, Korea Email: chomh@knu.ac.kr
- Received May 17, 2023 Revised June 26, 2023 Accepted June 28, 2023
- Abstract
-
Coronavirus disease 2019 (COVID-19) has spread considerably across the globe, affecting numerous children and adolescents besides adults. Despite its relatively lower incidence rates in children and adolescents than in adults, some infected children and adolescents exhibit a severe postinflammatory response known as multisystem inflammatory syndrome in children, followed by acute kidney injury, a common complication. Meanwhile, few reports have been available regarding kidney complications such as idiopathic nephrotic syndrome and other glomerulopathies associated with COVID-19 infection and vaccination in children and adolescents. However, the morbidity and mortality of these complications are not exceptionally high; more importantly, causality has yet to be clearly established. Finally, vaccine hesitancy in these age groups should be addressed, considering the strong evidence of COVID-19 vaccine safety and efficacy.
- Introduction
- Introduction
The coronavirus disease 2019 (COVID-19) pandemic, caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), has affected millions worldwide, including children and adolescents. Although most infected children experience mild to moderate symptoms or remain asymptomatic, some exhibit a severe postinflammatory response known as multisystem inflammatory syndrome in children (MIS-C) or pediatric inflammatory multisystem syndrome temporally associated with COVID-19 [1]. This condition reportedly occurs within 2–6 weeks after COVID-19 infection or exposure to an infected person and is characterized by persistent fever, inflammation, and dysfunction of multiple organs, including the heart, kidneys, and lungs. Despite the relatively lower incidence rate of MIS-C (1 of every approximately 3,000–4,000) than that of COVID-19 in adults and its risk of mortality and serious complications, it requires immediate recognition and management [1-6].Since the beginning of the pandemic, reports have shown that acute kidney injury (AKI) in children with MIS-C or critically ill children requiring hospitalization is significantly associated with intensive care unit (ICU) admission [7,8]. Furthermore, several studies reported other kidney complications, including idiopathic nephrotic syndrome (INS) and various types of glomerulonephritis (GN), in populations with COVID-19 who received the vaccination [9]. Understanding the epidemiology and pathophysiology of AKI and other kidney complications in relation to COVID-19 infection and vaccination can aid the establishment of treatment strategies and improve clinical outcomes.This review provided a brief overview of our current understanding of the epidemiology, pathogenesis, and clinical characteristics of AKI, nephrotic syndrome, and GN in children and adolescents who experienced COVID-19 infection and received vaccination.
- Kidney complications associated with COVID-19 infection in children and adolescents
- Kidney complications associated with COVID-19 infection in children and adolescents
- 1. Acute kidney injury
- 1. Acute kidney injury
The Kidney Disease: Improving Global Outcomes defines AKI as one or more of the following criteria: increase in serum creatinine by ≥0.3 mg/dL within 48 hours, increase in serum creatinine to ≥1.5 times the baseline value within the preceding 7 days, or a urine volume of ≤0.5 mL/kg/hr for 6 hours [10].The pathogenesis of COVID-19-associated AKI is multifactorial. First, the virus binds to the angiotensin-converting enzyme 2 receptors distributed across the proximal tubules, podocytes, epithelial cells, and endothelial cells of the kidneys, subsequently causing direct cell damage, resulting in glomerular collapse, endothelial damage, coagulopathy, and complement activation, leading to AKI. In addition, systemic consequences of viral infection, such as cytokine release, hypovolemia, ischemia, or iatrogenic nephrotoxin exposure, or the presence of viruses in distant organs such as the lungs (i.e., lung-kidney cross-talk) can indirectly cause AKI [1,11].Studies in adults reported that AKI affects more than 20% of hospitalized patients with COVID-19 and more than 50% of ICU patients [11]. Moreover, several observational studies of various sizes conducted from the beginning of the pandemic reported AKI incidence rates as high as approximately 11%–46% in children and adolescents with COVID-19 who are critically ill or developed MIS-C, similar to those observed in adults [8,12-20]. In contrast, only a few studies reported the incidence of AKI in those with mild to moderate COVID-19. A multicenter cross-sectional study conducted in Turkey reported incidence rates of 16.9% for AKI and 31% for subclinical AKI. Subclinical AKI was defined when at least one of 3 urine biomarkers—neutrophil gelatinase-associated lipocalin, kidney injury molecule-1, and interleukin-18—was positive without an elevated serum creatinine level [21].A small number of systematic reviews and meta-analyses recently reported the pooled incidence of AKI as 20%–30% in children and adolescents with severe COVID-19 infection such as MIS-C or ICU admission [22,23]. In a meta-analysis by Tripathi et al. [22], the pooled proportion of death in children with MIS-C was approximately 4% (95% confidence interval [CI], 1%–14%), whereas MIS-C patients with AKI had a 4.68 (95% CI, 1.06%–20.7%) higher odds of death than those without AKI. Moreover, evidence suggests that nearly 15% (95% CI, 4%–42%) of AKI patients with MIS-C require renal replacement therapy (RRT). In contrast, a meta-analysis by Raina et al. [23] revealed that the mortality rate of ICU children with COVID-19 was 2.55% (95 % CI, 1.67%–3.73%) and that the pooled proportion of AKI patients requiring RRT was 0.56% (95% CI, 0.16%–1.43%), significantly lower than that reported by Tripathi et al. [22].AKI associated with COVID-19 was diagnosed in the early stages of hospitalization in most patients, and they were reportedly infected with COVID-19 approximately 33 days (27.5– 46 days) before ICU admission. This appears consistent with reports that MIS-C develops a mean 2–6 weeks after infection with COVID-19. In addition, children with AKI have significantly lower serum albumin levels and higher white blood cell counts than those without AKI at admission [6,14,18].A large-scale retrospective study (n=2,546) conducted on pediatric ICU inpatients in North America found that COVID-19 patients with AKI had a 6.29-day (95% CI, 3.95–8.64) longer length of hospital stay, 2.69 times greater odds for mortality (95% CI, 1.48–4.88), and 5.34 times greater odds for kidney support (95% CI, 2.15–13.25) than COVID-19 patients without AKI [24]. Therefore, evidence suggests that AKI after COVID-19 infection in children should be considered a major risk factor for increased severity and mortality.Table 1 summarizes the major observational studies to date of AKI development in children and adolescents with COVID-19.- 2. Idiopathic nephrotic syndrome
- 2. Idiopathic nephrotic syndrome
INS in children is defined as nephrotic-range proteinuria (≥40 mg/m2/hr or a urine protein/creatinine ratio of ≥2 or 3+ protein on a urine dipstick) of unknown etiology plus hypoalbuminemia, edema, or hyperlipidemia [25]. Most children with INS receive chronic immunosuppressive therapy to control the disease activity, which is known to increase the risk of infectious diseases including viral infections [26].Morello et al. [26] conducted a systematic review of COVID-19 cases in children with INS. In this comprehensive review of 13 studies (43 children with COVID-19 of 1,126 children with INS) children with INS did not have a particularly high COVID-19 infection rate. Moreover, despite COVID-19 infection, they generally showed a mild clinical course, with low ICU hospitalization rates and a need for respiratory support. They also recommended that immunosuppressive therapy be continued regardless of the pandemic situation. In addition, despite the few cases of INS relapse during the COVID-19 infection period (n=5), they showed a good response to steroids, even de novo cases (n=2) showing typical symptoms and clinical improvement with steroid treatment.A recent retrospective study of 59 pediatric INS patients from a single center in Korea reported that 20 were infected with COVID-19 during the study period (34%). Consistent with other studies, this study showed that all patients had mild clinical symptoms that improved with symptomatic treatment comprising antipyretic or cold medications and did not require hospitalization or antiviral therapy. Furthermore, the relapse rate among INS patients with COVID-19 (3 of 20 [15%]) did not differ significantly from that of INS patients without COVID-19 (8 of 39 [20.5%]) [27].Chiodini et al. [28] performed a retrospective cohort analysis of 218 children with INS in Belgium and Italy. Comparison of the relapse rate between the 5 years immediately preceding the COVID-19 outbreak (i.e., 2015–2019) and the first year of the outbreak (i.e., 2020) showed no statistically significant difference, with an incidence rate ratio of 0.9 (95% CI, 0.76–1.06). Moreover, no severe complications among the study participants, such as death or hospitalization due to COVID-19, were reported.Morello et al. [29] retrospectively analyzed a cohort of 176 children with INS from the beginning of the pandemic to May 31, 2022. A total of 61 (34.7%) were infected with COVID-19 during the study period. After the spread of the omicron variant, children with INS showed a significantly higher COVID-19 infection rate than previously reported. However, the clinical symptoms were mild in children with INS taking immunosuppressive medication or had proteinuria. Moreover, none of the patients required immunosuppressive therapy discontinuation due to the COVID-19 infection.- 3. Glomerulopathy
- 3. Glomerulopathy
In adults with COVID-19, several pathological findings of kidney biopsies, such as podocytopathies (collapsing glomerulopathies), immune-mediated glomerular diseases (membranous glomerulopathy), tubulointerstitial diseases (acute tubular injury), and thrombotic microangiopathy, have been reported [1,30,31]. In contrast, pathological data in children and adolescents are lacking [32].A recent case report showed that a previously healthy 11-year-old boy hospitalized with gross hematuria and generalized edema 2 weeks after contracting the COVID-19 infection in Korea was diagnosed with crescentic immune-complex GN through a kidney biopsy. Steroid therapy, immunosuppressants, including cyclophosphamide and azathioprine, and antihypertensive treatment clinically improved his condition [33].Another case study reported on 2 patients (13- and 16-year-old boys) who developed severe, rapidly progressive GN and end-stage renal disease after COVID-19 in India. A kidney biopsy confirmed immunoglobulin A (IgA) nephropathy with crescentic GN, acute tubular injury, and focal medium-artery vasculitis [34].In Italy, 2 consecutive renal biopsies were performed in a 10-year-old girl after a COVID-19 infection; the first revealed diffuse and segmental mesangial-proliferative GN, while the second revealed crescentic GN. The same case study also confirmed acute tubulointerstitial nephritis (TIN) through a kidney biopsy in a 12-year-old girl infected with COVID-19 [32].Furthermore, case reports showed the presence of acute necrotizing GN in 17- and 16-year-old boys infected with COVID-19 in Iran, whereas another report from the United States showed the presence of necrotizing GN in a 17-year-old boy with perinuclear antineutrophil cytoplasmic antibodies/myeloperoxidase vasculitis [35,36].
- Kidney complications associated with COVID-19 vaccination in children and adolescents
- Kidney complications associated with COVID-19 vaccination in children and adolescents
Research has demonstrated the safety and efficacy of COVID-19 vaccines (Pfizer-BioNTech BNT162b2 and Moderna mRNA-1273) in children and adolescents, and the eligibility age for vaccination has been gradually expanded. Since June 2022, vaccination has become available for infants over 6 months of age. A well-known side effect of vaccination is the increased risk of myocarditis and pericarditis after the second dose in young men aged 12–24 years. However, most of these patients improved with conservative treatment, and the condition had no significant impact on their quality of life [37]. In contrast, several cases of renal side effects, such as minimal change disease (MCD), IgA nephropathy (IgAN), and vasculitis, have been reported after vaccination in adults. Nevertheless, causality has yet to be clearly established, with large population-based observational studies suggesting no increase in the risk of occurrence [9].Novel mRNA vaccines for SARS-CoV-2, including BNT162B2 (Pfizer), are based on an mRNA lipid nanoparticle-encapsulated platform and induce a stronger cell-mediated response by upregulating CD4+ and CD8+ T cells. Therefore, studies have suggested that the pathogenic mechanism involves the sequential production of proinflammatory cytokines, such as interferon-γ and tumor necrosis factor-α, which can exacerbate existing immune-mediated glomerular disease or cause de novo GN, including IgAN [38-40].In developed countries such as the United States and Japan, the eligibility age for COVID-19 vaccination, especially the Pfizer-BioNTech vaccine, has gradually expanded to include those aged 16+ years (December 2020), 12–15 years (May 2021), 5–11 years (October 2021), and 6 months to 4 years (June 2022). Therefore, case reports on kidney side effects in children and adolescents have been reported mainly in these countries and adolescents aged 12+ years with de novo or relapsed forms of glomerular disease (primarily IgAN and INS). Cases of IgAN mainly occurred de novo within 1–2 days after the second dose of the Pfizer-BioNTech vaccine, manifesting as gross hematuria and proteinuria of varying degrees. In most cases, the symptoms improved with intravenous/oral steroid therapy, angiotensin receptor blockers, and supportive care [39-45].In contrast to cases of IgAN, there have been cases in which kidney failure and oliguria were severe enough to require hemodialysis. A case report of a 16-year-old girl in Korea showed a relatively long interval between vaccination and symptom onset. She experienced nonspecific symptoms, such as respiratory distress and headache, for 6 weeks after receiving her second dose of the vaccine and was diagnosed with crescentic GN through a kidney biopsy after receiving hemodialysis for acute kidney failure [46]. In Luxembourg, a case of rapidly progressive GN was reported; a 13-year-old girl developed systemic symptoms, including gross hematuria, just 1 d after the first dose of the vaccine and rapidly progressed to AKI, requiring hemodialysis [47].Among patients with INS, most had a de novo occurrence than a relapse, and the interval between vaccination and symptom onset was 1–19 days. MCD was the main pathological finding in patients who underwent kidney biopsy, all of whom responded well to steroid treatment [48-52]. On the other hand, 2 reports showed cases of new-onset acute TIN after the second vaccination in Korea that reportedly responded well to oral steroid treatment (a 12-year-old boy) and supportive care (a 17-year-old boy) [53].Several case reports of kidney complications, such as IgAN and INS after COVID-19 vaccination in children and adolescents are summarized in Table 2.
- Management of kidney complications and vaccine hesitancy in children and adolescents with COVID-19
- Management of kidney complications and vaccine hesitancy in children and adolescents with COVID-19
Children and adolescents hospitalized with COVID-19 are at a high risk of developing AKI regardless of disease severity, thereby increasing their morbidity and mortality. In fact, evidence has shown that kidney disease in childhood and adolescence significantly impacted long-term outcomes, such as adult health status, social and behavioral adjustment, educational success, and employment security [1,54]. Therefore, the medical staff caring for these patients should pay special attention to their respiratory and systemic symptoms besides their urinary symptoms and kidney function. If AKI or other kidney complications are diagnosed, a referral to a pediatric nephrologist for active treatment is recommended.Despite strong evidence of the safety and effectiveness of COVID-19 vaccines, hesitancy remains widespread [55,56]. Wang et al. [57] analyzed vaccine hesitancy and current attitudes toward vaccines among parents of children with chronic kidney disease (n=207). Accordingly, approximately two-thirds of parents were hesitant or unsure about vaccinating their children, and parents with higher education levels were more willing to vaccinate their children. The main reasons for vaccine hesitancy were concerns about vaccine safety, a lack of sufficient information, and a lack of communication with medical experts. Therefore, medical professionals who frequently interact with parents must provide consistent and standardized COVID-19 vaccination information tailored to the parents’ level of understanding and maintain consistent communication to increase the COVID-19 vaccination rate.
- Conclusion
- Conclusion
The current review briefly examined the existing literature on kidney complications reportedly associated with COVID-19 infection and vaccination. A high incidence of AKI is shown in children and adolescents diagnosed with MIS-C or are critically ill because of infection, similar to that in adults. However, INS and other glomerulopathies did not appear to have particularly high morbidity or mortality rates. Vaccine hesitancy in these age groups should be addressed through consistent communication with the parents or guardians based on strong evidence regarding the safety and efficacy of COVID-19 vaccines.
- Footnotes
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Conflicts of interest No potential conflict of interest relevant to this article was reported.
Funding This study received no specific grant from any funding agency in the public, commercial, or not-for-profit sectors.
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Table 1.
Study, country | Study type | No. | Age (yr), median (range) | Conditions related to COVID-19 | Comorbidities | Clinical details | Management | Outcomes |
---|---|---|---|---|---|---|---|---|
Deep et al. [12] (2020), United Kingdom | Multicenter observational study | 116 | AKI (n=41; 41.4%) | PIMS-TS | Asthma (n=5), cystic fibrosis (3), T1DM (1), autism (1) | Vasodilated shock (49%), inflammatory markers↑ (CRP, lactate, ferritin, LDH, and CK), cardiac involvement markers↑ (troponin, CK, and NTpro-BNP) | PICU admission, vasoactive medication (54%), IMV (35%), ECMO (3/ 116), CRRT (4/116) | Death (n=2; 1.7%) |
González-Dambrauskas et al. [13] (2020), 5 countries | Case series | 17 | AKI (3; 18%) | Severe or cri- tical COVID-19 | Respiratory (n=1), cardiac (2), cancer or im- mune (2), obesity (8) | Pneumonia (76%), ARDS (47%), myocarditis (24 %), cardiac arrest (18 %) | PICU admission, antibio- tics (88%), corticostero- ids (53%), vasoactive in- fusion (53%), IMV (47%) | Death (1; 6%) |
Basalely et al. [14] 2021), United States | Retrospective study | 152 | AKI (18; 11.8%) | Acute COVID- 19 (97; 63%), MIS-C (55; 36.2%) | HTN (n=1), DM (1), asthma (13), cancer (4), CHD (9), immunosuppressed (5) | Gastrointestinal, fever, rash | PICU admission (60/152), Vasopressor (35/152), ECMO (2/152), MV (11/ 152), CRRT (2/152) | Death (2; 1.3%) |
Bjornstad et al. [8] (2021), United States | Multicenter cross-sectional | 106 | AKI (47; 44%) | Critically ill | Seizure/epilepsy (n= 16), CHD (11), asthma (11) | Shock/hemodynamic instability (n=39), sepsis/infection (30), respiratory distress (52), CNS (10) | ICU admission, invasive respiratory support (28 %), vasopressor (29%), ECMO (2%), | Death (6; 6%) |
Lipton et al. [15] (2021), United States | Retrospective study | 57 | AKI (26; 46%) | MIS-C | Obese (58% for the A KI group, 43% for the non-AKI group) | LV systolic dysfunction, lymphopenia, IL-6, peak CRP, peak ferritin, peak procalcitonin were more prominent in the AKI group | ICU admission (81%), va- sopressor (70%), MV (4 %), dialysis (4%), steroids (100%), IVIG (81%) for AKI group | No death, all pa- tients with AKI recovered renal function. |
Chopra et al. [16] (2021), India | Cross-sectional | 105 | AKI (24; 22.8%) | MIS-C (20; 19.0 %) | CNS (9.5%), tuberculosis (17.1%), hematological/malignancy (14.3 %), sepsis (44.8%), bac- terial pneumonia (20.0 %), liver abscess (9.5%) | Leukocytosis, lower platelet count for the AKI group | Invasive respiratory sup- port (34.3%) and vaso- pressor (25.7%) were significantly higher in the AKI group | Death (n=10; 41.7 % for AKIgroup vs. n=17; 20.9% for non-AKI group) |
Kari et al. [17] (2021), Saudi Arabia | Multicenter retrospective cohort study | 89 | AKI (19; 21%) | MIS-C (15% in the AKI group vs. 1.5% in the control group) | 63.2% for the AKI group 18.6% for the control group | high RAI scores were correlated with the severity of AKI. | PICU admission (32 %) in the AKI group, use of RRT (n=0) | Oliguria (n=1), use of RRT (n=0), Residual renal impairment at discharge (n=8) |
Ricci et al. [18] (2022), Italy | Multicenter retrospective study | 38 | AKI (8; 21%) | MIS-C | Not specified | fever >38.0°C (n=34), gastrointestinal (30), rash (16) | PICU admission, fluid re- placement, vasoactive drug, IVIG, methylpredni- solone bolus, no kidney support | All cases except one recovered re- nal function with- in the first week. AKI transient (4), persisted (4) |
Basu et al. [19] (2021), 15 countries | Multinational, prospective, point-preva- lencestudy | 331 | AKI (124; 37.4%) | Critically ill | Asthma(12.7%),seizure/epilepsy (13.3%), CHD (9.1%), cancer (8.8%), cerebral palsy/ence- phalopathy (10.3%) | Respiratory distress (48.0 %), shock/hemodynamic instability (27.5%), sepsis/infection (23.3%), CNS symptoms (11.8%) | ICU admission, invasive re- spiratory support (26.3 %), vasopressor use (23.5 %) ECMO (2.2%) for con- firmed infection | 28-Day hospital mortality; 9.5% for confirmed in- fection with AKI |
Stewart et al. [20] (2021), United Kingdom | A single-center observa- tional study | 110 | AKI (33; 30%) | PIMS-TS | T1DM (n=2), sickle cell disease (2), VP shunt (2) | Fever (100%), abdominal pain (72%), vomiting (60 %), diarrhea (59%), respiratory distress (29%) | PICU admission (89%), in- tubation (20%), inotropic support (76%), methylprednisolone (82%), IVIG (70%) | None had macroal- buminuria or he- maturia at follow- up (6-8 weeks, 6 months) |
Saygili et al. [21] (2022), Turkey | Cross-sectional | 71 | AKI (12; 16.9%), subclinical AKI (22; 31%) | Mild to mode-rate severity | Obesity (n=3), asthma (5),developmentaldelay (5), malignancy(2) | Cough (62%), fever (59 %), sore throat (23%), SOB (20%) | No respiratory support (90%), O2 (7%), high-flow nasal cannula O2 (3%) | At follow-up (4.3 months), all of AKI group had nor- mal SCr level. |
Neutrophil count was significantly higher in the AKI group. | ||||||||
Raina et al. [24] (2022), United States | Retrospective study | 2,597 | AKI (274; 10.8%) | Critically ill | Respiratory (64.2%), cardiovascular (58.8%), obesity (54.1%), hematology (45.3%), neurologic (31.8%) | WBC count↑, serum glucose↑, bicarbonate↓ in AKI group. | ICU admission, airway/re- spiratory support (55.5 %), cardio-respiratory support (2.9%), kidney support (4.7%), vascular access (67.2%) | Death (n=21; 7.7% for the AKI group vs. n=37; 1.6% for the non-AKI group) |
AKI, acute kidney injury; COVID-19, coronavirus disease 2019; PIMS-TS, pediatric inflammatory multisystem syndrome temporally associated with COVID-19; T1DM, type 1 diabetes mellitus; CRP, C reactive protein; LDH, lactate dehydrogenase; CK, creatine kinase; NT-pro-BNP, N-terminal pro B-type natriuretic peptide; PICU, pediatric intensive care unit; IMV, invasive mechanical ventilation; ECMO, extracorporeal membrane oxygenation; CRRT, continuous renal replacement therapy; ARDS, acute respiratory distress syndrome; MIS-C, multisystem inflammatory syndrome in children; HTN, hypertension; DM, diabetes mellitus; CHD, congenital heart disease; MV, mechanical ventilation; LV, left ventricle; IL-6, interleukin-6; ICU, intensive care unit; IVIG, intravenous immunoglobulin; CNS, central nervous system; RAI, renal angina index; RRT, renal replacement therapy; VP, ventriculoperitoneal; SOB, shortness of breath; SCr, serum creatinine; WBC, white blood cell.
Table 2.
Study, country | Study type | Age (yr) | Sex | Kidney complications | Onset type | Kidney biopsy | Comorbidities | Vaccine brand & dose | Onset interval (day) | Clinical details | Management | Outcomes |
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Udagawa et al. [41] (2022), Japan | Case report (letter) | 15 | F | IgAN | Relapse | - | IgAN in remission | Pfizer, 2nd | 1 | Gross hematuria, fever (38.5°C), mild proteinuria | Not specified | Urinary findings persisted for 3 days; kidney dysfunction was not observed. |
16 | F | IgAN | Relapse | - | IgAN in remission | Pfizer, 2nd | 1.5 | Gross hematuria, fever (37.7°C), headache | Not specified | 5 Days later, SCr level did not increase, and urinalysis re- sults had normalized. | ||
Uchiyama et al. [39] (2022), Japan | Case series | 15 | M | IgAN | De novo | + | 6-Month history of microscopic hematuria | Pfizer, 2nd | 1 | Gross hematuria, fever (37.7°C), moderate proteinuria, SCr of 0.97, eGFR of 92, morphological abnormality (–) in the kidneys on CT | Not specified | Gross hematuria spontane- ously resolved within 6 days without any treatment, al- though his microscopic he- maturia and proteinuria per- sisted. |
18 | M | IgAN | De novo | + | 3-Year history of microscopic hematuria | Pfizer, 2nd | 2 | Gross hematuria, fever (38.6°C), mild proteinuria, SCr of 0.82, eGFR of 99, morphological abnormality (–) in the kidneys on CT | Not specified | Gross hematuria spontane- ously resolved within 7 days without any treatment, and microscopic hematuria and proteinuria disappeared gra- dually. | ||
Okada et al. [42] (2022), Japan | Case report | 17 | F | IgAN | De novo | + | 10-Year history of microscopic hematuria | Pfizer, 1st | 4 | Gross hematuria, proteinuria (0.37 g/gCr), Scr of 0.58, eGFR of 109 | Not specified | Macroscopic hematuria chang- ed to microscopic hematuria, and proteinuria resolved spontaneously. |
Horino et al. [40] (2022), Japan | Case report | 17 | M | IgAN | De novo | + | 5 Months prior to pre-sentation, microhe- maturia (2+) | Pfizer, 2nd | 0.5 | Fever, headache, macrohe- maturia, CRP↑, SCr of 0.7, marked proteinuria (1.0 g/ gCr) | Not specified | Proteinuria and microhema- turia persisted for 2 months. |
Morisawa et al. [43] (2022), Japan | Case series (letter) | 16 | M | IgAN | De novo | + | Asymptomatic hematuria for 2 years, family history of IgAN (mother) | Not specified, 2nd | 1 | Fever, gross hematuria, peak SCr of 1.26, proteinuria (0.28 g/gCr) | Methylprednisolone pulse follo ed by oral prednisolone | Gross hematuria resolved 3 days after vaccination. Scr decreased to 1.05 3 mon- ths later. |
13 | F | IgAN | De novo | + | Asymptomatic hematuria for 2 months | Not specified, 2nd | 1 | Fever, gross hematuria, peak UPCR of 1.99 g/gCr | No treatment | Gross hematuria and pro- teinuria spontaneously resolved. | ||
Abdel-Qader et al. [44] (2022), Jordan | Case report (letter) | 12 | M | IgAN, AKI | De novo | + | No medical history | Pfizer, 1st | <1 | Gross hematuria, proteinuria | Methylprednisolone pulse | Gross hematuria resolved spontaneously, SCr improved at follow-up. |
Niel and Florescu [47] (2021), Luxembourg | Case report (letter) | 13 | F | IgAN pre- senting RPGN, AKI | De novo | + | No medical history | Pfizer, 1st | <1 | Fever, asthenia, muscle pain, pharyngitis, SCr of 3.57, macro- scopic hematuria, nephrotic- range proteinuria (3.88 g/L), Oliguria | HD for 5 days, IV methylprednis- olone pulse fol- lowed by oral prednisolone | Kidney function improved progressively. Microscopic hematuria and slight proteinuria persisted. |
Hanna et al. [45] (2021), United States | Case series (letter) | 13 | M | IgAN, AKI | Relapse | - | IgAN, T1DM | Pfizer, 2nd | <1 | Gross hematuria | Lisinopril | Gross hematuria resolved spontaneously, and kidney function recovered without intervention within 1 week. |
17 | M | IgAN, AKI | De novo | + | No medical history | Pfizer, 2nd | <1 | Gross hematuria, proteinuria | Methylprednisolone pulse | Gross hematuria resolved spontaneously, but kidney insufficiency persisted. | ||
Kim et al. [46] (2023), Korea | Case report | 16 | F | CrGN pre- senting RPGN, AKI | De novo | + | No medical history | Pfizer, 2nd | 6 Weeks | Dyspnea, headache, BP (155/89), edema, hematuria, proteinuria, swelling and increased echogenicity of both kidneys on renal doppler sonography, peak SCr of 12.7 | HD start, methylprednisolone pulse, followed by oral steroid, MMF | HD stopped. |
Remained in CKD stage at the 3-month follow-up. | ||||||||||||
Nakazawa et al. [48] (2022), Japan | Case report | 15 | M | NS | De novo | - | No medical history | Pfizer, 1st | 4 | Eyelid and peripheral edema, urine protein (4+), SCr of 0.64, eGFR of 116, UPCR (7.71 g/gCr), bilateral pleural effusions on chest x-ray, edema of the inte- stinal wall and ascites | Oral prednisolone | Complete remission |
Pella et al. [49] (2022), Greece | Case report | 18 | M | NS (MCD) | De novo | + | No medical history | Pfizer, 1st | 11 | Gastrointestinal symptoms, as- cites, lower extremity edema, hypoalbuminemia (1.8 g/dL), peak nephrotic-range protein- uria (23.4 g/24 hr), total chole- sterol (432 mg/dL) | Oral steroid | Complete remission |
Jongvilaikasem et al. [50] (2022), Thailand | Case report (letter) | 14 | M | NS (MCD, AIN), AKI | De novo | + | No medical history | Pfizer, 1st | 5 | Bilateral leg edema, hypertension, urine protein (4+), UPCR of 9 g/ gCr, hypoalbuminemia, cholesterol (257 mg/dL) | Methylprednisolone pulse fol- lowed by oral prednisolone, HD for 3 weeks | Partial remission |
Güngör et al. [51] (2022), Turkey | Case series (letter) | 17 | F | NS | Relapse | - | INS (MCD) in remission for 4.5 years | Not specified, 2nd | 19 | Lower extremity and pretibial edema, urea of 5 mmol/L, crea- tinine of 44.2 µmol/L, albumin of 12 g/L, spot UPCR of 8.7 mg/mg | Oral corticosteroid | Remission achieved 2 weeks after treatment. |
18 | F | NS | Relapse | - | INS in remission | Not specified, 2nd | 12 | Lower extremity edema, urea of 5 mmol/L, creatinine of 42.4 umol/L, albumin of 23 g/L, spot UPCR of 4.1 mg/mg | Oral corticosteroid | Remission achieved | ||
Alhosaini [52] (2022), United Arab Emirates | Case report | 16 | M | NS (MCD) | De novo | + | No medical history | Pfizer, 2nd | 7 | Bilateral leg pitting edema, nau- sea, SCr of 0.85, hypoalbumine- mia, urine protein (4+), UPCR of 5.6 g/gCr, ascites, pleural effusion | Oral prednisone along with furosemide and ol- mesartan | After 1 week, edema resolved. proteinuria and serum albumin started to improve. |
Choi et al. [53] (2022), Korea | Case series | 17 | M | ATIN | De novo | + | No medical history | Pfizer, 2nd | 3 | Epigastric pain, nausea, SCr 3, BP (150/85), SCr of 3.1, eGFR of 24, CRP of 3.23, urine blood (–), urine protein (–) | Supportive care | Renal insufficiency gradually improved, discharged after 1 week. |
12 | M | ATIN | De novo | + | No medical history | Pfizer, 2nd | 1 | Nausea, vomiting, SCr of 2.28, eGFR of 27, CRP of 6.05, urine protein (2+), UPCR of 1.95 g/gCr | Oral steroid | Remarkable improvement in renal insufficiency on day 10 of hospitalization. |
COVID-19, coronavirus disease 2019; IgAN, Immunoglobulin A nephropathy; SCr, serum creatinine; eGFR, estimated glomerular filtration rate; CT, computed tomography; HD, hemodialysis,; IV, intravenous; CKD, chronic kidney disease; AIN, acute interstitial nephritis; T1DM, type 1 diabetes mellitus; CRP, C reactive protein; CrGN, crescentic glomerulonephritis; RPGN, rapidly progressive glomerulonephritis; AKI, acute kidney injury; MMF, mycophenolate mofetil; BP, blood pressure; UPCR, urine protein to creatinine ratio; NS, nephrotic syndrome; MCD, minimal change disease; INS, idiopathic nephrotic syndrome; ATIN, acute tubulointerstitial nephritis.
- References
- 1. Bjornstad EC, Seifert ME, Sanderson K, Feig DI. Kidney implications of SARS-CoV2 infection in children. Pediatr Nephrol 2022;37:1453–67.
[Article] [PubMed] [PMC]2. Abrams JY, Godfred-Cato SE, Oster ME, Chow EJ, Koumans EH, Bryant B, et al. Multisystem inflammatory syndrome in children associated with severe acute respiratory syndrome coronavirus 2: a systematic review. J Pediatr 2020;226:45–54.e1.
[Article] [PubMed] [PMC]3. Dufort EM, Koumans EH, Chow EJ, Rosenthal EM, Muse A, Rowlands J, et al. Multisystem inflammatory syndrome in children in New York State. N Engl J Med 2020;383:347–58.
[Article] [PubMed] [PMC]4. Feldstein LR, Rose EB, Horwitz SM, Collins JP, Newhams MM, Son MBF, et al. Multisystem inflammatory syndrome in U.S. children and adolescents. N Engl J Med 2020;383:334–46.
[Article] [PubMed] [PMC]5. Payne AB, Gilani Z, Godfred-Cato S, Belay ED, Feldstein LR, Patel MM, et al. Incidence of multisystem inflammatory syndrome in children among US persons infected with SARS-CoV-2. JAMA Netw Open 2021;4:e2116420.
[PubMed] [PMC]6. Multisystem Inflammatory Syndrome (MIS) [Internet]. Centers for Disease Control and Prevention; 2020 [cited 2023 May 7]. Available from: https://www.cdc.gov/mis/mis-c/hcp/provider-families.html.7. Godfred-Cato S, Bryant B, Leung J, Oster ME, Conklin L, Abrams J, et al. COVID-19-Associated Multisystem Inflammatory Syndrome in Children — United States, March-July 2020. Morb Mortal Wkly Rep 2020;69:1074–80.
[Article] [PubMed] [PMC]8. Bjornstad EC, Krallman KA, Askenazi D, Zappitelli M, Goldstein SL, Basu RK, et al. Preliminary assessment of acute kidney injury in critically Ill children associated with SARS-CoV-2 infection: a multicenter crosssectional analysis. Clin J Am Soc Nephrol 2021;16:446.
[PubMed]9. Wu HHL, Shenoy M, Kalra PA, Chinnadurai R. Intrinsic kidney pathology in children and adolescents following COVID-19 vaccination: a systematic review. Children 2022;9:1467.
[Article] [PubMed] [PMC]10. Kidney Disease: Improving Global Outcomes (KDIGO) Acute Kidney Injury Work Group (2012) KDIGO clinical practical guidelines for acute kidney injury. Section 2: AKI definition. Kidney Int Suppl 2012;2:19–36.11. Nadim MK, Forni LG, Mehta RL, Connor MJ, Liu KD, Ostermann M, et al. COVID-19-associated acute kidney injury: consensus report of the 25th Acute Disease Quality Initiative (ADQI) Workgroup. Nat Rev Nephrol 2020;16:747–64.
[PubMed] [PMC]12. Deep A, Upadhyay G, du Pré P, Lillie J, Pan D, Mudalige N, et al. Acute kidney injury in pediatric inflammatory multisystem syndrome temporally associated with severe acute respiratory syndrome coronavirus-2 pandemic: experience from PICUs across United Kingdom. Crit Care Med 2020;48:1809–18.
[Article] [PubMed]13. González-Dambrauskas S, Vásquez-Hoyos P, Camporesi A, Díaz-Rubio F, Piñeres-Olave BE, Fernández-Sarmiento J, et al. Pediatric critical care and COVID-19. Pediatrics 2020;146:e20201766.
[PubMed]14. Basalely A, Gurusinghe S, Schneider J, Shah SS, Siegel LB, Pollack G, et al. Acute kidney injury in pediatric patients hospitalized with acute COVID-19 and multisystem inflammatory syndrome in children associated with COVID-19. Kidney Int 2021;100:138–45.
[Article] [PubMed] [PMC]15. Lipton M, Mahajan R, Kavanagh C, Shen C, Batal I, Dogra S, et al. AKI in COVID-19-associated multisystem inflammatory syndrome in children (MIS-C). Kidney360 2021;2:611–8.
[Article] [PubMed] [PMC]16. Chopra S, Saha A, Kumar V, Thakur A, Pemde H, Kapoor D, et al. Acute kidney injury in hospitalized children with COVID19. J Trop Pediatr 2021;67:fmab037.
[Article] [PubMed] [PMC]17. Kari JA, Shalaby MA, Albanna AS, Alahmadi TS, Alherbish A, Alhasan KA. Acute kidney injury in children with COVID-19: a retrospective study. BMC Nephrol 2021;22:202.
[Article] [PubMed] [PMC]18. Ricci Z, Colosimo D, Cumbo S, L’Erario M, Duchini P, Rufini P, et al. Multisystem inflammatory syndrome in children and acute kidney injury: retrospective study of five Italian PICUs. Pediatr Crit Care Med 2022;23:e361–5.
[Article] [PubMed]19. Basu RK, Bjornstad EC, Gist KM, Starr M, Khandhar P, Chanchlani R, et al. Acute kidney injury in critically Ill children and young adults with suspected SARS-CoV2 infection. Pediatr Res 2022;91:1787–96.
[Article] [PubMed] [PMC]20. Stewart DJ, Mudalige NL, Johnson M, Shroff R, du Pré P, Stojanovic J. Acute kidney injury in paediatric inflammatory multisystem syndrome temporally associated with SARS-CoV-2 (PIMS-TS) is not associated with progression to chronic kidney disease. Arch Dis Child 2022;107:e21.
[Article] [PubMed]21. Saygili S, Canpolat N, Cicek RY, Agbas A, Yilmaz EK, Sakalli AAK, et al. Clinical and subclinical acute kidney injury in children with mild-to-moderate COVID-19. Pediatr Res 2023;93:654–60.
[Article] [PubMed] [PMC]22. Tripathi AK, Pilania RK, Bhatt GC, Atlani M, Kumar A, Malik S. Acute kidney injury following multisystem inflammatory syndrome associated with SARS-CoV-2 infection in children: a systematic review and meta-analysis. Pediatr Nephrol 2023;38:357–70.
[Article] [PubMed] [PMC]23. 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;36:2627–38.
[Article] [PubMed] [PMC]24. Raina R, Mawby I, Chakraborty R, Sethi SK, Mathur K, Mahesh S, et al. Acute kidney injury in COVID-19 pediatric patients in North America: Analysis of the virtual pediatric systems data. PLoS One 2022;17:e0266737.
[Article] [PubMed] [PMC]25. Kidney Disease: Improving Global Outcomes (KDIGO) Glomerular Diseases Work Group. KDIGO 2021 clinical practice guideline for the management of glomerular diseases. Kidney Int 2021;100(4S): S1–276.
[PubMed]26. Morello W, Vianello FA, Proverbio E, Peruzzi L, Pasini A, Montini G. COVID-19 and idiopathic nephrotic syndrome in children: systematic review of the literature and recommendations from a highly affected area. Pediatr Nephrol 2022;37:757–64.
[Article] [PubMed] [PMC]27. Park MJ, Eun JK, Baek HS, Cho MH. Impact of COVID-19 on the clinical course of nephrotic syndrome in children: a single-center study. Child Kidney Dis 2022;26:74–9.
[Article]28. Chiodini B, Bellotti AS, Morello W, Bulgaro C, Farella I, Giordano M, et al. Relapse rate in children with nephrotic syndrome during the SARS-CoV-2 pandemic. Pediatr Nephrol 2023;38:1139–46.
[Article] [PubMed] [PMC]29. Morello W, Vianello FA, Bulgaro C, Montini G. Epidemiology, severity, and risk of SARS-CoV-2-related relapse in children and young adults affected by idiopathic nephrotic syndrome: a retrospective observational cohort study. Pediatr Nephrol 2023;38:1159–66.
[Article] [PubMed] [PMC]30. Akilesh S, Nast CC, Yamashita M, Henriksen K, Charu V, Troxell ML, et al. Multicenter clinicopathologic correlation of kidney biopsies performed in COVID-19 patients presenting with acute kidney injury or proteinuria. Am J Kidney Dis 2021;77:82–93.e1.
[Article] [PubMed] [PMC]31. Kudose S, Batal I, Santoriello D, Xu K, Barasch J, Peleg Y, et al. Kidney biopsy findings in patients with COVID-19. J Am Soc Nephrol 2020;31:1959.
[Article] [PubMed] [PMC]32. Serafinelli J, Mastrangelo A, Morello W, Cerioni VF, Salim A, Nebuloni M, et al. Kidney involvement and histological findings in two pediatric COVID-19 patients. Pediatr Nephrol 2021;36:3789–93.
[Article] [PubMed] [PMC]33. Eun JK, Park MJ, Kim MS, Han MH, Kim YJ, Baek HS, et al. De novo crescentic glomerulonephritis following COVID-19 infection: a pediatric case report. J Korean Med Sci 2023;38:e89.
[Article] [PubMed] [PMC]34. N V, Singh RKN, Kumari N, Ranjan R, Saini S. A novel association between coronavirus disease 2019 and normocomplementemic rapidly progressive glomerulonephritis-crescentic immunoglobulin A nephropathy: a report of two pediatric cases. Cureus 2022;14:e22077.
[Article] [PubMed] [PMC]35. Basiratnia M, Derakhshan D, Yeganeh BS, Derakhshan A. Acute necrotizing glomerulonephritis associated with COVID-19 infection: report of two pediatric cases. Pediatr Nephrol 2021;36:1019–23.
[Article] [PubMed] [PMC]36. Fireizen Y, Shahriary C, Imperial ME, Randhawa I, Nianiaris N, Ovunc B. Pediatric P-ANCA vasculitis following COVID-19. Pediatr Pulmonol 2021;56:3422–4.
[Article] [PubMed] [PMC]37. U.S. Food and Drug Administration. Coronavirus (COVID-19) update: FDA authorizes Moderna and Pfizer-BioNTech COVID-19 vaccines for children down to 6 months of age [Internet]. Silver Spring (MD), U.S. Food and Drug Administration. 2022;[cited 2023 Apr 7]. Available from: https://www.fda.gov/news-events/press-announcements/coronaviruscovid-19-update-fda-authorizes-moderna-and-pfizer-biontech-covid-19-vaccines-children.38. Negrea L, Rovin BH. Gross hematuria following vaccination for severe acute respiratory syndrome coronavirus 2 in 2 patients with IgA nephropathy. Kidney Int 2021;99:1487.
[Article] [PubMed] [PMC]39. Uchiyama Y, Fukasawa H, Ishino Y, Nakagami D, Kaneko M, Yasuda H, et al. Sibling cases of gross hematuria and newly diagnosed IgA nephropathy following SARS-CoV-2 vaccination. BMC Nephrol 2022;23:216.
[Article] [PubMed] [PMC]40. Horino T, Sawamura D, Inotani S, Ishihara M, Komori M, Ichii O. Newly diagnosed IgA nephropathy with gross haematuria following COVID-19 vaccination. QJM 2022;115:28–9.
[Article] [PubMed] [PMC]41. Udagawa T, Motoyoshi Y. Macroscopic hematuria in two children with IgA nephropathy remission following Pfizer COVID-19 vaccination. Pediatr Nephrol 2022;37:1693–4.
[Article] [PubMed] [PMC]42. Okada M, Kikuchi E, Nagasawa M, Oshiba A, Shimoda M. An adolescent girl diagnosed with IgA nephropathy following the first dose of the COVID-19 vaccine. CEN Case Rep 2022;11:376–9.
[Article] [PubMed] [PMC]43. Morisawa K, Honda M. Two patients presenting IgA nephropathy after COVID-19 vaccination during a follow-up for asymptomatic hematuria. Pediatr Nephrol 2022;37:1695–6.
[Article] [PubMed] [PMC]44. Abdel-Qader DH, Hazza Alkhatatbeh I, Hayajneh W, Annab H, Al Meslamani AZ, Elmusa RA. IgA nephropathy in a pediatric patient after receiving the first dose of Pfizer-BioNTech COVID-19 vaccine. Vaccine 2022;40:2528–30.
[Article] [PubMed] [PMC]45. Hanna C, Herrera Hernandez LP, Bu L, Kizilbash S, Najera L, Rheault MN, et al. IgA nephropathy presenting as macroscopic hematuria in 2 pediatric patients after receiving the Pfizer COVID-19 vaccine. Kidney Int 2021;100:705–6.
[Article] [PubMed] [PMC]46. Kim S, Jung J, Cho H, Lee J, Go H, Lee JH. A child with crescentic glomerulonephritis following SARS-CoV-2 mRNA (Pfizer-BioNTech) vaccination. Pediatr Nephrol 2023;38:299–302.
[Article] [PubMed] [PMC]47. Niel O, Florescu C. IgA nephropathy presenting as rapidly progressive glomerulonephritis following first dose of COVID-19 vaccine. Pediatr Nephrol 2022;37:461–2.
[Article] [PubMed] [PMC]48. Nakazawa E, Uchimura T, Hirai Y, Togashi H, Oyama Y, Inaba A, et al. New-onset pediatric nephrotic syndrome following Pfizer-BioNTech SARS-CoV-2 vaccination: a case report and literature review. CEN Case Rep 2022;11:242–6.
[Article] [PubMed] [PMC]49. Pella E, Sarafidis PA, Alexandrou ME, Stangou M, Nikolaidou C, Kosmidis D, et al. De novo minimal change disease in an adolescent after Pfizer-BioNTech COVID-19 vaccination: a case report. Case Rep Nephrol Dial 2022;12:44–9.
[Article] [PubMed] [PMC]50. Jongvilaikasem P, Rianthavorn P. Minimal change disease and acute interstitial nephritis following SARS-CoV-2 BNT162b2 vaccination. Pediatr Nephrol 2022;37:1419–21.
[Article] [PubMed] [PMC]51. Güngör T, Yazılıtaş F, Kargın Çakıcı E, Karakaya D, Bülbül M. Relapse of idiopathic nephrotic syndrome after SARS-CoV-2 vaccination: two case reports. J Paediatr Child Health 2022;58:939–40.
[PubMed]52. Alhosaini MN. A case of minimal change disease after SARS-CoV-2 vaccination under the age of 18. Avicenna J Med 2022;12:31–3.
[Article] [PubMed] [PMC]53. Choi JH, Kang KS, Han KH. Two adolescent cases of acute tubulointerstitial nephritis after second dose of COVID-19 mRNA vaccine. Hum Vaccines Immunother 2022;18:2059308.
[Article] [PubMed] [PMC]54. Bjornstad EC, Cutter G, Guru P, Menon S, Aldana I, House S, et al. SARS-CoV-2 infection increases risk of acute kidney injury in a bimodal age distribution. BMC Nephrol 2022;23:63.
[PubMed] [PMC]55. Morgans HA, Schuster JE, Warady BA. Pediatric vaccine hesitancy and COVID-19. Am J Kidney Dis 2023;81:13–4.
[Article] [PubMed] [PMC]