Acute Kidney Injury in COVID-19: The Chinese Experience.

Coronavirus disease 2019 (COVID-19) is spreading rapidly worldwide. Here, we review recently published studies on COVID-19-associated acute kidney injury (AKI) in China. The pooled incidence of AKI in all reported COVID-19 patients was 6.5%, with a much higher rate in patients from the intensive care unit (32.5%). AKI is associated with the severity of COVID-19 and mortality rates, which is similar to other kidney abnormalities including proteinuria and hematuria. The renal tubule is the main site of injury in COVID-19 patients, and the etiology of renal impairment in COVID-19 patients likely is diverse and multifactorial. Apart from direct viral attack via angiotensin-converting enzyme 2 and transmembrane serine proteases 2, hypoxia and hypercoagulability also may contribute to the occurrence of renal injury. To date, there is only randomized controlled trial evidence to support the use of dexamethasone in patients requiring oxygen therapy and remdesivir for shortening the time to recovery, with no specific treatment for COVID-19-associated AKI. Studies researching kidney pathologies or reporting renal outcome and prognosis are in urgent need. Further studies are urgently warranted to identify risk factors, to predict prognosis and renal outcome, to explore the exact mechanisms of renal injury, and to suggest targeted interventions.

Coronavirus disease 2019 (COVID-19) is a newly discovered contagious disease caused by severe acute respiratory syndrome coronavirus-2 (SARS-CoV-2 virus). The ongoing outbreak was first reported in Wuhan, China, and it is a pandemic that has spread worldwide. The clinical features of COVID-19 vary individually, ranging from no clinical symptoms (asymptomatic) to mild or severe respiratory illness symptoms. Common symptoms of COVID-19 include fever, fatigue, dry cough, and muscle ache, and critical patients may progress rapidly to acute respiratory distress syndrome (ARDS), septic shock, metabolic acidosis, coagulation dysfunction, acute kidney injury (AKI), and death.

Kidney complications in SARS-CoV-2 infection might occur owing to direct cytopathic effects and secondary damage resulting from the co-existence of a systemic inflammatory response or the use of renal-toxic therapies, respiratory distress syndrome–induced hypoxia, or multiple organ dysfunction. Histologic findings have shown acute tubular necrosis and interstitial inflammation. Clinical manifestations of kidney involvement in COVID-19 include proteinuria, hematuria, and AKI.3, 4, 5

The reported incidence of AKI in SARS-CoV-2 infection has varied substantially from 0.5% to 29%.6, 7, 8 It is believed that the occurrence of AKI is part of the multiorgan dysfunction that develops in critical SARS-CoV-2–infected patients, and the variety of AKI incidence reflects the wide clinical spectrum of COVID-19 in terms of disease severity and outcome. Because this is an emerging infectious disease, there are a paucity of data on the whole picture of kidney involvement in this disease. In this review, we aim to summarize China's initial experience of AKI in patients with COVID-19, with a focus on epidemiology, clinical characteristics, pathophysiology, treatment, and prognosis.

COVID-19: DIAGNOSIS AND CLINICAL CLASSIFICATIONS

According to the Guidance for Corona Virus Disease 2019 released by China's National Health Committee, suspected COVID-19 cases are identified via consideration of both epidemiologic histories and clinical manifestations. Confirmed cases are diagnosed with one of the following etiological evidences: a positive result of novel coronavirus 2019 (2019-nCoV) nucleic acid by real-time fluorescence RT-PCR or the virus gene sequence is highly homologous to the known 2019-nCoV. All confirmed cases were required to be admitted to either typical hospitals or temporary shelter hospitals according to the different degrees of disease severity. Disease severity was classified into four categories: (1) mild: mild clinical manifestation with no unusual imaging data; (2) ordinary: fever, respiratory symptoms, pneumonia manifestation on radiograph or computed tomography; (3) severe (satisfies any of the following): (i) respiratory distress, respiratory rate (RR) of 30 or more breaths/min; (ii) oxygen saturation of 93% at rest state; (iii) arterial partial pressure of oxygen/inspiration O2 of 300 mm Hg or less; (4) critical (satisfies any of the following): (i) respiratory failure that needs mechanical ventilation; (ii) shock; or (iii) complicated with other organ failure that requires intensive care unit (ICU) monitoring and treatment.

EPIDEMIOLOGY OF COVID-19–ASSOCIATED AKI

To better understand the incidence of COVID-19–associated AKI in different regions of China, we selected relevant studies published before July 30, 2020, by searching PubMed using the following search terms: “coronavirus” or “COVID-19” or “SARS-CoV-2” or “2019-nCoV” and “laboratory” or “clinical.” We excluded studies that had a large overlap in enrolled patients, had fewer than 90 patients, or did not have a clear description of kidney function tests.

Finally, we included 25 eligible peer-reviewed studies. The epidemiologic data of COVID-19–associated AKI reported in these studies are summarized in Table 1 . Sixteen of these studies were from various COVID-19–designated hospitals in Wuhan City, which was the most infected area in China.2, 3, 4 , , 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21 There was also a nationwide multicenter study supported by the National Health Commission of China that enrolled 1,099 patients from 552 hospitals in 30 provinces.

Table 1

Enrolled studies on the incidence of COVID-19 associated AKI in China

Study	Region	Hospital	Sample Size	Recruitment Time	Male (%)	Age*	CKD (%)	AKI rate (%)	Mortality (%)
								Total	ICU	Non-ICU	Deceased	Total
Chen et al10	Wuhan	Jinyintan Hospital	99	Jan1-Jan 20,2020	67 (67.7)	55±13	NA	3 (3.0)	NA	NA	NA	11 (11.1)
Cheng et al3	Wuhan	Tongji Hospital	701	Jan28-Feb11,2020	367 (52.4)	63 (50-71)	14 (2.0)	36 (5.1)	NA	NA	NA	113 (16.1)
Wang et al8	Wuhan	Tongji Hospital	344 (ICU)	Jan25-Feb25,2020	179 (52.0)	64 (52-72)	NA	86 (25.0)	86 (25.0)	0	80 (60.2)	133 (38.7)
Pei et al4	Wuhan	Tongji Hospital (Sino-French)	333	Jan28-Feb9,2020	182 (54.7)	56±13	Excluded	22 (6.6)	NA	NA	NA	29 (8.7)
Cao et al11	Wuhan	Zhongnan Hospital	102	Jan3-Feb1,2020	53 (52.0)	54 (37-67)	4 (3.9)	20 (19.6)	NA	NA	15 (88.2)	17 (16.7)
Shi et al12	Wuhan	Renmin hospital	416	Jan20-Feb10,2020	205 (49.3)	64 (range 21-95)	14 (3.4)	8 (1.9)	NA	NA	NA	57 (13.7)
Zhou et al2	Wuhan	Jinyintan Hospital, Wuhan Pulmonary Hospital	191 Died or Discharged	Dec29,2019-Jan31,2020	119 (62.3)	56 (46-67)	2 (1.0)	28 (14.7)	NA	NA	27 (50.0)	54 (28.3)
Hu et al13	Wuhan	Tianyou Hospital	323	Jan8-Feb20,2020	166 (51.4)	61 (range 23-91)	7 (2.2)	17 (5.3)	NA	NA	NA	35 (10.8)
Yu et al14	Wuhan	19 ICUs	226 (ICU)	Feb26-27,2020	139 (61.5)	64 (57-70)	3 (1.3)	57 (25.2)	57 (25.2)	0	NA	87 (38.5)
Zhang et al15	Wuhan	Union Hospital (West Court)	258	Jan29-Feb12,2020	138 (53.5)	64 (range 56-70)	9 (3.5)	7 (2.7)	NA	NA	NA	15 (5.8)
Deng et al16	Wuhan	Tongji Hospital (Hankou, Caidian), Central Hospital (Hankou)	225 Died or Discharged	Jan1-Feb21,2020	124 (55.1)	54 (95%CI 26-83)	NA	20 (8.9)	NA	NA	20 (18.4)	109 (48.4)
Li et al17	Wuhan	Central Hospital	134 Died or Discharged	Jan1-Feb20,2020	75 (56.0)	61 (47–69)	NA	5 (3.7)	NA	NA	NA	42 (31.3)
Zhang et al18	Wuhan	Zhongnan Hospital, Wuhan Fourth Hospital	394	Jan1-Feb1,2020	186 (47.2)	56 (42-67)	NA	37 (9.4)	NA	NA	7 (31.8)	22 (5.6)
Xu et al19	Wuhan	Union Hospital, Jinyintan Hospital, Wuhan Third Hospital	239 (ICU)	Jan12-Feb3,2020	143 (59.8)	63±13	NA	119 (49.8)	119 (49.8)	0	99 (67.4)	147 (61.5)
Chen et al20	Wuhan	Tongji Hospital (Three branches)	3309	Jan18-Mar27,2020	1642 (49.6)	62 (49-69)	57 (1.7)	401 (12.1)	NA	NA	NA	307 (9.3)
Cui et al21	Wuhan	Zhongnan Hospital, Tongji Hospital (Sino-French)	116	Jan5-Mar21,2020	66 (56.9)	59 (95%CI 67-62)	5 (4.3)	21 (18.1)	NA	NA	12 (50.0)	24 (20.7)
Zheng et al5	Wuhan, Shenzhen	Tongji Hospital (Sino-French), The Third People's Hospital of Shenzhen	555	Jan8-Feb28,2020	269 (48.5)	52 (36-64)	10 (1.8)	29 (5.6)	NA	NA	12 (44.4)	27 (4.9)
Zhao et al22	Jingzhou	Jingzhou Central Hospital	91	Jan16-Feb10,2020	49 (53.8)	46 (median)	1 (1.1)	5 (5.5)	NA	NA	NA	2 (2.2)
Zhang et al23	Zhejiang	Multicenter	645	Jan17-Feb8,2020	328 (50.8)	40.9 (95%CI 29-52)	6 (0.9)	2 (0.3)	NA	NA	NA	0 (0)
Ren et al24	Shenzhen	The Third People's Hospital	150	Jan11-Feb12,2020	82 (54.7)	54 (37-63)	NA	11 (7.3)	NA	NA	NA	3 (2.0)
Hou et al25	Beijing	Youan Hospital	101	Jan21-Mar9,2020	44 (43.6)	51±20	NA	12 (11.9)	NA	NA	NA	5 (5.0)
Wan et al26	Chongqing	Three Gorges Hospital	135	Jan23-Feb8,2020	72 (53.3)	47 (36‐55)	NA	5 (3.7)	NA	NA	NA	1 (0.7)
Guan et al6	China	National, multicenter	1099	Dec11,2019-Jan 29,2020	637 (58.0)	47 (35-58)	8 (0.7)	6 (0.5)	NA	NA	NA	15 (1.4)
Yang et al27	Yichang	Yichang Central People's Hospital	200	Jan30-Feb8,2020	98 (49.0)	55±17	3 (1.5)	24 (12.0)	12 (41.4)	12 (7.0)	NA	15 (7.5)
Hong et al28	Chengdu, Daofu	Public Health Clinical Center of Chengdu, Daofu People's Hospital	168	Jan16-Mar13,2020	92 (54.2)	47±18	4 (2.4)	1 (0.6)	NA	NA	NA	3 (1.8)

Note: Abbreviation: CKD, chronic kidney disease; ICU, intensive care unit; SD, standard deviation; CI, confidence interval.

mean±SD or median with interquartile range

A random-effects model was performed to generate the pooled incidence of AKI and AKI associated mortality. All pooled estimates are provided with 95% confidence intervals (CIs). We performed a meta-analyses using the meta package in R software version 3.6.3 (the R Foundation for Statistical Computing, Vienna, Austria). The pooled incidence of AKI in all reported COVID-19 patients from these 25 studies was 6.5% (95% CI, 4.1%-10.2%), with a much higher rate in patients from the ICU (32.5%; 95% CI, 21.2%-46.3%) , , than in patients from mixed departments (5.1%; 95% CI, 3.3%-7.8%)2, 3, 4, 5, 6 , 10, 11, 12, 13 , 15, 16, 17, 18 , 20, 21, 22, 23, 24, 25, 26, 27, 28 (Fig. 1 A). Studies from Wuhan showed a higher AKI incidence (9.7%; 95% CI, 6.2%-14.9%) than studies from outside Wuhan (2.8%; 95% CI, 1.2%-6.6%) (Fig. 1B). However, this regional difference in the AKI rate could be interpreted by the difference in disease severity.

Figure 1

AKI incidence in COVID-19 patients in China. Studies are subgrouped by (A) settings and (B) regions. Abbreviation: CI, confidence interval.

Recently published studies on COVID-19 worldwide reported AKI rates in hospitalized patients of 17.9% to 72.7% in Italy, , 9.2% to 18.3% in Korea, , 19.7% to 69.2% in Spain, , 5.8% to 56.9% in the United States, , 52.2% to 74.6% in Germany, , and 4.7% to 55.9% in France and Belgium, , which are much higher than the rates in China. The difference may be explained by the fact that only very sick COVID-19 patients were admitted to hospitals in those countries compared with the admission of less sick patients in China. Health care systems and policies for hospitalization and assigning levels of care (eg, ICU admission) are different across the world, and the admission rate of COVID-19 patients varied among different countries. Therefore, it is difficult to compare AKI rates based on the number of hospitalized patients.

COVID-19–Associated AKI in All Hospitalizations

Chen et al reported 99 patients with COVID-19 from January 1 to January 20, 2020, in Jinyintan Hospital, Wuhan. Three cases (3.0%) presented with AKI on admission. Cheng et al conducted a prospective cohort study of 701 COVID-19 patients from January 28, 2020, to February 11, 2020, in Tongji Hospital, Wuhan, and 5.1% (36 of 701) of the overall patients developed AKI during hospitalization. Hu et al observed a similar finding that 17 of 323 COVID-19 patients developed AKI in Tianyou Hospital, Wuhan, which is an AKI incidence of 5.3%.

A few subsequent studies described COVID-19 patients outside Wuhan. Zhang et al reported findings from 645 patients with COVID-19 in Zhejiang Province. The incidence of AKI was as low as 0.3% (2 of 645). Low rates of ICU admission (0.6%) and mortality (0%) also were observed in this study. Wan et al reported findings from 135 patients with COVID-19 in Chongqing City, where 5 subjects developed AKI (3.7%) and 1 died (0.7%). In the study by Guan et al regarding 1,099 COVID-19 patients from 552 hospitals across China, 6 subjects experienced AKI (0.5%), and 4 of them were critically ill. A relatively low AKI incidence (2% for in-hospital AKI, and 1% for prehospital AKI) also was reported in the overall population of COVID-19 patients in Shenzhen City.

The prevalence of AKI increases in parallel with the disease severity of COVID-19. , , In the study by Hu et al, AKI occurred in 1.3% (2 of 151) of nonsevere patients, in 3.4% (5 of 146) of severe patients, and in 38.5% (10 of 26) of critical patients. Similar findings were reported by Zheng et al, who found that the incidence of AKI in nonsevere, severe, and critical patients was 1.0% (3 of 297), 6.8% (13 of 190), and 39.4% (13 of 33), respectively.

COVID-19–Associated AKI in ICU/Critically Ill Cases

Evidence has shown that AKI is more common in ICU patients. In the study by Huang et al, of the first reported 41 COVID-19 patients in Jinyintan Hospital, 13 patients were admitted to the ICU, 3 developed AKI, and the presence of AKI was documented in 23.1% (3 of 13). Subsequently, Yang et al reported findings from 52 ICU cases admitted to the same hospital from December 24, 2019, to January 26, 2020, and the results suggested that AKI, which was the most common extrapulmonary complication, was observed in 15 patients (28.8%). This finding is consistent with the experience of a study from Tongji Hospital that documented the presence of AKI in 25.0% of 344 ICU patients with COVID-19 from January 25, 2020, to February 25, 2020, and a cross-sectional study in 19 ICUs in Wuhan in which 25.2% of 252 ICU cases developed AKI.

RISK FACTORS FOR AKI IN COVID-19

Observational studies from China have suggested that older age, hypertension, cardiovascular disease, and COVID-19 grade , are associated with the development of AKI in patients with COVID-19. Patients with AKI are more likely to require mechanical ventilation. More than two thirds of the in-hospital AKI episodes were reported to develop after the patients reached critical illness. Increased markers of inflammation, such as ferritin, C-reactive protein, and D-dimer, , suggest a role for inflammation in the underlying disease state. However, there are no data available on the association between medications and procedures (eg, surgeries, contrast administration) and the development of AKI.

Similarly, male sex, older age, , diabetes, hypertension, black race, cardiovascular disease (coronary artery disease, heart failure, peripheral vascular disease), , respiratory disease (asthma and chronic obstructive pulmonary disease), premorbid chronic kidney diseae, and the need for ventilator support or vasopressor drug treatment also were reported as risk factors in the United States, Italy, and France. In addition, a higher body mass index and greater baseline levels of inflammatory markers, including ferritin, C-reactive protein, procalcitonin, and lactate dehydrogenase, were observed in COVID-19 patients with AKI than in non-AKI patients, which suggests the risks for developing AKI and AKI stage escalation.

The rate of AKI varies considerably among different regions and countries. Data from China suggest that AKI is less common in China than in the United States, and the reported cases from China had lower rates of comorbidities such as diabetes and hypertension, and a lower proportion of cases with severe respiratory disease/ARDS than the reported cases from the United States. , To date, there are no data on risk factors between different hospital settings (eg, academic versus community, rural versus urban).

CLINICAL CHARACTERISTICS OF COVID-19–ASSOCIATED AKI

The studies of kidney involvement in COVID-19 patients show that abnormal urine findings, including proteinuria and hematuria, are more common than AKI. ,5In a prospective cohort study of 701 COVID-19 patients in Wuhan, 43.9% of the patients had proteinuria, 26.7% had hematuria, and 5.1% had AKI. These findings were confirmed by the study by Zheng et al describing 555 patients from two separate COVID-19 cohorts, one from Wuhan and one from Shenzhen city, where the incidence of proteinuria, hematuria, and AKI was 33.5%, 21.5%, and 5.6%, respectively.

As reported by Zheng et al, altogether 13.5% (75/555) of the patients were categorized as critical illness, and 29 patients were defined as having AKI (5.6%%), of whom 21 cases were recognized as in-hospital AKI (4.0%), and 8 (1.5%) as prehospital AKI. The median time of COVID-19 symptoms onset with respect to in-hospital AKI onset was 18 days (25% to 75% percentile, 14-22). The duration from symptom onset to critical illness and death was 13 days (8-17) and 29 days (22-38), respectively (Fig. 2 ). The peak stages of in-hospital AKI were stage 1 in 38% (8/21), stage 2 in 19% (4/21), and stage 3 in 43% (9/21). In the study by Pei et al, of the 22 COVID-19 patients with overall AKI, 18.2%, 31.8%, and 50.0% were staged as AKI stage 1, stage 2, and stage 3, respectively. The rate of renal replacement therapy (RRT) in COVID-19–associated AKI was rarely reported. In a preprint study from 11 designated ICUs in Wuhan, 21.1% (26/123) of the COVID-19 AKI patients required RRT.

Figure 2

Timeline of admission, occurrence of critical illness, onset of in-hospital acute kidney injury (AKI), and death from onset of symptom. The median time was 5 days (25% to 75% percentile, 3-11) for admission (n = 555), 13 days (25% to 75% percentile, 8-17) for critical illness (n = 75), 18 days (25% to 75% percentile, 14-22) for in-hospital AKI (n = 21), and 29 days (25% to 75% percentile, 22-38) for death (n = 27). Data adapted with permission from Zheng et al.

PATHOLOGIC CHANGES IN COVID-19–ASSOCIATED AKI

To date, more than 4,600 patients have died from COVID-19 in China. The first postmortem tissue biopsy report of kidney pathologic presentation was from 26 COVID-19 patients, and it described extensive acute tubular injury and endothelial injury. Among these 26 patients, acute tubular lesions were significant and diffuse, including the loss of brush border, vacuolar degeneration, and dilatation of the tubular lumen with cellular debris, but only 9 patients showed clinical signs of kidney injury, which included increased serum creatinine concentrations and/or new-onset proteinuria. Five patients presented with severe pathologic tubular injury with increased serum creatinine concentrations, and two of these patients showed multiple foci of bacteria and diffuse polymorphonuclear casts in the lumen of tubules, which was consistent with the pathologic findings in the lungs. Occasional hemosiderin granules in the tubular epithelium were identified in four patients with hematuria using a dipstick. Another common morphologic finding was erythrocyte stagnation in the peritubular and glomerular capillary loops without distinct fragmentation of erythrocytes, platelets, or fibrin thrombi. Angiotensin-converting enzyme 2 (ACE2) expression was prominent in proximal tubular cells, particularly in areas with severe acute tubular injury. Immunostaining with a SARS-CoV nucleoprotein antibody was positive in tubules, and electron microscopic examination showed clusters of coronavirus particles with distinctive spikes in the tubular epithelium and podocytes, showing a direct invasion of SARS-CoV-2 into kidney tissue.

Similar results were observed in a preprint study that reported postmortem kidney biopsy findings from six COVID-19 patients with AKI. Varying degrees of acute tubular necrosis, luminal brush-border sloughing, and vacuole degeneration were observed in all six renal specimens, and an accumulation of SARS-CoV-2 viral nucleoprotein antigen in kidney tubules was detected by immunohistochemistry. The earlier-described findings are consistent with kidney injury secondary to SARS-CoV and the Middle East respiratory syndrome coronavirus infections, in which viral invasion also was detected in renal tubular epithelial cells. ,

ETIOPATHOGENESIS OF COVID-19–ASSOCIATED AKI

The mechanism of the development of AKI in SARS-CoV-2 infection may be multifactorial and vary among cases and different disease conditions. In vitro Vero E6 and 293T cell experiments showed that the glycoprotein spikes on the outer surface of SARS-CoV are responsible for the attachment and entry of the virus into host cells. Recently, another in vitro study used human kidney and airway epithelial cells and suggested that the spike protein of SARS-CoV-2 binds to ACE2 for entry and that the spike protein is activated and cleaved by cellular transmembrane serine protease 2 (TMPRSS2), allowing the virus to release fusion peptides for membrane fusion. A study based on single-cell transcriptome analysis showed that the co-expression of the receptor ACE2 and TMPRSS genes in kidney cells was no less than that in the lung, esophagus, small intestine, and colon, and relatively high co-expression of ACE2 and TMPRSS genes was observed in podocytes and proximal straight tubule cells. These findings suggest that the kidney is an important target organ for SARS-CoV-2, with podocytes and proximal straight tubule cells as candidate host cells. Recently, some researchers successfully isolated SARS-CoV-2 virus particles from the urine of COVID-19 patients.53, 54, 55 Virus particles also were identified in kidney specimens of AKI patients. , These results show that SARS-CoV-2 is a cytopathic virus that can directly infect human renal tubules and podocytes and consequently lead to AKI and proteinuria in COVID-19 patients. Clinical findings showed exuberant inflammatory responses during SARS-CoV-2 infection, further resulting in uncontrolled pulmonary inflammation, likely a leading cause of case fatality, , suggesting that a possible cytokine storm may be involved in the occurrence and development of AKI. Other putative mechanisms include the use of renal-toxic therapies, respiratory distress syndrome–induced hypoxia, hypovolemia, and hypotension.

COVID-19 IN SPECIAL KIDNEY DISEASE POPULATIONS

Patients With End-Stage Kidney Disease on Maintenance Hemodialysis

In a large cohort of patients with end-stage kidney disease and undergoing maintenance hemodialysis (MHD) in Wuhan, 154 of 7,154 patients had laboratory-confirmed COVID-19, making the incidence of COVID-19 in MHD patients 2.15%, which is much higher than that of the general population (approximately 0.5% during the same period in Wuhan). Therefore, the MHD population is highly susceptible to COVID-19, and hemodialysis centers are a high-risk clinical setting for the spread of SARS-CoV-2 infection.

Management of MHD patients in the context of an epidemic poses several challenges. Patients usually require transportation from home to the dialysis units, and dialysis care delivery requires close contact and multiperson attendance. In response to this emerging threat, the Chinese Medical Association Nephrology Branch released guidance documents for the prevention and control of COVID-19 infection in hemodialysis settings, such as strict entrance screening of temperatures and symptoms and select nucleic acid tests and computed tomography scans. In addition, all patients and staff were required to wear medical masks during dialysis and in public places. Patients undergoing MHD who were suspected to have COVID-19 were quickly isolated and transferred to a fever clinic for further examination. Figure 3 showed patient screening and disposition for COVID-19 in hemodialysis settings recommended by the Chinese Society of Blood Purification Administration. The effectiveness of comprehensive intervention measures in controlling the development of the epidemic in patients undergoing MHD was verified because disease onset continued to decrease from 10 per day on January 30, 2020, to 4 per day on February 11, 2020. No new cases have occurred between February 26, 2020 and March 10, 2020.

Figure 3

Patient screening and disposition for coronavirus disease 2019 (COVID-19) in hemodialysis settings. aSuspicious symptoms include fever, cough, sore throat, chest pain, shortness of breath, fatigue, headache, conjunctivitis, and muscle soreness. bDialysis in general isolation should be the last shift of the day in a separate treatment room. cDialysis in enhanced isolation should be the last additional shift after daily routine treatment. Adapted with permission from the Chinese Journal of Blood Purification.

Kidney Transplant Patients

Kidney transplant recipients appear to be at higher risk for hospitalization and death from COVID-19. However, there is not much information on the mortality rate of kidney recipients co-infected with COVID-19 in China. The reported mortality rate in this population was as high as 28% (10 of 36) in a single institution in New York.

The Transplantation Technology Branch of Chinese Medicinal Biotechnology Association developed a recommendation on the prevention and treatment of COVID-19 kidney transplant recipients, which suggested determining an optimal follow-up schedule. By timely adjusting working methods and procedures and implementing the emergency prevention and control measures during the epidemic, none of the kidney transplant inpatients and outpatients were infected with COVID-19 in a single institution in Henan Province, China. The recommended treatment of kidney transplant recipients with COVID-19 infection is to tailor treatment options based on the patient's clinical status, duration of transplant, and severity of illness. The reduction or suppression of antimetabolic agents (eg, mycophenolate mofetil) is the first approach in mild cases. Immunosuppressive therapy (eg, a calcineurin inhibitor) and rapamycin also should be reduced in moderate-severe cases. For severe patients, withdrawal of all immunosuppressive therapies, except corticosteroids, is required to restore an adequate immune response.

PREVENTION AND CONTROL MANAGEMENT OF THE COVID-19 EPIDEMIC

Controlling the source and cutting off the route of transmission are the fundamental measures for the prevention and control of infectious diseases. After the outbreak of COVID-19, extreme disease control practices were adopted by the Chinese government to promote active case finding and case management in suppression and containment strategies. Wuhan, the epicenter of COVID-19 in China, suspended all transportation into and out of the city from January 23, 2020, to April 8, 2020. Hospitals were required to report confirmed or suspected cases within 2 hours. Laboratories reported test results within 12 hours, and local Centers for Disease Control and Prevention completed case investigations within 24 hours."?> Door-to-door and individual-to-individual universal symptom surveys were initiated to single out presumptive cases in the community.

All confirmed cases were hospitalized and transferred to isolation wards in COVID-19–designated hospitals, regardless of disease severity. Presumptive cases, that is, those with fever or respiratory symptoms, and close contacts of confirmed cases, were allocated to centralized isolation sites with protective conditions. To combat the shortage of hospital beds, 16 Fangcang shelter hospitals were built rapidly in Wuhan, which isolated more than 12,000 patients with mild and moderate COVID-19. Three mobile physical protection level 3 laboratories were transported to Wuhan to help enhance the capability and efficiency of nucleic acid testing. These hospitals and laboratories helped ensure that every suspected case could be tested, treated, and isolated, and that their close contacts could be traced and isolated in a timely manner.

According to China's national guidelines for the prevention and control of COVID-19, medical staff who provided diagnosis and treatment services to COVID-19 patients at designated medical and health institutions were required to keep effective personal protection. Individual protective equipment, including protective clothing, medical protective masks or powered air filter respirators, and protective face screens or goggles, were necessary. All of the medical staff lived in isolation, worked as a team to limit exposure to the infection, and were prohibited from working in non–COVID-19 wards during the same time. After finishing their work in the isolation wards, medical staff also were required to undergo centralized isolation medical observation. Patients with RRT indications were transferred to designated wards managed by a special team with significant expertise in catheter placement, management of RRT, and critical care. The use of at least double-layered protection was recommended for the personnel placing dialysis catheters.

The containment strategies, including the implemented nonpharmaceutical public health measures, were effective in China. The reconstruction of the full transmission dynamics of COVID-19 in Wuhan, on the basis of 32,583 laboratory-confirmed cases between December 8, 2019, and March 8, 2020, showed that the proportion of severe and critical cases decreased from 53.1% to 10.3% over time and that the effective reproduction number fluctuated above 3.0 before January 26, 2020, decreased to less than 1.0 after February 6, 2020, and decreased further to less than 0.3 after March 1, 2020.

TREATMENT OF COVID-19–ASSOCIATED AKI

General Management

To date, the care strategy for patients with COVID-19 and AKI largely is supportive because of the lack of specific treatments. Oxygen delivery is optimized to maintain a high level of oxygenation parameters and to prevent tissue hypoxia and worsening of AKI under severe infection. Appropriate fluid management is essential because patients with fever tend to be hypovolemic, and mechanical ventilation with high positive end-expiratory pressure maneuvers might exacerbate the condition. However, avoiding volume overload and pulmonary edema are equally important. The discontinuation of all potentially nephrotoxic drugs and dose adaptation of drugs excreted by the kidney are pivotal to the patient's renal function. Protein-calorie malnutrition is associated with mortality in patients with AKI, and the nutritional management of AKI patients with COVID-19 is vital. In addition, there has been no evidence in recent studies showing that renin-angiotensin-aldosterone system inhibitors would affect the risk of COVID-19 or mortality.67, 68, 69"?> Therefore, cardiovascular societies recommend against the addition or cessation of renin-angiotensin-aldosterone system inhibitors.

Antiviral Therapies

The use of antiviral drugs in treating COVID-19 patients varies from 22% to 93% in different studies.1, 2, 3 , , , 69, 70, 71 Guan et al retrospectively reviewed 1,099 patients with COVID-19 and found that 35.8% of the patients had received oseltamivir therapy. The proportion of patients reaching the composite outcome (including ICU admission, need for mechanical ventilation, and death) was higher in patients with oseltamivir administration than in those patients without oseltamivir therapy (9.2% versus 4.4%). This result could be interpreted by the fact that antiviral agents were more likely to be used in severe patients (46.2% in severe patients versus 33.8% in nonsevere patients) who tended to have a high viral load and a long virus-shedding period.

Currently, remdesivir appears to be the only antiviral agent with randomized controlled trial (RCT) evidence for shortening the time to recovery in COVID-19 patients. In an initial RCT in Wuhan, remdesivir use showed a nonsignificant trend toward reduced time to clinical improvement. However, this trial did not reach its target enrollment because of marked reductions in new patient presentations. A subsequent RCT enrolling 1,063 patients from 60 sites worldwide (45 in the United States) found accelerated recovery in patients receiving remdesivir (median time to recovery, 11 days in patients receiving remdesivir versus 15 days in patients receiving placebo; P < .001). In addition, mortality at 14 days was 7.1% with remdesivir and 11.9% with placebo (hazard ratio for death, 0.7; 95% CI, 0.47-1.04). Subgroup analysis found no benefit in patients on high-flow oxygen, noninvasive ventilation, or invasive ventilation, suggesting that antivirals such as remdesivir will be of limited efficacy in the late disease stage, during which the pathology likely is inflammatory in origin.

An open-label RCT of 150 hospitalized patients in China compared hydroxychloroquine with the standard of care and showed no difference in viral clearance at 28 days and a significantly higher risk of adverse events (30% in the hydroxychloroquine group vs 8.8% in the standard-of-care group; P = .001). Similar findings were observed in a press release from the Randomised Evaluation of COVID-19 therapy trial, which was conducted at 176 National Health Service hospital organizations in the United Kingdom. In total, 1,561 patients randomly allocated to receive hydroxychloroquine were compared with 3,155 patients concurrently allocated to usual care, and hydroxychloroquine was not associated with reductions in 28-day mortality (26.8% versus 25.0% usual care; RR, 1.09; 95% CI, 0.96-1.23; P = .18) but was associated with a lower probability of discharge alive within 28 days (60.3% versus 62.8% usual care; RR, 0.92; 95% CI, 0.85-0.99).

Corticosteroids

China's National Guidance on COVID-19 recommends the use of systematic corticosteroid treatment (methylprednisolone, 1-2 mg/kg body weight, for 3-5 days) in patients with disease development that manifests as uncontrollable high fever, exacerbation of dyspnea, progressive deterioration of oxygenation index, rapid progress on imaging, and a sharp increase in cytokine levels. Huang et al reported that 46% of ICU cases and 11% of non-ICU cases were given systemic corticosteroids. Subsequently, Guan et al reported similar findings from 1,099 cases, with 60% of ICU cases receiving corticosteroids. These results immediately raised concerns about whether patients would benefit from corticosteroid therapy because of the risk of inhibiting immune responses and impairing pathogen clearance.

Several observational studies in China failed to show solid evidence for the influence of corticosteroids on either severe or nonsevere COVID-19 patients. Two clinical trials aimed to explore their effectiveness and safety in the treatment of COVID-19 (NCT04273321 and NCT04263402). Both studies have been completed, but the results are not yet known. The recent results of the Randomised Evaluation of COVID-19 therapy trial in the United Kingdom indicate that at the doses tested, the benefits of steroid treatment outweighed the potential harm. A total of 2,104 patients were randomized to receive 6 mg dexamethasone once per day for 10 days and were compared with 4,321 patients randomized to usual care alone. Dexamethasone reduced mortality by 35% in patients on mechanical ventilation (29.3% versus 41.4%; RR, 0.64; 95% CI, 0.51-0.81) and by 20% in patients treated with oxygen (23.3% versus 26.2%; RR, 0.82; 95% CI, 0.72-0.94); however, a trend toward worse survival was observed in mild cases not requiring oxygen (17.8% versus 14.0%; RR, 1.19; 95% CI, 0.91-1.55). Therefore, the associations between corticosteroid use and disease severity and/or death that were found in observational studies might reflect a greater propensity to use corticosteroids in severe cases. , , , ,

Traditional Chinese Medicine

Traditional Chinese medicine (TCM), one of the oldest healing practices, mainly includes natural medication, acupuncture, and physiotherapy, and has been used in China for centuries to treat various diseases, including viral infections. The integration of TCM and Western medicine is recommended in the national guidelines for COVID-19 treatment, , with different TCM plans (lianhuaqingwen capsules, jinhuaqinggan granules, xuebijing injections, and so forth) based on patients’ clinical manifestations. Adjusting therapies according to patients’ physical conditions under the supervision of a TCM physician also is recommended.

In vitro, liushen capsules showed antiviral and anti-inflammatory abilities against SARS-CoV-2 via suppression of the nuclear factor-κB signaling pathway. Lianhuaqingwen capsules significantly inhibited SARS-CoV-2 replication in Vero E6 cells and markedly reduced proinflammatory cytokine production at the messenger RNA level. Furthermore, several observational studies showed that TCM, as an adjuvant therapy for COVID-19, played a role in promoting recovery by controlling fever symptoms and accelerating the absorption of lung lesions.85, 86, 87

A multicenter open-label RCT on lianhuaqingwen capsules enrolled 284 COVID-19 patients (142 each) from 23 hospitals in nine provinces throughout mainland China. Patients who received lianhuaqingwen capsules were more likely to achieve complete recovery of clinical symptoms such as fever, fatigue, and coughing (91.5% versus 82.4% in controls; P = .022). lianhuaqingwen capsules also shortened the time to symptom recovery (median, 7 versus 10 days in controls; P < .001) and improved the recovery of chest radiologic abnormalities (83.8% versus 64.1%; P < .001). There is another ongoing, multicenter, open-label RCT in China on the efficacy and safety of anluohuaxian, a proprietary Chinese medicine that improves hepatic fibrosis in patients with chronic hepatitis B virus infection, in the treatment of pulmonary fibrosis in severe COVID-19 patients (NCT04334265). Further well-designed RCTs are required to evaluate the efficacy and safety of TCM for COVID-19 patients.

Extracorporeal Blood Purification for COVID-19–Associated AKI

Extracorporeal blood purification with continuous renal replacement therapy (CRRT), as the most common technique in clinical practice, played an important role in the rescue of SARS, MERS, and other sepsis-associated AKI. Approximately 0.5% to 2.0% of COVID-19 patients required CRRT, with AKI as the main reason. , , The proportion increased to 5.6% to 23.0% in critically ill patients in the ICU. , , , , The national guidelines published by the Chinese National Health Commission proposed blood purification therapies for critically ill COVID-19 patients with AKI and increased inflammatory factors. Based on Chinese experts' consensus on blood purification treatment of severe COVID-19, , hemoperfusion, hemoadsorption, and plasma exchange were performed in addition to conventional CRRT to clear crucial inflammatory mediators in patients with sepsis and ARDS. Wang and Hu reported a patient with severe SARS-CoV-2 infection who recovered from a cytokine storm after treatment with the combination of a double plasma molecular adsorption system (BS330 and HA330II; Jafron, Zhuhai, China) and plasma exchange (2,000 mL each). The potential effect of blood purification therapy on reducing the cytokine storm also was described in the report by Ma et al of three critically ill COVID-19 patients. Although RCT evidence is lacking, multidisciplinary efforts should be made to maximize the availability of blood purification therapy for indicated patients.

PROGNOSIS OF COVID-19–ASSOCIATED AKI

As of August 6, 2020, the case-fatality ratio of COVID-19 was 6.6% (4,512 of 68,138) in Hubei Province, and 0.8% (172 of 20,666) in all other regions of China. According to the Johns Hopkins Coronavirus Resource Center, the global case-fatality ratio of COVID-19 was 3.8% (707,666 of 18,810,382), with higher mortality rates reported in Yemen (28.7%; 506 of 1760), the United Kingdom (15.1%; 46,295 of 307,256), and Italy (14.2%; 35,171 of 248,419). The differences in the mortality of COVID-19 in various countries may be owing to the differences in the testing policy, the efficacy of disease recognition, and the degree of overwhelmed health care facilities.

The mortality of COVID-19–associated AKI was reported mainly in studies from Wuhan. , , , , The pooled mortality rate was 77.2% (95% CI, 51.9%-91.4%) in patients with AKI versus 9.0% (95% CI, 3.6%-20.7%) in non-AKI COVID-19 total hospital admissions, and the rate correlated with AKI severity stage (75.0% for AKI stage 1, 85.7% for AKI stage 2, and 90.9% for AKI stage 3). Given the lack of information, it is difficult to compare mortality rates among AKI patients requiring RRT in COVID-19 across studies. Nonetheless, an extremely high mortality rate was observed in COVID-19 patients requiring RRT. Yang et al included 52 COVID-19 patients in their study and found that 8 of 9 subjects who required CRRT did not survive. In another study including 191 COVID-19 patients, all the 10 subjects who required CRRT did not survive.

Information on renal recovery in COVID-19–associated AKI is very limited. In the study by Pei et al, 18% (4 of 22) of patients with AKI achieved complete remission of kidney function in 3 weeks after the onset of infection, and the critical type of COVID-19 was associated independently with nonrecovery of AKI (odds ratio, 0.03; 95% CI, 0.004-0.32). More information on renal recovery and short- and long-term renal outcomes of COVID-19–associated AKI is needed.

CONCLUSIONS

SARS-CoV-2 infection is spreading rapidly and causing daily mortality worldwide. Studies have shown that AKI is prevalent in critically ill COVID-19 patients. Kidney involvement is associated with poor outcomes. Early detection and appropriate management should be instituted as soon as possible. Prevention is the critical aspect in the management of this disease. Extreme disease control practices effectively contains the spread of the disease. Several vaccines and promising treatments are undergoing clinical trials with the hope of finding a cure for this global crisis soon.