The Novel Coronavirus 2019 Epidemic and the Kidneys

The Severe Acute Respiratory Syndrome Coronavirus 2 is a recent disease that originated in China by the end of 2019. The origins of the disease can be traced to bats, but it has been transmitted to humans, and the inter-human transmission is particularly rampant which has led to a pandemic of unseen proportions. The organ principally involved is the lungs, and severe pneumonia with lack of oxygen leads to fatalities. The aim of this review was to study the involvement of the kidneys with regard to COVID-19 infection and how the disease may affect people on hemodialysis or those who have undergone a kidney transplant. Indeed, the virus, in addition to the lungs, may affect other vascularized organs to a common receptor on lung epithelium and the endothelium of any organ. The kidney, which has a large endothelium surface, is affected, and COVID-19 may lead to acute renal failure. On the other hand, the virus may easily spread among people who are on hemodialysis three times a week. People on hemodialysis may have low immunity, and the virus may have dangerous effects on such people. Finally, renal transplant patients may be easily affected, and the virus may have severe consequences, even death. We will summarize the principal prophylactic measures to be adopted and the therapeutic measures available. Clearly due to the recent occurrence of the pandemic the majority these measures lack a basis in evidence-based medicine and only highlight the efforts to limit COVID-19 induced damage.


Introduction
COVID-19 is a disease caused by the new Coronavirus strain, also called Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2). The disease was initially identified in the Hubei province of China in late 2019 (1) There are seven strains of coronavirus that can infect humans. Four of them cause a mild respiratory syndrome in humans and rarely may cause pneumonia, mainly in immunocompromised patients. In the past, two severe epidemics have been caused by two different Coronavirus strains: the Severe Acute Respiratory Syndrome (SARS-CoV) and the Middle East Respiratory Syndrome (MERS-CoV). The mortality rates for these epidemics were 10 and 37%, respectively (2,3). An in-depth knowledge about these two diseases helped us in understanding some of the characteristics of The question remains as to how the COVID-19 virus may enter the renal cells. Another study from Varga et al. (14) has documented that vascular damage in addition to respiratory disease may be observed in the course of COVID-19. Indeed, SARS CoV-2 infects the patient binding to the ACE2 receptor, which is expressed both on the pulmonary epithelium and on the endothelium of several organs, including the kidney. The endothelium involvement may be the way through which the virus enters the cells. Indeed, several studies have documented that during the COVID-19 disease, several organs may be affected in addition to lungs, such as the myocardium and the kidney (15).
In an observational study, Diao et al. (16) documented that, in a retrospective analysis of 85 patients with COVID-19 infection, confirmed in Wuhan, 23 patients (27.06%) exhibited acute renal failure (ARF), principally related to tubular necrosis, as histologically documented by Su (13). In addition, Diao et al. documented activation of CD68+ macrophages together with complement activation. Further studies have documented that SARS CoV-2 infection, in addition to the release of proinflammatory cytokines, may induce ARF by rhabdomyolysis, hypoxemia, and dehydrated and microvascular thrombosis related to complement activation (17,18) (Figures 1 and 2). Another cause of ARF in COVID-19 is associated with the collapsing glomerulopathy as documented in two different case reports in which ARF associated with heavy proteinuria affected black patients (19)(20)(21). All the patients were black with an APOL1 highrisk genotype.
Overall, COVID-19 patients show signs of renal injury including proteinuria (44%), hematuria (26.9%), and increased plasma creatinine (15.5%) (22). The presence of virus particles, both in urine and in renal parenchymal cells, is probably related to the penetration of the virus through the endothelium and the glomerular barrier (23). In another study, Pei et al. (24) documented a renal involvement in 251 out of 333 patients affected by COVID-19. Proteinuria was present in 65.8% of patients and hematuria in 41.7%.
The aforementioned study (11) on COVID-19 patients hospitalized in New York city documented, during univariate and multivariate logistic regression analyses, the risk factors associated with the development of AKI (Table 1).
To date, the exact mechanism of viral penetration inside the kidney and the subsequent renal damage has not been completely understood. The binding to ACE2 principally in the renal tubules represents the first step (25). The transmembrane protease, serine 2 (TMPRSS2), mediates this first priming step (26,27). Once inside the kidney, several pathways may be activated as complement activation, cytokine storm, and interstitial inflammation. Viral replication in podocytes could mediate proteinuria (28). the SARS-CoV-2. Covid-19 is more contagious than the other Coronavirus strains, has the bat as the source of origin, and its mode of transmission from bat to man has not been completely understood till date. The probability of virus transmission between humans is high and could occur via droplets, feces or direct contact.
The incubation period is between 1 and 10 days. In the vast majority of patients, the disease manifests with a flu-like syndrome, but in several patients the COVID disease has a more severe manifestation, with onset of fever, cough, myalgias, and diarrhea (4). Approximately, 16-20% of patients are affected by a severe syndrome, with bilateral pneumonia and reduced oxygen saturation requiring admission to the intensive care unit (ICU). These patients present with high levels of inflammatory cytokines in the blood as interleukin (IL)-2, IL-6, IL-7, IL-10, and TNFα (5)

COVID 19 and the kidney
The relationship between COVID-19 and the kidney may be divided into three main areas: 1. COVID-19-induced renal disease 2. COVID-19 and dialysis patients 3. COVID-19 and transplant patients

COVID-19-induced renal disease
Although pulmonary infection is the main manifestation in the course of COVID-19, other organs, such as the kidney, may be of interest as well.
Previous studies of SARS and MERS CoV documented the development of acute kidney injury (AKI) in 5-15% of patients with a high mortality rate.
Two recent reports from New York city noted an incidence of AKI in patients hospitalized with COVID-19 at 31% (10) and of 36.6% (11) respectively.
One study documented that patients on admission affected by leukocyturia, albuminuria, and hematuria, principally when associated with low albumin serum concentration and low antithrombin III concentration, will easily develop AKI (12).
In the renal histopathological analyses of 26 postmortem findings of patients with COVID-19 in China, Su et al. (13) were able to document renal lesions as proximal tubule injury, vacuolar degeneration, and necrosis. By electron microscopy, the same authors were able to find Coronavirus particles in the tubular epithelium and podocytes. In addition, an upregulation of angiotensin converting enzyme 2 (ACE2), the receptor of COVID, was found.  Rhabdomyolysis has also been documented in patients with COVID-19 and could contribute to the development of AKI (29).

COVID and dialysis patients
Useful guidelines and suggestions may be obtained from the previous epidemics involving the coronavirus, in particular, the MERS epidemic.
During such epidemics, useful recommendations have been given by the Korean Society of Nephrology (30). According to such recommendations, the following key points should be followed: a) Patients on hemodialysis with suspected or confirmed MERS-CoV infection should be transferred to a MERS clinic or to a hemodialysis center with facilities, such as isolation rooms.
b) If a patient on hemodialysis is subjected to quarantine due to close contact with a confirmed case, the center should follow the basic principles provided by the prevention authority. c) Interhospital transfers should be prohibited. d) All patients and health care workers should follow the standard contact and droplets precautions. A 2-year prospective cohort study (31) documented that a strict patient surveillance and a proper isolation practice prevented secondary transmission of the virus.
To mitigate the risk of COVID-19 in dialysis facilities, the following points have been recently suggested (32): a) A systemic screening should be adopted for all dialysis patients (symptomatic or not). b) Patients suspected or confirmed to be affected by COVID-19 should be isolated. c) Patients should be instructed on the use of face masks. It should be highlighted that controversies on the use and type of masks exist according the different organizations (33)(34)(35)(36)(37)(38)(39)(40)(41). d) Personnel should be provided with protective equipment, including face mask, eye protection, and isolation gowns. e) Rooms, beds, and dialysis machines should be routinely disinfected.
At the beginning of the COVID-19 spread in Europe, the European Dialysis (EUDIAL) Working Group of the European Renal Association-European Dialysis and Transplant Association (ERA-EDTA) recommended the following measures for the prevention, mitigation, and containment of the emerging SARS-CoV-2 pandemic in hemodialysis centers (42). Different sets of recommendations are needed for both the healthcare team and the dialysis patients: a) Recommendations for the health care team: The health care team should be trained in the use of personal protective equipment.
The health care team should be aware of possible symptoms, so that they can avoid contact with suspected persons.
The health care team should be instructed on the use of protective equipment, such as masks (possible FFP2), goggles, mobcap, and disposable surgical gowns and gloves. b) Recommendations for dialysis patients: Patients should be instructed on appropriate hygiene. Patients should inform the staff on their arrival in case of suspected symptoms. Patients should be instructed to self-isolate.
Patients' body temperature should be checked at the start and at the end of the dialysis session.
Symptomatic patients should be dialyzed in an isolated room.
Italy has been deeply affected by the COVID-19 infection, especially Northern Italy.
From an overall population of 643 hemodialysis patients who reported in four dialysis centers in the province of Brescia (Lombardy region), in March 2020, 94 patients (15%) were positive for SARS-CoV-2 RNA.

Patients' treatment
The drugs used in the treatment of COVID-19 infection to date are: a) Recombinant soluble ACE2 (44). The rationale behind using hrsACE2 is principally its inhibitory effect on pulmonary infection; however, other organs may also be of affected, especially the capillary walls, the heart, and the kidney. b) Antiviral treatment. The use of chloroquine and hydroxychloroquine is supported by studies performed

COVID-19 and renal transplant patients
There is not much data available on COVID-19 infection in renal transplant patients, and often they are related to case reports (58-60). Akalin et al. collected data on 36 adult kidney transplant recipients positive for COVID-19 (61) in New York. Patients were treated in different ways according to the severity of their illness. All received reduced immunosuppressive therapy. Overall, there was a high mortality rate (28% at 3 weeks), and all transplanted patients documented a more rapid clinical progression than the general population affected by COVID-19.
Better outcomes were observed at Columbia University Hospital, where 15 kidney transplant patients required hospitalization for confirmed COVID-19 (63). Six patients (40%) in previous SARS infections. Their efficacy in the treatment of COVID-19 infection seems to be relatively poor according to some studies (45,46). Hydroxychloroquine seems to have an improved immunomodulating effect and a better pharmacological profile. In a small study, hydroxychloroquine, when given in association with antiviral agents, shortens the time to reach the polymerase chain reaction (PCR) negativization (47).
However, the use of both chloroquine and hydroxychloroquine is limited by their myocardial toxicity as recently documented (48). In a recent study (49), both chloroquine and hydroxychloroquine were found to have substantial human toxicity, causing myocardial depression and vasodilatation with impaired myocardial conductivity.
The antiviral therapy uses second-generation antiretroviral drugs in association with lopinavir/ritonavir (50).
Both lopinavir and ritonavir may lead to myocardial toxicity, as they can prolong the QT interval and cause Torsade de Pointes (48). A different antiviral association is the use of darunavir/ritonavir or darunavir/cobicistat with a similar mechanism of action. The antiviral remdesivir is a nucleotide analogue, and its mechanism of action is to incorporate itself in the ribonucleic acid (RNA) chain. Several studies have documented its efficacy (51)(52)(53).
Plasma from convalescent patients (54) has been successfully used in the treatment of SARS 1 and MERS. Preliminary data indicate its usefulness in the treatment of SARS-2 as well. c) Other drugs. One study documented the efficacy of azithromycin when given in association with hydroxychloroquine in reducing the time to achieve PCR negativization (48). Tocilizumab for its efficacy against IL-6 is an important drug for patients with a severe cytokine storm (55).
Due to the coagulation activity and its involvement in the pathogenesis of the COVID-19-induced lesions, anticoagulant drugs, such as heparin, may play an important role in the treatment of COVID-19 infection (56).
The major limitations in documenting the effective activity of any of the cited drugs is the lack of controlled studies due to the recent occurrence of the disease. An emerging problem is the possible mutation of the viral genome. In a very recent study on translational medicine (57), the authors have described eight mutations of SARS-CoV-2 in different continents. The virus with mutation in position 14408 was identified in Europe in mid-February. The mutation is RNA dependent and RNA polymerase (RdRp), and the new virus could be resistant to the antiviral agents acting at that level.
had AKI and four patients required intubation or mechanical ventilation. Two patients died. The authors themselves do not understand the reason for this lower mortality rate with respect to similar patients in the same area (61). The small patient number does not allow a statistical comparison.
A study from Iran (64) described 12 renal transplant patients with COVID-19 infection. In this group, eight patients died and four were discharged.
Twenty kidney transplant patients were admitted for SARS-CoV-2 pneumonia in the Brescia hospital (65): six patients developed AKI and five patients (25%) died. The study confirms a rapid clinical deterioration in renal transplant patients. Transplant patients are at a higher risk of developing a severe COVID-19 infection. To reduce this risk, several prophylactic and therapeutic measures should be adopted: a) Prophylaxis. As aforementioned, a careful and repeated washing of hands with soap and alcohol is recommended, both for patients and the health care team.
Vaccinations as antipneumococcal are similarly recommended to avoid preventable infections.
Transplant patients should not travel, and the same holds good for their partners and family. Lockdown at home is recommended in areas with a high rate of COVID-19 spread.
Patients should wear a mask covering their mouth and nose when venturing out of home, and are recommended to stay at a distance from other people. As previously mentioned, the frequency of which mask should be used is open to wide discussion.
Prophylactic measures should be particularly adopted for patients with mild fever or cough and for those who had been in close contact with people suspected to have had Covid-19 in the last 14 days (66). In the case of patients with symptoms, they should stay in a protected site and should follow the guidelines that are continuously updated by the Center for Disease Control and Prevention (CDC) (67 Hydroxychloroquine for 5 days at a dose in accordance with the eGFR Azithromycin 500 mg/day 2) Patients with severe symptoms with dyspnea and/or positive chest X rays. These patients should receive the same antiviral treatment.
Remdesivir should be considered as a first-line treatment in patients with rapid deterioration, severe pneumonia, and needing mechanical ventilation.
In the case of rapid deterioration, treatment with tocilizumab should also be considered. Tocilizumab dose should be decided according to body weight (55).
3) Due to the interaction between hydroxychloroquine, ritonavir, cobicistat, and the immunosuppressants,  prior to transplantation, and the use of their organs should be discussed before transplantation.
The adoption of such measures has reduced the transplantation activity. Preliminary Italian data show a reduction of procured organs by about 25% in the first 4 weeks of the COVID-19 outbreak (70).

Conclusions
The interrelationship between COVID-19 and the kidneys is probably more complex than previously suspected. The localization of angiotensin-converting enzyme (ACE)2 receptor, which is the binding site of the virus on the epithelial surface, exposes many organs as possible targets of COVID-19.
In the case of kidney, several pathways have been identified, which can lead to acute renal injury. The presence of AKI in a patient with severe pulmonary distress may represent a clear cause leading to death.
A particular condition is represented by the hemodialysis patients who may easily be affected by COVID-19 infection, either because the virus may easily infect them or because they are generally older with reduced immune response.
Renal transplant patients represent a high-risk population because they are immunosuppressed.
To date, we do not have enough epidemiological data concerning transplant patients, but from the data we have, a high predisposition towards AKI or death seems to be documented.
Treatment still represents a crucial problem. The lack of evidence-based treatments and of randomized controlled trials makes any possible treatment the object of controversies.
To date, oxygen, lockdown, and protective measures seem to be the only safe methods. While waiting for a vaccine or the results of controlled trials, we have to carefully monitor our patients, and treat them with the available drugs with extreme caution.