key: cord-0795699-bocidwg4 authors: Patel, Dhwanil; Truong, Tiffany; Shah, Nikhil; Colbert, Gates B.; Thomas, Beje; Velez, Juan Carlos Q.; Lerma, Edgar V.; Hiremath, Swapnil title: COVID-19 EXTRAPULMONARY ILLNESS - The Impact of COVID-19 on Nephrology Care date: 2020-07-25 journal: Dis Mon DOI: 10.1016/j.disamonth.2020.101057 sha: a3ad363c5d29a21c2919a36a12c56bfaa2e5eee9 doc_id: 795699 cord_uid: bocidwg4 Coronavirus disease-2019 (COVID-19) has caused a pandemic that has affected millions of people worldwide. COVID-19 is caused by the severe acute respiratory syndrome coronavirus-2 (SARS-CoV-2) and is spread by close contact and by respiratory droplets. It has also impacted different aspects of caring for people with kidney disease, including those with acute kidney injury (AKI), chronic kidney disease (CKD), those requiring kidney replacement therapy (KRT), and those with a kidney transplant. All of these patients are considered high risk. The lessons learned from the COVID-19 pandemic will hopefully serve to protect patients with kidney disease in a similar situation in the future. Coronavirus disease-2019 (COVID- 19) has caused a pandemic that has affected millions of people worldwide. COVID-19 is caused by the severe acute respiratory syndrome coronavirus-2 (SARS-CoV-2) and spread by close contact and by respiratory droplets 1 . Though SARS-CoV-2 is considered a respiratory virus with the most fearful complication being respiratory failure, it does affect multiple organ systems including the kidneys. In this article we review how COVID-19 involves the kidney, causing acute kidney injury (AKI), and how it affects patients on kidney replacement therapy (KRT) with hemodialysis (HD) and peritoneal dialysis (PD), and those with a kidney transplant. The information in this review reflects the understanding as of the date of writing, which is still evolving, and regular updates are being posted on the NephJC blog (www.nephjc.com/covid19). Early studies coming primarily from China reported a relatively low incidence of AKI in COVID-19 (CoV-AKI), ranging between 3 to 9% depending on the population studied [2] [3] [4] . Subsequently, in the initial report from the United States of America (USA) in individuals with COVID-19 admitted to the intensive care unit (ICU), 19% (4/21 patients) acquired AKI 5 . However, more recent and larger reports (see Table 1 ) from the US and United Kingdom described a higher incidence of CoV-AKI, of 28 to 43% among hospitalized patients and 61 to 76% among those who are critically ill [6] [7] [8] [9] . Furthermore, rates of KRT have ranged between 15 to 20% of patients with CoV-AKI, and even higher rates of 34 to 73% for those admitted to the ICU. CoV-AKI is also associated with a higher mortality rate 8 . CoV-AKI is associated with proteinuria and hematuria, which is not uncommon with acute tubular injury (ATI), however the degree of each is not known as there has been sparse reporting of quantitative data 11 . A granular description of the AKI phenotype suggests that the predominant etiology of CoV-AKI, which is largely associated with hemodynamic instability, is indeed acute tubular injury (ATI) 6 13 . Thus far, there is a paucity of data from pre-mortem tissue diagnosis. From the same group, 3 patients, all African American (AA), out of 161 patients with CoV-AKI with findings suggestive of glomerular disease underwent kidney biopsy which revealed collapsing glomerulopathy in each biopsy 6 . This is in line with emerging reports of collapsing glomerulopathy in AA individuals who are carriers of the Apolipoprotien L1 (APOL1) high risk genotype and acquire COVID-19 [14] [15] . Thus, collapsing glomerulopathy should be suspected in AA individuals presenting with AKI and new onset nephrotic range proteinuria, where the COVID-19 potentially serves as a second hit. Nevertheless, this entity does not account for the bulk of the AKI cases. Lastly, even thrombotic microangiopathy has been reported, which is probably rare, but might be underreported given the paucity of kidney biopsy data 16 . Despite the notion that ischemic ATI is the predominant etiology of AKI in patients with COVID-19, AKI without a clear cause has been observed. As a result, speculation regarding direct viral entrance of the SARS-CoV-2 coronavirus into the kidneys has arisen. The speculation has been driven by the fact that the membrane-bound peptidase angiotensin converting enzyme 2 (ACE2) acts as a receptor for SARS-CoV-2 and is expressed in the kidney tissue, both in tubules and glomerular podocytes [17] [18] [19] . The aforementioned postmortem study by Su et al. reported enhanced expression of ACE2 in parietal epithelial cells and presence of viral nucleoproteins in tubular cells. Another report of viral detection in kidney tissue has added ammunition to that contention 20 . However, there is still no definite demonstration that viral presence in the kidneys is a causative phenomenon in CoV-AKI. With the sudden surge in COVID-19 cases in the USA, healthcare resources were quickly saturated in states such as New York, California, New Jersey, and Louisiana. There was national coverage in the media regarding the shortage of ventilators due to respiratory failure in COVID-19. However, there was little mention of the stretched dialysis resources. Among the options used as a contingency include shortening the time on dialysis, even for continuous Kidney Replacement Therapy (KRT), by making it less continuous, decreasing dialysis frequency, and decreasing the need for dialysis, by being more judicious in fluid resuscitation, and using potassium binding exchange resins [21] [22] . Centers throughout the world with similar issues reported initiation of an urgent peritoneal dialysis (PD) program, which is unprecedented in the Western Hemisphere for AKI to be able to provide KRT to patients (further discussed in the following section on PD). Patients on long term KRT are on either hemodialysis (HD) or peritoneal dialysis (PD) on a regular basis. These patients on long term dialysis have chronic health conditions and immunomodulating factors that make them especially vulnerable to COVID-19. This increased vulnerability to nosocomial and community spread infections requires several steps by caregivers and healthcare systems to continue dialysis treatments in a safe environment. We will first discuss long term KRT in terms of HD then PD. Patients on chronic HD routinely receive three treatments weekly at an outpatient dialysis unit. During these dialysis sessions, the patients are in continual contact and close proximity with other patients and caregivers. Thus, patients on HD cannot self-isolate, and have repeated and ongoing potential exposure. Dialysis centers implemented strategies to keep the staff and patients from contracting COVID-19 through the known mechanisms of spread 23 . These strategies included screening at the entrance of the dialysis facilities with a health and symptom questionnaire, and a rapid temperature check for fever 24 . Patients with symptoms or an elevated temperature were advised to not enter the facility and go for COVID-19 testing. Strategies used to avoid nosocomial spread including cohorting patients with suspected or confirmed COVID in separate units, the last shift of dialysis, and/or physically isolate them as much as possible, All patients and staff were encouraged to wear Centers for Disease Control (CDC) endorsed personal protective equipment (PPE) including facial masks at a minimum, with staff wearing gowns and gloves 25 . If a patient who is on dialysis therapy contracted COVID-19, the disease course and severity has ranged widely. As with AKI, the initial data from China has been overshadowed by more grim numbers from larger studies. A small preprint study from a Chinese dialysis unit suggested the course may be milder in dialysis patients compared to other patient cohorts [26] [27] . Of the 230 patients at this one unit, only 37 developed COVID-19 and 27 of those patients were asymptomatic. Subsequent data is much worse, with mortality rates in the range of 20 -30% ( The COVID-19 pandemic brought the benefits of home dialysis with peritoneal dialysis (PD) into sharp focus. The ability to dialyze and stay quarantined in the patient's own home is ideal compared to travelling three times a week to an in-center dialysis unit. However, the other aspect of PD that had an important role was the use of urgent start PD (see Figure 1 ). Sample protocol for peritoneal dialysis (PD) in acute kidney injury. ICU: Intensive Care unit 32 The ability to initiate urgent PD has been crucial since during the COVID-19 pandemic many health care systems have been stretched thin including to the point that there was a shortage of continuous KRT machines and supplies [21] [22] [23] [24] [25] [26] [27] [28] [29] . In some centers, even the availability of HD to accommodate AKI patients needing dialysis became a problem. PD provides a viable option in these situations. Acute PD protocols are clearly outlined in the International Society for Peritoneal Dialysis (ISPD) guidelines [30] [31] . Specific concerns relate to arranging the insertion of these catheters (typically surgeons, or interventional radiologists or nephrologists), and the specific protocols that need to be used to ensure metabolic and volume control which can be challenging in the critically ill patient 21,29-31 . The majority of elective surgeries were initially cancelled during the COVID-19 crisis, however many institutes and professional organizations including the American Society of Nephrology classified PD catheter insertion as an essential service 32 . Avoiding the start of PD would result in a greater pressure on HD services, which are under stress, as discussed before. Even for chronic kidney disease (CKD) patients in need of urgent dialysis (e.g. in cases where the kidney function has worsened rapidly, or were previously not recognized to have CKD 'crash starts') an urgent PD start can be considered. Urgent PD can mostly be started within 24-48 hours of catheter insertion, using low volume exchanges in the supine position, especially using cyclers [33] [34] . Peritoneal dialysis in a patient with acute respiratory distress syndrome (ARDS) requiring prone ventilation presents several challenges. PD in prone patients has been previously described, one recent protocol provides some suggestions on managing patients with PD in prone position [35] [36] . PD catheter exit site could be placed more laterally than usual to accommodate the prone position. In addition, there is some anecdotal experience in using pillows to prop up the chest and pelvis to reduce the intra-abdominal pressure in a prone patient on PD. We have listed the possible advantages and disadvantages of PD in Table 3 . Precise ultrafiltration is slightly more difficult Avoid vascular access and need for anticoagulation May need innovative exit sites and dialysis scheduling to accommodate prone ventilation. Intra-abdominal pressure may be affected by prone positioning PD depends heavily on supplies provided by the companies that make and supply the consumables required for PD. In addition to the PD bags and cyclers, PD patients require large daily quantities of masks and hand sanitizer supplies to perform the procedure using aseptic precautions. With the broad disruption of supply chains during the pandemic, it is advisable to keep a minimum of 2 weeks of rolling stock at hand to ensure safe PD. The COVID-19 pandemic has adversely affected multiple aspects of kidney transplantation. Kidney transplant rates dropped (see Figure 2 ) at the onset of the pandemic with the suspension of 72% of living donor programs and limitations on the operations of 84% of deceased donor programs 39 Initially, transplantation evaluations decreased during the early period of COVID-19 42 . This occurred due to drops in actual transplantation rates, as well as concern for increasing exposure to COVID-19 during evaluations. In response, the increased use of telemedicine pre-and posttransplant has allowed patients to continue their evaluation while minimizing risk of exposure to COVID-19 43 . The Organ Procurement and Transplant Network (OPTN) also recognized the decreased access to transplantation during the pandemic. They have allowed for a program to apply for a waiting time modification that back dates listing times to the start of the pandemic 44 . Additionally, concerns for donor-derived infection have led to the implementation of routine screening of living and deceased donors for COVID-19 with test results available within hours 45 . Presently, if a donor tests positive for COVID-19 they likely will not be used though this could change in the future 36 . Kidney transplant patients are considered a high risk patient population due to immunosuppression and their increased risk of infection 47 . Risk factors associated with increased morbidity and mortality with COVID-19 infection include increased age, obesity, and history of chronic heart, lung, or kidney disease. All these risk factors are commonly found in patients with CKD and hence in kidney transplant patients. Kidney transplant recipients infected with COVID-19 appear to have similar clinical presentations as the general population, though morbidity, including need for mechanical ventilation, and mortality vary among reports. In a case series of 15 kidney transplant recipients hospitalized with COVID-19 in New York, patients most often presented with symptoms of fever and/or cough, chest x-ray findings of bilateral infiltrates, and other elevated inflammatory markers. Mechanical ventilation was required in about 30% of these patients 48 . In another case series of 35 kidney transplant recipients with COVID-19 from both the inpatient and outpatient settings in New York, 39% of patients needed mechanical ventilation, 21% needed KRT, and the mortality rate was 28% at 3 weeks, significantly higher than the general population in the United States whose mortality rate is reported to be 1 to 5% 49 . This contrasts with a large, international European study, which reported the mortality rate in patients with kidney transplant was 18%, comparable to the 20% mortality rate of patients on dialysis 50 . For those transplant recipients with mild disease, few comorbidities, and ability to communicate closely with their transplant team, outpatient management may be considered 51 . Management of immunosuppression for patients with kidney transplant and COVID-19 primarily consists of discontinuation of the anti-metabolite, usually mycophenolate mofetil or mycophenolate acid, and, with severe infection, also holding the calcineurin inhibitor 52 . Calcineurin inhibitors in vitro have been shown to inhibit the replication of coronaviruses, though it is unclear if this effect will occur in vivo 53 . Corticosteroids have unclear benefit at this time as they have been associated with a longer duration of viral shedding and higher viral loads, but have also been explored as an experimental therapy with variable success [54] [55] [56] [57] [58] [59] [60] . A wide range of experimental therapies (see table 3 ) have been used, including hydroxychloroquine, azithromycin, tocilizumab, and remdesivir 39, 61, 62 . Careful consideration of drug dosing and interactions need to be always considered in the kidney transplant patient. We have already discussed the rapid adaptation of telehealth in kidney transplantation. However, telehealth or telenephrology was also adapted during the pandemic for use for CKD patients in the outpatient clinic setting. Recently a review by Koraishy et al. discussed telenephrology in detail 63 . Although telehealth carries limitations in the ability to thoroughly assess patients, nephrology is well-suited for it due to its nature of being primarily a "numerical specialty". CKD is known as a "silent killer" highlighting the fact that most CKD patients are not typically symptomatic until the late stages of CKD. Periodical assessment of changes if kidney function, degree of proteinuria, anemia etc.,is fully accomplished with lab review and addresses the most relevant aspects of CKD care. Patients are required to undergo blood draws at a lab facility and though this is an exposure risk many private and in-hospital clinics have taken precautions to limit exposure. In regard to physical findings, edema, the most salient in this patient population, can be assessed with the use of video or photography. Thus, telehealth proved to be a viable tool to manage outpatient CKD clinics during the pandemic. COVID-19 has had a tremendous effect on the world and causes very high morbidity and mortality. In the critically ill patient, COVID-19 also causes AKI, with 10 to 30% needing KRT. We have discussed how in the dialysis population there had to be changes to protect patients and staff. That the stress on the healthcare systems caused at times a lack of availability of certain kidney replacement modalities and that the innovative use of urgent PD became a more widely used option. Finally, the effects on kidney transplantation included a drop in transplant evaluations and transplant surgeries. We noted that while transplant patients are considered high risk for infection with COVID-19, their presentations have been similar to the general population, but with higher mortality rates comparable to that of patients on dialysis. Much of this information, especially the role of specific therapeutic management, is still evolving as trials are ongoing. As we move forward with preventative measures, it is important to remember the unique characteristics of patients with chronic kidney disease, end stage kidney disease, or those with a transplant and how they might be affected by a future situation similar to the COVID-19 epidemic. What you should know about COVID-19 to protect yourself and others The Novel Coronavirus 2019 epidemic and kidneys Clinical Characteristics of 138 Hospitalized Patients With 2019 Novel Coronavirus-Infected Pneumonia in Wuhan, China Clinical course and outcomes of critically ill patients with SARS-CoV-2 pneumonia in Wuhan, China: a single-centered, retrospective, observational study Characteristics and Outcomes of 21 Critically Ill Patients With COVID-19 in Washington State Acute Kidney Injury Associated with Coronavirus Disease Acute kidney injury in patients hospitalized with COVID-19 Acute Kidney Injury in Hospitalized Patients with COVID-19. Nephrology Clinical Characteristics of Coronavirus Disease 2019 in China Kidney disease is associated with in-hospital death of patients with COVID-19 Urinary Sediment Microscopy in Acute Kidney Injury Associated with COVID-19. Kidney360 Renal histopathological analysis of 26 postmortem findings of patients with COVID-19 in China Collapsing Glomerulopathy in a Patient With COVID-19 AKI and Collapsing Glomerulopathy Associated with COVID-19 and APOL1 High-Risk Genotype Thrombotic microangiopathy in a patient with COVID-19 Structural basis of receptor recognition by SARS-CoV-2 Glomerular Localization and Expression of Angiotensin-Converting Enzyme 2 and Angiotensin-Converting Enzyme: Implications for Albuminuria in Diabetes Characterization of reninangiotensin system enzyme activities in cultured mouse podocytes Multiorgan and Renal Tropism of SARS-CoV-2 Impending Shortages of Kidney Replacement Therapy for COVID-19 Patients Patiromer for the treatment of hyperkalemia Information for screening and management of COVID-19 in the outpatient dialysis facility Mitigating Risk of COVID-19 in Dialysis Facilities Centers for Disease Control and Prevention. Frequently asked questions and answers: Coronavirus disease-2019 (COVID-19) and Children COVID-19 in Hemodialysis (HD) Patients: Report from One HD Center in Maintenance Hemodialysis and COVID-19: Saving Lives With Caution, Care, and Courage Maintaining lifelines for ESKD patients-ASDIN and VASA joint statement Ensuring Sustainability of Continuous Kidney Peritoneal dialysis for acute kidney injury Peritoneal Dialysis in the time of COVID-19 Critical clarification from CMS: PD catheter and vascular access placement is essential | Kidney News Urgent-start peritoneal dialysis: a chance for a new beginning Unplanned Start on Peritoneal Dialysis Right after PD Catheter Implantation for Older People with End-Stage Renal Disease Peritoneal dialysis in a patient receiving mechanical ventilation in prone position Covid-Acute-PD-on-ICU-protocol-final.pdf. Accessed Sweeping CMS Waivers Give Flexibility to Nephrologists during COVID-19 Crisis | Kidney News Early Use of Telehealth in Home Dialysis During the COVID-19 Pandemic Early impact of COVID-19 on transplant center practices and policies in the United States New adult elective surgery and procedure guidelines prioritize transplant surgeries as essential care United Network for Organ Sharing. COVID-19 and Solid Organ Transplant Global Transplantation COVID Report The Role of Telemedicine in Kidney Transplantation: Opportunities and Challenges COVID-19 Emergency Policy Package COVID-19) for Transplant Clinicians Centers for Disease Control and Prevention. Groups at Higher Risk for Severe Illness The Columbia University Kidney Transplant Program. Early Description of Coronavirus Disease in Kidney Transplant Recipients in New York Covid-19 and Kidney Transplantation European Renal Association-European Dialysis and Transplant Association. The ERA-EDTA COVID-19 Database for Patients on Kidney Replacement Therapy -Fifth ERACODA Study Report Outpatient Management of the Kidney Transplant Recipient during the SARS-CoV-2 Virus Pandemic COVID-19: implications for immunosuppression in kidney disease and transplantation COVID-19 and Calcineurin Inhibitors: Should They Get Left Out in the Storm? Prolonged Shedding of Human Coronavirus in Hematopoietic Cell Transplant Recipients: Risk Factors and Viral Genome Evolution Cytokine Responses in Porcine Respiratory Coronavirus-Infected Pigs Treated with Corticosteroids as a Model for Severe Acute Respiratory Syndrome Effects of early corticosteroid treatment on plasma SARS-associated Coronavirus RNA concentrations in adult patients Clinical evidence does not support corticosteroid treatment for 2019-nCoV lung injury. The Lancet On the use of corticosteroids for 2019-nCoV pneumonia. The Lancet Dexamethasone treatment for the acute respiratory distress syndrome: a multicentre, randomised controlled trial Low-cost dexamethasone reduces death by up to one third in hospitalised patients with severe respiratory complications of COVID-19 Interactions with Experimental COVID-19 Viral Therapies Telenephrology: An Emerging Platform for Delivering Renal Health Care