key: cord-1008470-ocsz3qy7 authors: Siga, Esteban; Garcia, Mariano; Vivas, Nora title: Feasibility of long‐term twice‐weekly hemodialysis during the Covid‐19 pandemic date: 2022-04-13 journal: Hemodial Int DOI: 10.1111/hdi.13017 sha: 4decd64caf87309bc6a327f50f5eea7ebde60753 doc_id: 1008470 cord_uid: ocsz3qy7 nan To the Editor As the pandemic continues to rage in many developing countries, the saving of material and staff resources is a major priority in these resource-limited settings. The option of reducing the usual thrice-weekly session schedule to a twice-weekly one has been advocated by some authors 1 but rejected by others. 2 Different proposals to implement a twice-weekly schedule in selected hemodialysis (HD) patients were recently published, from practical step-wise approaches based mainly in the ultrafiltration rate (UFR) 3, 4 to a detailed framework. 5 However, only the Kt/V urea was suggested to measure dialysis adequacy. If a long-term twice-weekly schedule is necessary, an equivalent continuous clearance should be estimated at regular intervals to certify that an adequate HD dose is delivered. In patients who reach and sustain a minimum HD dose, 6 a long-term twice-weekly schedule would be a safe option during the COVID-19 pandemic. Our aim was to evaluate the percentage of patients that could achieve the minimum target and would therefore be suitable for safe, long-term, twice-weekly HD. This study was performed in accordance with the Declaration of Helsinki. Average data from the first semester of 2021 were extracted from deidentified patients undergoing thrice-weekly HD. Twenty-four-hour urine and blood samples were processed in local laboratories using automated and standardized methods. Urea kinetics analysis was performed using Solute-Solver, 7 version 2.14. Solute-Solver is a web-based urea kinetic modelling software that enables urea modelling in patients dialyzing from 1 to 7 sessions a week. A twiceweekly schedule was simulated in all patients. Solute-Solver estimates two variants of an equivalent continuous clearance: the standard fractional urea clearance in volumes per week (stdKt/V) and the equivalent renal urea clearance in ml/min (EKRU). The characteristics of the 110 patients included have been described previously. 3 Mean spKt/V urea was 1.60 (SD: 0.38). The left column of Table 1 shows the major parameters of the anuric patients and the right column shows those of patients with a diuresis of at least 200 ml/ day. With the exception of the double-pool equilibrated Kt/V urea (eKt/V), this group performed better in all parameters. The group comprised 36 patients (33%) with a median daily urine output of 956 ml/day (interquartile range: 622-1300). The median ultrafiltration rate (UFR) of these 36 patients was 4.9 ml/kg/h (interquartile range 2.9-9.0). This UFR is below the upper limit of 13 ml/kg/h that has been set by many dialysis providers and below the recently proposed upper limit of 8.5 ml/kg/h. 3 However, only those with a diuresis >519 ml/day (n = 24, 22%) reached the minimum dose 6 of 2.1 stdKt/V- Figure 1a . This minimum dose has been proposed by the 2015 update of National Kidney Foundation's Kidney Disease Outcomes Quality Initiative (KDOQI) guidelines. 6 However, to be sure that the minimum dose is delivered a target of 2.3 stdKt/V has been suggested by these guidelines. Figure 1b shows the estimated eKt/V required in each session to achieve the 2.3 stdKt/V target. Alternatively, a minimum session time can also be estimated (Figure 1c) . Patients participating in a long-term twice-weekly schedule need careful monitoring. Based on the results of the present study, we wish to suggest the following framework. Initially, urea kinetic modelling should be determined in all patients with a diuresis higher than 500 ml/ day. Then, modelling should be determined at least quarterly. In the meantime, in those patients who fulfilled the minimum target, 24-h urine volume should be measured frequently. Alternatively, the modelled eKt/V could be estimated from the Kt/V measured online by contemporary dialysis machines. 10 If the HD machines do not provide this technology, one may prescribe the session time estimated by the mobile app. 9 In addition to the adequacy, other clinical parameters might be considered, such as ultrafiltration rate, hyperkalemia, nutritional status, anemia and hyperphosphatemia. 3, 4 We recognize that this framework may increase workload, but this should be balanced by the saving of valuable and limited material and staff resources. The small sample of the present study limits its external validity. Nevertheless, it provides support for the notion that selected patients could be safely transferred to a long-term twice-weekly schedule during the COVID-19 pandemic. A sizeable percentage of our HD patients (24 out of 110: 22%), would be suitable for a long-term twice-weekly schedule. This represents 96 HD sessions/month and these resources could be reallocated to serve the increasing acute dialysis needs during the COVID-19 pandemic. None of the authors had any financial or personal relations with people or organizations that could have inappropriately influenced their work. Funding was provided by each dialysis unit. The corresponding author states that he had full access to all the data in the study and F I G U R E 1 Feasibility of twice-weekly hemodialysis (HD) in patients with residual kidney function. Vertical axis on scatter Plot 1a represents stdKt/V, standard fractional urea clearance in volumes per week. On Plot 1b vertical axis represents eKt/V, double-pool equilibrated Kt/V urea and on Plot 1c time of one HD session in minutes. Number of patients is presented on the horizontal axis of the three plots. The stdKt/V -estimated with Solute-Solver 7 version 2.14 -of 36 patients with a diuresis of at least 200 ml.day is depicted in Plot 1a. Twenty four reached the guidelines 6 proposed minimum dose of 2.1. This represents 22% of the total sample (n = 110) who would be suitable for a twiceweekly schedule. In Plot 1b, only 24 patients who reached the minimum dose are depicted. Using the spreadsheet Speedy, 8 we estimate the eKt/V needed in each session for these 24 patients to achieve an stdKt/V target 6 of 2.3 volumes per week. All but two patients needed an eKt/V lower than 1.5 to reach the target. Speedy also estimates an equivalent renal urea clearance normalized to 35 ml of body water (EKRUn). Using this metric, the number of patients suitable for twice-weekly HD would increase from 24 to 29. To the best of our knowledge, controlled evidence supporting either EKRUn or stdKt/V as a guide for HD prescription is still missing. The current guidelines adopt stdKt/V to determine dialysis dose. Plot 1c shows the estimated session time required for these 24 patients to reach the 2.3 stdKt/V target. For all except five patients, a session time of 240 min was sufficient to reach the target. Time in minutes was estimated with a recently developed 9 mobile phone application: stdKtV calculator for iOS and stdKt/V calculator for Android had final responsibility for the decision to submit for publication. Twice-weekly hemodialysis is an option for many patients in times of dialysis unit stress Counterpoint: twice-weekly hemodialysis should be an approach of last resort even in times of dialysis unit stress Twice-weekly hemodialysis in the time of COVID-19: a multicenter study in prevalent patients Reduced frequency hemodialysis in times of COVID19: A prospective study in prevalent patients Balancing the needs of acute and maintenance dialysis patients during the COVID-19 pandemic National Kidney Foundation. KDOQI Clinical Practice Guideline for Hemodialysis Adequacy: 2015 update Solute-solver: a web-based tool for modeling urea kinetics for a broad range of hemodialysis schedules in multiple patients A user-friendly tool for incremental haemodialysis prescription Barriers to Reducing Hemodialysis Time and Frequency in Patients with Residual Kidney Function Eliminating the need for rutine monthly postdialysis urea nitrogen measurement. A method for monitoring Kt/V and normalizaed protein catabolic rate using conductivity determined dialyzer clearance