Abstract
Acute kidney injury (AKI) is a serious complication in critically ill patients with COVID-19 with a reported incidence ranging from <5% to >25%. Proposed aetiologies include hypovolemia, hemodynamic disturbance and inflammation but also specific factors like direct viral invasion, microvascular thrombosis, and altered regulation of the renin-angiotensin-aldosterone system. To date, there are no confirmed specific therapies, and prevention and management of AKI should follow established guidelines. Novel therapies specifically targeting COVID-19 related pathologies are under investigation. The incidence of renal replacement therapy (RRT) is variable, ranging from 0-37%. In a pandemic, RRT practice is likely to be determined by the number of patients, availability of machines, consumables and staff, clinical expertise, and acceptable alternatives. Close collaboration between critical care and renal services is essential.
In this article, we describe the epidemiology and pathophysiology of COVID-19 associated AKI, outline current management and suggest strategies to provide RRT during a pandemic when resources may be scarce.
Key words: COVID-19, Acute kidney injury, Renal replacement therapy, Pandemic
1. AKI epidemiology
Despite initial reports, acute kidney injury (AKI) has emerged as a serious complication in critically ill patients with COVID-19. The prevalence appears to vary with incidence rates of <5% in some initial publications from China and figures exceeding 25% in subsequent publications [[1], [2], [3], [4]]. This variation may be explained by differences in pre-existing comorbidities and clinical practice (i.e. fluid management, use of nephrotoxic drugs) but socioeconomic and genetic reasons may also play a role. For instance, the SARS-CoV-2 virus uses the angiotensin-converting enzyme 2 (ACE2) receptor to enter tubular cells. Pan et al showed that the expression of the ACE2 receptor in renal podocytes and proximal tubule cells was more pronounced in Occidental subjects than in Asians, suggesting that the risk of COVID-19 associated AKI may vary between different ethnic groups [5].
2. Aetiology and pathophysiology
The aetiology of COVID-19 associated AKI is multifactorial and includes general risk factors like haemodynamic disturbance, inflammation and cytokine release, endothelial dysfunction, alteration of the microcirculation, nephrotoxic exposure, and the impact of invasive mechanical ventilation, similar to AKI in non-COVID-19 settings [[6], [7], [8]]. However, there is emerging evidence that additional factors specific to SARS-CoV-2 virus infection play an important role, too.
-
1.
Viral infiltration: In the kidney, ACE2 is present in podocytes, mesangial cells, parietal epithelium of the Bowman’s capsule, proximal cells and the collecting duct [9]. It has been reported that SARS-CoV-2 can directly infect podocytes and tubular epithelial cells [9,10]. After binding to the ACE2 receptor, the spike (S) protein of SARS-CoV-2 is activated and cleaved by cellular transmembrane serine proteases. This process allows the fusion of the viral envelope with cellular membranes and entry of the virus into host cells. After entering the cytosol, the SARS-CoV-2 RNA begins the translation of its replicase exploiting the endogenous transcriptional processes of the infected cell to generate new virions [9]. The virus appears to exert direct cytopathic effects, too [9]. In addition, the tropism of SARS-CoV-2 to podocytes which form an important component of the glomerular filtration barrier, may explain the common finding of proteinuria in patients with COVID-19. Finally, the deposition of immune complexes of viral antigen or virus-induced specific immunological effector mechanisms (specific T-cell lymphocytes or antibodies) can induce inflammatory processes and cause additional kidney damage.
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2.
Altered Renin-Angiotensin-Aldosterone (RAAS) regulation: The role of ACE2 is to metabolize Angiotensin-II (Ang-II) to the vasodilatory and anti-inflammatory peptide angiotensin-(1–7). Imbalance of the components of the RAAS can change renal hemodynamics, alter tubular handling of electrolytes and induce pro-inflammatory changes. In the early stage of COVID-19, viral entry leads to ACE2 consumption followed by increased local Ang-II concentrations [12]. The effects of Ang-II include vasoconstriction, endothelial activation, and pro-inflammatory cytokine release [12]. Ang-II also has potent chemotactic effects that may accelerate both lymphocyte recruitment and at a later stage, pulmonary endothelial activation can lead to ACE-1 shedding where endothelial surface-bound ACE-1 is released into the interstitium [13]. This produces a decrease of Ang-II to sub-physiologic levels. Low Ang-II concentrations in this phase can lead to vasodilation, worsened capillary leak, alteration of glomerular autoregulation and reduction of glomerular filtration.
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3.
Microthrombi: COVID-19 is a pro-thrombotic state where innate immunity and coagulation pathways are closely linked [14,15]. Activation of macrophages and release of cytokines, pathogen-associated molecular patterns and damage-associated molecular proteins can result in release of tissue factor and activation of coagulation factors. Post-mortem histology of kidneys has confirmed thrombi and erythrocyte aggregates obstructing peritubular capillaries and impacting intrarenal microcirculation [11].
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4.
Rhabdomyolysis: Rhabdomyolysis is also a feature of COVID-19. Some reports of renal histology demonstrated pigmented tubular casts containing high levels of creatine phosphokinase [11].
3. Renal histology
In a post-mortem case series including 26 COVID-19 patients from China, the predominant kidney histology in 9 patients with AKI was acute tubular injury, erythrocyte aggregation in peritubular capillaries, segmental fibrin thrombi in glomeruli, direct viral infection of tubular epithelium and podocytes, and infiltration of inflammatory cells [11]. Features consistent with rhabdomyolysis were noted in 3 of the 9 cases. A different post-mortem report in 6 patients showed similar findings: severe acute tubular injury, lymphocyte and macrophage infiltration, detection of viral antigen in tubular epithelial cells, and complement C5b-9 deposition [10].
Collapsing glomerulopathy, an aggressive variant of focal segmental glomerulosclerosis with high rates of podocyte injury and depletion, has also been reported in renal biopsies of patients with COVID-19 associated AKI [16]. It is known to occur with a variety of conditions, including viral infections such as human immunodeficiency virus, influenza, cytomegalovirus and non-viral infections including tuberculosis, autoimmune diseases, drug exposures (such as pamidronate and interferon), hemophagocytic syndrome, and acute glomerular ischemia. Many of these exposures are thought to mediate the disease by podocyte cytotoxicity such as via pro-inflammatory cytokine expression. Given the variable renal histology findings, it is not surprising that proteinuria and haematuria have been reported in patients with COVID-19 associated AKI [17].
4. Medical management
During periods of scarce resources, prevention of AKI is particularly important. Where AKI develops, all efforts should be made to mitigate progression to severe AKI, particularly where renal replacement therapy (RRT) might be needed. Presently, there is no specific treatment for COVID-19 associated AKI. Until new evidence emerges, general management should follow current consensus recommendations for AKI in general [18,19]. However, potential therapies targeting specific aspects of the pathophysiology of COVID-19 associated AKI are being explored and tested [[20], [21], [22], [23], [24]]. (Table 1 )
Table 1.
COVID-19 associated AKI and potential management strategies.
| Conditions contributing to AKI | Pathophysiology | Recommended management and potential strategies |
|---|---|---|
| Hypovolemia |
|
|
| Haemodynamic disturbance |
|
|
| Viral infection |
|
|
| Inflammation and cytokine release |
|
|
| Activation of pro-thrombotic processes |
|
|
| Rhabdomyolysis |
|
|
| Fluid overload |
|
|
| Altered RAAS regulation |
|
|
| Invasive mechanical ventilation |
|
|
| Cardiogenic shock |
|
|
Abbreviations: ACE = angiotensin converting enzyme; ECMO = extracorporeal membrane oxygenation; RAAS = renin – angiotensin – aldosterone system; RRT = renal replacement therapy
In case of progressive AKI, measures to avoid or delay the need for RRT are particularly important, including avoidance of nephrotoxic exposures and fluid overload, use of diuretics in case of fluid accumulation, and strategies to avoid hyperkalemia.
5. Renal replacement therapy
The incidence of RRT in critically ill COVID-19 patients with AKI appears to be highly variable with some reports suggesting that RRT is necessary in more than 30% of critically ill patients with COVID-19. (Table 2 ) In general, clinical practice of RRT should follow existing guidelines and be provided as optimally as possible to avoid wasting of scarce resources. However, adjustments may need to be made in case of reduced RRT capacity (environment, machines, consumables, staff) [6,25,26]. (Table 3 and Table 4 ) Ideally, policies and protocols for RRT during a pandemic should be in place before capacity is reached so that risks to patients, staff and the wider hospital community and the impact on quality standards are minimized [27].
Table 2.
“Real-time” RRT data (on 13th April 2020; personal communication).
| Investigator | Region | Total number of COVID patients in Critical Care | Incidence of RRT |
|---|---|---|---|
| Bouchard | Montreal (Ca) | 25 | 0% |
| Kellum | Pittsburgh (USA) | 3 | 0% |
| Hoste | Gent (B) | 47 | 8.5% |
| Joannidis | Innsbruck (Au) | 44 | 9% |
| De Vlieger | Leuven (B) | 127 | 10.2% |
| Monard | Lyon (Fr) | 62 | 15% |
| Neyra | Lexington (USA) | 13 | 15.4% |
| Ronco | Vicenza (It) | - | 18% |
| O’Loughlin | Dublin (Ie) | - | 20% |
| Prowle | London (UK) | 142 | 20-25% |
| Ostermann | London (UK) | 236 | 27% |
| Silversides | Belfast (UK) | 27 | 33% |
| Forni | Surrey (UK) | 61 | 16% |
Abbreviations: Ca = Canada; USA = United States of America; B = Belgium; Au = Austria; Fr = France; It = Italy; Ie = Ireland; UK = United Kingdom
Table 3.
Provision of RRT during COVID-19 pandemic
| Ideal situation | Reality |
|---|---|
| modality based on individual patient’s needs | choice of modality based on availability, number of patients and expertise of staff |
| initiation before onset of life-threatening complications | strict criteria for initiation in the absence of absolute criteria for RRT: need for medical management of complications of AKI (diuretics, potassium binders, bicarbonate) |
| prescription of appropriate dose to compensate for unplanned ‘downtime’ | minimal dose to control metabolic and fluid status |
| optimal anticoagulation to maintain filter patency and avoid harm | need to maintain long filter life to avoid wasting circuits (high risk of filter clogging/clotting) |
| highly qualified ICU staff | less qualified staff/surge staff |
| ICU environment | non-critical care areas |
| high standards and benchmarks | need to accept lower standards and performance indicators |
Abbreviations: ICU = intensive care unit
Table 4.
Alternatives in case of limited RRT resources
| Resource limitation | Potential alternatives (in combination with optimal management of AKI to avoid RRT) |
|---|---|
| CRRT machines |
|
| Fluids |
|
| Circuits catheters |
|
Abbreviations: AKI = acute kidney injury; CRRT = continuous renal replacement therapy; IHD = intermittent hemodialysis; PIRRT = prolonged intermittent hemodialysis; RRT = renal replacement therapy; SLED = sustained low efficiency dialysis
5.1. Modality
Continuous renal replacement therapy (CRRT), prolonged intermittent RRT (PIRRT) and intermittent haemodialysis (IHD) are the most common modalities of RRT for AKI in most ICUs. Acute peritoneal dialysis (PD) is used less often. There is no consistent evidence that CRRT is superior to IHD with regards to mortality and renal recovery. However, CRRT provides superior removal of fluid and resolution of fluid overload, and is associated with more consistent metabolic control and less hypotension, in particular in patients with haemodynamic instability [18].
In the absence of data clearly demonstrating superiority of one modality over another, during a pandemic, the choice of RRT modality should be informed foremost by clinical expertise and resources readily available [25]. In surge situations where CRRT machines may be limited, alternative strategies, including acute PD and the use of IHD and PIRRT with standard CRRT machines (i.e. 40-50 ml/kg for 4-8 hours) should be considered to provide renal support for a higher number of patients.
If IHD is employed, extra trained staff may be needed. In addition, IHD requires access to permanent or mobile reverse osmosis units and sufficient water and drain resources with adequate water pressures to generate a dialysate.
5.2. Timing
The optimal timing for initiation of RRT in COVID-19 patients is unknown [[28], [29], [30], [31], [32]]. In patients not suffering from COVID-19, there is no convincing evidence that earlier initiation is beneficial [32]. Therefore, in a pandemic with scarce resources, initiation of acute RRT should only be considered to control or prevent complications of AKI which cannot be managed medically. Ideally, this decision should be made collaboratively with all relevant specialties involved (critical care, nephrology, nursing, patient, surrogate decision maker).
5.3. Vascular access
During a pandemic, appropriate vascular access is important in order to maintain circuit patency and avoid wasting of scarce resources. In patients who need regular proning, internal jugular access is preferred over femoral lines and the catheter length should be chosen based on insertion site [33]. (Table 5)
Table 5.
Preferential catheter insertion site during COVID-19 pandemic and corresponding catheter length (adapted from reference [34]).
| Preference | Insertion site | Catheter length |
|---|---|---|
| 1 | Right internal jugular vein | 15 cm |
| 2 | Left internal jugular vein | 20 cm |
| 3 | Right or left femoral vein | 25 cm |
| 4 | Dominant arm subclavian vein | Right: 15-20 cm Left: 20 cm |
| 5 | Non-dominant arm subclavian vein | Right: 15-20 cm Left: 20 cm |
5.4. Anticoagulation
COVID-19 is a prothrombotic illness, and premature filter clotting is frequently reported. Appropriate vascular access is essential and systemic anticoagulation is recommended to prolong filter life [34]. In case of ongoing problems with premature filter clotting, other forms of thrombophilia should be excluded (i.e. heparin induced thrombocytopenia).
5.5. Blood purification
The role of blood purification using specific membranes, adsorption, hemoperfusion or other extracorporeal techniques in COVID-19 has not been studied formally and remains unknown to-date [21].
6. Staff wellbeing
During a pandemic, all members of the multidisciplinary team will be experiencing emotional, physical, psychological and moral stress. The need for RRT will add to this and additional support and resources may be necessary. Access to appropriate personal protective equipment is essential.
7. Operational aspects
Close collaboration with other ICUs, critical care networks, local renal units and local health care systems in general is essential to share equipment, consumables, expertise and support. Clear criteria for transfer of patients to renal units need to be agreed between all stakeholders.
8. Outcome
Evidence is clearly emerging that AKI is associated with an increased risk of mortality in patients with COVID-19, especially if RRT is required [35,36]. The long-term impact of COVID-19 associated AKI on kidney function, risk of chronic dialysis, cardiovascular morbidity and mortality remain unknown at this stage.
9. Conclusions
The COVID-19 pandemic provides unique challenges for patients, healthcare providers, administrators and the community in general. Preparedness for rapid changes, flexibility, resilience and team work are the key essentials to enable everybody to overcome the challenges. In addition to the high physical and emotional demand, the situation also offers opportunities for fascinating clinical and basic science research, and new ways of working.
Declaration of Competing Interest
The authors have no conflict of interest.
Acknowledgments
Acknowledgement
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1.
This article is based on a webinar by the European Society of Intensive Care Medicine given by the authors in April 2020.
-
2.
We would like to thank colleagues and friends who provided institutional data related to the epidemiology of COVID-19 associated AKI (Table 2).
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