key: cord-0894284-t8vytua4 authors: Christ-Crain, Mirjam; Hoorn, Ewout J; Sherlock, Mark; Thompson, Chris J; Wass, John title: ENDOCRINOLOGY IN THE TIME OF COVID-19-2021 UPDATES: The management of diabetes insipidus and hyponatraemia date: 2021-07-22 journal: Eur J Endocrinol DOI: 10.1530/eje-21-0596 sha: 24f4f4ac53d5fdbb083c7b07dac1194ea09584a8 doc_id: 894284 cord_uid: t8vytua4 COVID-19 has changed the nature of medical consultations, emphasizing virtual patient counselling, with relevance for patients with diabetes insipidus (DI) or hyponatraemia. The main complication of desmopressin treatment in DI is dilutional hyponatraemia. Since plasma sodium monitoring is not always possible in times of COVID-19, we recommend to delay the desmopressin dose once a week until aquaresis occurs allowing excess retained water to be excreted. Patients should measure their body weight daily. Patients with DI admitted to the hospital with COVID-19 have a high risk for mortality due to volume depletion. Specialists must supervise fluid replacement and dosing of desmopressin. Patients after pituitary surgery should drink to thirst and measure their body weight daily to early recognize the development of postoperative SIAD. They should know hyponatraemia symptoms. Hyponatraemia in COVID-19 is common with a prevalence of 20–30% and is mostly due to SIAD or hypovolaemia. It mirrors disease severity and is an early predictor of mortality. Hypernatraemia may also develop in COVID-19 patients, with a prevalence of 3–5%, especially in ICU, and derives from different multifactorial reasons, for example, due to insensible water losses from pyrexia, increased respiration rate and use of diuretics. Hypernatraemic dehydration may contribute to the high risk of acute kidney injury in COVID-19. IV fluid replacement should be administered with caution in severe cases of COVID-19 because of the risk of pulmonary oedema. This is an update of the previously published guidelines 1 year ago (1) . While there is not much new literature about diabetes insipidus (DI) and COVID-19, knowledge about the prevalence of dysnatraemia in COVID-19 and about the association of dysnatraemia with the outcome has increased. Patients with pre-existing endocrine conditions may be vulnerable to perturbations in plasma sodium in more severe cases of COVID-19. Especially patients with central DI or pre-existing hyponatraemia may be at risk of more severe, life-threatening dysnatraemia. Regardless of pre-existing endocrine conditions, hyponatraemia is common in patients hospitalized with COVID-19 (2, 3, 4, 5, 6, 7, 8, 9) and is associated with disease severity and mortality. This article is intended to advise how endocrinologists can still optimally care for ambulatory patients with central DI and hyponatraemia, where regular physical consultations and biochemical assessments are not possible. Furthermore, we provide guidance on the management of these patients when they are admitted to the hospital with severe COVID-19. DI is a rare disease (10) , characterized by hypotonic polyuria and polydipsia (11) . The differential diagnosis of DI involves the distinction between primary forms (central DI) or nephrogenic DI and secondary forms, where polyuria results from primary polydipsia (12) . Treatment of DI consists of fluid administration in case of dehydration, and in cases of central DI, desmopressin as hormone replacement for the absent vasopressin (13) . In the majority of cases with central DI, osmoregulated thirst is intact, and oral fluid intake accurately compensates for urinary and insensible water losses. Even prior to treatment with desmopressin, patients are, therefore, typically eunatraemic. To reduce the symptoms of polyuria and polydipsia, desmopressin is given orally or intranasally; the major complication of desmopressin therapy is hyponatraemia. A retrospective review has shown that 27% of central DI patients show mild hyponatraemia (131-134 mmol/L) on routine electrolyte testing, and 15% develop more severe hyponatraemia (≤130 mmol/L) over longterm follow-up (14) . Hyponatraemia develops when the antidiuretic effects of continuous desmopressin therapy prevent free water excretion, even with normal fluid intakes. This can be prevented by delaying doses of desmopressin to allow regular aquaresis, but regular electrolyte checks are recommended during the initiation of therapy. Annual electrolyte checking is recommended for long-term follow-up, though more frequent monitoring is needed where hyponatraemia episodes are more frequent. - The COVID-19 pandemic has limited the accessibility of blood testing, and the priority of routine treatment of central DI should be to avoid hyponatraemia. This emphasizes the importance of delaying desmopressin doses, to allow regular periods of free water clearance, so that excess water intake does not lead to dilutional hyponatraemia. This can be achieved by recommending that the patient delays a dose of desmopressin once or twice per week, until an aquaresis occurs. Some patients regularly delay each dose until they begin to feel polyuric, as they are aware that they otherwise feel bloated by fluid retention. Alternatively, especially in patients known to experience recurrent hyponatraemia, one dose each week can be entirely omitted, though significant polyuria and social disruption may occur. -Although patients with central DI should be no more vulnerable to COVID-19 than the rest of the population, those DI patients who develop respiratory complications of COVID-19 are at significantly increased risk of dysnatraemia. -Epidemiological data show that hypernatraemia is rare in ambulatory patients with DI; in contrast, the rate of hypernatraemia during hospital admission is significant (14) . The aetiology of this hypernatraemia is multifactorial; if cognition is attenuated by critical illness, fluid intake may be reduced, and if the patient is vomiting, oral desmopressin intake may be difficult. Most hospital studies report increased mortality in intensive care units associated with hypernatraemia (15) , and it is a poor prognostic sign in patients who develop DI following head injury (16) . In addition, data from a nationwide Swiss cohort study showed an increased mortality rate in complex hypopituitary patients with central DI admitted to hospital, compared with hypopituitary patients without DI, consistent with vulnerability of DI patients to develop hypernatraemic dehydration in the context of severe illness (17) . The propensity to develop hypernatraemia during hospital admission is particularly marked in patients with adipsic DI (14) , and this subgroup of DI patients has been documented to develop severe hypernatraemia (18) , which may be complicated by thrombotic episodes (19) . Patients with adipsic DI may also have hypothalamic obesity, and there is increasing evidence that obesity per se may be an important risk factor for poor outcome in patients with Covid-19. Thus, these patients may be amongst the most (20) . This report was prompted by a study of patients hospitalized with central DI, which showed that desmopressin treatment had been missed or delayed in 88% of admissions, and that 35% of patients consequently developed dysnatraemia (21) . This was attributed to a lack of understanding of the critical nature of desmopressin amongst clinical staff (22) . In this context, it is very important that patients themselves are empowered with the knowledge of their condition and the essential difference between DI and diabetes mellitus, which caused confusion with serious consequences at the time of admission. The results of these guidelines have generated a sensible basis for the management of DI when patients are admitted to the hospital. - The key practice points in the SfE in 2018 guidelines are particularly valid for DI patients with COVID-19. Most importantly, all patients with central DI admitted to the hospital with COVID-19 should be managed in consultation with endocrinology advice. In addition, a careful prescribing alert system for all patients treated with desmopressin is recommended to reduce prescribing errors and to ensure that essential desmopressin therapy is maintained. - In patients with mild COVID-19 cold symptoms, who are alert and able to drink, it may, in some patients, be advisable to prescribe oral rather than nasal desmopressin due to the limited absorption from congested nasal passages. As COVID-19 is characterized by persistent fever and tachypnoea, insensible water losses are likely to be substantially increased; ordinarily, osmotically stimulated drinking should generate fluid intake sufficient to make up for insensible losses, but if the cognitive function is impaired by fever, hypoxia or sepsis, i.v. fluids may be required. - In patients with severe COVID illness, desmopressin should be given parenterally, usually with a starting dose of 0.5 μg. The i.v. route is generally preferred because it obviates concerns about absorption and has the same total duration of action as the other parenteral routes. Prompt reduction in urine output should occur, and the antidiuretic effect generally lasts for 6-12 h. Urine osmolality and urine volume should be monitored to ascertain whether the dose was effective, and the plasma sodium should be measured at frequent intervals (every 2-4 h) to ensure improvement of hypernatraemia. Since arterial blood gas point of care testing for sodium may be the main laboratory estimation available in some hospitals (particularly 'field hospitals'), sodium measurement can be done using this method instead of sending it to the laboratory. -Hypernatraemia in COVID-19 patients (without central DI) in intensive care units is seen with a prevalence of 2-5% (2, 4, 5, 6, 7, 8); excessive insensible water losses from the constant pyrexia and increased respiration rate may play a major aetiological role in this, as well as this gives rise to the need for significant diuretic use or conservative fluid regimens in some patients in order to aid oxygenation. Hypernatraemic dehydration may, therefore, rapidly develop in patients with DI, particularly in those who need diuretic therapy or in whom desmopressin is withheld or delayed. If diuresis is necessary, the optimum management of these patients should be a collaboration between intensive care and endocrinology. - In patients with hypovolaemic shock due to COVID-19 restoration of blood volume with i.v. 0.9% sodium chloride is preferable, even if there is hypernatraemia. In the absence of hypovolaemic shock, patients with DI and severe dehydration should be treated with hypotonic fluids, either enterally (using water or milk) or, if necessary, intravenously (using 5% dextrose in water). Hypotonic fluids should be administered as an i.v. infusion, with the rate adjusted to exceed the hourly urine output and reverse the calculated total body water deficit. The usual aim is to provide just enough water to safely normalize serum sodium at a rate of < 0.5 mmol/L per h (<10-12 mmol/L per day) (23 https://eje.bioscientifica.com extracellular volume expansion since two-thirds of the administered fluid is distributed intracellularly. Initial data suggested that hypernatraemia, in contrast to other critically ill patients, is not a risk factor for severe mortality in COVID-19 (25) . More recent data, however, show that hypernatraemia is associated with adverse outcomes and mortality, similar to other critically ill patients (4, 5, 6, 7). -However, it may be that endocrinologists may have to accept mild hypernatraemia (<155 mmol/L) as the price of preventing pulmonary oedema. In patients with central DI. we will have a major role in ensuring that severe hypernatraemia, which compromises recovery, does not occur, and multidisciplinary input is needed to discuss the individual merits and contingencies of treatment in DI patients with COVID-19. - It is important to stress that, as hypernatraemic dehydration is associated with a hypercoagulable state, the risk of venous thrombosis, and pulmonary embolism, is substantial, particularly in an immobile patient (26) . We, therefore, recommend the routine prescription of prophylactic s.c. low molecular weight heparin during episodes of hypernatraemic dehydration, until eunatraemia is restored. This is particularly important since pulmonary embolism is emerging as one of the factors associated with mortality in COVID-19 patients. Low molecular weight heparin is also recommended in patients with hypercoagulable states in COVID-19 (27) . -As the majority of patients with postoperative or post-traumatic central DI also have ACTH deficiency, concomitant stress dose corticosteroids are essential during COVID infection. Hyponatraemia (plasma sodium < 35 mmol/L) is the most common electrolyte disorder in clinical practice (28) . It is divided into euvolaemic, hypovolaemic, and hypervolaemic hyponatraemia, each of which is treated differently (29, 30) . The syndrome of inappropriate antidiuresis (SIAD) is the commonest cause of hyponatraemia (28, 31) . Management of patients with hyponatraemia in the routine endocrine practice -SIAD is seen by endocrinologists after pituitary or other neurosurgery (32) and as part of consultations throughout the hospital. One effect of the COVID-19 pandemic has been the cancellation of most elective pituitary operations, though neurosurgical interventions for subarachnoid haemorrhage or traumatic brain injury continue to induce SIAD. Patients with SIAD will continue to be treated according to well-established guidelines (29, 30) . As patients who develop SIAD after pituitary surgery characteristically do so after discharge from the hospital, it will continue to be important to draw attention to the possible occurrence of hyponatraemia, to both patients and primary care physicians. Hyponatraemia has been recorded to be the commonest cause of hospital readmission following transsphenoidal surgery; as access to routine phlebotomy may be compromised by the needs for social isolation and the limitations of many health provisions, the emphasis should be on prevention and awareness. Patients should be advised to limit their fluid intake in the 2 weeks following surgery and to drink only to thirst and to measure their body weight daily. We recommend that the primary care physician is contacted if there is weight gain, bloating or unusual headache. Instruction on hyponatraemia-associated symptoms, such as headache, dizziness, nausea or fatigue, is important. -All other patients with chronic SIAD, who are treated with either fluid restriction, urea or vaptans should be instructed to continue their treatment as usual. We recommend advising the patients to daily monitor their body weight and to be aware of hyponatraemia symptoms (see above), where access to phlebotomy for electrolytes is restricted. -Hyponatraemia occurs in up to 30% of pneumonia cases (33) , and several studies show that admission hyponatraemia predicts increased mortality and morbidity (34, 35, 36) , independent of the underlying disease. Of note, 60% of SARS-COV-1 patients were reported to have mild hyponatraemia (37) . Recent literature suggests that hyponatraemia in COVID-19 patients is as common as in other pneumonia cases. Berni et al. showed a prevalence of hyponatraemia of 22.9%, which is in the range of most other literature showing a prevalence of around 20-30% (5, 6, 7, 9) . An even higher prevalence of 40% has been shown in a large study in 10 000 patients across 13 hospitals in a New York health system (4). Of note, hyponatraemia https://eje.bioscientifica.com seems to be more common in COVID-19 compared to controls hospitalized with similar symptoms, but without COVID-19 (6) . There is only limited information about the aetiology of hyponatraemia, but SIAD and hypovolaemia are suggested to be the main causes. One study identified a correlation between serum sodium and interleukin-6 and greater correction of hyponatraemia in patients with COVID-19 who were treated with tocilizumab (38) . This suggests that interleukin-6-mediated vasopressin release may contribute to COVID-19-associated hyponatraemia (39, 40) . COVID-19 can also cause adrenal insufficiency with accompanying hyponatraemia responsive to steroid replacement (41, 42) . In almost all studies, hyponatraemia was associated with an increased prevalence of non-invasive ventilation and ICU transfer and was an independent predictor for adverse outcome and mortality. Each mmol/L of serum sodium reduction was associated with a 14.7% increased risk of death in one study (2) . In another study, each level of worsening hyponatraemia (mild to moderate to severe) conferred a 43% increased odds of in-hospital death, even after adjusting for age, gender, race, BMI, past medical history, laboratory abnormalities, kidney failure, mechanical ventilation and sequential organ failure assessment (SOFA) score. Still, it is unclear whether this association of hyponatraemia and outcome mirrors causality or simply defines hyponatraemia as a marker for severity of the disease. Whatever the case, sodium levels at admission should be considered an early prognostic marker in patients with COVID-19. -As the mortality from hypovolaemic hyponatraemia is higher than that of SIAD (31) , the temptation is, if it occurs in COVID-19 patients, to respond with i.v. fluid resuscitation. However, in severely ill COVID-19 patients, clinical experience dictates that caution should be exercised in the rate of i.v. fluid administration because of the risk of precipitating pulmonary oedema. Similar caution is advised in patients with severe hyponatraemia complicated by symptoms of cerebral irritation. Although guidelines recommend bolus hypertonic saline treatment to rapidly elevate plasma sodium concentration (29) , and published data suggests that this is effective (43) , the sudden volume load might cause pulmonary oedema. In this circumstance, the safer option might be low-dose hypertonic saline infusion, with careful control of the volume of fluid administered; the clinical experience in the COVID-19 situation is insufficient to be definitive about this, and each centre should use the method with which they are most familiar. Table 1 highlights the risks and preventive measures in patients with DI or hyponatraemia in times of COVID-19 and Table 2 shows the management of DI and hyponatraemia in the COVID-19 patient in intensive care. In summary, patients with central DI or hyponatraemia should be managed according to existing guidelines as ambulatory patients, with careful explanation to DI patients of how to avoid dilutional hyponatraemia in circumstances where plasma sodium measurements are difficult to access. Patients with DI are vulnerable to adverse effects and potentially poor outcomes if hospitalized with COVID-19. Hyponatraemia seems to be common in patients hospitalized with COVID-19 with a prevalence rate of around 20-30%, mainly due to SIAD or hypovolaemia. Hypernatraemia is less common (prevalence of 2-5%) and is more a problem of COVID-19 in intensive care units, most probably due to insensible water losses from the constant pyrexia and due to increased respiration rate. This tendency may be enhanced in patients with DI, who are at risk of hypernatraemic dehydration. Treatment of dehydration must be tempered with the potential to precipitate pulmonary oedema with i.v. fluid; treatment plans should be carefully agreed upon between endocrinologists and intensivists. Hyponatraemia in severely COVID-19-affected patients should be treated by guideline principles but with similar caution with respect to the volume of i.v. fluids in hypovolaemic hyponatraemia or in acute hyponatraemia with cerebral irritation. The authors declare that there is no conflict of interest that could be perceived as prejudicing the impartiality of this guidance. This work did not receive any specific grant from any funding agency in the public, commercial or not-for-profit sector. Due to the emerging nature of the COVID-19 crisis, this document is not based on extensive systematic review or meta-analysis but on rapid expert consensus. 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