Endothelial Function, Inflammation and Organ Dysfunction in COVID-19
關鍵詞
抽象
描述
COVID-19 is a rapidly evolving pandemic with approximately 5% of all patients requiring admission to an intensive care unit. In critically ill patients infected with COVID-19, acute respiratory distress syndrome (ARDS) is found in 40%, 11.9% required continuous renal replacement therapy (RRT), and 13.4% had vasodilatory shock.
Currently, supportive treatment is the mainstay treatment, with fluid administration and vasopressors for haemodynamic support and lung-protective ventilation in patients with severe respiratory failure.3 Targeted drugs, antiviral therapies, and vaccines are still currently being developed, but there is currently insufficient evidence to recommend any drug over another.
Dysregulation of vasomotor tone and alteration of microcirculatory function are common in patients infected with COVID-19. The underlying pathophysiology and contributing factors are unknown. The association with subsequent organ dysfunction and outcome is also unclear.
Circulating bio-adrenomedullin regulates vascular tone and endothelial permeability during sepsis, and has been shown to associate with 28-day mortality, vasopressor requirement, RRT, and positive fluid balance. Proenkephalin is a biomarker of glomerular function, and was shown to elevate in patients with acute kidney injury (AKI), especially in those with persistent AKI, and major adverse kidney events. Dipeptidyl peptidase 3 (DPP-3) is a myocardial depressant factor, which is involved in angiotensin II cleavage. High DPP-3 levels were associated with severe organ dysfunction and short-term mortality. In critically ill patients, COVID-19 has been reported to be associated with cardiovascular dysfunction and high mortality.
The renin-angiotensin-aldosterone system (RAAS) may be linked to the pathogenesis of COVID-19. The coronavirus receptor utilizes angiotensin converting enzyme 2 (ACE2) to enter target cells. Endogenous angiotensin II is hypothesized to prevent binding of coronavirus to ACE2, causing internalization and downregulation of ACE2, and causing lysosome-mediated destruction of ACE2. There are no human studies in COVID-19 patients to confirm this hypothesis yet.
There is very little knowledge of underlying pathogenesis in patients with COVID-19 and vasodilatory shock. Therefore, we aim to investigate serial changes of relevant biomarkers in this population to give further understanding of this disease and to investigate the association with clinically important outcomes. The data will serve to develop strategies for individualized management of this high-risk group.
日期
| 最後驗證: | 04/30/2020 |
| 首次提交: | 05/26/2020 |
| 提交的預估入學人數: | 05/26/2020 |
| 首次發布: | 05/28/2020 |
| 上次提交的更新: | 05/26/2020 |
| 最近更新發布: | 05/28/2020 |
| 實際學習開始日期: | 05/31/2020 |
| 預計主要完成日期: | 05/30/2021 |
| 預計完成日期: | 05/30/2021 |
狀況或疾病
相
手臂組
| 臂 | 干預/治療 |
|---|---|
| COVID-19 patients Adult COVID-19 patients admitted to intensive care units |
資格標準
| 有資格學習的年齡 | 18 Years 至 18 Years |
| 有資格學習的性別 | All |
| 取樣方式 | Non-Probability Sample |
| 接受健康志願者 | 是 |
| 標準 | Inclusion Criteria: 1. Adult patients (≥ 18 years old) admitted to intensive care units 2. Confirmed or suspected severe acute respiratory syndrome coronavirus 2 (SARS-CoV2) infection resulting in coronavirus disease 2019 (COVID-19) Exclusion Criteria: None |
結果
主要結果指標
1. Plasma bio-adrenomedullin, proenkephalin, dipeptidyl peptidase-3, renin and angiotensin II [Daily from admission, and around the onset of vasodilatory shock until day 7]
次要成果指標
1. Duration of vasodilatory shock [7 and 28 days]
2. Acute kidney injury [7 and 28 days]
3. Need for renal replacement therapy [7 and 28 days]
4. Duration of ventilation [7 and 28 days]
5. Duration of extracorporeal membrane oxygenation [7 and 28 days]
6. Mortality [28 days]
