Literature DB >> 32894160

Assessment of pulmonary surfactant in COVID-19 patients.

Peter Schousboe1, Lothar Wiese2, Christian Heiring3, Henrik Verder1, Porntiva Poorisrisak3, Povl Verder1, Henning Bay Nielsen4.   

Abstract

Entities:  

Keywords:  ARDS; COVID-19; Pulmonary surfactant

Mesh:

Substances:

Year:  2020        PMID: 32894160      PMCID: PMC7475719          DOI: 10.1186/s13054-020-03268-9

Source DB:  PubMed          Journal:  Crit Care        ISSN: 1364-8535            Impact factor:   9.097


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The clinical presentation of coronavirus 2 (SARS-CoV-2) ranges from asymptomatic to severe respiratory failure, and correspondingly requirement for respiratory support ranging from varying levels of supplementary O2, to non-invasive and invasive ventilation. In a recent editorial by Gattinoni et al. [1], it is proposed that, based on different pathophysiology need for ventilator support, there are two groups of COVID-19 patients: one group that develops acute respiratory distress syndrome (ARDS) with low compliance, and another classified as non-ARDS with normal compliance and hypoxemia caused by a high level of intrapulmonary shunting. Furthermore, non-ARDS type COVID-19 pneumonia may transit to ARDS-type COVID-19 by self-inflicted or ventilator-induced lung injury. We propose that the direct effects on pulmonary tissue by SARS-CoV-2 in COVID-19 pneumonia in ARDS COVID-19 patients resembles neonatal respiratory distress syndrome (NRDS), caused by surfactant deficiency.

COVID-19 patients and pulmonary surfactant

SARS-CoV-2 enters and replicates in the alveolar type II cells impacting the production and turnover of pulmonary surfactants. This results in alveolar collapse and inflammation leading to increased capillary permeability, edema, and microvascular thrombosis; where the associated ARDS clinical picture closely resembles NRDS. Of importance, as ARDS progresses, vascular permeability increases and surfactant deactivates making the lung increasingly unstable [2]. Thus, clinical studies have provided promising data on the effect of surfactant treatment in patients with ARDS [3]. These pathophysiological findings have prompted several groups to investigate if surfactant administration could improve the COVID-19 patient outcome. Interventional trials are currently underway in the UK, USA, and Canada (ClinicalTrials.gov IDs: NCT04375735, NCT04362059, NCT04384731). Treatment of NRDS with rescue surfactant and continuous positive airway pressure (CPAP), when compared to mechanical ventilation, results in reduced development of pulmonary fibrosis; a complication also reported in intubated COVID-19 patients. Antenatal corticosteroid treatment may also accelerate fetal lung maturation in the risk of preterm birth. A multicentre trial evaluates whether surfactant plus budesonide improves survival in NRDS [4]. In COVID-19 patients, dexamethasone seems to improve the outcome. We suggest assessment of surfactant levels should be added to the evaluation of COVID-19 patients. A point-of-care test for fast measuring surfactant at birth in premature babies has been developed [5]. This method may be suitable for determining the surfactant in tracheal fluid obtained from critically ill adults. Knowledge of surfactant levels contributes to understanding pathophysiology in COVID-19 patients. Surfactant treatment may be considered included with other interventions for the treatment of COVID-19 induced respiratory failure.
  4 in total

1.  Bronchoscopic surfactant administration in patients with severe adult respiratory distress syndrome and sepsis.

Authors:  D Walmrath; A Günther; H A Ghofrani; R Schermuly; T Schneider; F Grimminger; W Seeger
Journal:  Am J Respir Crit Care Med       Date:  1996-07       Impact factor: 21.405

2.  Acute lung injury: how to stabilize a broken lung.

Authors:  Gary F Nieman; Penny Andrews; Joshua Satalin; Kailyn Wilcox; Michaela Kollisch-Singule; Maria Madden; Hani Aiash; Sarah J Blair; Louis A Gatto; Nader M Habashi
Journal:  Crit Care       Date:  2018-05-24       Impact factor: 9.097

3.  Predicting respiratory distress syndrome at birth using a fast test based on spectroscopy of gastric aspirates: 2. Clinical part.

Authors:  Christian Heiring; Henrik Verder; Peter Schousboe; Torben E Jessen; Lars Bender; Finn Ebbesen; Marianne Dahl; Christian Eschen; Jesper Fenger-Grøn; Agnar Höskuldsson; Morgaine Matthews; Jes Reinholdt; Nikolaos Scoutaris; Heidi Smedegaard
Journal:  Acta Paediatr       Date:  2019-05-31       Impact factor: 2.299

4.  COVID-19 pneumonia: ARDS or not?

Authors:  Luciano Gattinoni; Davide Chiumello; Sandra Rossi
Journal:  Crit Care       Date:  2020-04-16       Impact factor: 9.097
  4 in total
  12 in total

Review 1.  Alveolar type II cells and pulmonary surfactant in COVID-19 era.

Authors:  A Calkovska; M Kolomaznik; V Calkovsky
Journal:  Physiol Res       Date:  2021-12-16       Impact factor: 1.881

Review 2.  Insights Gained Into the Treatment of COVID19 by Pulmonary Surfactant and Its Components.

Authors:  Dan Li; Xianzheng Wang; Yingzhao Liao; Shouchuan Wang; Jinjun Shan; Jianjian Ji
Journal:  Front Immunol       Date:  2022-05-03       Impact factor: 8.786

Review 3.  Pneumothorax in otherwise healthy non-intubated patients suffering from COVID-19 pneumonia: a systematic review.

Authors:  Apostolos C Agrafiotis; Peter Rummens; Ines Lardinois
Journal:  J Thorac Dis       Date:  2021-07       Impact factor: 2.895

4.  Non-destructive vacuum-assisted measurement of lung elastic modulus.

Authors:  Jiawen Chen; Seyed Mohammad Mir; Meghan R Pinezich; John D O'Neill; Brandon A Guenthart; Matthew Bacchetta; Gordana Vunjak-Novakovic; Sarah X L Huang; Jinho Kim
Journal:  Acta Biomater       Date:  2021-06-27       Impact factor: 10.633

5.  Surfactant for the Treatment of ARDS in a Patient With COVID-19.

Authors:  Moshe Heching; Shaul Lev; Dorit Shitenberg; Dror Dicker; Mordechai R Kramer
Journal:  Chest       Date:  2021-01-22       Impact factor: 9.410

6.  Breath-Synchronized Nebulized Surfactant in a Porcine Model of Acute Respiratory Distress Syndrome.

Authors:  Robert M DiBlasi; Masaki Kajimoto; Jonathan A Poli; Gail Deutsch; Juergen Pfeiffer; Joseph Zimmerman; David N Crotwell; Patrik Malone; James B Fink; Coral Ringer; Rajesh Uthamanthil; Dolena Ledee; Michael A Portman
Journal:  Crit Care Explor       Date:  2021-02-15

Review 7.  Coronavirus-Induced Host Cubic Membranes and Lipid-Related Antiviral Therapies: A Focus on Bioactive Plasmalogens.

Authors:  Yuru Deng; Angelina Angelova
Journal:  Front Cell Dev Biol       Date:  2021-03-12

8.  ProLung™-budesonide Inhibits SARS-CoV-2 Replication and Reduces Lung Inflammation.

Authors:  Kameswari S Konduri; Ram Pattisapu; Jogi Pattisapu; Girija G Konduri; John Zwetchkenbaum; Bidhan Roy; Monalisa Barman; Adria Frazier; Brett L Hurst; Nejat Düzgüneş
Journal:  Arch Pharmacol Ther       Date:  2021

Review 9.  The Role of Pulmonary Surfactants in the Treatment of Acute Respiratory Distress Syndrome in COVID-19.

Authors:  Shengguang Wang; Zhen Li; Xinyu Wang; Shiming Zhang; Peng Gao; Zuorong Shi
Journal:  Front Pharmacol       Date:  2021-06-29       Impact factor: 5.810

Review 10.  Roles of steroid receptors in the lung and COVID-19.

Authors:  Damien A Leach; Greg N Brooke; Charlotte L Bevan
Journal:  Essays Biochem       Date:  2021-12-17       Impact factor: 8.000
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