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Abstract

Due to its ability to induce heterogenous, patient-specific damage in pulmonary alveoli and capillaries, COVID-19 poses challenges in defining a uniform profile to elucidate infection across all patients. Computational models that integrate changes in ventilation and perfusion with heterogeneous damage profiles offer valuable insights into the impact of COVID-19 on pulmonary health. This study aims to develop an in silico hypothesis-testing platform specifically focused on studying microvascular pulmonary perfusion in COVID-19-infected lungs. Through this platform, we explore the effects of various acinar-level pulmonary perfusion abnormalities on global lung function. Our modelling approach simulates changes in pulmonary perfusion and the resulting mismatch of ventilation and perfusion in COVID-19-afflicted lungs. Using this coupled modelling platform, we conducted multiple simulations to assess different scenarios of perfusion abnormalities in COVID-19-infected lungs. The simulation results showed an overall decrease in ventilation-perfusion (V/Q) ratio with inclusion of various types of perfusion abnormalities such as hypoperfusion with and without microangiopathy. This model serves as a foundation for comprehending and comparing the spectrum of findings associated with COVID-19 in the lung, paving the way for patient-specific modelling of microscale lung damage in emerging pulmonary pathologies like COVID-19.

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Keywords

Lung mechanics lung perfusion pulmonary circulation COVID-19 computational modelling ventilation-perfusion ratio

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References

Dimbath

Maddipati

Stahl

, et al. Implications of microscale lung damage for COVID-19 pulmonary ventilation dynamics: a narrative review. Life Sci 2021; 274: 119341.

Gattinoni

Coppola

Cressoni

, et al. COVID-19 does not lead to a “typical” acute respiratory distress syndrome. Am J Respir Crit Care Med 2020; 201: 1299–1300.

Busana

Gasperetti

Giosa

, et al. Prevalence and outcome of silent hypoxemia in COVID-19. Minerva Anestesiol 2021; 87: 325–333.

Busana

Giosa

Cressoni

, et al. The impact of ventilation–perfusion inequality in COVID-19: a computational model. J Appl Physiol 2021; 130: 865–876.

Poschenrieder

Meiler

Lubnow

, et al. Severe COVID-19 pneumonia: perfusion analysis in correlation with pulmonary embolism and vessel enlargement using dual-energy CT data. PLoS One 2021; 16: e0252478.

Sobin

Tremer

Fung

. Morphometric basis of the sheet-flow concept of the pulmonary alveolar microcirculation in the cat. Circ Res 1970; 26: 397–414.

Weibel

. Morphometry of the human lung: the state of the art after two decades. Bull Eur Physiopathol Respir 1979; 15: 999–1013.

Haber

Clark

Tawhai

. Blood flow in capillaries of the human lung. J Biomech Eng 2013; 135: 101006.

West

. Fragility of pulmonary capillaries. J Appl Physiol 2013; 115: 1–15.

10.

West

Luks

. West’s respiratory physiology. Philadelphia, PA: Lippincott Williams Wilkins, 2020.

11.

West

Dollery

. Distribution of blood flow and the pressure-flow relations of the whole lung. J Appl Physiol 1965; 20: 175–183.

12.

Huang

Doerschuk

Kamm

. Computational modeling of RBC and neutrophil transit through the pulmonary capillaries. J Appl Physiol 2001; 90: 545–564.

13.

Dhadwal

Wiggs

Doerschuk

, et al. Effects of anatomic variability on blood flow and pressure gradients in the pulmonary capillaries. J Appl Physiol 1997; 83: 1711–1720.

14.

Fung

Sobin

. Theory of sheet flow in lung alveoli. J Appl Physiol 1969; 26: 472–488.

15.

Fung

Y-C

. Biomechanics: circulation. New York: Springer Science Business Media, 2013.

16.

Roth

Yoshihara

Ismail

, et al. Computational modelling of the respiratory system: discussion of coupled modelling approaches and two recent extensions. Comput Methods Appl Mech Eng 2017; 314: 473–493.

17.

Ismail

. Reduced dimensional modeling of the entire human lung. Germany: Technische Universität München, 2014.

18.

Burrowes

Doel

Kim

, et al. A combined image-modelling approach assessing the impact of hyperinflation due to emphysema on regional ventilation–perfusion matching. Comput Methods Biomech Biomed Eng Imaging Visualization 2017; 5: 110–126.

19.

Clark

Burrowes

Tawhai

. Contribution of serial and parallel microperfusion to spatial variability in pulmonary inter-and intra-acinar blood flow. J Appl Physiol 2010; 108: 1116–1126.

20.

Middleton

Dimbath

Pant

, et al. Towards a multi-scale computer modeling workflow for simulation of pulmonary ventilation in advanced COVID-19. Comput Biol Med 2022; 145: 105513.

21.

Cooper

Baker

Bernabeu

, et al. Chaste: cancer, heart and soft tissue environment. J Open Source Softw 2020; 5: 1848.

22.

Bordas

Lefevre

Veeckmans

, et al. Development and analysis of patient-based complete conducting airways models. PLoS One 2015; 10: e0144105.

23.

Clark

Tawhai

Hoffman

, et al. The interdependent contributions of gravitational and structural features to perfusion distribution in a multiscale model of the pulmonary circulation. J Appl Physiol 2011; 110: 943–955.

24.

Haefeli-Bleuer

Weibel

. Morphometry of the human pulmonary acinus. Anat Rec 1988; 220: 401–414.

25.

Bshouty

Younes

. Distensibility and pressure-flow relationship of the pulmonary circulation. I. Single-vessel model. J Appl Physiol 1990; 68: 1501–1513.

26.

Zhou

Gao

Huang

, et al. Vascular impedance analysis in human pulmonary circulation. In: ASME international mechanical engineering congress and exposition, New Orleans, Louisiana, 2002, pp.433–434.

27.

Clark

Tawhai

. Temporal and spatial heterogeneity in pulmonary perfusion: a mathematical model to predict interactions between macro-and micro-vessels in health and disease. ANZIAM J 2018; 59: 562–580.

28.

Sobin

Fung

Tremer

, et al. Distensibility of human pulmonary capillary blood-vessels in the interalveolar septa. In: Microvascular research 1979. San Diego, CA: Academic Press Inc JNL-Comp Subscriptions 525 B St, Ste 1900, 1979, pp.S87–S87.

29.

Roth

Ismail

Yoshihara

, et al. A comprehensive computational human lung model incorporating inter-acinar dependencies: application to spontaneous breathing and mechanical ventilation. Int J Numer Method Biomed Eng 2017; 33: e02787.

30.

Cobes

Guernou

Lussato

, et al. Ventilation/perfusion SPECT/CT findings in different lung lesions associated with COVID-19: a case series. Eur J Nucl Med Mol Imaging 2020; 47: 2453–2460.

31.

Ackermann

Verleden

Kuehnel

, et al. Pulmonary vascular endothelialitis, thrombosis, and angiogenesis in COVID-19. N Engl J Med 2020; 383: 120–128.

32.

Beigee

Toutkaboni

Khalili

, et al. Diffuse alveolar damage and thrombotic microangiopathy are the main histopathological findings in lung tissue biopsy samples of COVID-19 patients. Pathol Res Pract 2020; 216: 153228.

33.

Shi

Lai

Teboul

J-L

, et al. COVID-19 ARDS is characterized by higher extravascular lung water than non-COVID-19 ARDS: the PiCCOVID study. Crit Care 2021; 25: 1–12.

34.

Mangalmurti

Reilly

Cines

, et al. COVID-19–associated acute respiratory distress syndrome clarified: a vascular endotype? Am J Respir Crit Care Med 2020; 202: 750–753.

35.

Herrmann

Mori

Bates

, et al. Modeling lung perfusion abnormalities to explain early COVID-19 hypoxemia. Nat Commun 2020; 11: 4883.

36.

Burrowes

Hunter

Tawhai

. Anatomically based finite element models of the human pulmonary arterial and venous trees including supernumerary vessels. J Appl Physiol 2005; 99: 731–738.

37.

Fujioka

Halpern

Gaver

III . A model of surfactant-induced surface tension effects on the parenchymal tethering of pulmonary airways. J Biomech 2013; 46: 319–328.

38.

Lin

S-Y

Chou

A-H

Tsai

Y-F

, et al. Evaluation of the use of the fourth version FloTrac system in cardiac output measurement before and after cardiopulmonary bypass. J Clin Monit Comput 2018; 32: 807–815.

39.

Shen

Hiebert

Rahman

, et al. Understanding obesity-related high output heart failure and its implications. Int J Heart Failure 2021; 3: 160.

40.

Mogensen

Steimle

Karbing

, et al. A model of perfusion of the healthy human lung. Comput Methods Programs Biomed 2011; 101: 156–165.

41.

Ball

Stewart

Newsham

, et al. Regional pulmonary function studied with xenon 133. J Clin Invest 1962; 41: 519–531.

42.

Cao

Wang

Schapiro

, et al. Effects of respiratory cycle and body position on quantitative pulmonary perfusion by MRI. J Magn Reson Imaging 2011; 34: 225–230.

43.

Marquis

Jezek

Pinsky

, et al. Hypoxic pulmonary vasoconstriction as a regulator of alveolar-capillary oxygen flux: a computational model of ventilation-perfusion matching. PLoS Comput Biol 2021; 17: e1008861.

44.

Sarkar

Niranjan

Banyal

. Mechanisms of hypoxemia. Lung India 2017; 34: 47.

45.

Bhutta

Alghoula

Berim

. Hypoxia. StatPearls [Internet]. St. Petersburg, FL: StatPearls Publishing, 2022.

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Physics-based in silico modelling of microvascular pulmonary perfusion in COVID-19

Abstract

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