Developing a Lung Model in the Age of COVID-19: A Digital Image Correlation and Inverse Finite Element Analysis Framework

Maghsoudi-Ganjeh, Mohammad; Mariano, Crystal A; Sattari, Samaneh; Arora, Hari; Eskandari, Mona

doi:10.3389/fbioe.2021.684778

Cited by 25 publications

(26 citation statements)

References 61 publications

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“…The increase in static compliance is unexpected because it indicates a softer lung that is easier to inflate at higher volumes. Lung tissue is known to experience strain-stiffening which would cause a decrease in static compliance, a stiffer lung, at higher inflation volumes 40 , 41 ; this effect has been demonstrated on the surface of the murine lung during inflation at 0.7 and 0.9 ml using digital image correlation, which allows analysis of simultaneous global and local behavior 42 , 43 . However, increasing the internal space available within the lung, as caused by the opening of a secondary (daughter) set of alveoli, would create more regions for air migration, alleviating the excess strain on alveoli and thus increasing the static compliance 36 , 44 .…”

Section: Discussionmentioning

confidence: 99%

Mouse lung mechanical properties under varying inflation volumes and cycling frequencies

Quiros

Nelson

Sattari

et al. 2022

Sci Rep

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Respiratory pathologies alter the structure of the lung and impact its mechanics. Mice are widely used in the study of lung pathologies, but there is a lack of fundamental mechanical measurements assessing the interdependent effect of varying inflation volumes and cycling frequency. In this study, the mechanical properties of five male C57BL/6J mice (29–33 weeks of age) lungs were evaluated ex vivo using our custom-designed electromechanical, continuous measure ventilation apparatus. We comprehensively quantify and analyze the effect of loading volumes (0.3, 0.5, 0.7, 0.9 ml) and breathing rates (5, 10, 20 breaths per minute) on pulmonary inflation and deflation mechanical properties. We report means of static compliance between 5.4–16.1 µl/cmH2O, deflation compliance of 5.3–22.2 µl/cmH2O, percent relaxation of 21.7–39.1%, hysteresis of 1.11–7.6 ml•cmH2O, and energy loss of 39–58% for the range of four volumes and three rates tested, along with additional measures. We conclude that inflation volume was found to significantly affect hysteresis, static compliance, starting compliance, top compliance, deflation compliance, and percent relaxation, and cycling rate was found to affect only hysteresis, energy loss, percent relaxation, static compliance and deflation compliance.

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Section: Discussionmentioning

confidence: 99%

Mouse lung mechanical properties under varying inflation volumes and cycling frequencies

Quiros

Nelson

Sattari

et al. 2022

Sci Rep

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“…Given the similarity between porcine and human lung size and anatomy, findings can help support studies aimed at lowering the risk of ventilation injuries and complications [ 35 ]. Furthermore, the variable inflation volume and breathing rate data collected in this work can inform finite element computational models to enable predictive ventilation techniques [ 36 ].…”

Section: Introductionmentioning

confidence: 99%

Examining lung mechanical strains as influenced by breathing volumes and rates using experimental digital image correlation

et al. 2022

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Background Mechanical ventilation is often employed to facilitate breathing in patients suffering from respiratory illnesses and disabilities. Despite the benefits, there are risks associated with ventilator-induced lung injuries and death, driving investigations for alternative ventilation techniques to improve mechanical ventilation, such as multi-oscillatory and high-frequency ventilation; however, few studies have evaluated fundamental lung mechanical local deformations under variable loading. Methods Porcine whole lung samples were analyzed using a novel application of digital image correlation interfaced with an electromechanical ventilation system to associate the local behavior to the global volume and pressure loading in response to various inflation volumes and breathing rates. Strains, anisotropy, tissue compliance, and the evolutionary response of the inflating lung were analyzed. Results Experiments demonstrated a direct and near one-to-one linear relationship between applied lung volumes and resulting local mean strain, and a nonlinear relationship between lung pressures and strains. As the applied air delivery volume was doubled, the tissue surface mean strains approximately increased from 20 to 40%, and average maximum strains measured 70–110%. The tissue strain anisotropic ratio ranged from 0.81 to 0.86 and decreased with greater inflation volumes. Local tissue compliance during the inflation cycle, associating evolutionary strains in response to inflation pressures, was also quantified. Conclusion Ventilation frequencies were not found to influence the local stretch response. Strain measures significantly increased and the anisotropic ratio decreased between the smallest and greatest tidal volumes. Tissue compliance did not exhibit a unifying trend. The insights provided by the real-time continuous measures, and the kinetics to kinematics pulmonary linkage established by this study offers valuable characterizations for computational models and establishes a framework for future studies to compare healthy and diseased lung mechanics to further consider alternatives for effective ventilation strategies.

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“…Investigations into the physiological and mechanical functions of the lung have since been rejuvenated due to the recent global Covid-19 pandemic. Computational mechanical models have the ability to enhance the predictive capabilities and determine more precise physiological estimates of lung properties, however, most of these studies are impeded by the lung’s complex mechanical responses and structural networks [ 117 ]. There is also an absence of mechanical experiments linking the load-bearing organ-level response to regional tissue behaviours.…”

Section: Constitutive Theory Of Lung Parenchymamentioning

confidence: 99%

“…Maghsoudi-Ganjeh et al. [ 117 ] address these shortcomings by introducing a novel reduced-order surface model of the lung, which incorporates the mechanical response of the bronchial network, parenchymal tissue, and the visceral pleura. Specifically, they provide the first inverse finite element analysis to computationally characterise the entire lung, supported through digital image correlation (DIC) analysis, resulting from applied pressure-volume loading [ 117 ].…”

Section: Constitutive Theory Of Lung Parenchymamentioning

confidence: 99%

“…[ 117 ] address these shortcomings by introducing a novel reduced-order surface model of the lung, which incorporates the mechanical response of the bronchial network, parenchymal tissue, and the visceral pleura. Specifically, they provide the first inverse finite element analysis to computationally characterise the entire lung, supported through digital image correlation (DIC) analysis, resulting from applied pressure-volume loading [ 117 ]. Inverse finite element analysis yields specimen-specific mechanical properties by minimising the error between displacement values approximated through general finite element methods and those determined through experimental techniques [ 111 , 117 ].…”

Section: Constitutive Theory Of Lung Parenchymamentioning

confidence: 99%

See 1 more Smart Citation

Lung Mechanics: A Review of Solid Mechanical Elasticity in Lung Parenchyma

Bhana

2023

J Elast

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The lung is the main organ of the respiratory system. Its purpose is to facilitate gas exchange (breathing). Mechanically, breathing may be described as the cyclic application of stresses acting upon the lung surface. These forces are offset by prominent stress-bearing components of lung tissue. These components result from the mechanical elastic properties of lung parenchyma. Various studies have been dedicated to understanding the macroscopic behaviour of parenchyma. This has been achieved through pressure-volume analysis, numerical methods, the development of constitutive equations or strain-energy functions, finite element methods, image processing and elastography. Constitutive equations can describe the elastic behaviour exhibited by lung parenchyma through the relationship between the macroscopic stress and strain. The research conducted within lung mechanics around the elastic and resistive properties of the lung has allowed scientists to develop new methods and equipment for evaluating and treating pulmonary pathogens. This paper establishes a review of mathematical studies conducted within lung mechanics, centering on the development and implementation of solid mechanics to the understanding of the mechanical properties of the lung. Under the classical theory of elasticity, the lung is said to behave as an isotropic elastic continuum undergoing small deformations. However, the lung has also been known to display heterogeneous anisotropic behaviour associated with large deformations. Therefore, focus is placed on the assumptions and development of the various models, their mechanical influence on lung physiology, and the development of constitutive equations through the classical and non-classical theory of elasticity. Lastly, we also look at lung blast mechanics. No explicit emphasis is placed on lung pathology.

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Developing a Lung Model in the Age of COVID-19: A Digital Image Correlation and Inverse Finite Element Analysis Framework

Cited by 25 publications

References 61 publications

Mouse lung mechanical properties under varying inflation volumes and cycling frequencies

Mouse lung mechanical properties under varying inflation volumes and cycling frequencies

Examining lung mechanical strains as influenced by breathing volumes and rates using experimental digital image correlation

Lung Mechanics: A Review of Solid Mechanical Elasticity in Lung Parenchyma

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