In silico study of airway/lung mechanics in normal human breathing

Marconi, Silvia; Lazzari, Claudio De

doi:10.1016/j.matcom.2020.05.014

Cited by 7 publications

(8 citation statements)

References 27 publications

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“…As such, it is unsurprising to see the increasing deployment of in silico models in this area. 86 For example, a recent study proposed the use of a lumped parameter model, CARDIOSIM, for educational purposes 87 in which the system can demonstrate the physiology involved in MV 88 and simulate the interaction between MV and devices that support the functioning of the cardiovascular system. 89 Systems that can illustrate the safe principles of MV have been proposed to help enable understanding of the effects of pre-existing disease on therapeutic management.…”

Section: Education and Trainingmentioning

confidence: 99%

Modeling Mechanical Ventilation In Silico—Potential and Pitfalls

Hannon

Mistry

Das

et al. 2022

Semin Respir Crit Care Med

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Computer simulation offers a fresh approach to traditional medical research that is particularly well suited to investigating issues related to mechanical ventilation. Patients receiving mechanical ventilation are routinely monitored in great detail, providing extensive high-quality data-streams for model design and configuration. Models based on such data can incorporate very complex system dynamics that can be validated against patient responses for use as investigational surrogates. Crucially, simulation offers the potential to “look inside” the patient, allowing unimpeded access to all variables of interest. In contrast to trials on both animal models and human patients, in silico models are completely configurable and reproducible; for example, different ventilator settings can be applied to an identical virtual patient, or the same settings applied to different patients, to understand their mode of action and quantitatively compare their effectiveness. Here, we review progress on the mathematical modeling and computer simulation of human anatomy, physiology, and pathophysiology in the context of mechanical ventilation, with an emphasis on the clinical applications of this approach in various disease states. We present new results highlighting the link between model complexity and predictive capability, using data on the responses of individual patients with acute respiratory distress syndrome to changes in multiple ventilator settings. The current limitations and potential of in silico modeling are discussed from a clinical perspective, and future challenges and research directions highlighted.

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Section: Education and Trainingmentioning

confidence: 99%

Modeling Mechanical Ventilation In Silico—Potential and Pitfalls

Hannon

Mistry

Das

et al. 2022

Semin Respir Crit Care Med

View full text Add to dashboard Cite

show abstract

“…Combining these modules, clinicians may virtually reproduce patient’s hemodynamic conditions, simulate the effects of different therapeutic interventions in real time and obtain accurate prediction of device performance. Thus, such computational simulators (e.g., CARDIOSIM, CircAdapt Simulator, HemoLab and Harvi) could support physicians in clinical decision making [ 31 , 32 , 33 , 34 ].…”

Section: Computational Cardiovascular Simulatorsmentioning

confidence: 99%

Computational Simulator Models and Invasive Hemodynamic Monitoring as Tools for Precision Medicine in Pulmonary Arterial Hypertension

Manzi

Miotti

Mariani

et al. 2021

JCM

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Precision medicine, providing the right therapeutic strategy for the right patient, could revolutionize management and prognosis of patients affected by cardiovascular diseases. Big data and artificial intelligence are pivotal for the realization of this ambitious design. In the setting of pulmonary arterial hypertension (PAH), the use of computational models and data derived from ambulatory implantable hemodynamic monitors could provide useful information for tailored treatment, as requested by precision medicine.

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“…Examples are provided by the single-compartment model ( Bates, 2009 ; Ghafarian et al, 2016 ; Gertler, 2021 ) corresponding to a first-order linear differential system, the two-compartment model ( Bates, 2009 ; Carvalho and Zin, 2011 ; Ghafarian et al, 2016 ) corresponding to a second-order differential system, and the viscoelastic model ( Ganzert et al, 2009 ). Over the last few years, different types of respiratory mechanics models have been put forward, including nonlinear models involving elastance and resistance of the respiratory system ( Chiew et al, 2015 ; Redmond et al, 2017 ; Ellwein Fix et al, 2018 ; Marconi and De Lazzari, 2020 ). These studies generally provide a good theoretical modelling and may be used to simulate the respiratory system.…”

Section: Introductionmentioning

confidence: 99%

An enhanced respiratory mechanics model based on double-exponential and fractional calculus

Li,

Pei,

Wang

et al. 2023

Front. Physiol.

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We address mathematical modelling of respiratory mechanics and put forward a model based on double-exponential and fractional calculus for parameter estimation, model simulation, and evaluation based on actual data. Our model has been implemented on a publicly available executable code with adjustable parameters, making it suitable for different applications. Our analysis represents the first application of fractional calculus and double-exponential modelling to respiratory mechanics, and allows us to propose a hybrid model fitting experimental data in different ventilation modes. Furthermore, our model can be used to study the mechanical features of the respiratory system, improve the safety of ventilation techniques, reduce ventilation damages, and provide strong support for fast and adaptive determination of ventilation parameters.

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In silico study of airway/lung mechanics in normal human breathing

Cited by 7 publications

References 27 publications

Modeling Mechanical Ventilation In Silico—Potential and Pitfalls

Modeling Mechanical Ventilation In Silico—Potential and Pitfalls

Computational Simulator Models and Invasive Hemodynamic Monitoring as Tools for Precision Medicine in Pulmonary Arterial Hypertension

An enhanced respiratory mechanics model based on double-exponential and fractional calculus

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