DocumentCode
7839
Title
Optimization of Mechanical Ventilator Settings for Pulmonary Disease States
Author
Das, Aruneema ; Menon, Prathyush P. ; Hardman, J.G. ; Bates, D.G.
Author_Institution
Coll. of Eng., Math. & Phys. Sci., Univ. of Exeter, Exeter, UK
Volume
60
Issue
6
fYear
2013
fDate
Jun-13
Firstpage
1599
Lastpage
1607
Abstract
The selection of mechanical ventilator settings that ensure adequate oxygenation and carbon dioxide clearance while minimizing the risk of ventilator-associated lung injury (VALI) is a significant challenge for intensive-care clinicians. Current guidelines are largely based on previous experience combined with recommendations from a limited number of in vivo studies whose data are typically more applicable to populations than to individuals suffering from particular diseases of the lung. By combining validated computational models of pulmonary pathophysiology with global optimization algorithms, we generate in silico experiments to examine current practice and uncover optimal combinations of ventilator settings for individual patient and disease states. Formulating the problem as a multiobjective, multivariable constrained optimization problem, we compute settings of tidal volume, ventilation rate, inspiratory/expiratory ratio, positive end-expiratory pressure and inspired fraction of oxygen that optimally manage the tradeoffs between ensuring adequate oxygenation and carbon dioxide clearance and minimizing the risk of VALI for different pulmonary disease scenarios.
Keywords
biomedical equipment; diseases; injuries; lung; patient care; ventilation; VALI risk; carbon dioxide clearance; global optimization algorithm; intensive care clinicians; mechanical ventilator settings optimization; oxygenation; pulmonary disease states; ventilator associated lung injury; vpulmonary pathophysiology; Atmospheric modeling; Carbon dioxide; Diseases; Lungs; Mathematical model; Optimization; Ventilation; Computer simulation; lung disease; mechanical ventilation; multiobjective optimization; pulmonary physiology; systems engineering; Biomedical Engineering; Computer Simulation; Humans; Lung; Lung Diseases; Models, Biological; Pulmonary Alveoli; Respiration, Artificial; Tidal Volume; Ventilators, Mechanical;
fLanguage
English
Journal_Title
Biomedical Engineering, IEEE Transactions on
Publisher
ieee
ISSN
0018-9294
Type
jour
DOI
10.1109/TBME.2013.2239645
Filename
6410003
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