Your search keyword '"Shiner RJ"' showing total 2 results

1. Integrated approach for in vivo evaluation of respiratory muscles mechanics.

Author

Ratnovsky A, Zaretsky U, Shiner RJ, and Elad D

Subjects

Adult, Computer Simulation, Diagnosis, Computer-Assisted instrumentation, Equipment Design, Equipment Failure Analysis, Female, Humans, Male, Middle Aged, Reproducibility of Results, Sensitivity and Specificity, Spirometry instrumentation, Spirometry methods, Systems Integration, Diagnosis, Computer-Assisted methods, Electromyography methods, Models, Biological, Muscle Contraction, Respiratory Function Tests instrumentation, Respiratory Function Tests methods, Respiratory Mechanics physiology, Respiratory Muscles physiology

Abstract

The respiratory muscles constitute the respiratory pump, which determines the efficacy of ventilation. Any functional disorder in their performance may cause insufficient ventilation. This study was designed to quantitatively explore the relative contribution of major groups of respiratory muscles to global lung ventilation throughout a range of maneuvers in healthy subjects. A computerized experimental system was developed for simultaneous noninvasive measurement of inspired/expired airflow, mouth pressure and up to 8 channels of EMG surface signals from major respiratory muscles which are located near the skin (e.g., sternomastoid, external intercostal, rectus abdominis and external oblique) during various respiratory maneuvers. Lung volumes values were calculated by integration of airflow data. Hill's muscle model was utilized to calculate the forces generated by the muscles from the acquired EMG data. Analysis of EMG measurements and respiratory muscles forces revealed the following characteristics: (a) muscle activity increased with increased breathing effort, (b) inspiratory muscles contributed to inspiration even at relatively low flow rates, while expiratory muscles are recruited at higher flow rates, (c) the forces generated by the muscle depended on the muscle properties as well as on their EMG performance and (d) the pattern of the muscle's force curves varied between subjects, but were generally consistent for the same subject regardless of breathing effort.

Published

2003

2. Analysis of stress distribution in the alveolar septa of normal and simulated emphysematic lungs.

Author

Gefen A, Elad D, and Shiner RJ

Subjects

Animals, Capillaries physiology, Capillaries ultrastructure, Collagen physiology, Collagen ultrastructure, Computer Simulation, Disease Progression, Elastin physiology, Elastin ultrastructure, Finite Element Analysis, Image Processing, Computer-Assisted, Lung Compliance physiology, Mice, Microscopy, Electron, Scanning, Models, Biological, Pressure, Pulmonary Alveoli blood supply, Pulmonary Alveoli ultrastructure, Pulmonary Emphysema pathology, Respiration, Stress, Mechanical, Pulmonary Alveoli physiology, Pulmonary Emphysema physiopathology

Abstract

The alveolar septum consists of a skeleton of fine collagen and elastin fibers, which are interlaced with a capillary network. Its mechanical characteristics play an important role in the overall performance of the lung. An alveolar sac model was developed for numerical analysis of the internal stress distribution and septal displacements within the alveoli of both normal and emphysematic saline-filled lungs. A scanning electron micrograph of the parenchyma was digitized to yield a geometric replica of a typical two-dimensional alveolar sac. The stress-strain relationship of the alveolar tissue was adopted from experimental data. The model was solved by using commercial finite-element software for quasi-static loading of alveolar pressure. Investigation of the state of stresses and displacements in a healthy lung simulation yielded values that compared well with experimentally reported data. Alteration of the mechanical characteristics of the alveolar septa to simulate elastin destruction in the emphysematic model induced significant stress concentrations (e.g., at a lung volume of 60% total capacity, tensions at certain parts in an emphysematic lung were up to 6 times higher than those in a normal lung). The combination of highly elevated stress sites together with the cyclic loading of breathing may explain the observed progressive damage to elastin fibers in emphysematic patients.

Published

1999