PEER-REVIEWED PUBLICATION

2020

Introducing a Custom-Designed Volume-Pressure Machine for Novel Measurements of Whole Lung Organ Viscoelasticity and Direct Comparisons Between Positive- and Negative-Pressure Ventilation

Sattari S, Mariano CA, et al.

Frontiers in Bioengineering and Biotechnology

University of California – Riverside

RESEARCH SUMMARY

This study introduces a novel, automated volume-controlled pressure–measurement system for characterizing the viscoelastic macromechanics of whole lungs and enabling direct comparison between positive-pressure ventilation (PPV) and negative-pressure ventilation (NPV). Unlike traditional pressure-controlled systems, the device generates standardized, continuous volume–pressure curves without requiring lung degassing, while accounting for air compressibility in real time. Validation using ex vivo murine lungs, elastic balloons, and water bladders demonstrated accurate capture of compliance, hysteresis, preconditioning, and pressure-relaxation behavior. The system revealed clear dependencies of lung mechanics on inflation volume and rate and enabled the first direct experimental comparison between PPV and physiologically relevant NPV mechanics. The platform expands experimental capabilities for studying healthy and diseased pulmonary biomechanics and provides a foundation for improving ventilator strategies.

CellScale Biomaterials Testing collaborated in the design and fabrication of a custom volume-pressure lung testing system capable of controlled air displacement and real-time pressure measurement. The CellScale-built system enabled standardized inflation–deflation protocols, pressure relaxation holds, and rate-dependent testing of intact murine lungs under hydrated conditions. By allowing precise control of applied volume while recording lung pressure, the device provided direct quantification of lung compliance, hysteresis, and viscoelastic relaxation without the need for degassing. These CellScale-enabled measurements were central to the study’s core contribution: revealing macromechanical differences between positive- and negative-pressure ventilation and enabling new insights into lung viscoelastic behavior relevant to pulmonary disease and ventilator-induced injury.

AUTHORS

Samaneh Sattari; Crystal A. Mariano; Swathi Vittalbabu; Jalene V. Velazquez; Jessica Postma; Caleb Horst; Eric Teh; Tara M. Nordgren; Mona Eskandari.

PUBLICATION DETAILS

JOURNAL

Frontiers in Bioengineering and Biotechnology

YEAR

2020

INSTITUTIONS

University of California – Riverside

COUNTRIES

United States

INSTRUMENT USED

Custom

TESTING METHODS

Hydrated and Temperature Controlled TestingPressure TestingStress Relaxation TestingViscoelastic & Time-Dependent Testing

RESEARCH APPLICATIONS

Fibrosis & Tissue RemodelingLung and Pleural Tissue BiomechanicsMechanotransduction

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