Authors
Di Palo, J., Ibinson, J. T., Lin, L., Suh, B., Gwin, M. S., Zaeh, S., Szafron, J. M., Manning, E. P.
Abstract
Mammalian lungs operate within a thoracic cage composed of parietal pleura, rib cage, skeletal muscle, and diaphragm, yet clinical ventilator metrics largely reflect the combined mechanics of lung and surrounding structures and the thoracic cage. We hypothesized that thoracic boundary conditions selectively alter measured lung biomechanics. We performed paired pulmonary function testing (FlexiVent) in C57BL6 mice of both sexes spanning development through adulthood, measuring quasi-static pressure-volume behavior and dynamic forced-oscillation parameters in vivo (supine, mechanically ventilated) and again ex vivo in the same lungs. In a subset, we additionally compared in vivo and ex vivo microCT-derived lung volumes, including a pressure-fixed ex vivo protocol using snap freezing at controlled inflation pressure. Quasi-static pressure-volume curves were similar between conditions, with near-identity at higher pressures and only modest divergence at low pressures, consistent with thoracic structures primarily modulating recruitment/de-recruitment rather than intrinsic elastic recoil. Maximal volume at 30 cmH2O showed strong in vivo-ex vivo correlation and minimal bias, and static compliance and PV-loop hysteresis exhibited small biases relative to reported disease-model effect sizes. In contrast, dynamic mechanics demonstrated a clear in vivo elevation of tissue damping (G) with only modest change in tissue elastance (H) and little change in Newtonian resistance (Rn), producing a meaningful increase in hysteresivity (G/H). This dissociation implicates frequency-dependent mechanical heterogeneity (time-constant mismatch/pendelluft) imposed or amplified by nonuniform thoracic loading. Ex vivo microCT enabled reliable whole-lung segmentation and correlated with ex vivo PFT volumes at matched pressures, whereas in vivo volumetry showed weaker agreement. These results indicate that thoracic structures contribute modest restriction but disproportionately increase dynamic dissipation and heterogeneity, suggesting that ex vivo functional testing and oscillometry-like metrics may better detect biomechanical changes inherent to lung parenchyma.
Preprint server:
bioRxiv
The authors list and abstract were imported from bioRxiv on 30 Jun 2026.
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