Micromechanics of lung capillaries across mouse lifespan and in positive- vs negative-pressure ventilation

The lung undergoes continuous remodeling throughout normal development and aging, including changes to alveolar and capillary structure and function. While histological methods allow for static analysis of these age-related changes, characterizing the changes that occur in response to mechanical stimuli remains difficult, particularly over a dynamic, physiologically relevant range in a functioning lung. Alveolar and capillary distension – the change in diameter of alveoli and capillaries, respectively, in response to pressure changes – is one such process, where dynamically controlling and monitoring the diameter of the same capillary or alveolus is essential to inferring its mechanical properties. We overcome these limitations by utilizing the recently developed crystal ribcage to image the alveoli and vasculature of a functional mouse lung across the lifespan in postnatal (6–7 days), young adult (12–18 weeks), and aged (20+ months) mice. Using a range of biologically relevant vascular (0–15 cmH2O) and transpulmonary (3–12 cm H2O) pressures, we directly quantify vascular and alveolar distention in the functional lung as we precisely adjust pulmonary pressures. Our results show differences in age-related alveolar and vascular distensibility: when we increase transpulmonary alveolar or vascular pressure, vessels in postnatal lungs expand less and undergo less radial and axial strain under each respective pressure type, suggesting stiffer capillaries than in older lungs. However, while vessels in young adult and aged lungs respond similarly to variations in vascular pressure, differences in elasticity start to emerge at the alveolar scale in response to transpulmonary alveolar pressure changes. Our results further indicate that differing effects of ventilation mode (i.e., positive vs. negative) present themselves at the capillary level, with vessels under positive pressure undergoing more compression than when under negative-pressure conditions. These findings contribute both to the understanding of the functional changes that occur within the lung across the lifespan, as well as to the debate of ventilation effects on lung microphysiology.

• Publication year

  2025

• Venue

  npj Biological Physics and Mechanics

• Publication date

  2025-09-03

• Fields of study

  Medicine, Engineering

• Identifiers
  DOI 10.1038/s44341-025-00026-2PMID 40919424PMCID 12408335
• External record

  Open on Semantic Scholar

• Source metadata

  Semantic Scholar, PubMed

• No claims are published for this paper.

• No concepts are published for this paper.

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