Lung Mechanics and Structure in Aged C57BL/6x129 Mice

Aging‐related changes in lung mechanics of human subjects are characterized by a decrease in resistance and an increase in static compliance (decrease in elastic recoil). Together, these changes result in an increase in residual volume in the absence of an increase in total lung capacity. In C57BL/6x129 mice, it was reported that lung compliance increases with aging while elastic recoil pressure does not change. However, in these studies, “old” mice at 24 months of age were compared to “young” mice at 2 months of age, but at this younger age, alveologenesis is incomplete (completion does not occur until ~6 months of age). Accordingly, it remains to be established if the same aging‐related changes in lung mechanics are observed using fully developed adult C57BL/6x129 mice for comparison. To this end, we compared lung mechanics in C57BL/6x129 mice at 6 months (100% survival, n = 6), 18 months (90% survival, n = 6), and 24 months (75% survival, n = 6) of age. Respiratory system static mechanics (Resistance, R rs ; Compliance, C rs ; Elastance, E rs ) were assessed following tracheal intubation using the FlexiVent. There was a progressive aging‐related decrease in R rs (6 month, 0.47 ± 0.02; 18 month, 0.41 ± 0.02; 24 month, 0.35 ± 0.02 cmH 2 O.s/ml), an increase in C rs (6 month, 0.046 ± 0.002; 18 month, 0.052 ± 0.002; 24 month, 0.062 ± 0.002 ml/cmH 2 O), and a decrease in E rs (6 month, 21.73 ± 1.19; 18 month, 19.30 ± 0.87; 24 month, 16.62 ± 1.25 cmH 2 O/ml). Additionally, lungs were fixed following tracheal instillation of 4% paraformaldehyde at 25 cmH 2 O. Thereafter, lungs were dehydrated, paraffin embedded, sectioned (6 μm thick), and stained (hematoxylin and eosin). Using standard stereological approaches, lung sections were analyzed in a uniform systematic but random fashion to assess alveolar morphology (measurement of average distance between alveolar walls based on mean linear intercept, L m ). There was a progressive aging‐related increase in L m (6 month, 34 ± 2; 18 month, 40 ± 2; 24 month, 45 ± 2 μm) consistent with an aging‐related emphysematous‐like change in lung morphometry. Taken together, these results in appropriately aged C57BL/6x129 mice demonstrate an aging‐related change in lung mechanics and morphometry consistent with what is observed in aging humans. Therefore, the results of the present study confirm the use of rodent models for studying aging‐related changes in lung mechanics and morphometry. Support or Funding Information National Institute of Health grants R01‐AG044615 (CBM & GCS) and T32‐HL105355 (JEE).