Interaction between Physical Activity and Smoking on Lung, Muscle, and Bone in Mice.

Physical inactivity is an important contributor to skeletal muscle weakness, osteoporosis, and weight loss in chronic obstructive pulmonary disease. However, the effects of physical inactivity, in interaction with smoking, on lung, muscle, and bone are poorly understood. To address this issue, male mice were randomly assigned to an active (daily running), moderately inactive (space restriction), or extremely inactive group (space restriction followed by hindlimb suspension to mimic bed rest) during 24 weeks and simultaneously exposed to either cigarette smoke or room air. The effects of different physical activity levels and smoking status and their respective interaction were examined on lung function, body composition, in vitro limb muscle function, and bone parameters. Smoking caused emphysema, reduced food intake with subsequent loss of body weight, and fat, lean, and muscle mass, but increased trabecular bone volume. Smoking induced muscle fiber atrophy, which did not result in force impairment. Moderate inactivity only affected lung volumes and compliance, whereas extreme inactivity increased lung inflammation, lowered body and fat mass, induced fiber atrophy with soleus muscle dysfunction, and reduced exercise capacity and all bone parameters. When combined with smoking, extreme inactivity also aggravated lung inflammation and emphysema, and accelerated body and muscle weight loss. This study shows that extreme inactivity, especially when imposed by absolute rest, accelerates lung damage and inflammation. When combined with smoking, extreme inactivity is deleterious for muscle bulk, bone, and lungs. These data highlight that the consequences of physical inactivity during the course of chronic obstructive pulmonary disease should not be neglected.

Long-term nose-only cigarette smoke exposure induces emphysema and mild skeletal muscle dysfunction in mice.

Mouse models of chronic obstructive pulmonary disease (COPD) focus on airway inflammation and lung histology, but their use has been hampered by the lack of pulmonary function data in their assessment. Systemic effects such as muscle dysfunction are also poorly modeled in emphysematous mice. We aimed to develop a cigarette-smoke-induced emphysema mouse model in which serial lung function and muscular dysfunction could be assessed, allowing the disease to be monitored more appropriately. C57Bl6 mice were nose-only exposed to cigarette smoke or filtered air for 3-6 months. Lung function tests were repeated in the same mice after 3 and 6 months of cigarette smoke or air exposure and compared with lung histological changes. Contractile properties of skeletal muscles and muscle histology were also determined at similar time points in separate groups of mice. Serial lung function measurements documented hyperinflation after 3 and 6 months of cigarette smoke exposure, with a significant 31-37% increase in total lung capacity (TLC) and a significant 26-35% increase in compliance (Cchord) when compared with animals exposed to filtered air only (P<0.001 after 3 and after 6 months). These functional changes preceded the changes in mean linear intercept, which became only significant after 6 months of cigarette smoke exposure and which correlated very well with TLC (r=0.74, P=0.004) and Cchord (r=0.79, P=0.001). After 6 months of cigarette smoke exposure, a significant fiber-type shift from IIa to IIx/b was also observed in the soleus muscle (P<0.05), whereas a 20% reduction of force was present at high stimulation frequencies (80 Hz; P=0.09). The extensor digitorum longus (EDL) muscle was not affected by cigarette smoke exposure. These serial pulmonary function variables are sensitive outcomes to detect emphysema progression in a nose-only cigarette-smoke-exposed animal model of COPD. In this model, muscular changes became apparent only after 6 months, particularly in muscles with a mixed fiber-type composition.

Repeated invasive lung function measurements in intubated mice: an approach for longitudinal lung research.

Invasive lung function measurements are useful tools to describe respiratory disease models in mice but only result in one time-point measurements because of tracheostomy. We explored if intubation may overcome the need for tracheostomy thereby allowing invasive lung function monitoring of individual mice over time. Repeated invasive lung function measurements with Scireq(©) - FlexiVent or Buxco(©) - Forced Pulmonary Maneuvers(®) were performed three times in BALB/c mice with intervals of 10 days. Each lung function assessment following intubation was compared with a similar measurement in age-matched tracheostomized mice, the golden standard in lung function measurements. Tracheostomy and intubation gave similar results for resistance, elastance and compliance of the whole respiratory system as assessed by Flexivent. Likewise, Forced Pulmonary Maneuvers used to measure lung volumes such as total lung capacity, functional residual capacity, forced expiratory volume in 0.1 s and forced vital capacity, resulted in identical outcomes for both airway approaches. No interaction was found between the procedures for any of the pulmonary function variables. The observed changes over time were rather related to animal growth than to repetitive intubation. Eighty percent of the animals survived three consecutive intubations, which were hampered by transient breathing difficulties, weight loss and neutrophilic bronchoalveolar lavage immediately postextubation. Repetitive invasive lung function measurements by intubation are feasible and reproducible in healthy mice and results are comparable to the standard method. This may open new perspectives for longitudinal research in animal models of respiratory diseases.