Effect of aging on maximum shortening velocity, peak power output and endurance of rat diaphragm muscle

Abstract

Sarcopenia is defined as age-related atrophy of muscle fibers as well as a decrease in specific force (force per cross-sectional area). In the rat diaphragm muscle (DIAm), sarcopenia primarily affects type IIx/IIb fibers that generate greater specific force, have the fastest maximum shortening velocities, but display greater fatigue with repeated activation. We hypothesized that as a result of sarcopenia, maximum shortening velocity and power output of the DIAm decrease with age. DIAm strips ~2-3 mm wide were excised from 6-month and 24-month female (n=4 per age group) and male (n=4 per age group) rats. DIAm strips were suspended in a tissue chamber containing Rees–Simpson solution maintained at 26oC, with the costal margin clamped and the central tendon attached to a Cambridge Dual-Mode force/length transducer. To determine maximum isometric specific force, DIAm strips were stimulated using platinum plate electrodes with supramaximal current (~250 mA) pulses (1 ms) at 75 Hz delivered in 1-s duration train. The muscle strips were then allowed to shorten over a 30-ms period against different percentages of maximum isometric load. Based on the load/velocity relationship, the maximum shortening velocity (Vmax) and peak power output were determined. Subsequently, the muscle strip was repetitively stimulated and allowed to shorten at 30% maximum load (approximating peak power output). In this protocol, the muscle strip was stimulated at 75 Hz an generated isometric force during the initial 225 ms of the 330 ms duration train the muscle. Thereafter, the load was reduced to 30% maximum and the muscle strip was allowed to shorten for the subsequent 105 ms. Finally, the DIAm strip was stretched to ~150% its resting length (corresponding to optimal sarcomere length) and rapidly frozen in melting isopentane. Transverse serial sections of DIAm fibers were cut, and fiber types identified by immunoreactivity to specific myosin heavy chain (MyHC) isoforms. As previously observed, the cross-sectional areas of type IIx/IIb DIAm fibers and maximum isometric specific force were reduced in 24-month compared to 6-month rats confirming sarcopenia. The maximum shortening velocity of the DIAm in 24-month rats was slower than in the 6-month rats and peak power output of the DIAm was reduced in 24-month rats. The duration during which peak power output could be maintained (i.e., endurance) of the DIAm was prolonged in 24-month compared to 6-month rats (120 s vs 60 s, respectively). These results support our hypothesis that aging affects maximum shortening velocity and peak power output of the DIAm. It is important to note that endurance of the DIAm is preserved, consistent with resilience of breathing motor function in old age. Research supported by NIH grant AG44615 This is the full abstract presented at the American Physiology Summit 2023 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.