Abstract
Populations with obesity are more likely to fall and exhibit balance instability. The reason for this is likely multifactorial, but there is some evidence that sensory function is impaired during obesity. We tested the hypothesis that muscle proprioceptor function is compromised in a mouse model of diet induced obesity. An in vitro muscle-nerve preparation was used to record muscle spindle afferent responses to physiological stretch and sinusoidal vibration. We compared the responses of C57/Bl6 male and female mice on a control diet (10% kcal fat) with those eating a high fat diet (HFD; 60% kcal fat) for 10 weeks (final age 14–15 weeks old). Following HFD feeding, adult mice of both sexes exhibited decreased muscle spindle afferent responses to muscle movement. Muscle spindle afferent firing rates during the plateau phase of stretch were significantly lower in both male and female HFD animals as were two measures of dynamic sensitivity (dynamic peak and dynamic index). Muscle spindle afferents in male mice on a HFD were also significantly less likely to entrain to vibration. Due to the importance of muscle spindle afferents to proprioception and motor control, decreased muscle spindle afferent responsiveness may contribute to balance instability during obesity.
Highlights
Populations with obesity are more likely to fall [1,2,3], more likely to visit the hospital with fall related injuries [4], and have a higher risk of disability from falls than normal weight populations [5]
into stretch (IST) and FST were significantly lower in high fat diet (HFD) mice than control group (CON) mice, with both M and F mice exhibiting the same pattern
Understanding why muscle spindle afferent function is altered by obesity may improve our understanding of how muscle spindle afferent function is regulated and suggest other conditions in which function may be altered
Summary
Populations with obesity are more likely to fall [1,2,3], more likely to visit the hospital with fall related injuries [4], and have a higher risk of disability from falls than normal weight populations [5]. Higher variability in balance motor commands is observed in people with obesity that could be due to less reliable sensory information and/or increased reliance on the more variable input from the visual and vestibular systems [15].
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