Feeding intervention potentiates the effect of mechanical loading to induce new bone formation in mice.
Hasmik Jasmine SamvelyanJohn Cummings MathersTimothy Michael SkerryPublished in: FASEB journal : official publication of the Federation of American Societies for Experimental Biology (2021)
The benefits of increased human lifespan depend upon duration of healthy, independent living; the healthspan. Bone-wasting disorders contribute significantly to loss of independence, frailty, and morbidity in older people. Therefore, there is an unmet need globally for lifestyle interventions to reduce the likelihood of bone fractures with age. Although many mechanisms are involved in disorders of bone loss, there is no single regulatory pathway and, therefore, there is no single treatment available to prevent their occurrence. Our aim in these studies was to determine whether fasting/feeding interventions alter the effect of mechanical loading on bone anabolic activities and increase bone mass. In young 17-week-old mice, 16-hour fasting period followed by reintroduction of food for 2 hours increased markedly the potency of mechanical loading, that mimics the effect of exercise, to induce new cortical bone formation. Consistent with this finding, fasting and re-feeding increased the response of bone to a loading stimulus that, alone, does not stimulate new bone formation in ad-lib fed mice. Older mice (20 months) experienced no potentiation of loading-induced bone formation with the same timing of feeding interventions. Interestingly, the pre-, prandial, and postprandial endocrine responses in older mice were different from those in young animals. The hormones that change in response to timing of feeding have osteogenic effects that interact with loading-mediated effects. Our findings indicate associations between timing of food ingestion and bone adaptation to loading. If translated to humans, such non-pharmacological lifestyle interventions may benefit skeletal health of humans throughout life-course and in older age.
Keyphrases
- bone loss
- physical activity
- bone mineral density
- high fat diet induced
- insulin resistance
- soft tissue
- middle aged
- blood glucose
- bone regeneration
- community dwelling
- metabolic syndrome
- public health
- endothelial cells
- cardiovascular disease
- healthcare
- postmenopausal women
- blood pressure
- mental health
- mesenchymal stem cells
- adipose tissue
- skeletal muscle
- high intensity
- human health
- high glucose