Genetic and tissue level muscle-bone interactions during unloading and reambulation.

Cardiovascular & Fluid Dynamics

genetic, tissue, level, muscle, bone, interactions, during, unloading, reambulation, bone, during, density, significantly, calcium, elevated, study, examining, genetic, tissue, bone, study, examining, genetic, tissue, level, muscle, interactions, during, unloading

genetic, tissue, level, muscle, bone, interactions, during, unloading, reambulation

bone, study, examining, genetic, tissue, level, muscle, interactions, during, unloading

bone, during, density, significantly, calcium, elevated, study, examining, genetic, tissue

Study examining genetic and tissue level muscle-bone interactions during unloading. Extended spaceflight causes significant bone loss through increased osteoclast activity and decreased osteoblast function. Calcium metabolism is disrupted, with elevated resorption markers. While countermeasures provide partial protection, complete recovery requires 12-18 months post-flight, presenting major challenges for long-duration missions.

Study examining genetic and tissue level muscle-bone interactions during unloading. Bone mineral density decreased significantly during extended spaceflight missions. Osteoclast activity increased while osteoblast function declined. Calcium metabolism was disrupted with elevated urinary calcium excretion. Bone resorption markers TRAP and CTX-1 were significantly elevated. Mechanical loading countermeasures showed partial effectiveness. Recovery of bone density post-flight required 12-18 months on average.

‹ Cytoskeletal configuration modulates mechanically induced changes in mesenchymal stem cell osteogenesis, morphology, and stiffness.

Osteocyte apoptosis caused by hindlimb unloading is required to trigger osteocyte RANKL production and subsequent resorption of cortical and trabecular bone in mice femurs. ›