1007/s00198-012-2236-y In the abstract it should have read “There is a moderate relationship between

vitamin D status and muscle strength” instead of “There is a moderate inverse relationship between vitamin D status and muscle strength”. The complete corrected abstract is reproduced here. The authors regret their error. Abstract Muscle strength plays an important role in determining risk for falls, which check details result in fractures and www.selleckchem.com/products/sbe-b-cd.html other injuries. While bone loss has long been recognized as an inevitable consequence of aging, sarcopenia—the gradual loss of skeletal muscle mass and strength that occurs with advancing age—has recently received increased attention. A review of the literature was undertaken to identify nutritional factors that contribute to loss of muscle mass. The role of protein, acid–base

balance, vitamin D/calcium, and other minor nutrients like B vitamins was reviewed. Muscle wasting is a multifactorial process involving intrinsic and extrinsic alterations. A loss of fast twitch fibers, glycation of proteins, and insulin resistance may play an important role in the loss of muscle strength and development of sarcopenia. Protein intake plays an integral part in muscle health and an intake of 1.0–1.2 g/kg of body weight per day is probably optimal for older adults. There is a moderate relationship between vitamin D status and muscle strength. Chronic ingestion of acid-producing diets H 89 chemical structure appears to have a negative impact on muscle performance, and decreases in vitamin B12 and folic acid intake may also impair muscle function through their action on homocysteine. An adequate nutritional intake and an optimal dietary acid–base balance are important elements of any strategy to preserve muscle mass and strength during aging.”
“Introduction Osteoporosis is a skeletal disease

Rebamipide characterized by low bone mass and micro-architectural deterioration of bone tissue, leading to bone fragility and increased susceptibility to fracture. One of the most important risk factors of osteoporosis is a positive family history of fracture [1, 2], emphasizing the importance of genetics in osteoporosis. The purinergic P2X7 receptor (P2X7R) functions as a non-selective ion channel upon activation by high levels (i.e. low millimolar) of extracellular ATP. Sustained stimulation with ATP or repeated stimulation with sequential ATP pulses induces formation of a large pore that permeabilizes the plasma membrane to molecules up to 900 Da. The P2X7R is demonstrated to be expressed by major bone cell types, including osteoblasts [3–5], osteoclasts [6–8] and osteocytes [9] and the overall effect of a functional P2X7R on bone metabolism is thought to be pro-osteogenic [10, 11]. In vitro studies showed that activation of the P2X7R inhibited bone resorption through initiation of apoptosis of osteoclasts [12].