[MINERAL BONE DENSITY AND BODY COMPOSITION IN PARTICIPANTS IN EXPERIMENT MARS-500].

Investigations of the bone system and body composition in Mars-500 test-subjects (prior to and on completion of the experiment) involved dual-energy X-ray absorptiometry (DXA) using the HOLOGIC Delphy densitometer and the protocol performed to examine cosmonauts. Bone density of lumber vertebrae and femoral proximal epiphysis, and body composition were measured. Reliable changes in vertebral density found in 3 test-subjects displayed different trends from +2.6 to -2.4%. At the same time, the experiment decreased significantly mineral density of the femoral proximal epiphysis, including the neck, in all test-subjects. Four test-subjects had cranial mineralization increased by 5-9%, same as in some cosmonauts after space flight. All tests-subjects incurred adipose loss from 2 to 7 kg; one test-subject lost 20 kg, i.e. his adipose mass became three times less. Changes in lean mass (1-3 kg) typically were negative; as for changes in lean mass of extremities, they could be linked with adherence to one or another type of physical activity. Therefore, extended exposure to confinement may affect mineralization of some parts of the skeleton. Unlike real space missions and long-term bedrest studies conducted at the Institute of Biomedical Problems in the past, Mars-500 did not cause clinically significant mineral losses (osteoporosis, osteopenia), probably because of the absence of effects of microgravity.

[Changes in bone structure according to the results of investigations on biosatellites of the "BION" series].

Noninvasive technologies of bone investigations measure largely the main skeletal sites and are not quite suitable to have a look at the bone internal organization in situ. However, there are data obtained noninvasively in experiments on board the space biosatellites. The review is dedicated to analysis and comparison of the evidence for the bone organic and mineral matrix restructuring due to microgravity. These changes have presumably evolved in the course of the system reaction of bone tissue and the whole skeleton.

Bone ultrastructural changes in Bion 11 rhesus monkeys.

Iliac crest biopsies of Bion 11 monkeys were examined by electron microscopy. The flight samples contained a large number of inactive osteoblasts. Together with ultrastructural changes of the rough endoplasmic reticulum and the Golgi complex, the predominance of inactive osteoblasts pointed to a lower rate of specific syntheses. Some osteoblasts were transformed to fibroblast-like cells. It was found that osteogenesis declined, osteoid mineralization changed, and fibrotic zones developed.