Effects of remobilization on rat femur are dose-dependent.

Seventy 9 to 11-week-old Sprague-Dawley male rats were divided into seven groups [baseline, 3-week, 11-week control groups; a group with a left limb immobilization for 3 weeks; and three groups with a similar immobilization and subsequent 8-week free (FR), low-intensity running (LR) or high-intensity running (HR) remobilization] to determine the site-specific effects of decreased mechanical loading and subsequent increased activity on rat femur. Bone mineral content of the proximal femur (PBMC), femoral midshaft (SBMC) and distal femur (DBMC) and the histomorphometry of the distal femur were used as outcome variables. The 3-week immobilization period resulted in significant bone loss in the proximal and distal ends of the immobilized left limb, the deficit being -5.

Free mobilization and low- to high-intensity exercise in immobilization-induced muscle atrophy.

After 3 wk of immobilization, the effects of free cage activity and low- and high-intensity treadmill running (8 wk) on the morphology and histochemistry of the soleus and gastrocnemius muscles in male Sprague-Dawley rats were investigated. In both muscles, immobilization produced a significant (P < 0.001) increase in the mean percent area of intramuscular connective tissue (soleus: 18.

Natural radiation--a perspective to radiological risk factors of nuclear energy production.

Radiation doses from natural radiation and from man-made modifications on natural radiation, and different natural radiological environments in the Nodic countries are summarized and used as a perspective for the radiological consequences of nuclear energy production. The significance of different radiation sources can be judged against the total collective effective dose equivalent from natural radiation in the Nordic countries, 92,000 manSv per year. The collective dose from nuclear energy production during normal operation is estimated to 20 manSv per year and from non-nuclear energy production to 80 manSv per year.

Ultrastructure and collagen composition of the myo-fascial junction in rat calf muscles.

The collagen composition and ultrastructural organization of the myo-fascial junction was studied using immunohistochemical techniques and electron microscopy. At the myo-fascial junction, a small amount of type-III collagen was found; however, the major collagen component was the type-I collagen. On the longitudinal sites of muscle cells, there were deep recesses and, within these, finger-like structures containing sarcomeres.

Structure and macromolecular composition of the myotendineal junction. Histochemical, immunohistochemical and electron microscopic study of the rat calf muscles.

The macromolecular composition and ultrastructure of the myotendineal junction (MTJ) of slow-twitch (type 1) and fast-twitch (type 2) muscle fibers were studied in the gastrocnemius-soleus-Achilles unit of the rat. Both proteoglycans and glycosaminoglycans, type III collagen, fibronectin and laminin could be detected at the MTJ. Due to membrane folding, finger-like processes were seen at the myotendineal junction.