Specific timing of taurine supplementation affects learning ability in mice.

The effects of taurine supplementation on visual discrimination in mice were examined. Taurine, 2-aminoethane-sulphonic acid, found in high concentrations in the central nervous system of mammals and in human milk, has been shown to be essential for development. Male mice were divided into four groups according to taurine supplementation periods. 1) Lifelong: taurine (400 mg/kg/day) was dissolved in distilled water and provided as drinking water. In the prenatal period, taurine was given via the mother. After weaning mice were administered taurine in drinking water. 2) Pre-weaning: mice were exposed to taurine prior to weaning, 3) Post-weaning: mice were exposed to taurine after weaning. 4) CONTROL: no supplementation of taurine. It was shown that the Lifelong group required a longer period of time to acquire visual discrimination than the CONTROL group. Conversely, in the Post-weaning group, mice learned the task faster than CONTROLs. Visual discrimination learning time in the Pre-weaning group showed no significant difference compared with that in the CONTROL group. From these results, we suggest that the perinatal to early postnatal period is a "sensitive period" where taurine supplementation can result in retardation of learning in later life. At the same time, taurine supplementation after weaning improved visual discrimination learning. Thus, timing of taurine supplementation affected learning.

Histological and physicochemical studies of hypercalcified primear lines in the laminar bone of young calves.

There are many reports on laminar bone in various young animals during their growth periods. One of the concentric laminar bone units around the long-bone marrow periphery consists of three components: bright line, woven bone, and lamellar bone in the long-bone cortex of young calves and pigs. However, the fine structure, especially the uniform bright line or 'hypercalcified line' present in the unit-center, has not been elucidated as yet. The laminar bone of young calves was found to be initially formed from the hypercalcified lines; that is, 'hypercalcified primear' reported previously by the other authors. Such primear lines containing collagen fibrils scattered deposits of rod-like structures containing fine non-collagenous fibrils and globular structures showing no fibrils and some remnants. Osteocytes occasionally existed in the lines as well as adjacent to the lines, although no cells have been reported in the line. The cell lacunae were larger than those of woven bone and lamellar bone. The hypercalcified primear lines contained higher Ca and P content, and the molar ratio (1.78) was similar to 1.75 in the woven bone and lamellar bone. However, the physical and chemical resistances were significantly lower than that of the surrounding bone. Therefore, the hypercalcified primear lines are strongly suggested to show a lower crystallization. Further, fine structural observations of the primear-line forming cells and histochemical and immuno-histochemical investigations of the primear lines will be necessary.