摘要
Objective To determine the effects of zine-deficiency and zine-excess on hone metabolism. Methods We developed the culture model of fetal mouse limbs (16th day) cultivated in self-made rotator with continuing flow of mixed gas for six days in vitro. The cultured limbs were examined by the techniques of 45Ca tracer and X-roentgenography. Results The right limbs cultivated had longer bone length, higher bone density than the left limbs uncultivated from the same embryo; and histologically, the right limbs had active bone cell differentiation, proliferation, increased bone trabecula. clearly calcified cartilage matrix, and osteogenic tissue. Compared with the control group, the zinc-deficient group and zine-excess (Zn2+ l20) μmol/L) group contained less osteocalcin (BGP) and 45Ca content, and lower AKP activity; whereas zine-normal (Zn2+ 45 μmol/L and Zn2+ 70 μmol/L) groups contained more BGP and 45Ca contents, and higher AKP (alkaline phosphatase) activity. Conclusion Both zine-deficiency and zine-excess can alter bone growth and normal metabolism. The results indicate that the culture model of fetal mouse limbs (16th day) in vitro can be used as a research model of bone growth and development.
Objective To determine the effects of zine-deficiency and zine-excess on hone metabolism. Methods We developed the culture model of fetal mouse limbs (16th day) cultivated in self-made rotator with continuing flow of mixed gas for six days in vitro. The cultured limbs were examined by the techniques of 45Ca tracer and X-roentgenography. Results The right limbs cultivated had longer bone length, higher bone density than the left limbs uncultivated from the same embryo; and histologically, the right limbs had active bone cell differentiation, proliferation, increased bone trabecula. clearly calcified cartilage matrix, and osteogenic tissue. Compared with the control group, the zinc-deficient group and zine-excess (Zn2+ l20) μmol/L) group contained less osteocalcin (BGP) and 45Ca content, and lower AKP activity; whereas zine-normal (Zn2+ 45 μmol/L and Zn2+ 70 μmol/L) groups contained more BGP and 45Ca contents, and higher AKP (alkaline phosphatase) activity. Conclusion Both zine-deficiency and zine-excess can alter bone growth and normal metabolism. The results indicate that the culture model of fetal mouse limbs (16th day) in vitro can be used as a research model of bone growth and development.
基金
This work was supported by Grant 39600122 from the National Natural Science Foundation of China.
