In this article, we report the changes in serum triglyceride (TG) levels that occurred during repeated tail blood sampling using a mouse restrainer. We used three groups of mice, namely, “PBS-restrained” “PBS-unres...In this article, we report the changes in serum triglyceride (TG) levels that occurred during repeated tail blood sampling using a mouse restrainer. We used three groups of mice, namely, “PBS-restrained” “PBS-unrestrained” and “mock-restrained”. The mice in the PBS-restrained and PBS-unrestrained groups were intraperitoneally (i.p.) injected with 100 mL PBS and tail blood sampling was performed at 1, 5, 8, 24, and 48 h after i.p. injection. For the mock-restrained group, no i.p. injection was performed whereas the subsequent tail blood sampling was similarly performed. During the tail blood sampling, the mice of the two “restrained” groups were placed inside the restrainer designed from an open-ended 50 mL conical tube. The blood from the mice in the PBS-unrestrained group mice was sampled from the tail held by the operator’s hands while being allowed to move on a stage. Strikingly, in all of the three groups, the serum TG level initially decreased to remarkably low levels (approximately 30 mg/dL) after several blood samplings were performed over 8 h. This decrease was followed by a 2 - 3-fold increase in the levels relative to that in the control mice in the subsequent 24 - 48 h time period. We concluded that the acute stress associated with blood sampling caused alterations in TG levels. Serum levels of free fatty acid showed only modest changes. Changes in TG levels were not associated with serum corticosterone levels but with a dramatic increase in CD36 transcript levels in the liver. The relevance of this finding to the previously reported release of lipoprotein lipase (LPL) from white fatty tissue into the plasma during acute stress is also discussed.展开更多
文摘In this article, we report the changes in serum triglyceride (TG) levels that occurred during repeated tail blood sampling using a mouse restrainer. We used three groups of mice, namely, “PBS-restrained” “PBS-unrestrained” and “mock-restrained”. The mice in the PBS-restrained and PBS-unrestrained groups were intraperitoneally (i.p.) injected with 100 mL PBS and tail blood sampling was performed at 1, 5, 8, 24, and 48 h after i.p. injection. For the mock-restrained group, no i.p. injection was performed whereas the subsequent tail blood sampling was similarly performed. During the tail blood sampling, the mice of the two “restrained” groups were placed inside the restrainer designed from an open-ended 50 mL conical tube. The blood from the mice in the PBS-unrestrained group mice was sampled from the tail held by the operator’s hands while being allowed to move on a stage. Strikingly, in all of the three groups, the serum TG level initially decreased to remarkably low levels (approximately 30 mg/dL) after several blood samplings were performed over 8 h. This decrease was followed by a 2 - 3-fold increase in the levels relative to that in the control mice in the subsequent 24 - 48 h time period. We concluded that the acute stress associated with blood sampling caused alterations in TG levels. Serum levels of free fatty acid showed only modest changes. Changes in TG levels were not associated with serum corticosterone levels but with a dramatic increase in CD36 transcript levels in the liver. The relevance of this finding to the previously reported release of lipoprotein lipase (LPL) from white fatty tissue into the plasma during acute stress is also discussed.