摄入丙氨酸、葡萄糖和淀粉对运动及饥饿所致酮症的影响。
The effects of alanine, glucose and starch ingestion on the ketosis produced by exercise and by starvation.
作者信息
Koeslag J H, Noakes T D, Sloan A W
出版信息
J Physiol. 1982 Apr;325:363-76. doi: 10.1113/jphysiol.1982.sp014155.
Abstract
- Several investigators have found that the development of post-exercise ketosis is not counteracted by glucose ingestion. Post-exercise ketosis might therefore have more in common with diabetic ketoacidosis than with starvation ketosis. 2. The effects of ingesting 100 g of glucose, alanine or starch were therefore studied in subjects rendered hyperketonaemic by prolonged running on a low carbohydrate diet, or by 65 h of starvation. These substances were also ingested by normal post-prandial subjects. 3. The runners developed post-exercise ketosis (1.81 +/- S.D. 0.81 mmol/l), which was counteracted by alanine and glucose, but only minimally by starch. 4. Fasting caused a variable ketosis (2.19 +/- S.D. 1.63 mmol/l), also counteracted by glucose and less by starch, but alanine caused vomiting. 5. Glucose and alanine lowered the blood ketone body levels of the post-prandial subjects. 6. The rising ketone body levels in starvation and after exercise were accompanied by simultaneous increases in the plasma insulin/glucagon ratios; in both, glucose ingestion increased the ratio further, while alanine decreased it. 7. It is concluded that there is no essential difference between established post-exercise and starvation ketosis, and that the blood fuel-hormone changes do not correlate with the changes in blood ketone body concentrations.
摘要
- 几位研究者发现,运动后酮症的发展不会因摄入葡萄糖而受到抑制。因此,运动后酮症可能与糖尿病酮症酸中毒的共同点比与饥饿性酮症更多。2. 因此,对通过低碳水化合物饮食长时间跑步或禁食65小时而导致酮血症的受试者,研究了摄入100克葡萄糖、丙氨酸或淀粉的影响。正常餐后受试者也摄入了这些物质。3. 跑步者出现了运动后酮症(1.81±标准差0.81毫摩尔/升),丙氨酸和葡萄糖可抑制这种酮症,但淀粉的抑制作用很小。4. 禁食导致了程度不一的酮症(2.19±标准差1.63毫摩尔/升),葡萄糖也可抑制这种酮症,淀粉的抑制作用较小,但丙氨酸会引起呕吐。5. 葡萄糖和丙氨酸降低了餐后受试者的血酮体水平。6. 饥饿和运动后血酮体水平的升高伴随着血浆胰岛素/胰高血糖素比值的同时增加;在这两种情况下,摄入葡萄糖会进一步提高该比值,而丙氨酸则会降低该比值。7. 得出的结论是,既定的运动后酮症和饥饿性酮症之间没有本质区别,并且血液中燃料-激素的变化与血酮体浓度的变化不相关。
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