Moore M C, Pagliassotti M J, Swift L L, Asher J, Murrell J, Neal D, Cherrington A D
Department of Molecular Physiology and Biophysics, Vanderbilt University, Nashville, Tennessee 37232.
Am J Physiol. 1994 Apr;266(4 Pt 1):E666-75. doi: 10.1152/ajpendo.1994.266.4.E666.
The disposition of a mixed meal administered intragastrically was examined in 13 24-h-fasted conscious dogs, using the arteriovenous (AV) difference technique (and isotopic methods in 6 dogs). Postprandial net gut output totaled (in g of glucose equivalents) 42 +/- 6 glucose, 3 +/- 0.3 lactate, 2 +/- 0.2 alanine, and 0.2 +/- 0.0 glycerol. The gut oxidized 2 +/- 1 g of glucose, and 0.2 +/- 0.1 g remained within the intestinal lumen. Of the administered glucose 68 +/- 6% were accounted for, and volatile fatty acid production by the gut (n = 1) accounted for at least an additional 4%. Of the labeled glucose in the meal 82 +/- 5% appeared in the systemic circulation, an apparent overestimate of absorption of glucose from the meal. Cumulative net hepatic uptakes (in g of glucose equivalents) were 4.1 +/- 3.1 glucose, 12.1 +/- 2.1 gluconeogenic amino acids, and 1.5 +/- 0.2 glycerol. Net hepatic glycogen synthesis and lactate and CO2 production accounted for 6.2 +/- 4.1, 9.3 +/- 2.8, and 1.6 +/- 0.8 g of glucose equivalents, respectively. In summary, the AV difference method could account for the gut disposition of about two-thirds of the meal glucose. Nonsplanchnic tissues disposed of threefold more glucose than the liver. Net hepatic uptake of glucose equivalents as gluconeogenic amino acids was threefold > glucose uptake, and net hepatic uptake of gluconeogenic amino acids was > net gut release of gluconeogenic amino acids. In conclusion, the net hepatic uptake of glucose and gluconeogenic substrates provided adequate carbon for net hepatic synthesis of glycogen and production of lactate and CO2. In a net sense, peripheral tissues must have been the source of some of the gluconeogenic carbon taken up by the liver after the meal.
在13只禁食24小时的清醒犬中,采用动静脉(AV)差值技术(6只犬还采用了同位素方法)研究了胃内给予混合餐后的代谢情况。餐后肠道净输出总量(以葡萄糖当量计,单位:克)为:葡萄糖42±6、乳酸3±0.3、丙氨酸2±0.2、甘油0.2±0.0。肠道氧化了2±1克葡萄糖,0.2±0.1克葡萄糖留在肠腔内。所给予葡萄糖的68±6%得到了 accounted for,肠道产生的挥发性脂肪酸(n = 1)至少额外占4%。餐中的标记葡萄糖有82±5%出现在体循环中,这明显高估了餐中葡萄糖的吸收量。肝脏累积净摄取量(以葡萄糖当量计,单位:克)为:葡萄糖4.1±3.1、糖异生氨基酸12.1±2.1、甘油1.5±0.2。肝脏净糖原合成以及乳酸和二氧化碳生成分别占葡萄糖当量6.2±4.1、9.3±2.8和1.6±0.8克。总之,AV差值法能够解释约三分之二餐中葡萄糖的肠道代谢情况。非内脏组织处理的葡萄糖量是肝脏的三倍多。肝脏作为糖异生氨基酸对葡萄糖当量的净摄取量是葡萄糖摄取量的三倍,且肝脏对糖异生氨基酸的净摄取量大于肠道对糖异生氨基酸的净释放量。总之,肝脏对葡萄糖和糖异生底物的净摄取为肝脏净糖原合成以及乳酸和二氧化碳生成提供了充足的碳源。从净平衡角度来看,餐后肝脏摄取的一些糖异生碳源必定来自外周组织。 (注:“accounted for”这里根据语境暂译为“得到了解释”,可能需要结合更专业背景进一步优化表述)
