Ferrannini E, Smith J D, Cobelli C, Toffolo G, Pilo A, DeFronzo R A
J Clin Invest. 1985 Jul;76(1):357-64. doi: 10.1172/JCI111969.
Understanding the influence of insulin on glucose turnover is the key to interpreting a great number of metabolic situations. Little is known, however, about insulin's effect on the distribution and exchange of glucose in body pools. We developed a physiological compartmental model to describe the kinetics of plasma glucose in normal man in the basal state and under steady-state conditions of euglycemic hyperinsulinemia. A bolus of [3-3H]glucose was rapidly injected into a peripheral vein in six healthy volunteers, and the time-course of plasma radioactivity was monitored at very short time intervals for 150 min. A 1-mU/min kg insulin clamp was then started, thereby raising plasma insulin levels to a high physiological plateau (approximately 100 microU/ml). After 90 min of stable euglycemic hyperinsulinemia, a second bolus of [3-3H]glucose was given, and plasma radioactivity was again sampled frequently for 90 min more while the clamp was continued. Three exponential components were clearly identified in the plasma disappearance curves of tracer glucose of each subject studied, both before and after insulin. Based on stringent statistical criteria, the data in the basal state were fitted to a three-compartment model. The compartment of initial distribution was identical to the plasma pool (40 +/- 3 mg/kg); the other two compartments had similar size (91 +/- 12 and 96 +/- 9 mg/kg), but the former was in rapid exchange with plasma (at an average rate of 1.09 +/- 0.15 min-1), whereas the latter exchanged 10 times more slowly (0.12 +/- 0.01 min-1). The basal rate of glucose turnover averaged 2.15 +/- 0.12 mg/min kg, and the total distribution volume of glucose in the postabsorptive state was 26 +/- 1% of body weight. In view of current physiological information, it was assumed that the more rapidly exchanging pool represented the insulin-independent tissues of the body, while the slowly exchanging pool was assimilated to the insulin-dependent tissues. Insulin-independent glucose uptake was estimated (from published data) at 75% of basal glucose uptake, and was constrained not to change with euglycemic hyperinsulinemia. When the kinetic data obtained during insulin administration were fitted to this model, neither the size nor the exchange rates of the plasma or the rapid pool were appreciably changed. In contrast, the slow pool was markedly expanded (from 96 +/- 9 to 190 +/- 30 mg/kg, P less than 0.02) at the same time as total glucose disposal rose fourfold above basal (to 7.96 +/- 0.85 mg/min kg, P less than 0.001). Furthermore, a significant direct correlation was found to exist between the change in size of the slow pool and the insulin-stimulated rate of total glucose turnover (r=0.92, P<0.01). We conclude that hyperinsulinemia, independent of hyperglycemia, markedly increases the exchangeable mass of glucose in the body, presumably reflecting the accumulation of free, intracellular glucose in insulin-dependent tissues.
了解胰岛素对葡萄糖周转的影响是解读众多代谢情况的关键。然而,关于胰岛素对体内葡萄糖池分布和交换的影响,人们所知甚少。我们建立了一个生理房室模型来描述正常男性在基础状态和正常血糖高胰岛素血症稳态条件下血浆葡萄糖的动力学。向六名健康志愿者的外周静脉快速注射一剂[3-³H]葡萄糖,并在非常短的时间间隔内监测血浆放射性的时间进程,持续150分钟。然后开始以1 mU/分钟·千克的速率进行胰岛素钳夹,从而将血浆胰岛素水平提高到较高的生理平台期(约100微单位/毫升)。在稳定的正常血糖高胰岛素血症持续90分钟后,给予第二剂[3-³H]葡萄糖,并在继续钳夹的同时,再次频繁采集血浆放射性样本,持续90分钟。在研究的每个受试者的示踪葡萄糖血浆消失曲线中,无论是在胰岛素给药前还是给药后,都清楚地识别出三个指数成分。基于严格的统计标准,将基础状态下的数据拟合到一个三室模型。初始分布室与血浆池相同(40±3毫克/千克);另外两个室大小相似(91±12和96±9毫克/千克),但前者与血浆快速交换(平均速率为1.09±0.15分钟⁻¹),而后者交换速度慢10倍(0.12±0.01分钟⁻¹)。基础葡萄糖周转率平均为2.15±0.12毫克/分钟·千克,吸收后状态下葡萄糖的总分布体积为体重的26±1%。鉴于当前的生理信息,假定交换较快的池代表身体中不依赖胰岛素的组织,而交换较慢的池被认为是依赖胰岛素的组织。根据已发表的数据估计,不依赖胰岛素的葡萄糖摄取量为基础葡萄糖摄取量的75%,并且在正常血糖高胰岛素血症时保持不变。当将胰岛素给药期间获得的动力学数据拟合到该模型时,血浆或快速池的大小和交换率均无明显变化。相比之下,在总葡萄糖处置量比基础值增加四倍(至7.96±0.85毫克/分钟·千克,P<0.001)的同时,慢池明显扩大(从96±9毫克/千克增至190±30毫克/千克,P<0.02)。此外,发现慢池大小的变化与胰岛素刺激的总葡萄糖周转率之间存在显著的直接相关性(r=0.92,P<0.01)。我们得出结论,高胰岛素血症独立于高血糖,显著增加了体内可交换的葡萄糖量,推测这反映了依赖胰岛素的组织中游离细胞内葡萄糖的积累。