The mechanism(s) and site(s) of the insulin resistance were examined in nine normal-weight noninsulin-dependent diabetic (NIDD) subjects. The euglycemic insulin clamp technique (insulin concentration -100 MU/mi) was employed in combination with hepatic and femoral venous catheterization and measurement of endogenous glucose production using infusion of tritiated glucose. Total body glucose metabolism in the NIDD subjects (4.37±0.45 mg/kg per min) was 38% (P < 0.01) lower than in controls (7.04+0.63 mg/kg per min).Quantitatively, the most important site of the insulin resistance was found to be in peripheral tissues. Leg glucose uptake in the diabetic group was reduced by 45% as compared with that in controls (6.0±0.2 vs. 11.0±0.1 mg/kg leg wt per min; P < 0.01). A strong positive correlation was observed between leg and total body glucose uptake (r = 0.70, P < 0.001). Assuming that muscle is the primary leg tissue responsible for glucose uptake, it could be estimated that 90 and 87% of the infused glucose was disposed of by peripheral tissues in the control and NIDD subjects, respectively. Net splanchnic glucose balance during insulin stimulation was slightly more positive in the control than in the diabetic subjects (0.31±0.10 vs. 0.05±0.19 mg/kg per min; P < 0.07). The difference (0.26 mg/kg per min) in net splanchnic glucose balance in NIDD represented only 10% of the reduction (2.67 mg/kg per min) in total body glucose uptake in the NIDD group and thus contributed very little to the insulin resistance. The results emphasize the imnportance of the peripheral tissues in the disposal of Infused glucose and indicate that muscle is the most important site of the insulin resistance in NIDD.
Although it is an established concept that the liver is important in the disposition of glucose, the quantitative contribution of the splanchnic and peripheral tissues, respectively, to the disposal of an oral glucose load is still controversial. In the present investigation, we have employed the hepatic venous catheter technique in combination with a double-tracer approach (in which the glucose pool is labeled with 3H-glucose and the oral glucose load is labeled with 14C-glucose) to quantitate the four determinants of oral glucose tolerance: rate of oral glucose appearance, splanchnic glucose uptake, peripheral glucose uptake, and suppression of hepatic glucose production. Studies were carried out in 11 normal volunteers in the overnight-fasted state and for 3.5 h after the ingestion of glucose (1 g/kg body wt; range, 55-93 g). In the postabsorptive state, the rate of endogenous (hepatic) glucose production, evaluated from the 3H-glucose infusion, was 2.34 +/- 0.06 mg/min X kg. Glucose ingestion was accompanied by a prompt reduction of endogenous glucose output, which reached a nadir of 0.62 +/- 0.23 mg/min X kg at 45 min and remained suppressed after 3.5 h (0.85 +/- 0.22 mg/min X kg). The average inhibition of hepatic glucose output during the absorptive period was 53 +/- 5%. The appearance of ingested glucose in arterial blood, as derived from the 14C-glucose measurements after correction for recycling 14-C radioactivity, reached a peak after 15-30 min, and 14C-glucose continued to enter the systemic circulation throughout the observation period. The rate of appearance of ingested glucose was 2.47 +/- 0.45 mg/min X kg at 3.5 h. A total of 73 +/- 4% of the oral load was recovered in the systemic circulation within 3.5 h.(ABSTRACT TRUNCATED AT 250 WORDS)
Physical exercise is accompanied by increased plasma levels of ammonia but it is not known whether this rise primarily reflects accelerated formation in muscle or decreased removal by the liver. Consequently, leg and splanchnic exchange of ammonia was examined, using the catheter technique, in 11 healthy subjects at rest, during three consecutive 15 min periods of bicycle exercise at gradually increasing work loads (35%, 55% and 80% of maximum oxygen uptake) and for 60 min during post-exercise recovery. The basal arterial ammonia level was 22 +/- 2 mumol/l, the concentration rose curvilinearly in response to increasing work loads (peak value 84 +/- 12 mumol/l), and fell rapidly after exercise, reaching basal levels after 30-60 min. A linear regression was found for ammonia levels in relation to lactate concentrations at rest and during exercise (r = 0.85, P less than 0.001). A significant relationship was also observed between arterial ammonia and alanine levels (r = 0.75, P less than 0.001). Leg tissues showed a net uptake of ammonia in the basal state (2.4 +/- 0.5 mumol/min). During exercise this changed to a net production, which increased curvilinearly with rising work intensity (peak value 46 +/- 15 mumol/min) but reverted to a net ammonia uptake at 30-60 min after exercise. Splanchnic ammonia uptake (basal 12 +/- 2 mumol/min) did not change in response to exercise but increased transiently during the early post-exercise period. From the above observations we conclude that the hyperammonaemia of exercise comes primarily from muscle release, while the splanchnic removal of ammonia is essentially unaltered. Part of the ammonia formed in contracting muscle is most likely used in the synthesis of amino acids, mainly glutamine and probably alanine.
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