The ventromedial hypothalamic nucleus (VMH) is necessary for the integrated hormonal response to hypoglycemia. To determine the role of the VMH as a glucose sensor, we performed experiments designed to specifically prevent glucopenia in the VMH, while producing hypoglycemia elsewhere. We used awake chronically catheterized rats, in which local VMH glucose perfusion (100 mM or 15 mM of D-glucose) was combined with a sequential euglycemichypoglycemic clamp. In two control groups the VMH was perfused either with ( a) an iso-osmotic solution lacking glucose, or with ( b ) nonmetabolizable L-glucose (100 mM). During systemic hypoglycemia glucagon and catecholamine concentrations promptly increased in the control animals perfused with either 100 mM L-glucose or the iso-osmotic solution lacking glucose. In contrast, glucagon, epinephrine and norepinephrine release was inhibited in the animals in which the VMH was perfused with D-glucose; hormonal secretion was partially suppressed by the VMH perfusion with 15 mM D-glucose and suppressed by ف 85% when the VMH was perfused with 100 mM D-glucose, as compared with the control groups. We conclude that the VMH must sense hypoglycemia for full activation of catecholamine and glucagon secretion and that it is a key glucose sensor for hypoglycemic counterregulation. ( J. Clin. Invest. 1997. 99:361-365.)
To test the hypothesis that nuclei of the ventromedial hypothalamus (VMH) play a key role in the detection of counterregulatory responses to hypoglycemia, we delivered the glucopenic agent 2-deoxyglucose via bilaterally placed microdialysis probes into the VMH of conscious, chronically catheterized rats. The goal was to produce cellular glucopenia localized to the VMH. The volume of brain tissue exposed to 2-deoxyglucose was determined by adding [3H]2-deoxyglucose to the dialysate; its distribution in cerebral tissue was almost exclusively limited to the VMH. Rats with microdialysis probes placed into the frontal lobes served as a control group. Local perfusion of 2-deoxyglucose (but not glucose) into the VMH caused a prompt twofold increase in plasma glucose in association with a striking elevation of plasma glucagon (3.5-fold), epinephrine (30-fold), and norepinephrine (3.5-fold). No effect was seen when 2-deoxyglucose was delivered into the frontal lobes. We conclude that glucopenia localized to the VMH triggers the release of counterregulatory hormones that defend against hypoglycemia. Thus, the neurons that sense glucopenia may be situated in the VMH.
The central nervous system has been implicated in the activation of counterregulatory hormone release during hypoglycemia. However, the precise loci involved are not established. To determine the role of the ventromedial hypothalamic nuclei (VMH) in the hormonal response to hypoglycemia, we performed hypoglycemic clamp studies in conscious SpragueDawley rats with bilateral VMH lesions produced by local ibotenic acid injection 2 wk earlier. Rats with lesions in the lateral hypothalamic area, frontal lobe, sham operated (stereotaxic needle placement into hypothalamus without injection), and naive animals served as control groups. The clamp study had two phases. For the first hour plasma glucose was fixed by a variable glucose infusion at euglycemia ( 5.9 mM). Thereafter, for an additional 90 min, glucose was either allowed to fall to (a) mild hypoglycemia ( -3.0 mM) or (b) more severe hypoglycemia ( -2.5 mM). Glucagon and catecholamine responses of lateral hypothalamic area-, frontal lobe-lesioned, sham operated, and naive animals were virtually identical at each hypoglycemic plateau. In contrast, glucagon, epinephrine, and norepinephrine responses in the VMH-lesioned rats were markedly inhibited; hormones were diminished by 50-60% during mild and by 75-80% during severe hypoglycemia as compared with the other groups. We conclude that the VMH plays a crucial role in triggering the release of glucagon and catecholamines during hypoglycemia. (J. Clin. Invest. 1994. 93:1677-1682.) Key words: ventromedial hypothalamus * hypoglycemia * glucagon -epinephrine * counterregulation Introduction The role of the central nervous system (CNS) in the regulation of counterregulatory responses to hypoglycemia remains controversial. Although several lines ofevidence strongly implicate the CNS in hypoglycemia detection and counterregulation ( 1-3), the precise brain regions involved are not known. While various nuclei have been implicated, current data suggest that counterregulatory responses during hypoglycemia are activated, at least in part, via the hypothalamus (4-6). It has
Previous studies have demonstrated that the ventromedial hypothalamus (VMH) plays a critical role in sensing and responding to systemic hypoglycemia. To evaluate the mechanisms of defective counterregulation caused by iatrogenic hypoglycemia and diabetes per se, we delivered 2-deoxy-glucose (2-DG) via microdialysis into the VMH to produce localized cellular glucopenia in the absence of systemic hypoglycemia. Three groups of awake chronically catheterized rats were studied: 1) nondiabetic (with a mean daily glucose [MDG] of 6.9 mmol/l) BB control rats (n = 5); 2) chronically hypoglycemic nondiabetic (3-4 weeks, with an MDG of 2.7 mmol/l) BB rats (n = 5); and 3) moderately hyperglycemic insulin-treated diabetic (with an MDG of 12.4 mmol/l) BB rats (n = 8). In hypoglycemic rats, both glucagon and catecholamine responses to VMH glucopenia were markedly (77-93%) suppressed. In diabetic rats, VMH 2-DG perfusion was totally ineffective in stimulating glucagon release. The epinephrine response, but not the norepinephrine response, was also diminished by 38% in the diabetic group. We conclude that impaired counterregulation after chronic hypoglycemia may result from alterations of the VMH or its efferent pathways. In diabetes, the capacity of VMH glucopenia to activate the sympathoadrenal system is only modestly diminished; however, the communication between the VMH and the alpha-cell is totally interrupted.
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