HUMANGGP:034761 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Target Concepts:

Query: HUMANGGP:034761 (insulin)
211,843 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Both naturally occurring disease processes and experimental models of human disease in the Mongolian gerbil were reviewed. The gerbil was highly susceptible to cerebral infarction following unilateral ligation of one common carotid artery and was useful in studies of the pathogenesis of stroke. Spontaneous epileptiform seizures mimicked those of human idiopathic epilepsy, and both seizure-sensitive and resistant strains have been bred. Perhaps because of its more efficient nephron, the gerbil accumulated four to six times as much renal lead as the rat, and the gerbil has been proposed as an experimental model of lead nephropathy. On standard diets, about 10% of the animals became obese, and some showed decreased glucose tolerance, elevated serum immunoreactive insulin and diabetic changes in the pancreas and other organs. Some breeders exhibited hyperactivity of the adrenal cortex associated with hyperglycemia, hyperlipidemia and degenerative vascular disease. Although dietary supplements of cholesterol were toxic and did not induce atherosclerosis, the gerbil was useful in other studies of cholesterol absorption and metabolism. Spontaneous, insidious periodontal disease became evident after about 6 months on standard diets, and dental caries were induced by cariogenic diets or by pathodontic streptococci. Spontaneous neoplasia occurred in 8.4--24% of gerbils, usually after 2 years of life. Adrenal cortical, ovarian and cutaneous tumors were the most consistently reported neoplasms.
...
PMID:The pathology of the Mongolian Gerbil (Meriones unguiculatus): a review. 9 95

Crystalline insulins have been obtained from the insular tissue of the teleosts O. gorbuscha and Th. chalcogramma which is located separately from the exocrine tissue. Some tests to the homogeneity and purity of the preparations obtained were made. Biological activity of insulin as revealed by seizure tests in mice is equal to 20.1 +/- 1.19 IU/mg in O. gorbuscha and 16.9 +/- 1.99 IU/mg in Th. chalcogramma, amounting correspondingly to 83 and 70% of the activity of mammalian standard insulin. The yield of preparations calculated per wet weight of the insular tissue is equal to 2 mg/g in O. gorbuscha and 0.7 mg/g in Th. chalcogramma. It is significantly higher than the yield of mammalian insulins calculated per the weight of the pancreas. This finding may be of some interest with respect to the use of fish as a source of hormonal preparations.
...
PMID:[The isolation and purification of insulins from the pink salmon Oncorhynchus gorbuscha and the walleye pollock Theragra chalcogramma]. 9 50

Changes in plasma glucose, nonesterified fatty acids, insulin, glucagon, cortisol, growth hormone, and prolactin have been studied in baboons during the course of generalized epileptic seizures induced by intravenous bicuculline. Plasma glucose rose to a peak at 25 min but fell to hypoglycemic levels after 60 min of seizure activity. This hypoglycemia was accompanied by a marked elevation in plasma insulin. Plasma glucagon rose to a peak at 14 min, then returned to normal. Plasma growth hormone levels were elevated after 60 min of seizure activity. Plasma prolactin and cortisol levels also rose during the seizure. These changes result from sequential interaction of (1) autonomic activation at seizure onset, (2) spread of neuronal activity to the hypothalamus leading to the liberation of releasing factors, and (3) indirect physiologic consequences of seizure activity.
...
PMID:Endocrine factors and glucose metabolism during prolonged seizures in baboons. 11 9

In idiopathic or generalized epilepsy, serum glucose and cholesterol concentrations tend to be low, especially just before the seizure. Glucose tolerance curves are abnormal and variable. The electrolyte balance is disturbed, and epileptics tend to go readily into alkalosis. Serum [Na+] is usually unaffected, but [K+] is normal to low between attacks and increases during and after the seizure. Serum [Cl-] is usually high just before the seizure. Epileptics are generally mildly hypocalcemic, especially in the period before the seizure. Serum urea and nonprotein nitrogen values are low between paroxysms but increase after the seizure. Serum protein concentration is usually normal. Stress, which releases epinephrine and corticotropin, results in high serum citrate concentration, which probably contributes to decreased serum [Ca2+] just before a seizure. In the healthy individual, any increase in serum citrate is accompanied by increasing [Ca2+]. In the rabbit, convulsions can be induced with corticotropin, a result of increased serum citrate concentration coupled with a decrease in [Ca2+]. The net result is severe hypo-ionic-calcemia. A similar phenomenon has been reported in a few humans. Administration of insulin causes serum citrate concentrations to decrease. Apparently, the dynamic system that controls glucose and lipid metabolism, and thus electrolyte balance, through the hormones epinephrine, corticotropin, insulin, glucagon, calcitonin, and parathormone, is abnormal in the epileptic.
...
PMID:Clinical biochemistry of epilepsy. I. Nature of the disease and a review of the chemical findings in epilepsy. 22 Nov 36

The relation of endotoxicosis to insulin responsiveness was evaluated in male Holtzman rats. Salmonella enteritidis lipopolysaccharide at 0.5 or 1.0 mg per 300 g rat increased lethality in convulsive seizure deaths to 0.25, 0.50, or 1.0 U insulin sc. The hypoglycemic nadir induced by 0.05, 0.10, or 0.25 U of insulin sc was greater in rats rendered endotoxic with 1 mg of lipopolysaccharide IV. Oxidation of U-14C-D-glucose to 14 CO2 by endotoxic tissues in vitro was augmented in liver slices, epididymal fat pads, hemidiaphragms, and spleen slices; no pronounced glucose oxidation increases occurred in lung, heart, stomach, cerebrum, kidney, or whole blood. Epididymal fat pads from endotoxic rats (100 g) manifested increased basal glucose oxidation as well as an enhanced maximal response to incremental insulin doses of 0.01 to 25 mU/ml. It is suggested that altered tissue responsiveness in concert with hyperinsulinemia underlie the profound alterations in glucose homeostasis during endotoxicosis.
...
PMID:Increased insulin responsiveness in endotoxicosis. 37 53

To evaluate the effects of substrate deficiency on cerebral function, metabolism, and blood flow during seizures, rats were injected intravenously with bicuculline (1.2 mg.kg-1) following a 24-hour period of starvation. During the course of seizures, blood glucose concentrations fell, and when they were reduced to below about 3 mumol.gm-1, cerebral function, metabolism, and blood flow altered. Changes in function involved the transition of an electroencephalographic pattern of bursts and suppression into one of frequent or sparse single spikes. Oxygen consumption, which initially increased at least twofold, fell toward normal or subnormal values in the single-spike period. Cortical blood flow was markedly reduced, and there was an attenuated response to carbon dioxide administration. Simultaneously, a small but clear fall was detected in the cerebral phosphorylation potential, and concentrations of glycolytic metabolites (including lactate) and citric acid cycle intermediates were reduced. Changes in amino acids and ammonia were somewhat similar to those observed in insulin-induced hypoglycemia, but since the amino acid pool did not fall, the experiments failed to give evidence that amino acids serve as oxidative substrates. The perturbation of cerebral energy state (and of levels of carbohydrate substrates and amino acids) was reversed by glucose administration; but since neither this procedure nor additional bicuculline injections could cause resumption of continuous seizure activity, the results suggest that cellular substrate depletion may have given rise to a sustained disturbance of synaptic transmission.
...
PMID:Effects of bicuculline-induced seizures on cerebral metabolism and circulation of rats rendered hypoglycemic by starvation. 42 77

In order to determine the effects of acetate on signs and symptoms of hypoglycemic seizures, Swiss Webster albino mice were injected intraperitoneally with solutions of NaCl, NaHCO3, NH4Cl, Na-acetate, or NH4-acetate, followed by subcutaneous injection of 7 U of insulin/kg body wt. Administration of Na- or NH4-acetate delayed and reduced the incidence of hypoglycemic reactions. Reinjection with Na-acetate or repeated injections with NH4-acetate caused a return to normal behavior patterns for 60 and 75%, respectively, of the affected hypoglycemic experimental animals. Injections of control animals with NaHCO3 or NH4Cl showed that the results were not due to alkalosis or acidosis. Acetate administration significantly increased plasma acetate and citrate, but not glucose, lactate, beta-hydroxybutyrate, or acetoacetate concentrations. The results indicate that intraperitoneal administration of acetate directly acted to prevent signs of hypoglycemia from occurring and reversed its manifestations when they were present. The protective effect of acetate suggests that it may serve as a fuel for the brain.
...
PMID:Effect of acetate on hypoglycemic seizures in mice. 48 41

Glucose and insulin injections both decrease seizure susceptibility in C57BL/6J mice subjected to audiogenic priming at 16 days of age and tested at 21 days of age. These data support an hypothesis of defect in immediately available energy reserves in brains of audiogenic seizure prone mice.
...
PMID:Time course of protection from audiogenic seizures by glucose and insulin in audiogenically primed C57BL/6J mice. 67 68

The neutral glycolipids of rabbit central cortex were analyzed during epileptic seizures produced by insulin or pentetrazol injection. The two agents gave similar results. A decrease of glycolipid content occurred in the cortex and in the neuronal fraction during seizures. The normal glycolipid level was restored during the recovery phase.
...
PMID:Effect of insulin-induced epileptic seizures on neutral glycolipids of rabbit cerebral cortex. 68 12

Coma and other neurologic abnormalities are present in patients with either diabetic ketoacidosis (DKA) or nonketotic coma (NKC), and the cause of such phenomena are not known. Patients with NKC also manifest seizures and focal neurologic changes. Treatment of diabetic coma with insulin may induce cerebral edema by as yet undefined mechanism(s). In patients with DKA, cerebral oxygen utilization is impaired, and there is hyperviscosity of the blood. A substantial part of the brain's energy source is derived from ketones, which in themselves can depress sensorium. Extracellular hyperosomolality is present, which may also contribute to the genesis of coma. In addition, most ketoacidotic patients have associated medical conditions, which may further impair consciousness. Biochemical changes in the brains of animals with DKA include impairment of both phosphofructokinase activity and pyruvate oxidation, and accumulation of citrate. The net effect upon sensorium in ketoacidotic patients probably represents the interaction of most of the above factors and differs markedly among individuals. Patients with NKC manifest not only depression of sensorium, but also focal motor seizures, hemiparesis, and other neurologic changes, such as aphasia, hypereflexia, sensory defects, autonomic changes, and brainstem dysfunction. Most of the aforementioned changes revert to normal after correction of hyperosomolality. Gamma amino butyric acid, which has been shown to elevate the seizure threshold, is normal in brains of ketoacidotic animals, but may be low in nonketotic coma. Also, hyperosomolality per se may produce seizures. Cerebral edema may complicate the treatment of either DKA or NKC. The available experimental evidence suggests that many of the commonly held theories for the production of such brain swelling probably do not occur. There is no breakdown of the sodium pump, sorbitol or fructose do not accumulate in brain, and brain glucose is only about 25 percent of that in plasma; Cerebral edema is probably produced largely by a direct action of insulin on brain at a time when plasma glucose is approaching normal values. Cerebral edema can thus theoretically be avoided by stopping insulin when plasma glucose has been lowered to values approaching normal.
...
PMID:Neurologic manifestations of diabetic comas: correlation with biochemical alterations in the brain. 80 37

1 2 3 4 5 6 7 8 9 10 Next >>