Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0011849 (diabetes)
277,896 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

This study reviews the pathogenic hormonal abnormalities (insulin deficiency and stress hormone excess) in diabetic ketoacidosis. The data both supporting and negating a primary role for insulin deficiency in the pathogenesis of diabetic ketoacidosis are examined. Evidence implicating excess stress hormone secretion as a necessary event in the development of severe metabolic decompensation is discussed. The data suggest that diabetic ketoacidosis may be prevented by correcting either the relative deficiency of insulin or the excess secreation of one or a combination of the stress hormones. Studies supporting a primary role for insulin deficiency in the pathogenesis of diabetic ketoacidosis include the beneficial therapeutic response to insulin administration in ketoacidosis, development of ketoacidosis; and (3) stress hormone excess is necessary for fulminant ketoacidosis to be manifested.s following insulin withdrawal from diabetic man and animals, and hypoglycemic and hypoketonemic effects of insulin. Studies negating a primary role for insulin deficiency in ketoacidosis include the "normal" plasma insulin concentration in the majority of ketoacidotic cases, delayed onset of ketoacidosis after insulin withdrawal from diabetic man, and lack of hypolipolytic and hypoketonemic effect of insulin without prior stress hormone adipocyte and hepatocyte stimulation. Evidence that stress hormones (glucagon, catecholamines, cortisol, and growth hormone) contribute to the metabolic decompensation of ketoacidosis includes: (1) in all cases of ketoacidosis, at least one stress hormone is always elevated; (2) pharmacologic blockade of each of the stress hormones reduces the rate and/or frequency of metabolic decompensation in diabetic man; (3) removal of the pituitary and/or the adrenal gland in diabetic animals completely prevents the development of ketoacidosis after insulin withdrawal; and (4) administration of each of the four stress hormones under appropriate conditions induces metabolic decompensation in diabetic man with "normal" circulating levels of plasma insulin concentration. From these studies, the following conclusions are supported: (1) absolute insulin deficiency is an unusual cause of ketoacidosis; (2) the presence of relative insulin deficiency is necessary for the development of ketoacidosis; and (3) stress hormone excess is necessary for fulminant ketoacidosis to be manifested.
Diabetes Care
PMID:Pathogenesis of diabetic ketoacidosis: a reappraisal. 11 31

The clinical features of the experimental hyperosmolar diabetic (EHD) rat model resemble those seen in the human syndrome--extreme hyperglycemia without ketoacidosis is common to both. The absence of ketoacidosis in the syndrome has been ascribed to both substrate (free fatty acid) deficiency and to interference with hepatic ketone body synthesis. The potential for hepatic ketone body synthesis in the experimental model has been directly assessed by challenging the EHD animals with medium-chain triglycerides (MCT) administered intragastrically. This neutral lipid, largely consisting of C8 and C10 fatty acids, leads to a dose- and thime-related increase in the plasma concentration of acetoacetate and beta-hydroxybutyrate. The EHD rats respond to MCT with an increase in plasma ketone bodies that rises to levels that are twice as high as those observed in normal rats receiving MCT and are equivalent to the levels seen in untreated ketoacidotic animals. These data indicate that hepatic medium-chain fatty acid oxidation and ketogenesis are unimparied in the EHD animal. An analysis of the factors responsible for the greater ketogenic response in the EHD rat reveals that moderate diabetes and dehydration enhance MCT-induced ketone body accumulation, while cortisol is without effect. The plasma free fatty acid concentration in EHD animals does not differ from normal rats, but is significantly lower than that seen in diabetic ketoacidosis. These data support the concept that a principal reason for the absence of ketoacidosis in the EHD syndrome is the limitation in availiability of substrate, free fatty acids, for ketone body synthesis.
Diabetes 1975 Mar
PMID:Experimental hyperosmolar diabetic syndrome. Ketogenic response to medium-chain triglycerides. 12 10

1. The regulation of glucose uptake and disposition in skeletal muscle was studied in the isolated perfused rat hindquarter. 2. Insulin and exercise, induced by sciatic-nerve stimulation, enhanced glucose uptake about tenfold in fed and starved rats, but were without effect in rats with diabetic ketoacidosis. 3. At rest, the oxidation of lactate (0.44 mumol/min per 30 g muscle in fed rats) was decreased by 75% in both starved and diabetic rats, whereas the release of alanine and lactate (0.41 and 1.35 mumol/min per 30 g respectively in the fed state) was increased. Glycolysis, defined as the sum of lactate+alanine release and lactate oxidation, was not decreased in either starvation or diabetes. 4. In all groups, exercise tripled O2 consumption (from approximately 8 to approximately 25 mumol/min per 30 g of muscle) and increased the release and oxidation of lactate five- to ten-fold. The differences in lactate release between fed, starved and diabetic rats observed at rest were no longer apparent; however, lactate oxidation was still several times greater in the fed group. 5. Perfusion of the hindquarter of a fed rat with palmitate, octanoate or acetoacetate did not alter glucose uptake or lactate release in either resting or exercising muslce; however, lactate oxidation was significantly inhibited by acetoacetate, which also increased the intracellular concentration of acetyl-CoA. 6. The data suggest that neither that neither glycolysis nor the capacity for glucose transport are inhbitied in the perfused hindquarter during starvation or perfusion with fatty acids or ketone bodies. On the other hand, lactate oxidation is inhibited, suggesting diminished activity of pyruvate dehydrogenase. 7. Differences in the regulation of glucose metabolism in heart and skeletal muscle and the role of the glucose/fatty acid cycle in each tissue are discussed.
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PMID:Glucose metabolism in perfused skeletal muscle. Effects of starvation, diabetes, fatty acids, acetoacetate, insulin and exercise on glucose uptake and disposition. 13 49

A case of N-3 pyridylmethyl-N' 4 nitrophenyl urea (Vacor) rodenticide poisoning in a 52-year-old man is presented. Vacor is structurally related to alloxan and streptozotocin, agents that have been used extensively to produce diabetes mellitus in laboratory animals. Seven days after ingestion of Vacor, the patient presented in diabetic ketoacidosis complicated by postural hypotension and adynamic ileus. The patient recovered from ketoacidosis but has continued to require insulin. With infusion of arginine, glucagon rose from 185 to 650 pg./ml. and C-peptide from 0.5 to 3.4 ng./ml. Six weeks after onset of diabetes, no anti-islet-cell antibodies were detected. Muscle capillary basement membrane thickness on electron microscopy was found to be 1,918 +/- 194 A. The absence of hyperglycemia after Vacor ingestion should not lead to complacency on the part of the attending physician. The patient must be observed closely for development of ketoacidosis and treated prophylactically with nicotinamide, the suggested antidote.
Diabetes Care
PMID:Diabetes mellitus and autonomic dysfunction after vacor rodenticide ingestion. 15 23

A healthy 10-year-old boy was admitted to the hospital in diabetic ketoacidosis within three days of onset of symptoms of a flu-like illness. He died seven days later and post-mortem examination showed lymphocytic infiltration of the islets of Langerhans and necrosis of beta cells. Inoculation of mouse, monkey and human cell cultures with homogenates from the patient's pancreas led to isolation of a virus. Serologic studies revealed a rise in the titer of neutralizing antibody to this virus from less than 4 on the second hospital day to 32 on the day of death. Neutralization data showed that the virus was related to a diabetogenic variant derived from Coxsackievirus B4. Inoculation of mice with the human isolate produced hyperglycemia, inflammatory cells in the islets of Langerhans and beta-cell necrosis. Staining of mouse pancreatic sections with fluorescein-labeled antiviral antibody revealed viral antigens in beta cells. Both the clinical picture and animal studies suggested that the patient's diabetes was virus induced.
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PMID:Isolation of a virus from the pancreas of a child with diabetic ketoacidosis. 21 45

Stupor in patients with nonketotic hyperglycemia has been ascribed to hyperosmolarity, but the cause of depressed consciousness in patients with ketoacidosis has been puzzling. In this study, blood pH, serum glucose and sodium concentrations, and serum osmolality were measured in eighty-five consecutive episodes of diabetic ketoacidosis and forty-seven of nonketotic hyperglycemia. In the acidotic patients, as in those with nonketotic hyperglycemia, stupor closely paralleled hyperosmolarity and not the severity of acidemia. Indeed, the mean elevations of serum osmolarity were almost the same in the ketotic and in the nonketotic patients who were deeply obtunded. It seems likely that depression of consciousness in patients with severely uncontrolled diabetes mellitus, if not due to a nonmetabolic disorder, such as acute stroke, is attributable to hyperosmolarity, whether or not ketoacidosis is present.
Diabetes 1975 Jun
PMID:Hyperosmolar nature of diabetic coma. 23 99

In order to study the determining factors for oxygen transport the oxyhaemoglobin dissociation curve (ODC), red cell 2,3-diphosphoglycerate (2,3-DPG), and plasma inorganic phosphate were estimated in insulin-requiring juvenile and adult diabetics in various conditions of metabolic control. 2,3-DPG has been shown to vary much more in diabetics than in normals, depending upon the state of metabolic control. These fluctuations of 2,3-DPG are mediated by variations in plasma inorganic phosphate as indicated by a close correlation. While 2,3-DPG was markedly decreased in diabetic ketoacidosis, it tended to be increased in ambulatory, non-acidotic patients. Since in the non-acidotic patients the oxygen-carrying capacity, i.e. the haemoglobin concentration was simultaneously elevated, these findings suggest the presence of relative tissue hypoxia in diabetes. Both in non-acidotic and in ketoacidotic patients there was a strong correlation between the amount of 2,3-DPG and the P50 at actual pH as an experssion of the oxygen affinity of haemoglobin. In order to guarantee an optimal erythrocyte oxygen release in diabetics the content of red cell 2,3-DPG and plasma inorganic phosphate should be higher than normal.
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PMID:The problem of tissue oxygenation in diabetes mellitus. 23 28

A family had three siblings affected with classic Friedreich's ataxia. One sibling died at age 20 with fulminant diabetic ketoacidosis. The other two affected siblings are identical twin sisters without clinical diabetes but with an abnormality in the metabolism of exogenously administered glucose. These twins also have abnormal hypothalamic-pituitary control of prolactin and possibly of growth-hormone secretion. This study extends the previous reports of endocrine deficienceis associated with Friedreich's ataxia. The mechanisms underlying this association are undetermined but could represent pleiotropic effects of the Friedreich's ataxia gene or secondary manifestations of the primary central nervous system degeneration, or both.
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PMID:Abnormal function of endocrine pancreas and anterior pituitary in Friedreich's ataxia. Studies in a family. 34 4

We investigated the importance of glucagon in the development of diabetic ketoacidosis by withholding insulin from six patients with juvenile-type diabetes and four totally pancreatectomized subjects. Patients were fasting and had previously been maintained on intravenous insulin for 24 hours. In diabetic patients plasma glucagon concentrations rose sharply after withdrawal of insulin, and the increases were accompanied by a rise in blood ketone concentration of 4.1+/-0.7 (S.E.M.) and blood glucose concentration of 12.5+/-1.8 mmol per liter by 12 hours. In the pancreatectomized patients, despite the absence of measurable glucagon, blood ketones rose by 1.8+/-0.8 and blood glucose by 7.7+/-1.5 mmol per liter. Thus, glucagon is not essential for the development of ketoacidosis in diabetes, as has previously been suggested, but it may accelerate the onset of ketonemia and hyperglycemia in situations of insulin deficiency.
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PMID:Ketoacidosis in pancreatectomized man. 40 53

Diabetic ketoacidosis is characterized by an excess secretion of counterregulatory hormones (glucagon, catecholamines, cortisol, and growth hormone). Experimental evidence obtained in both diabetic man and animals suggests that elevation of the plasma concentration of these hormones is necessary to initiate excess hepatic production of ketone bodies. This increase in hepatic ketogenesis in concert with inability of peripheral tissues to completely utilize ketone bodies results in clinical ketoacidosis. This hypothesis would suggest that pharmacologic control of excess counterregulatory hormone secretion would be a rational therapeutic modality to prevent diabetic ketoacidosis.
Diabetes 1977 Jun
PMID:The controversy concerning counterregulatory hormone secretion. A hypothesis for the prevention of diabetic ketoacidosis? 40 65


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