Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0011860 (type 2 diabetes)
57,723 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Over the past few years, several oral agents for the treatment of type 2 diabetes have become available in the United States. Metformin, a biguanide that has been used for decades in other countries throughout the world, improves glycemic control without exacerbating hyperinsulinemia or promoting weight gain. This agent has recently been reintroduced in the United States. Acarbose is an alpha-glucosidase inhibitor that improves glycemic control by decreasing the intestinal absorption of glucose, thereby decreasing postprandial glucose elevations. The use of metformin and acarbose may be limited by their side effects and potential risks, especially the risk of lactic acidosis with metformin. The third newly available agent, troglitazone, has been shown to improve insulin sensitivity. Combinations of metformin, acarbose and troglitazone may facilitate improved glycemic control without the use of insulin, or they may allow sulfonylurea or insulin dosages to be reduced, in this way minimizing the adverse effects of hyperinsulinemia. Unfortunately, current oral therapies do not prevent the inevitable decline in glycemic control that occurs during the natural history of type 2 diabetes.
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PMID:New oral therapies for type 2 diabetes. 937 Oct 13

Although low-density lipoprotein (LDL) cholesterol is a critically important factor in the development of atherosclerosis, nearly half the patients with coronary artery disease have LDL cholesterol levels within the National Cholesterol Education Program (NCEP) guidelines. Therefore, attention has focused on other modifiable risk factors that could strongly impact the development of coronary artery disease. Type 2 diabetics have a 3-fold increased risk of coronary artery disease; prediabetics, without chronic hyperglycemia, have a 2-fold increased risk compared with normal subjects. Insulin resistance has also been implicated as the cause of atherosclerosis. Insulin resistance is associated with hyperinsulinemia and a constellation of other factors, some of which are themselves independent risk factors for coronary artery disease. These include reduced levels of high-density lipoprotein (HDL) cholesterol, hypertriglyceridemia, increased small dense LDL particles, hypertension, visceral obesity, and increased levels of plasminogen activator inhibitor-1 (PAI-1). Hyperinsulinemia and insulin resistance at the vascular level also may contribute to vascular injury and the atherosclerotic process. Current studies suggest that controlling hyperglycemia, LDL cholesterol, and blood pressure are important to protect the diabetic from atherosclerosis. A key question, particularly in type 2 diabetes, is to define the best regimen for glucose control that will protect the vasculature. Sulfonylureas, metformin, and troglitazone have direct vascular actions. Metformin lowers LDL cholesterol and triglycerides, while troglitazone reverses many of the components associated with the insulin resistance syndrome. Clinical trials focusing on coronary artery disease outcomes are now warranted to prevent coronary artery disease, the major vascular complication and cause of mortality in diabetes.
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PMID:Cardiovascular risk continuum: implications of insulin resistance and diabetes. 970 62

We investigated the role of glucose-6 phosphatase (Glc6Pase), glucokinase (GK), and glucose-6 phosphate (Glc6P) in liver insulin resistance, an early characteristic of type 2 diabetes, and its correction by metformin. We determined hepatic glucose production (HGP) by tracer dilution, and enzyme activities and substrate concentrations after saline or insulin perfusions during euglycemic clamps in rats fed: 1) a standard hyperglucidic diet (S); 2) a high-fat diet (HF); and 3) a high-fat diet and treated with the oral antidiabetic metformin (HF/Met). Basal HGP was similar in the 3 groups: 75+/-8, 65+/-9.5 and 71+/-3 micromol x kg(-1) x min(-1) (means+/-SEM, N=5) in S, HF and HF/Met rats, respectively. Upon insulin perfusion at 240 pmol/hr, HGP was decreased by 35% in S rats (49+/-4.5 micromol x kg(-1) x min(-1), P < 0.01 vs. basal) and 65% in HF/Met rats (23+/-10 micromol x kg(-1) x min(-1), P < 0.01 vs basal), whereas it was not decreased in HF rats (60+/-12 micromol x kg(-1) x min(-1)), revealing insulin resistance. GK activity was lower (by 65%, P < 0.01) in HF and HF/Met rats (0.8+/-0.1 and 0.9+/-0.1 U/g liver, respectively) than in S rats (2.4+/-0.3 U/g). Microsomal Glc6Pase activity was lower (by 35%, P < 0.01) in HF and HF/Met rats (0.25+/-0.01 and 0.27+/-0.02 micromol r min(-1) x mg prot x (-1), respectively) than in S rats (0.39+/-0.03 micromol x min(-1) x mg prot x (-1)). Glc6P concentration was decreased by insulin perfusion at 480 pmol/hr in S and HF/Met rats (P < 0.05 vs. saline), but not in HF rats, in agreement with insulin resistance in the latter group. However, the differential inhibitions of HGP by insulin could not be ascribed to the variations in Glc6P concentrations. Metformin was present in the liver at a concentration of 27+/-2 nmol/g wet tissue and was not detected in the plasma. These results strongly suggest that the regulation of HGP by insulin additionally involves short-term regulatory mechanism(s) of Glc6Pase, occurring in vivo, and lost under in vitro conditions. These might be impaired in HF rats, in keeping with insulin resistance of HGP, and restored by metformin.
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PMID:Role of glucose-6 phosphatase, glucokinase, and glucose-6 phosphate in liver insulin resistance and its correction by metformin. 971 75

The hyperglycemia, hyperinsulinemia, insulin resistance, and obesity syndrome associated with type 2 diabetes can have debilitating consequences. The biguanide metformin has a mechanism of action that is complementary to those of insulin and the sulfonylureas, suggesting that combination therapy that includes metformin may result in improved glycemic control. The purpose of this retrospective chart review was to determine the effects of adding metformin in an uncontrolled fashion to existing therapy in obese patients with type 2 diabetes who had suboptimal glycemic control and insulin resistance. For the review, the records of 124 patients were divided into two groups: group 1 included 71 patients who were taking insulin with or without a sulfonylurea, and group 2 consisted of 53 patients who were taking a sulfonylurea alone. Metformin was added to patients' existing therapy in conjunction with downward titration of the sulfonylurea and insulin doses. A retrospective chart review was conducted at the end of 6 months for group 1 and at the end of 12 months for group 2 to determine the change from baseline in measures of diabetes control (ie, insulin and sulfonylurea dose, glycated hemoglobin [Hb A1c] value, body mass index [BMI], and lipid profiles). In group 1, the mean insulin dose decreased from 46.4 U/d at baseline to 6.1 U/d at the end of follow-up. Eighty-three percent of the patients were able to discontinue insulin therapy completely. Similarly, group 2 had statistically significant reductions in mean sulfonylurea dose. Both groups also achieved statistically significant reductions in Hb A1c, BMI, and total cholesterol level. The addition of metformin to treatment with insulin or sulfonylureas, either alone or in combination, significantly improved glycemic control and cholesterol levels and promoted weight loss in obese type 2 diabetic patients with insulin resistance. Less than 5% of patients reported mild, transient gastrointestinal side effects, none of which required cessation of metformin therapy. Five patients discontinued metformin due to lack of efficacy.
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PMID:A retrospective chart review of uncontrolled use of metformin as an add-on therapy in type 2 diabetes. 973 29

Obesity is common in NIDDM; in a cohort of 314 diabetics in Singapore, 44.3% are overweight. Management of obesity in diabetics differs from that in non-diabetics in that it is more urgent; weight maintenance is more difficult and hypoglycaemic medication may cause weight changes. Like in the non-diabetic, management of obesity in diabetic requires a pragmatic and realistic approach. A team approach is required: the help of the nurse educator, the dietitian, behaviour modification therapist, exercise therapist etc are required. A detailed history, careful physical examination and relevant investigations are required to assess the severity of the diabetic state and to exclude an occasional underlying cause of the obesity in the obese NIDDM. Weight loss is urgent in the obese NIDDM, especially those with android obesity. There must be a reduction in caloric intake. Weight loss leads to improvement in the glucose tolerance, insulin sensitivity, reduction in lipid levels and fall in blood pressure in the hypertensive. Exercise is of limited value except in the younger obese NIDDM. Metformin is the hypoglycaemic drug of choice as it leads to consistent weight reduction. The sulphonylureas may cause weight gain. Insulin should be avoided where possible as it causes further weight gain. Other hypoglycaemic agents include Glucobay (alpha-glucosidase inhibitor) and Troglitazone (insulin sensitizer) which do not alter the weight. Orlistat (lipase inhibitor) is promising as it causes reduction of weight, blood-glucose and lipid levels. Anti-obesity drugs (noradrenergic and serotonergic agents) have modest effects on weight reduction in the obese NIDDM; a widely use preparation, Dexfenfluramine (Adifax) has been withdrawn because of side effects. Surgery such as gastric plication is the last resort in treating the morbidly obese NIDDM. The discovery of leptin in 1994 has led to intense research into energy homeostasis in obesity; hopefully this will lead to better treatment of obesity in diabetics and non-diabetics.
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PMID:Management of obesity in NIDDM (non-insulin-dependent diabetes mellitus). 984 3

Methylglyoxal (MG) is a reactive alpha-dicarbonyl that is thought to contribute to diabetic complications either as a direct toxin or as a precursor for advanced glycation end products. It is produced primarily from triose phosphates and is detoxified to D-lactate (DL) by the glyoxalase pathway. Because guanidino compounds can block dicarbonyl groups, we have investigated the effects of the diamino biguanide compound metformin and of hyperglycemia on MG and its detoxification products in type 2 diabetes. MG and DL were measured by high-performance liquid chromatography in plasma from 57 subjects with type 2 diabetes. Of these subjects, 27 were treated with diet, sulfonylureas, or insulin (nonmetformin), and 30 were treated with metformin; 28 normal control subjects were also studied. Glycemic control was determined by HbA1c. MG was significantly elevated in diabetic subjects versus the normal control subjects (189.3 +/- 38.7 vs. 123.0 +/- 37 nmol/l, P = 0.0001). MG levels were significantly reduced by high-dosage (1,500-2,500 mg/day) metformin (158.4 +/- 44.2 nmol/l) compared with nonmetformin (189.3 +/- 38.7 nmol/l, P = 0.03) or low-dosage (< or = 1,000 mg/day) metformin (210.98 +/- 51.0 nmol/l, P = 0.001), even though the groups had similar glycemic control. Conversely, DL levels were significantly elevated in both the low- and high-dosage metformin groups relative to the nonmetformin group (13.8 +/- 7.7 and 13.4 +/- 4.6 vs. 10.4 +/- 3.9 micromol/l, P = 0.03 and 0.06, respectively). MG correlated with rising HbA1c levels (R = 0.4, P = 0.03, slope = 13.2) in the nonmetformin subjects but showed no increase with worsening glycemic control in the high-dosage metformin group (R = 0.0004, P = 0.99, slope = 0.02). In conclusion, MG is elevated in diabetes and relates to glycemic control. Metformin reduces MG in a dose-dependent fashion and minimizes the effect of worsening glycemic control on MG levels. To the extent that elevated MG levels lead to their development, metformin treatment may protect against diabetic complications by mechanisms independent of its antihyperglycemic effect.
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PMID:Metformin reduces systemic methylglyoxal levels in type 2 diabetes. 989 43

Metformin is a biguanide used to treat type II diabetes mellitus. Since the recent introduction of this drug into the United States there has been considerable interest in metformin associated lactic acidosis (MALA) following intravenous contrast media. The Royal College of Radiologists published advice in November, 1996 (Advice to Members and Fellows with regard to metformin-induced lactic acidosis and X-ray contrast medium agents, RCR Publication) supporting the manufacturers' advice that metformin should not be used in the 48 h before or after intravenous (i.v.) contrast medium. We performed a systematic review of the literature and this has shown that almost all reported cases of MALA following i.v. contrast medium occurred where there was either pre-existing poor renal function or another contraindication to metformin usage. There has been only one reported case of lactic acidosis following the use of intravenous contrast medium in a patient with normal renal function. We suggest that the Royal College of Radiologists' advice should be modified and that it is safe to give i.v. contrast medium to patients on metformin with normal renal function.
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PMID:Metformin and contrast media--a dangerous combination? 991 7

The treatment of NIDDM patients with secondary failure to sulphonylurea is a common problem. We performed a crossover study in 50 NIDDM patients with secondary failure to glibenclamide by comparing the addition to sulphonylurea of either a low-dose bedtime NPH insulin or a t.i.d. oral metformin and by analyzing treatment efficacy in relation to patient and disease characteristics. Both combined therapies clearly improved glycaemic control. HbA1 c were similarly reduced by the addition of either bedtime NPH insulin (7.6+/-0.34 vs 8.7+/-0.35, p<0.01) or metformin (7.6+/-0.22 vs 8.6+/-0.31, p<0.01). Also fasting plasma glucose (FPG) and post-prandial plasma glucose (PPPG) significantly decreased (p<0.01) with both treatments. Bed-time NPH insulin was more effective on FPG reduction than metformin (-36+/-2% vs -25+/-2%, p<0.01); in contrast, metformin addition was more effective on PPPG reduction than bedtime NPH insulin addition (-30+/-2% vs 20+/-3%, p<0.01). Serum cholesterol was marginally but significantly decreased after metformin (5.49+/-0.19 vs 5.91 +/-0.18 mM, p<0.05) but not after NPH insulin. Body weight increase was significantly greater after insulin addition than after metformin (1.47+/-0.25 Kg vs 0.64+/-0.17 p=0.02). All patients preferred the addition of metformin rather than NPH insulin. None of the measured clinical and metabolic variables (before treatment FPG and PPPG, HbA1 c, post-glucagon C-peptide levels, insulin sensitivity, patient age, BMI and diabetes duration) significantly correlated to the efficacy of the two combined treatments studied. In conclusion, in NIDDM patients with secondary failure to sulphonylureas the addition of either low-dose bedtime NPH insulin or t.i.d. metformin is similarly effective in improving glycaemic control. Metformin is better accepted by patients and provides a modest advantage in terms of body weight and cholesterol levels. The most common clinical and metabolic variables are not useful for predicting the efficacy of these two combined treatments.
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PMID:Efficacy of combined treatments in NIDDM patients with secondary failure to sulphonylureas. Is it predictable? 997 73

Metformin, one of the biguanides, is an oral hypoglycemic agent which acts primarily by decreasing hepatic glucose output and by increasing peripheral glucose disposal, therefore it has different hypoglycemic mechanism from that of sulfonylureas. The hypoglycemic effects of metformin are observed not only in obese NIDDM patients, but also in non-obese NIDDM patients. Moreover, addition of metformin improves glycemic control in patients with suboptimal glycemic control while taking maximum sulfonylurea therapy. Therefore, it is complementary to sulfonylurea therapy and represents a useful additional drug for the treatment, irrespective of obesity. The rare but serious condition of lactic acidosis should be kept in mind as a potential side effect, however, if metformin is avoided in patients with contraindications, the medication is very safe.
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PMID:[Therapeutic utility of biguanides in the treatment of NIDDM]. 1019 50

In 43 amenorrheic women with polycystic ovary syndrome (PCOS), 31 (74%) with fasting hyperinsulinemia (> or =20 microU/mL), our aim was to determine whether Metformin (Bristol-Myers Squibb, Princeton, NJ), which reduces hyperinsulinemia, would reverse the endocrinopathy of PCOS, allowing resumption of regular normal menses. A second aim was to assess the effects of weight loss versus other Metformin-induced effects on ovarian function, and to determine if there were different responses to Metformin between those who lost weight and those who did not. A third aim was to assess associations between PCOS, 4G/5G polymorphism in the promoter sequence of the plasminogen activator inhibitor-1 gene (PAI-1 gene), and PAI activity (PAI-Fx). Of the 43 women, 40 (93%) had normal fasting blood glucose and 37 had normal hemoglobin A1C (HgA1C); onlythree (7%) had type 2 diabetes mellitus. Metformin (1.5 to 2.25 g/d) was given for 6.1+/-5.1 months (range, 1.5 to 24), to 16 patients for less than 3 months, to 12 for 3 to 6 months, and to 15 for at least 6 months. On Metformin, 39 of 43 patients (91%) resumed normal menses. The percentage of women resuming normal menses did not differ among treatment duration groups (P<.1) or among dose groups (P>.1). The body mass index (BMI) decreased from 36.4 + 7 Kg/m2 at study entry to 35.1+/-6.7 on Metformin (P=.0008). Of 43 patients, 28 (67%) lost weight (1 to 69 pounds), with nine (21%) losing at least 12 pounds. On Metformin, the median fasting serum insulin decreased from 26 microU/mL to 22 (P=.019), testosterone decreased from 61 ng/dL to 47 (P=.003), and estradiol increased from 41 pg/mL to 71 (P=.0001). Metformin-induced improvements in ovarian function were independent of weight loss (testosterone decrease, P<.002; estradiol increase, P<.0004). The change in response variables on Metformin did not differ (P>.05) between those who lost weight and those who did not, excepting Lp(a), which increased 4 mg/dL in those who lost weight and decreased 9 mg/dL in those who did not (P = .003). The change in response variables on Metformin did not differ among the five quintiles of weight loss, excepting fasting glucose (P<.05), which increased 6 mg/dL in those who lost the least weight on Metformin versus those in the 60th to 80th percentile for weight loss, in whom glucose decreased 33 mg/dL. Although the pretreatment fasting serum insulin was not significantly correlated with testosterone (r=.24, P=.13) or androstenedione (r=.27, P=.09), on Metformin, the change in insulin correlated positively with the change in testosterone (r=.35, P=.047) and with the change in androstenedione (r=.48, P=.01). Patients were more likely than normal controls (83% v 64%, P=.016) to be heterozygous or homozygous for 4G polymorphism of the PAI-1 gene and were also more likely to have high PAI-Fx (> or =22 U/mL, 28% v3%, chi(2)=10.1, P=.001). Metformin reduces the endocrinopathy of PCOS, allowing resumption of normal menses in most (91%) previously amenorrheic women with PCOS.
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PMID:Metformin-induced resumption of normal menses in 39 of 43 (91%) previously amenorrheic women with the polycystic ovary syndrome. 1020 47


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