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

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Query: UMLS:C0027497 (nausea)
23,468 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Exenatide is the first in a new class of compounds that exhibit activity similar to the naturally occurring hormone glucagon-like peptide-1 (GLP-1). Released from cells in the gut in response to food, GLP-1 binds to pancreatic beta-cell receptors to stimulate the release of insulin. Exenatide mirrors many of the effects of GLP-1, improving glycemic control through a combination of mechanisms, which include glucose-dependent stimulation of insulin secretion, suppression of glucagon secretion, slowing of gastric emptying, reduced appetite and enhanced beta-cell function. As stimulation of insulin secretion occurs only in the presence of elevated blood glucose concentrations, the risk of hypoglycemia should be greatly reduced with exenatide. In addition to positive therapeutic effects on fasting and postprandial glucose levels, exenatide treatment is associated with significant, dose-dependent reductions in glycated hemoglobin (HbA1c) from baseline and progressive reductions in body weight. Exenatide is generally well tolerated; nausea is the most commonly reported side effect, but it can be significantly reduced when a target dose of exenatide is achieved in patients with gradual dose titration. Exenatide may enable patients with type 2 diabetes to achieve glycemic control while reducing or eliminating the risk of hypoglycemia and weight gain. These would represent significant therapeutic gains.
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PMID:Exenatide. 1634 Dec 88

Recognizing that type 1 diabetes was characterized not only by insulin deficiency, but also by amylin deficiency, Cooper (Cooper, 1991) predicted that certain features of the disease could be related thereto, and he proposed amylin/insulin co-replacement therapy. Although the early physiological rationale was flawed, the idea that glucose control could be improved over that attainable with insulin alone without invoking the ravages of worsening insulin-induced hypoglycemia was vindicated. The proposal spawned a first-in-class drug development program that ultimately led to marketing approval by the U.S. Food and Drug Administration of the amylinomimetic pramlintide acetate in March 2005. The prescribers' package insert (Amylin Pharmaceuticals Inc., 2005), which includes a synopsis of safety and efficacy of pramlintide, is included as Appendix 1. Pramlintide exhibited a terminal t1/2, in humans of 25-49 min and, like amylin, was cleared mainly by the kidney. The dose-limiting side effect was nausea and, at some doses, vomiting. These side effects usually subsided within the first days to weeks of administration. The principal risk of pramlintide co-therapy was an increased probability of insulin-induced hypoglycemia, especially at the initiation of therapy. This risk could be mitigated by pre-emptive reduction in insulin dose. Pramlintide dosed at 30-60 microg three to four times daily in patients with type 1 diabetes, and at doses of 120 microg twice daily in patients with type 2 diabetes, invoked a glycemic improvement, typically a decrease in HbA1c of 0.4-0.5% relative to placebo, that was sustained for at least 1 year. This change relative to control subjects treated with insulin alone typically was associated with a reduction in body weight and insulin use, and was not associated with an increase in rate of severe hypoglycemia other than at the initiation of therapy. Effects observed in animals, such as slowing of gastric emptying, inhibition of nutrient-stimulated glucagon secretion, and inhibition of food intake, generally have been replicated in humans. A notable exception appears to be induction of muscle glycogenolysis and increase in plasma lactate.
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PMID:Clinical studies. 1649 55

Pramlintide is the first new antihyperglycemic agent approved for both type 2 and type 1 diabetes since insulin was developed in the 1920s. It is a synthetic analogue of human amylin, a naturally occurring neuroendocrine hormone synthesized by pancreatic beta cells. Pramlintide helps regulate the rate of glucose appearance and improves glucose control postprandially. This action is accomplished through suppressing inappropriate postprandial glucagon secretion and regulating gastric emptying, and is associated with a feeling of satiety. It is given at mealtimes and is indicated for use in type 2 and type 1 diabetes as an adjunct treatment in patients who use mealtime insulin therapy and who have failed to achieve desired glucose control despite optimal insulin therapy. Pramlintide therapy should only be considered for patients who are receiving ongoing care under the guidance of a health care professional skilled in the use of insulin and supported by services of diabetes educators. Pramlintide is used with insulin and has been associated with an increased risk of insulin-induced severe hypoglycemia, particularly in type 1 diabetes. Appropriate patient selection, careful patient instruction, and insulin dose adjustments help reduce this risk. In type 2 diabetes, pramlintide is initiated at 60 microg and may be increased to 120 microg two to three times daily with meals. In type 1 diabetes, pramlintide is initiated at 15 microg and may be increased to 30 or 60 microg with meals. Mealtime insulin should be reduced by 50% at pramlintide initiation and adjusted as the pramlintide dose is increased. It should be given subcutaneously with an insulin syringe and should not be mixed with insulin. The most commonly reported side effect is mild to moderate nausea with initiation, which is usually transient and short term in nature. Frequent self-monitoring of blood glucose is important during initiation to assist in insulin adjustments. Insulin type, dose, and timing as well as basal/bolus balance may require adjustment during pramlintide initiation. Despite requiring additional injections, patients report satisfaction with pramlintide therapy.
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PMID:Use of pramlintide: the patient's perspective. 1675 52

We provide a global assessment, with detailed multi-scale data, of the ecological and toxicological effects generated by inorganic nitrogen pollution in aquatic ecosystems. Our synthesis of the published scientific literature shows three major environmental problems: (1) it can increase the concentration of hydrogen ions in freshwater ecosystems without much acid-neutralizing capacity, resulting in acidification of those systems; (2) it can stimulate or enhance the development, maintenance and proliferation of primary producers, resulting in eutrophication of aquatic ecosystems; (3) it can reach toxic levels that impair the ability of aquatic animals to survive, grow and reproduce. Inorganic nitrogen pollution of ground and surface waters can also induce adverse effects on human health and economy. Because reductions in SO2 emissions have reduced the atmospheric deposition of H2SO4 across large portions of North America and Europe, while emissions of NOx have gone unchecked, HNO3 is now playing an increasing role in the acidification of freshwater ecosystems. This acidification process has caused several adverse effects on primary and secondary producers, with significant biotic impoverishments, particularly concerning invertebrates and fishes, in many atmospherically acidified lakes and streams. The cultural eutrophication of freshwater, estuarine, and coastal marine ecosystems can cause ecological and toxicological effects that are either directly or indirectly related to the proliferation of primary producers. Extensive kills of both invertebrates and fishes are probably the most dramatic manifestation of hypoxia (or anoxia) in eutrophic and hypereutrophic aquatic ecosystems with low water turnover rates. The decline in dissolved oxygen concentrations can also promote the formation of reduced compounds, such as hydrogen sulphide, resulting in higher adverse (toxic) effects on aquatic animals. Additionally, the occurrence of toxic algae can significantly contribute to the extensive kills of aquatic animals. Cyanobacteria, dinoflagellates and diatoms appear to be major responsible that may be stimulated by inorganic nitrogen pollution. Among the different inorganic nitrogenous compounds (NH4+, NH3, NO2-, HNO2NO3-) that aquatic animals can take up directly from the ambient water, unionized ammonia is the most toxic, while ammonium and nitrate ions are the least toxic. In general, seawater animals seem to be more tolerant to the toxicity of inorganic nitrogenous compounds than freshwater animals, probably because of the ameliorating effect of water salinity (sodium, chloride, calcium and other ions) on the tolerance of aquatic animals. Ingested nitrites and nitrates from polluted drinking waters can induce methemoglobinemia in humans, particularly in young infants, by blocking the oxygen-carrying capacity of hemoglobin. Ingested nitrites and nitrates also have a potential role in developing cancers of the digestive tract through their contribution to the formation of nitrosamines. In addition, some scientific evidences suggest that ingested nitrites and nitrates might result in mutagenicity, teratogenicity and birth defects, contribute to the risks of non-Hodgkin's lymphoma and bladder and ovarian cancers, play a role in the etiology of insulin-dependent diabetes mellitus and in the development of thyroid hypertrophy, or cause spontaneous abortions and respiratory tract infections. Indirect health hazards can occur as a consequence of algal toxins, causing nausea, vomiting, diarrhoea, pneumonia, gastroenteritis, hepatoenteritis, muscular cramps, and several poisoning syndromes (paralytic shellfish poisoning, neurotoxic shellfish poisoning, amnesic shellfish poisoning). Other indirect health hazards can also come from the potential relationship between inorganic nitrogen pollution and human infectious diseases (malaria, cholera). Human sickness and death, extensive kills of aquatic animals, and other negative effects, can have elevated costs on human economy, with the recreation and tourism industry suffering the most important economic impacts, at least locally. It is concluded that levels of total nitrogen lower than 0.5-1.0 mg TN/L could prevent aquatic ecosystems (excluding those ecosystems with naturally high N levels) from developing acidification and eutrophication, at least by inorganic nitrogen pollution. Those relatively low TN levels could also protect aquatic animals against the toxicity of inorganic nitrogenous compounds since, in the absence of eutrophication, surface waters usually present relatively high concentrations of dissolved oxygen, most inorganic reactive nitrogen being in the form of nitrate. Additionally, human health and economy would be safer from the adverse effects of inorganic nitrogen pollution.
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PMID:Ecological and toxicological effects of inorganic nitrogen pollution in aquatic ecosystems: A global assessment. 1678 74

We wanted to assess the effectiveness and safety of glargine in the treatment of patients with type 2 diabetes mellitus in secondary failure and/or with severe comorbidities ("T2DM group"), and patients with secondary diabetes after corticosteroid and/or anticancer treatment ("secondary DM group"). We reviewed the records of patients on glargine from 1 August 2004 to 30 July 2005. The after-minus-before change in HbA1c was the main outcome measure. At baseline, the 18 "T2DM" patients had a mean (+/-SD) age of 66.7+/-9.5 years and a diabetes duration of 13.6+/-10.3 years; 52.9% were male. Their fasting plasma glucose (FPG) decreased from 228.6+/-76.6 to 134.6+/-37.5, two-hour post-prandial glycaemia (2hPPG) from 268.2+/-10.4 to 140.6+/-30.8 and HbA1c from 10.4+/-2.3 to 7.9+/-1.6%. Mean daily insulin dosage was 12.0+/-4.8 UI for glargine alone and 37.4+/-22.6 UI for basal-bolus scheme. The daily cost was Euro 0.75 (range Euro 0.31-1.15). The 24 "secondary DM" patients had a mean age of 67.0+/-11.0 years and a diabetes duration of 3.7+/-6.5 years; 54.2% were male and 91.7% had a metastatic cancer. Their FPG decreased from 222.3+/-108.6 to 121.5+/-28.7 mg/dl, 2hPPG from 259.4+/-108.6 to 133.0+/-35.0 mg/dl and HbA1c from 10.1+/-2.5 to 7.6+/-1.3%. Mean daily insulin dosage was 12.5+/-6.1 UI for glargine alone and 27.2+/-9.1 UI for basal-bolus scheme. Mean daily cost was Euro 0.70 (range Euro 0.31-1.38). One (4.2%) cancer patient withdrew from glargine because of nausea. Nine (37.5%) cancer patients had an increase in appetite after glargine therapy, including 3 end-of-life patients. No severe hypoglycaemia occurred. Insulin glargine was safe and effective in improving glycaemic control both in severe "T2DM" and in "secondary DM" patients.
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PMID:Effectiveness and safety of insulin glargine in the therapy of complicated or secondary diabetes: clinical audit. 1686 31

Hyperglycemic hyperosmolar state (HHS) is an acute complication mostly occurring in elderly type 2 diabetes mellitus (DM). Thyrotoxicosis causes dramatic increase of glycogen degradation and/or gluconeogenesis and enhances breakdown of triglycerides. Thus, in general, it augments glucose intolerance in diabetic patients. A 23-yr-old female patient with Graves' disease and type 2 DM, complying with methimazole and insulin injection, had symptoms of nausea, polyuria and generalized weakness. Her serum glucose and osmolarity were 32.7 mM/L, and 321 mosm/kg, respectively. Thyroid function tests revealed that she had more aggravated hyperthyroid status; 0.01 mU/L TSH and 2.78 pM/L free T3 (reference range, 0.17-4.05, 0.31-0.62, respectively) than when she was discharged two weeks before (0.12 mU/L TSH and 1.41 pM/L free T3). Being diagnosed as HHS and refractory Graves' hyperthyroidism, she was treated successfully with intravenous fluids, insulin and high doses of methimazole (90 mg daily). Here, we described the case of a woman with Graves' disease and type 2 DM developing to HHS.
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PMID:A case of hyperglycemic hyperosmolar state associated with Graves' hyperthyroidism: a case report. 1689 29

We present the case of an 80-year-old lady known to be sensitive to chlorocresol (4-chloro-3-methyl phenol) who developed severe erythrodermic exfoliative dermatitis with atypical features 2 weeks after commencing subcutaneous insulin. All medications except insulin were stopped, without major improvement. It was noted that the insulin contained m-cresol (m-methyl phenol) so a parabens-based insulin was substituted. There was a significant improvement in her clinical condition within 72 hr. Further patch and intradermal testing to the insulin and m-cresol was planned, but she developed a nosocomial infection and died. We hypothesize that the adverse cutaneous reaction was a systemic manifestation of cresol sensitivity, given the rapid clinical resolution on changing insulins and the previously demonstrated sensitivity to chlorocresol, particularly as cross-reactivity between different low molecular weight methyl phenols is documented. Local injection site reactions and systemic side-effects including nausea, diarrhoea and vomiting have previously been reported with cresol-containing insulins, although to our knowledge, this is the first reported case of a severe cutaneous reaction. It is important to be aware of m-cresol as a potential allergen, as it is contained in most commercially available insulins.
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PMID:Severe adverse cutaneous reaction to insulin due to cresol sensitivity. 1693 Feb 41

It has been postulated that the stress response is associated with water balance via regulating vasopressin release. Nausea, surgical stress and insulin-induced hypoglycaemia were shown to stimulate vasopressin secretion in humans. Increased vasopressin release in turn induces water resorption through the kidneys. Although the mechanism of the stress-mediated vasopressin release is not entirely understood, it is generally accepted that catecholamines play a crucial role in influencing water balance by modulating the secretion of vasopressin. However, the morphological substrate of this modulation has not yet been established. The present study utilised double-label immunohistochemistry to reveal putative juxtapositions between tyrosine hydroxylase (TH)-immunoreactive (IR) catecholaminergic system and the vasopressin systems in the human hypothalamus. In the paraventricular and supraoptic nuclei, numerous vasopressin-IR neurones received TH-IR axon varicosities. Analysis of these juxtapositions with high magnification combined with oil immersion did not reveal any gaps between the contacted elements. In conclusion, the intimate associations between the TH-IR and vasopressin-IR elements may be functional synapses and may represent the morphological basis of vasopressin release modulated by stressors. Because certain vasopressin-IR perikarya receive no detectable TH innervations, it is possible that additional mechanisms may participate in the stress-influenced vasopressin release.
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PMID:Morphological substrate of the catecholaminergic input of the vasopressin neuronal system in humans. 1707 65

Incretin mimetics are a new class of pharmacological agents with multiple antihyperglycemic actions that mimic several of the actions of incretin hormones originating in the gut, such as glucagon-like peptide (GLP)-1. Dipeptidyl peptidase-IV (DPP-IV) inhibitors suppress the degradation of many peptides, including GLP-1, thereby extending their bioactivity. These agents seem to have multiple mechanisms of action for the treatment of type 2 diabetes mellitus (T2DM), including some or all the following: enhancement of glucose-dependent insulin secretion, suppression of inappropriately elevated glucagon secretion, slowing of gastric emptying, and decreased food intake. Exenatide (BYETTA) is the first incretin mimetic approved for clinical use by the US Food and Drug Administration. In phase 3 clinical trials, exenatide reduced HbA(1c) by approximately 1% and body weight by approximately 2 kg in T2DM patients failing to achieve glycemic control with metformin and/or a sulfonylurea, with mild-to-moderate nausea the most common side effect. Several GLP-1 analogues and DPP-IV inhibitors are in late-stage clinical testing and may soon become available for treating T2DM patients. The use of these agents may provide an opportunity to bring about new improvements in diabetes care.
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PMID:Incretin mimetics and DPP-IV inhibitors: new paradigms for the treatment of type 2 diabetes. 1709 Jul 94

Glucagon-like peptide 1 (GLP-1) is a gut-derived incretin hormone that stimulates insulin and suppresses glucagon secretion, inhibits gastric emptying, and reduces appetite and food intake. Therapeutic approaches for enhancing incretin action include degradation-resistant GLP-1 receptor agonists (incretin mimetics), and inhibitors of dipeptidyl peptidase-4 (DPP-4) activity (incretin enhancers). Clinical trials with the incretin mimetic exenatide (two injections per day or long-acting release form once weekly) and liraglutide (one injection per day) show reductions in fasting and postprandial glucose concentrations, and haemoglobin A1c (HbA1c) (1-2%), associated with weight loss (2-5 kg). The most common adverse event associated with GLP-1 receptor agonists is mild nausea, which lessens over time. Orally administered DPP-4 inhibitors, such as sitagliptin and vildagliptin, reduce HbA1c by 0.5-1.0%, with few adverse events and no weight gain. These new classes of antidiabetic agents, and incretin mimetics and enhancers, also expand beta-cell mass in preclinical studies. However, long-term clinical studies are needed to determine the benefits of targeting the incretin axis for the treatment of type 2 diabetes.
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PMID:The incretin system: glucagon-like peptide-1 receptor agonists and dipeptidyl peptidase-4 inhibitors in type 2 diabetes. 1725 57


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