UMLS:C0011860 - FACTA Search

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Query: UMLS:C0011860 (type 2 diabetes)
57,723 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The expression of leptin, an adipocyte-derived protein whose circulating levels reflect energy stores, can be induced by tumor necrosis factor (TNF)alpha in rodents, but an association between the TNF alpha system and leptin levels has not been reported in humans. To evaluate the potential association between serum leptin and the TNF alpha system, we measured the levels of soluble TNF alpha-receptor (sTNF alpha-R55), which has been validated as a sensitive indicator of activation of the TNF alpha system. We studied two groups: 1) 82 young healthy normal controls and 2) 48 patients with noninsulin dependent diabetes mellitus (NIDDM) and 24 appropriately matched controls. By simple regression analysis in controls, there was a strong positive association between leptin and 3 parameters: body mass index, sTNF alpha-R55, and insulin levels. In a multiple regression analysis model, leptin remained significantly and strongly associated with body mass index, and the association of leptin with both insulin and sTNF alpha-R55, although weakened, remained significant. Patients with NIDDM had leptin concentrations similar to controls of similar weight. Importantly, serum levels of sTNF alpha-R55 were also positively and independently associated with leptin in this group of diabetic subjects and matched controls. These data are consistent with the hypothesis that the TNF alpha system plays a role in regulating leptin levels in humans. Further elucidation of a possible role of the TNF alpha system in leptin expression and circulating levels may have important implications for our understanding of obesity and cachexia in humans.
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PMID:Leptin concentrations in relation to body mass index and the tumor necrosis factor-alpha system in humans. 932 77

Non-insulin-dependent diabetes mellitus (type 2 diabetes) is known to be a polygenic and polyfactorial disorder. Here we describe the long-term examination of a transgenic mouse line showing the disruption of the leptin receptor (Lepr, Ob-R) gene caused by transgene insertion. The absence of the expression of the long isoform Ob-Rb uncovered a strong variation of the obesity and diabetes phenotype in the homozygous mutant mice of the outbred strain used. One part of the homozygous mice developed severe persistent early-onset obesity, whereas the other part developed cachexia after having shown initial obesity in the examination period up to 26 weeks p.p. The leptin-receptor-defective mice of this line might serve as a model for the investigation of genes modulating the development and mode of expression of diabetes.
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PMID:Contrasting obesity phenotypes uncovered by partial leptin receptor gene deletion in transgenic mice. 1070 83

In most mammals, two types of adipose tissue, white and brown, are present. Both are able to store energy in the form of triacylglycerols and to hydrolyze them into free fatty acids and glycerol. Whereas white adipose tissue can provide lipids as substrates for other tissues according to the needs of the organism, brown adipose tissue will use fatty acids for heat production. Over the long term, white fat mass reflects the net balance between energy expenditure and energy intake. Even though these two parameters are highly variable during the life of an individual, most adult subjects remain relatively constant in body weight throughout their lives. This observation suggests that appetite, energy expenditure, and basal metabolic rate are linked. An important characteristic of the adipose tissue is its enormous plasticity for volume and cell-number variations and an apparent change in phenotype between the brown and white adipose tissues. The present review focuses on the cellular mechanisms participating in the plasticity of adipose tissues and their regulation by the autonomic nervous system. There is compelling evidence with regard to the importance of the nervous system in the regulation of adipose tissue mass, either brown or white, by acting on the metabolic pathways and on the plasticity (proliferation, differentiation, transdifferentiation, apoptosis) of these tissues. A better comprehension of the different mechanisms involved in the feedback loop linking the brain and these two types of adipose tissue will lead to a better understanding of the pathophysiology of various disorders including obesity, cachexia, anorexia, and type II diabetes mellitus.
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PMID:The autonomic nervous system, adipose tissue plasticity, and energy balance. 1105 95

Four years ago Kojima and coworkers discovered ghrelin. Within this short lifespan ghrelin has become one of the "hottest topics" in metabolic research, and today more than 300 papers have emerged (PubMed search). The huge interest in ghrelin is partly due to its involvement in appetite regulation. Over-nutrition, obesity and type 2 diabetes are major burdens of health services in all Western countries, and the discovery of ghrelin opens for the development of antagonists that may make it possible to control appetite and food intake. At the other end of the nutritional scale, ghrelin agonists may be used in cachexia in e.g. anorexia nervosa and cancer. Thus, the potential clinical value of ghrelin research appears to be enormous. At the time of writing several in-house as well as commercial ghrelin assays have been developed. However, we still need to come to a consensus on measurement of circulating ghrelin levels. Up till now, blood ghrelin has been estimated by use of serum as well as various types of plasma, with or without extraction prior to assay. This may affect both results and conclusions. In the present paper we shall review the current literature on ghrelin, with special focus on measurements in human blood specimens.
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PMID:Assessment of ghrelin. 1287 66

Somatomedin-1 binding protein-3 [insulin-like growth factor-1 binding protein-3, SomatoKine] is a recombinant complex of insulin-like growth factor-1 (rhIGF-1) and binding protein-3 (IGFBP-3), which is the major circulating somatomedin (insulin-like growth factor) binding protein; binding protein-3 regulates the delivery of somatomedin-1 to target tissues. Somatomedin-1 binding protein-3 has potential as replacement therapy for somatomedin-1 which may become depleted in indications such as major surgery, organ damage/failure and traumatic injury, resulting in catabolism. It also has potential for the treatment of osteoporosis; diseases associated with protein wasting including chronic renal failure, cachexia and severe trauma; and to attenuate cardiac dysfunction in a variety of disease states, including after severe burn trauma. Combined therapy with somatomedin-1 and somatomedin-1 binding protein-3 would prolong the duration of action of somatomedin-1 and would reduce or eliminate some of the undesirable effects associated with somatomedin-1 monotherapy. Somatomedin-1 is usually linked to binding protein-3 in the normal state of the body, and particular proteases clip them apart in response to stresses and release somatomedin-1 as needed. Therefore, somatomedin-1 binding protein-3 is a self-dosing system and SomatoKine would augment the natural supply of these linked compounds. Somatomedin-1 binding protein-3 was developed by Celtrix using its proprietary recombinant protein production technology. Subsequently, Celtrix was acquired by Insmed Pharmaceuticals on June 1 2000. Insmed and Avecia, UK, have signed an agreement for the manufacturing of SomatoKine and its components, IGF-1 and binding protein-3. CGMP clinical production of SomatoKine and its components will be done in Avecia's Advanced Biologics Centre, Billingham, UK, which manufactures recombinant-based medicines and vaccines with a capacity of up to 1000 litres. In 2003, manufacturing of SomatoKine is planned to move to Avecia's larger facility with a capacity of 10 000 litres. Somatomedin-1 binding protein-3 was originally licenced to Welfide for Japan. On October 1 2001, Welfide Corporation merged with Mitsubishi-Tokyo Pharmaceuticals to form Mitsubishi Pharma Corporation. The new company is a subsidiary of Mitsubishi Chemical. In April 2003 Insmed initiated a named patient programme in Europe, that will make available somatomedin-1 binding protein-3 for the treatment of growth hormone insensitivity syndrome (GHIS)--Laron syndrome. The treatment of patients was initiated in Scandinavia, with authorisation pending in several other European countries. Somatomedin-1 binding protein-3 will be made available to those GHIS patients who, in the opinion of their doctor, may benefit from IGF-1 therapy. At precommercial scale quantities, the drug will be available on a limited basis. Safety data generated from the named patient programme will be used to support marketing applications in 2004. A phase II dose-ranging study in children with GHIS was completed at Saint Bartholomew's and the Royal London School of Medicine, London, UK. A single dose of somatomedin-1 binding protein-3 delivered the same amount of IGF-1 as two daily injections of unbound IGF-1. There were no adverse events reported. GHIS is a genetic condition in which patients do not produce adequate quantities of IGF because of a failure to respond to the growth hormone signal. This results in a slower growth rate and short stature. Insmed has acquired an exclusive licence to Pharmacia's regulatory filings concerning yeast-derived IGF-1. These filings were used by Pharmacia to receive marketing approvals in several European countries and also in the investigational New Drug Application with the US FDA. This licence will facilitate the development of SomatoKine for the treatment of children with GHIS. In January 2003, Insmed announced positive results from a double-blind, placebo-controlled, dose-ranging study of SomatoKine in adolescent patients with type 1 diabetes mellitus redolescent patients with type 1 diabetes mellitus receiving insulin therapy. The study was conducted at the University of Cambridge, Cambridge, UK, under the supervision of Professor D. Dunger. It has also been granted orphan drug status for the treatment of GHIS--Laron syndrome in the US and in Europe. Celtrix has been granted 11 US patents for its recombinant protein production technology, which it used for developing somatomedin-1 binding protein-3. Subsequently, Celtrix was acquired by Insmed Pharmaceuticals on June 1 2000. Following the acquisition, Insmed announced that it intends to maintain the US rights to Celtrix's products portfolio. These US patents will expire between 2010 through 2017. Insmed is holding a US patent (expires in 2019) for the use of SomatoKine in the treatment of both type 1 and type 2 diabetes mellitus.
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PMID:Somatomedin-1 binding protein-3: insulin-like growth factor-1 binding protein-3, insulin-like growth factor-1 carrier protein. 1449 68

Insmed is developing mecasermin rinfabate, a recombinant complex of insulin-like growth factor-I (rhIGF-I) and binding protein-3 (rhIGFBP-3) [insulin-like growth factor-I/insulin-like growth factor binding protein-3, rhIGF-I/rhIGFBP-3, SomatoKine], for a number of metabolic and endocrine indications. In the human body, IGF-I circulates in the blood bound to a binding protein-3 (IGFBP-3), which regulates the delivery of IGF-I to target tissues, and particular proteases clip them apart in response to stresses and release IGF-I as needed. IGF-I, a naturally occurring hormone, is necessary for normal growth and metabolism. For the treatment of IGF-I deficiency, it is desirable to administer IGF-I bound to IGFBP-3 to maintain the normal equilibrium of these proteins in the blood. Mecasermin rinfabate (rhIGF-I/rhIGFBP-3) mimics the effects of the natural protein complex in the bloodstream and would augment the natural supply of these linked compounds. The most advanced indication in development of mecasermin rinfabate is the treatment of severe growth disorders due to growth hormone insensitivity syndrome (GHIS), also called Laron syndrome. GHIS is a genetic condition in which patients do not produce adequate quantities of IGF because of a failure to respond to the growth hormone signal. This results in a slower growth rate and short stature. Mecasermin rinfabate also has potential as replacement therapy for IGF-I, which may become depleted in indications such as major surgery, organ damage/failure, traumatic injury, cachexia and severe burn trauma. It also has potential for the treatment of osteoporosis. Mecasermin rinfabate was developed by Celtrix using its proprietary recombinant protein production technology. Subsequently, Celtrix was acquired by Insmed Pharmaceuticals on 1 June 2000. Insmed and Avecia of the UK have signed an agreement for manufacturing mecasermin rinfabate and its components, rhIGF-1 and rhIGFBP-3. CGMP clinical production of mecasermin rinfabate and its components will be carried out in Avecia's Advanced Biologics Centre, Billingham, UK, which manufactures recombinant-based medicines and vaccines at the capacity of up to 1000L. In April 2004, Insmed announced that it acquired a lease to operate the manufacturing facility formerly operated by Baxter for the commercial production of SomatoKine in Boulder, CO, USA. With the two manufacturing facilities for SomatoKine, Insmed plans to meet the development and commercial demands for the product over the next several years. In its 2003 Form-10K, Insmed announced plans to conduct comparative studies with the previously used drug substance and the new substance produced by Avecia. The comparative data will be included in the regulatory filing for mecasermin rinfabate. Mecasermin rinfabate was originally licensed to Welfide for Japan. On 1 October 2001, Welfide Corporation merged with Mitsubishi-Tokyo Pharmaceuticals to form Mitsubishi Pharma Corporation. The new company is a subsidiary of Mitsubishi Chemical. In October 2004, Insmed announced that Tzamal Pharma has been granted exclusive distribution and marketing rights for mecasermin rinfabate in certain Middle Eastern territories including Israel. Tzamal Pharma also acquired exclusive rights to Insmed's named patient programme for the agent in these territories. Tzamal Pharma intends to begin the appropriate registration activities for mecasermin rinfabate in the treatment of children with growth hormone-insensitivity syndrome. This pivotal, 12-month, multicentre, open-label trial in 30 children with GHIS was initiated in June 2003 and was designed to evaluate the safety and efficacy of the agent in prepubescent children with GHIS. The 6-month endpoint data analysis showed that mecasermin rinfabate given as a once-daily injection was safe and well tolerated. The agent demonstrated a significant increase in height velocity in children with GHIS similar to that observed by Pfizer in their pivotal study with twice-daily injections of rhIGF-I. The full results from the pivotal trial are expected in 2005. In April 2003 Insmed initiated a named patient programme in Europe that will make available mecasermin rinfabate for the treatment of GHIS-Laron syndrome. The treatment of patients was initiated in Scandinavia, with authorisation pending in several other European countries. Mecasermin rinfabate will be made available to those GHIS patients who, in the opinion of their doctor, may benefit from IGF-I therapy. At precommercial scale quantities, the drug will be available on a limited basis.A phase II dose-ranging study in children with GHIS was completed at Saint Bartholomew's and the Royal London School of Medicine, London, UK. A single dose of mecasermin rinfabate delivered the same amount of IGF-1 as two daily injections of unbound IGF-1. No adverse events were reported. Insmed has acquired an exclusive licence to Pharmacia's regulatory filings concerning yeast-derived insulin-like growth factor 1 (IGF-1). These filings were used by Pharmacia to receive marketing approvals in several European countries and also in the IND application with the US FDA. Insmed believes that this licence will facilitate the development of mecasermin rinfabate for the treatment of children with GHIS. In January 2003, Insmed announced positive results from a double-blind, placebo-controlled, dose-ranging study of mecasermin rinfabate in adolescent patients with type 1 diabetes receiving insulin therapy. The study was conducted at the University of Cambridge, Cambridge, UK, under supervision of Prof. D. Dunger. The researchers from The Robarts Research Institute and the University of Western Ontario, Canada (leading investigator T.L. Delovitch, the Sheldon H. Weinstein scientist in Diabetes at the University of Western Ontario) have found that mecasermin rinfabate complex was significantly more effective than IGF-1 in reducing the severity of insulitis, beta cell destruction and delaying the onset of type 1 diabetes. The study was supported by grants from Canadian Institutes of Health and the Juvenile Diabetes Research Foundation. Insmed plans to initiate large-scale phase II clinical studies in this indication. At the BIO 2004 Annual International Convention (BIO-2004) in June 2004, Insmed announced that it has received a grant from the US National Institutes of Health (NIH)/Muscular Dystrophy Association (MDA) worth USD $6.5 million to investigate the efficacy of mecasermin rinfabate for the treatment of myotonic dystrophy. It has also been granted orphan drug status for the treatment of GHIS-Laron syndrome in the US and Europe. In December 2003, Insmed announced that mecasermin rinfabate was designated orphan drug status by the FDA for the treatment of extreme insulin resistance. This provides Insmed with 7 years of market exclusivity following approval of mecasermin rinfabate for this indication. Insmed has received orphan drug designation for mecasermin rinfabate in the treatment of extreme insulin resistance in Europe (October 2004). In November 2004, Insmed was granted the European patent EP1183042 entitled "Methods for Treating Diabetes". This patent corresponds with the US patent US 6,040,292 also entitled "Methods for Treating Diabetes". Both patents cover type 1 and type 2 diabetes mellitus and insulin resistant diabetes including type A insulin resistance (the least severe form of extreme insulin resistance syndromes). In January 2004, Insmed obtained a non-exclusive licence to the patents for use of IGF-I for the treatment of extreme or severe insulin-resistant diabetes from Fujisawa Pharmaceutical. Insmed will have worldwide rights in territories (excluding Japan) with existing valid patent claims including the US and Europe. Insmed holds 28 US issued or allowed patents for the composition, production, antibodies and methods of use of mecasermin rinfabate. These US patents expire at various times between the years 2010 and 2019. Insmed through their lawyers filed its defense and counterclaim to the alleged patent infringement brought by Tercica against Insmed in the London High Court of Justice. Insmed asserted that it did not infringe any valid patent claims as none of the claims of the patent were patentable because the subject matter was not new. Insmed also stated that the patent did not involve an inventive step, did not have capability of industrial application and had no clear description of the invention so that invention can be performed by the person skilled in the art. Insmed is seeking revocation of the patent on these grounds.
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PMID:Mecasermin rinfabate: insulin-like growth factor-I/insulin-like growth factor binding protein-3, mecaserimin rinfibate, rhIGF-I/rhIGFBP-3. 1577 6

Ghrelin is a 28 aminoacids peptide secreted from the stomach that stimulates the release of growth hormone (GH) from the anterior pituitary cells and is the strongest orexigenic hormone discovered so far. Ghrelin seems to be involved in the pathogenesis of obesity, anorexia nervosa and cachexia. Furthermore, low levels of ghrelin are negatively correlated with the degree of insulin resistance, blood pressure and the prevalence of type 2 diabetes. The role of ghrelin in the energy homeostasis and carbohydrate metabolism is discussed.
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PMID:[Ghrelin--role in energy homeostasis and glucose metabolism]. 1623 72

The analyses of large epidemiological databases have suggested that infants and children who show catch-up growth, or adiposity rebound at a younger age, are predisposed to the development of obesity, type 2 diabetes and cardiovascular diseases later in life. The pathophysiological mechanisms by which these growth trajectories confer increased risks for these diseases are obscure, but there is compelling evidence that the dynamic process of catch-up growth per se, which often overlaps with adiposity rebound at a younger age, is characterized by hyperinsulinemia and by a disproportionately higher rate in the recovery of body fat than lean tissue (i.e. preferential 'catch-up fat'). This paper first focuses upon the almost ubiquitous nature of this preferential 'catch-up fat' phenotype across the life cycle as a risk factor for obesity and insulin-related complications - not only in infants and children who experienced catch-up growth after earlier fetal or neonatal growth retardation, or after preterm birth, but also in adults who show weight recovery after substantial weight loss owing to famine, disease-cachexia or periodic dieting. It subsequently reviews the evidence indicating that such preferential catch-up fat is primarily driven by energy conservation (thrifty) mechanisms operating via suppressed thermogenesis, with glucose thus spared from oxidation in skeletal muscle being directed towards de novo lipogenesis and storage in white adipose tissue. A molecular-physiological framework is presented which integrates emerging insights into the mechanisms by which this thrifty 'catch-up fat' phenotype crosslinks with early development of insulin and leptin resistance. In the complex interactions between genetic constitution of the individual, programming earlier in life, and a subsequent lifestyle of energy dense foods and low physical activity, this thrifty 'catch-up fat' phenotype--which probably evolved to increase survival capacity in a hunter-gatherer lifestyle of periodic food shortages--is a central event in growth trajectories to obesity and to diseases that cluster into the insulin resistance (metabolic) syndrome.
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PMID:The thrifty 'catch-up fat' phenotype: its impact on insulin sensitivity during growth trajectories to obesity and metabolic syndrome. 1713 32

Since it is widely distributed into the body, beta(3)-adrenoceptor is becoming an attractive target for the treatment of several pathologies such as obesity, type 2 diabetes, metabolic syndrome, cachexia, overactive bladder, ulcero-inflammatory disorder of the gut, preterm labour, anxiety and depressive disorders, and heart failure. New compounds belonging to the class of arylethanolamines bearing one or two stereogenic centres were prepared in good yields as racemates and optically active forms. They were, then, evaluated for their intrinsic activity towards beta(3)-adrenoceptor and their affinity for beta(1)- and beta(2)-adrenergic receptors. Stereochemical features were found to play a crucial role in determining the behaviour of such compounds. In particular, alpha-racemic, (alphaR)- and (alphaS)-2-{4-[2-(2-hydroxy-2-phenylethylamino)ethyl]phenoxy}-2- methylpropanoic acid, (alpha-rac, beta-rac)-, (alphaR, betaS)- and (alphaR, betaR)- 2-{4-[2-(2-hydroxy-2-phenylethylamino)ethyl]phenoxy}propanoic acid were found to be endowed with beta(3)-adrenoceptor agonistic activity. Whereas, (alphaS, betaS)- and (alphaS, betaR)-2-{4-[2-(2-hydroxy-2-phenylethylamino)ethyl]phenoxy}propanoic acid behaved as beta(3)-adrenoceptor inverse agonists. Such compounds showed no affinity for beta(1)- and beta(2)-adrenergic receptor, respectively. Thus, resulting highly selective beta(3)-adrenoceptor ligands.
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PMID:Stereospecific synthesis and bio-activity of novel beta(3)-adrenoceptor agonists and inverse agonists. 1808 78

Genetic mutations resulting in obesity and type 2 diabetes mellitus (T2D) are described for both inbred and outbred mice. However, no known mouse model completely recapitulates human T2D and its comorbidities. We identified a cohort of obese, male, outbred Swiss-Webster (SW) mice as polyuric, polydipsic, glucosuric, and hyperglycemic. Prevalence of glucosuria in the SW colony reached 60% (n=70) in males 8 weeks to 6 months of age. Despite severe obesity in some females, no females were diabetic. Pathologic findings in affected males included cachexia, dilated gastrointestinal tracts with poor muscular tone, pancreatic islet degeneration and atrophy with compensatory metaplasia and/or neogenesis, bacterial pyelonephritis, membranous glomerulopathy, and late-onset hepatic tumors with macrosteatosis, microsteatosis, and hydropic change in aged males. Serum insulin correlated with blood glucose in a nonlinear pattern, suggestive of islet exhaustion. Circulating leptin levels showed a weak inverse correlation with glucose. Diabetic males were bred with obese colony females to produce 20 male and 20 female offspring. Prevalence of diabetes in male offspring was 80% (16/20) with a median age of onset of 18 weeks. By contrast, no diabetic females were identified, despite being significantly more obese than males. Male predominance is likewise a feature of T2D in humans. To our knowledge, this is the first documentation of hepatocellular carcinoma and islet metaplasia and/or neogenesis in a spontaneous outbred mouse model of T2D. The SW availability and histopathologic features represent a promising new model for the study of T2D.
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PMID:Obesity and non-insulin-dependent diabetes mellitus in Swiss-Webster mice associated with late-onset hepatocellular carcinoma. 1866 86

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