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Aldose reductase-IN-1 Sale

(Synonyms: Aldose reductase-IN-1; AT-001) 目录号 : GC31376

An aldose reductase inhibitor

Aldose reductase-IN-1 Chemical Structure

Cas No.:1355612-71-3

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10mM (in 1mL DMSO)
¥1,374.00
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5mg
¥1,250.00
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10mg
¥1,785.00
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50mg
¥7,140.00
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100mg
¥11,603.00
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产品描述

AT-001 is an inhibitor of aldose reductase (IC50 = 28.9 pM).1 It reduces infarct area in streptozotocin-induced diabetic mice expressing human aldose reductase in a model of cardiomyopathy induced by ischemia-reperfusion injury when administered at a dose of 40 mg/kg.2

1.Wasmuth, A., Landry, D., Deng, S.X., et al.Aldose reductase inhibitors and uses thereof(2014) 2.Perfetti, R., Rowell, P., Shendelman, S., et al.Preclinical and clinical proof of concept for metabolic intervention in diabetic cardiomyopathyJ. Card. Fail.25(8)S77(2019)

Chemical Properties

Cas No. 1355612-71-3 SDF
别名 Aldose reductase-IN-1; AT-001
Canonical SMILES O=C1C2=NC=CN=C2C(CC(O)=O)=NN1CC3=NC4=C(C=CC(C(F)(F)F)=C4)S3
分子式 C17H10F3N5O3S 分子量 421.35
溶解度 DMSO : ≥ 28 mg/mL (66.45 mM) 储存条件 Store at -20°C
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1 mg 5 mg 10 mg
1 mM 2.3733 mL 11.8666 mL 23.7332 mL
5 mM 0.4747 mL 2.3733 mL 4.7466 mL
10 mM 0.2373 mL 1.1867 mL 2.3733 mL
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Research Update

Aldose Reductase: a cause and a potential target for the treatment of diabetic complications

Diabetes mellitus, a disorder of metabolism, results in the elevation of glucose level in the blood. In this hyperglycaemic condition, aldose reductase overexpresses and leads to further complications of diabetes through the polyol pathway. Glucose metabolism-related disorders are the accumulation of sorbitol, overproduction of NADH and fructose, reduction in NAD+, and excessive NADPH usage, leading to diabetic pathogenesis and its complications such as retinopathy, neuropathy, and nephropathy. Accumulation of sorbitol results in the alteration of osmotic pressure and leads to osmotic stress. The overproduction of NADH causes an increase in reactive oxygen species production which leads to oxidative stress. The overproduction of fructose causes cell death and non-alcoholic fatty liver disease. Apart from these disorders, many other complications have also been discussed in the literature. Therefore, the article overviews the aldose reductase as the causative agent and a potential target for the treatment of diabetic complications. So, aldose reductase inhibitors have gained much importance worldwide right now. Several inhibitors, like derivatives of carboxylic acid, spirohydantoin, phenolic derivatives, etc. could prevent diabetic complications are discussed in this article.

In Search of Differential Inhibitors of Aldose Reductase

Aldose reductase, classified within the aldo-keto reductase family as AKR1B1, is an NADPH dependent enzyme that catalyzes the reduction of hydrophilic as well as hydrophobic aldehydes. AKR1B1 is the first enzyme of the so-called polyol pathway that allows the conversion of glucose into sorbitol, which in turn is oxidized to fructose by sorbitol dehydrogenase. The activation of the polyol pathway in hyperglycemic conditions is generally accepted as the event that is responsible for a series of long-term complications of diabetes such as retinopathy, cataract, nephropathy and neuropathy. The role of AKR1B1 in the onset of diabetic complications has made this enzyme the target for the development of molecules capable of inhibiting its activity. Virtually all synthesized compounds have so far failed as drugs for the treatment of diabetic complications. This failure may be partly due to the ability of AKR1B1 to reduce alkenals and alkanals, produced in oxidative stress conditions, thus acting as a detoxifying agent. In recent years we have proposed an alternative approach to the inhibition of AKR1B1, suggesting the possibility of a differential inhibition of the enzyme through molecules able to preferentially inhibit the reduction of either hydrophilic or hydrophobic substrates. The rationale and examples of this new generation of aldose reductase differential inhibitors (ARDIs) are presented.

Comparative Evaluation of Aldose Reductase Inhibition in Polycystic Ovarian Syndrome-Induced Rats

Polycystic ovary syndrome (PCOS) represents a spectrum of disorders, associated with hyperandrogenism, oligoanovulation, and polycystic ovaries. Aldose reductase (AR), a rate-limiting enzyme of polyol pathway, is responsible for maintenance of intracellular osmotic balance, facilitation of oocyte development, and organization of the granulosa cells in the ovary. Cyclic changes in the aldose reductase level were found during the 4-5 days estrus cycle in rat, which is regulated by gonadotropin-releasing hormone (GnRH). Irregular GnRH secretion in PCOS patients may lead to altered aldose reductase expression and ovarian dysfunction. Treatment with a novel AR inhibitor, fidarestat, has been reported to improve erythrocyte sorbitol content in diabetic patients. Hence, the potential role AR in pathogenesis of PCOS was investigated by inhibiting AR with fidarestat in PCOS-induced rats. Pre-pubertal female Sprague-Dawley rats were divided into five groups. PCOS is induced either by administering letrozole or by feeding high-fat diet for 90 days. After induction of PCOS, fidarestat treatment was given for 28 days and various parameters were measured. In PCOS-induced rats, parameters like food intake, body weight, insulin, OGTT, triglycerides, cholesterol, prolonged diestrus phase, ovary weight, and immunohistological localization AR were found to be significantly altered. Fidarestat treatment significantly improved ovary weight, ovarian aldose reductase localization in PCOS-induced rats. Improvement in all these parameters suggest involvement of aldose reductase in the pathogenesis of PCOS.

Aldose reductase inhibitors: 2013-present

Introduction: Aldose reductase (ALR2) is both the key enzyme of the polyol pathway, whose activation under hyperglycemic conditions leads to the development of chronic diabetic complications, and the crucial promoter of inflammatory and cytotoxic conditions, even under a normoglycemic status. Accordingly, it represents an excellent drug target and a huge effort is being done to disclose novel compounds able to inhibit it.
Areas covered: This literature survey summarizes patents and patent applications published over the last 5 years and filed for natural, semi-synthetic and synthetic ALR2 inhibitors. Compounds described have been discussed and analyzed from both chemical and functional angles.
Expert opinion: Several ALR2 inhibitors with a promising pre-clinical ability to address diabetic complications and inflammatory diseases are being developed during the observed timeframe. Natural compounds and plant extracts are the prevalent ones, thus confirming the use of phytopharmaceuticals as an increasingly pursued therapeutic trend also in the ALR2 inhibitors field. Intriguing hints may be taken from synthetic derivatives, the most significant ones being represented by the differential inhibitors ARDIs. Differently from classical ARIs, these compounds should fire up the therapeutic efficacy of the class while minimizing its side effects, thus overcoming the existing limits of this kind of inhibitors.

In silico Designing of Novel Inhibitors for Triple Inhibition of Aldose Reductase, Aldose Reductase Like Protein 1, and Aldehyde Reductase

Background: Cancer is a well-known and well-studied disease. There are environmental as well as genetic factors that trigger cancer. All forms of cancer are associated with the deregulation of genes and proteins. Aldose reductase, Aldose Reductase like protein 1 and Aldehyde Reductase are homologous proteins that are overexpressed in different types of cancer. They are NADPHdependent oxidoreductases. The active site is conserved, thus there is very less substrate specificity among those proteins. In this study, novel molecules targeting the three proteins are designed.
Methods: LigBuilder V2 software is used to design novel molecules. Molecular docking is performed to study the binding affinity of each ligand towards the targets. Molecular Dynamics Simulation was done to check the stability of protein-ligand complexes in an aqueous environment.
Results: Six novel molecules have been designed. The six molecules studied are found to have better in silico affinity than tolrestat (known inhibitor). The designed molecules are predicted to be orally active. Finally, Molecular Dynamics Simulation showed that the protein-ligand complexes are stable in an aqueous environment.
Conclusion: New molecules targeting Aldose reductase, Aldose Reductase like protein 1 and Aldehyde Reductase have been designed.