购物车 
-
MK-0608
- names:
MK-0608
- CAS号:
443642-29-3
MDL Number: MFCD14584964 - MF(分子式): C12H16N4O4 MW(分子量): 280.28
- EINECS: Reaxys Number:
- Pubchem ID:3011893 Brand:BIOFOUNT
MK-0608(443642-29-3)是一种有效的HCV复制抑制剂,在亚基因组复制子分析中,EC50为0.3μM(EC90=1.3μM)。
| 货品编码 | 规格 | 纯度 | 价格 (¥) | 现价(¥) | 特价(¥) | 库存描述 | 数量 | 总计 (¥) |
|---|---|---|---|---|---|---|---|---|
| YZM000546-10mg | 10mg | 99% | ¥ 3560.00 | ¥ 3560.00 | 2-3天 | ¥ 0.00 | ||
| YZM000546-5mg | 5mg | 99% | ¥ 2180.00 | ¥ 2180.00 | 2-3天 | ¥ 0.00 |
| 中文别名 | MK-0608(cas:443642-29-3),MK-0608,MK-608 |
| 英文别名 | MK-0608(cas:443642-29-3),MK-0608,MK-608,7-Deaza-2'-C-methyladenosine |
| CAS号 | 443642-29-3 |
| SMILES | O[C@@]1(C)[C@H](N2C=CC3=C(N)N=CN=C32)O[C@H](CO)[C@H]1O |
| Inchi | InChI=1S/C12H16N4O4/c1-12(19)8(18)7(4-17)20-11(12)16-3-2-6-9(13)14-5-15-10(6)16/h2-3,5,7-8,11,17-19H,4H2,1H3,(H2,13,14,15)/t7-,8-,11-,12-/m1/s1 |
| InchiKey | IRZRJANZDIOOIF-GAJNKVMBSA-N |
| 分子式 Formula | C12H16N4O4 |
| 分子量 Molecular Weight | 280.28 |
| 闪点 FP | 329.2±31.5 °C |
| 熔点 Melting point | No data available |
| 沸点 Boiling point | 620.7±55.0 °C at 760 mmHg |
| Polarizability极化度 | 26.4±0.5 10-24cm3 |
| 密度 Density | 1.8±0.1 g/cm3 |
| 蒸汽压 Vapor Pressure | 0.0±1.9 mmHg at 25°C |
| 溶解度Solubility | |
| 性状 | Solid |
| 储藏条件 Storage conditions | 请根据产品建议的存储条件进行存储,Please store the product under the recommended condition sin the description. |
MK-0608(CAS:443642-29-3)实验注意事项:
1.实验前需戴好防护眼镜,穿戴防护服和口罩,佩戴手套,避免与皮肤接触。
2.实验过程中如遇到有毒或者刺激性物质及有害物质产生,必要时实验操作需要手套箱内完成以免对实验人员造成伤害
3.实验后产生的废弃物需分类存储,并交于专业生物废气物处理公司处理,以免造成环境污染Experimental considerations:
1. Wear protective glasses, protective clothing and masks, gloves, and avoid contact with the skin during the experiment.
2. The waste generated after the experiment needs to be stored separately, and handed over to a professional biological waste gas treatment company to avoid environmental pollution.
Tag:MK-0608蒸汽压,MK-0608合成,MK-0608标准,MK-0608应用,MK-0608合成,MK-0608沸点,MK-0608闪点,MK-0608用途,MK-0608溶解度,MK-0608价格,MK-0608作用,MK-0608结构式,MK-0608用处
1.实验前需戴好防护眼镜,穿戴防护服和口罩,佩戴手套,避免与皮肤接触。
2.实验过程中如遇到有毒或者刺激性物质及有害物质产生,必要时实验操作需要手套箱内完成以免对实验人员造成伤害
3.实验后产生的废弃物需分类存储,并交于专业生物废气物处理公司处理,以免造成环境污染Experimental considerations:
1. Wear protective glasses, protective clothing and masks, gloves, and avoid contact with the skin during the experiment.
2. The waste generated after the experiment needs to be stored separately, and handed over to a professional biological waste gas treatment company to avoid environmental pollution.
Tag:MK-0608蒸汽压,MK-0608合成,MK-0608标准,MK-0608应用,MK-0608合成,MK-0608沸点,MK-0608闪点,MK-0608用途,MK-0608溶解度,MK-0608价格,MK-0608作用,MK-0608结构式,MK-0608用处
| 产品说明 | MK-0608(443642-29-3) 是一种有效的HCV复制的抑制剂,在亚基因组复制子测定中,EC50是 0.3 μM (EC90=1.3 μM) |
| Introduction | MK608(443642-29-3) is a potent and orally bioavailable inhibitor of HCV replicationin vitro with anEC50of 0.3 μM (EC90=1.3 μM) in the subgenomiceplicon assay. |
| Application1 | |
| Application2 | |
| Application3 |
| 警示图 | |
| 危险性 | warning |
| 危险性警示 | Not available |
| 安全声明 | H303吞入可能有害+H313皮肤接触可能有害+H2413吸入可能对身体有害 |
| 安全防护 | P264处理后彻底清洗+P280戴防护手套/穿防护服/戴防护眼罩/戴防护面具+P305如果进入眼睛+P351用水小心冲洗几分钟+P338取出隐形眼镜(如果有)并且易于操作,继续冲洗+P337如果眼睛刺激持续+P2393获得医疗建议/护理 |
| 备注 | 实验过程中防止吸入、食入,做好安全防护 |
| 2013-04-01 Synthesis and evaluation against hepatitis C virus of 7-deaza analogues of 2'-C-methyl-6-O-methyl guanosine nucleoside and L-Alanine ester phosphoramidates Bioorganic & medicinal chemistry |
| 2012-08-01 Synthesis and antiviral properties of novel 7-heterocyclic substituted 7-deaza-adenine nucleoside inhibitors of Hepatitis C NS5B polymerase Bioorganic & medicinal chemistry |
| 2012-06-15 Synthesis and characterization of 2'-C-Me branched C-nucleosides as HCV polymerase inhibitors Bioorganic & medicinal chemistry letters |
| 2011-05-01 Elimination of hepatitis C virus by short term NS3-4A and NS5B inhibitor combination therapy in human hepatocyte chimeric mice Journal of hepatology |
| 2009-03-01 Robust antiviral efficacy upon administration of a nucleoside analog to hepatitis C virus-infected chimpanzees Antimicrobial agents and chemotherapy |
1.Viral RNA Polymerase Inhibitors/Todd Appleby i-hung shi and Wei understand zhong/02 May 2009
abstract:Infections by RNA viruses continue to exist as significant public health problems worldwide. In response to the urgent need for safer and more efficacious treatment options against infections caused by RNA viruses, the pharmaceutical and biotechnology industries have devoted significant efforts over the last two decades to discovering and developing new antiviral agents. As the primary viral enzyme responsible for genome replication and transcription, RNA-dependent RNA polymerases (RdRps) emerged early and remained as one of the most promising targets for therapeutic intervention of RNA virus infections. Advances in both basic research and drug discovery technology have resulted in the identification of a significant number of nucleoside (NIs) and non-nucleoside inhibitors (NNIs) of viral RdRps. In this chapter, we will focus our attention on various classes of viral RdRp inhibitors, with main emphases on those of hepatitis C virus (HCV) due to its significant unmet medical need. Recent progress in understanding their mechanism of action, antiviral activity profiles, and emergence of drug resistance mutations will be discussed.
2.Approaches for the Development of Antiviral Compounds: The Case of Hepatitis C Virus/Raymond F. SchinaziEmail authorSteven J. CoatsLeda C. BassitJohan LennerstrandJames H. NettlesSelwyn J. Hurwitz
abstract:Traditional methods for general drug discovery typically include evaluating random compound libraries for activity in relevant cell-free or cell-based assays. Success in antiviral development has emerged from the discovery of more focused libraries that provide clues about structure activity relationships. Combining these with more recent approaches including structural biology and computational modeling can work efficiently to hasten discovery of active molecules, but that is not enough. There are issues related to biology, toxicology, pharmacology, and metabolism that have to be addressed before a hit compound becomes nominated for clinical development. The objective of gaining early preclinical knowledge is to reduce the risk of failure in Phases 1, 2, and 3, leading to the goal of approved drugs that benefit the infected individual. This review uses hepatitis C virus (HCV), for which we still do not have an ideal therapeutic modality, as an example of the multidisciplinary efforts needed to discover new antiviral drugs for the benefit of humanity.
abstract:Infections by RNA viruses continue to exist as significant public health problems worldwide. In response to the urgent need for safer and more efficacious treatment options against infections caused by RNA viruses, the pharmaceutical and biotechnology industries have devoted significant efforts over the last two decades to discovering and developing new antiviral agents. As the primary viral enzyme responsible for genome replication and transcription, RNA-dependent RNA polymerases (RdRps) emerged early and remained as one of the most promising targets for therapeutic intervention of RNA virus infections. Advances in both basic research and drug discovery technology have resulted in the identification of a significant number of nucleoside (NIs) and non-nucleoside inhibitors (NNIs) of viral RdRps. In this chapter, we will focus our attention on various classes of viral RdRp inhibitors, with main emphases on those of hepatitis C virus (HCV) due to its significant unmet medical need. Recent progress in understanding their mechanism of action, antiviral activity profiles, and emergence of drug resistance mutations will be discussed.
2.Approaches for the Development of Antiviral Compounds: The Case of Hepatitis C Virus/Raymond F. SchinaziEmail authorSteven J. CoatsLeda C. BassitJohan LennerstrandJames H. NettlesSelwyn J. Hurwitz
abstract:Traditional methods for general drug discovery typically include evaluating random compound libraries for activity in relevant cell-free or cell-based assays. Success in antiviral development has emerged from the discovery of more focused libraries that provide clues about structure activity relationships. Combining these with more recent approaches including structural biology and computational modeling can work efficiently to hasten discovery of active molecules, but that is not enough. There are issues related to biology, toxicology, pharmacology, and metabolism that have to be addressed before a hit compound becomes nominated for clinical development. The objective of gaining early preclinical knowledge is to reduce the risk of failure in Phases 1, 2, and 3, leading to the goal of approved drugs that benefit the infected individual. This review uses hepatitis C virus (HCV), for which we still do not have an ideal therapeutic modality, as an example of the multidisciplinary efforts needed to discover new antiviral drugs for the benefit of humanity.
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