A1 腺苷受体激动剂及其潜在的治疗应用。

A1 adenosine receptor agonists and their potential therapeutic applications.

作者信息

Elzein Elfatih, Zablocki Jeff

机构信息

CV Therapeutics, Inc., Department of Bioorganic Chemistry, 3172 Porter Drive, Palo Alto, CA 94304, USA.

出版信息

Expert Opin Investig Drugs. 2008 Dec;17(12):1901-10. doi: 10.1517/13543780802497284.

DOI:10.1517/13543780802497284

PMID:19012505

Abstract

BACKGROUND

The challenges in developing any A(1) adenosine receptor (A(1)-AdoR) agonist involve having the desired effect on target tissue while avoiding side effects due to activation of A(1)-AdoR on other tissues. A(1)-AdoR de-sensitization leading to tachyphylaxis is also another challenge.

OBJECTIVES

The major goal of this review is twofold: to highlight the structure affinity relationships (SAR) of A(1)-AdoR agonists, starting with initial lead compounds that were the genesis for second-generation compounds with high selectivity, affinity, and partial agonism; and to give an overview of the A(1)-AdoR agonists under development for various indications.

RESULTS

Intense efforts by many pharmaceutical companies and academicians in the A(1)-AdoR agonist field have led to the discovery of clinical candidates for the following conditions: atrial arrhythmias - Tecadenoson, Selodenoson and PJ-875; type 2 diabetes (T2D) and insulin-sensitizing agents - GR79236, ARA, and CVT-3619; pain management - SDZ WAG 994, GW493838; and angina - BAY-68-4986. For the i.v. antiarrhythmic agents that act as ventricular rate control agents, a selective response can be accomplished by careful dosing paradigms. The treatment of T2D using A(1)-AdoR agonists has been met by limited success due to cardiovascular side effects and well-defined desensitization of full agonists in both animal models and human trials (GR79236 and ARA). However, new partial A(1)-AdoR agonists are in development, including CVT-3619 (hA(1)-AdoR K(i) = 55 nm, selectivity A(2A) > 200; A(2B) > 1000; A(3) > 20, CV Therapeutics), that have the potential to provide enhanced insulin sensitivity without cardiovascular side effects or tachyphylaxis. The A(1)-AdoR agonists GW493838 and GR792363 are under evaluation for pain management. The non-nucleosidic A(1)-AdoR agonist, BAY-68-4986 (Capadenoson), represents a unique approach to angina wherein both animal studies and early human studies are promising.

CONCLUSION

The challenges associated with developing an A(1)-AdoR agonist for therapeutic intervention are now well defined in humans. Significant progress has been made in identifying agents for the treatment of atrial arrhythmias, T2D, and angina.

摘要

背景

开发任何A(1)腺苷受体（A(1)-AdoR）激动剂面临的挑战包括在对靶组织产生预期效果的同时，避免因激活其他组织上的A(1)-AdoR而产生副作用。A(1)-AdoR脱敏导致快速耐受性也是另一个挑战。

目的

本综述的主要目标有两个：突出A(1)-AdoR激动剂的结构亲和力关系（SAR），从最初的先导化合物开始，这些先导化合物是具有高选择性、亲和力和部分激动作用的第二代化合物的起源；概述正在开发用于各种适应症的A(1)-AdoR激动剂。

结果

许多制药公司和学者在A(1)-AdoR激动剂领域的大力努力已导致发现了适用于以下病症的临床候选药物：房性心律失常——替卡地诺、塞洛地诺和PJ-875；2型糖尿病（T2D）和胰岛素增敏剂——GR79236、ARA和CVT-3619；疼痛管理——SDZ WAG 994、GW493838；以及心绞痛——BAY-68-4986。对于用作心室率控制剂的静脉内抗心律失常药物，可通过谨慎的给药方案实现选择性反应。由于心血管副作用以及在动物模型和人体试验（GR79236和ARA）中全激动剂明确的脱敏作用，使用A(1)-AdoR激动剂治疗T2D取得的成功有限。然而，新的部分A(1)-AdoR激动剂正在开发中，包括CVT-3619（人A(1)-AdoR K(i)=55纳米，对A(2A)的选择性>200；对A(2B)的选择性>1000；对A(3)的选择性>20，CV Therapeutics公司），其有可能在无心血管副作用或快速耐受性的情况下提高胰岛素敏感性。A(1)-AdoR激动剂GW493838和GR792363正在进行疼痛管理评估。非核苷类A(1)-AdoR激动剂BAY-68-4986（卡帕地诺）代表了一种独特的心绞痛治疗方法，动物研究和早期人体研究均显示出前景。

结论

在人类中，开发用于治疗干预的A(1)-AdoR激动剂相关的挑战现已明确。在确定用于治疗房性心律失常、T2D和心绞痛的药物方面已取得重大进展。

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A1 腺苷受体激动剂及其潜在的治疗应用。

A1 adenosine receptor agonists and their potential therapeutic applications.

作者信息

机构信息

出版信息

BACKGROUND

OBJECTIVES

RESULTS

CONCLUSION

背景

目的

结果

结论

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