Devi Sri Chiriki, Beeraka Narasimha Murthy, P R Hemanth Vikram, Bidye Durgesh Paresh, Kumar B R Prashantha, Nikolenko Vladimir N, Bannimath Gurupadayya
Department of Pharmaceutical Chemistry, JSS College of Pharmacy, JSS Academy of Higher Education & Research (JSS AHER), Mysuru, Karnataka, India.
Raghavendra Institute of Pharmaceutical Education and Research (RIPER), Anantapuramu, Chiyyedu, Andhra Pradesh 515721, India.
Curr Top Med Chem. 2025 Jan 1. doi: 10.2174/0115680266323908241114064318.
Several chemical studies described the physiological efficacy of 1,4- dihydropyridines (DHPs). DHPs bind to specific sites on the α1 subunit of L-type calcium channels, where they demonstrate a more pronounced inhibition of Ca2+ influx in vascular smooth muscle compared to myocardial tissue. This selective inhibition is the basis for their preferential vasodilatory action on peripheral and coronary arteries, a characteristic that underlies their therapeutic utility in managing hypertension and angina. Among the vascular-selective DHPs, nifedipine, felodipine, and isradipine are key representatives, with nifedipine often considered the archetype due to its widespread use and efficacy in promoting vascular relaxation. Significant efforts have been made to modify the structure of nifedipine, the prototype of DHPs to better understand structure-activity relationships (SARs) and amplify calcium-modulating effects.
The objective of this study is to explore the SARs of various DHPs and the implications of 1,4- dihydropyrimidines (DHPMs) to block L- (CaV1.2)/T-type (CaV3.1 and CaV3.2) calcium channels subtypes in medicinal chemistry and physiology as calcium channel blockers (CCBs).
We have searched public databases such as National Library of Medicine (NLM), PubMed, and Google Scholar. Collected information pertinent to these chemical entities from reviews, and original articles. We have used keywords to search in these databases such as 'calcium channel physiology', 'calcium channel blockers', 'medicinal chemistry', '1,4-dihydropyridines', and '1,4-dihydropyrimidines', 'structure-activity relationship'. We included the original articles, short communications, meta-analysis, and review articles published from the years 1975 to 2024.
Previous efforts by medicinal chemists have made significant strides in the synthesis of DHPs and DHPMs. These researchers have focused on creating CCBs that could effectively replicate the pharmacological properties of those currently in clinical use. While the standard one-pot synthesis of DHPMs typically involves three key components under various reaction conditions, more intricate synthetic routes have also been explored. These include enzyme-catalyzed processes, solvent-free reactions, ultrasonic methods, conventional reactions, acid-catalyzed pathways, and microwave-assisted synthesis, each of which offers distinct advantages and potential for the efficient production of DHPMs. DHPs have been the focus of significant research efforts to improve their potency and selectivity. However, a major limitation identified for this class of compounds is their short plasma half-life, potentially caused by metabolic oxidation to pyridine derivatives. To address these limitations, developing DHPMs through efficient modifications of the DHP scaffold has been explored. This research has also investigated the quantitative structure-activity relationships (QSARs) of C2-substituted DHPMs, fused 1,4-dihydropyrimidines, N3-substituted DHPMs, the bioactive role of fused pyrimidines, and comparison with fourth-generation CCBs, drug combinations considering their impact on calcium channel physiology. Subsequently, we discussed the efficacy of various CCBs, which are in clinical trials, lifestyle modifications, and other emerging technologies to ameliorate cardiovascular diseases.
Ongoing research into DHPs and DHPMs has greatly advanced our understanding of their SARs and potential as CCBs. Diverse synthetic methods, including enzyme-catalyzed, solvent-free, and microwaveassisted techniques, have been developed, enhancing the production and pharmacological properties of DHPMs. Future research should aim to optimize the DHP and DHPM scaffolds to improve potency, selectivity, and metabolic stability. Focus on significant modifications, such as C2 and N3 substitutions, could lead to more selective and potent CCBs. Additionally, integrating QSAR models and high-throughput screening will help identify promising clinical candidates, potentially expanding DHPMs' therapeutic use beyond cardiovascular diseases. In summary, continued exploration of novel DHPMs and innovative synthesis approaches will be key to developing next-generation calcium channel blockers with improved efficacy and safety.
多项化学研究描述了1,4 - 二氢吡啶(DHPs)的生理功效。DHPs与L型钙通道α1亚基上的特定位点结合,与心肌组织相比,它们在血管平滑肌中对Ca2+内流的抑制作用更为显著。这种选择性抑制是它们对外周和冠状动脉具有优先舒张血管作用的基础,这一特性是其在治疗高血压和心绞痛中发挥治疗作用的基础。在血管选择性DHPs中,硝苯地平、非洛地平和伊拉地平是关键代表,由于硝苯地平广泛使用且能有效促进血管舒张,常被视为原型。人们已做出大量努力来修饰DHPs的原型硝苯地平的结构,以更好地理解构效关系(SARs)并增强钙调节作用。
本研究的目的是探索各种DHPs的构效关系以及1,4 - 二氢嘧啶(DHPMs)作为钙通道阻滞剂(CCBs)在药物化学和生理学中对L - (CaV1.2)/T型(CaV3.1和CaV3.2)钙通道亚型的阻断作用及意义。
我们检索了美国国立医学图书馆(NLM)、PubMed和谷歌学术等公共数据库。从综述和原始文章中收集与这些化学实体相关的信息。我们使用“钙通道生理学”“钙通道阻滞剂”“药物化学”“1,4 - 二氢吡啶”“1,4 - 二氢嘧啶”“构效关系”等关键词在这些数据库中进行搜索。我们纳入了1975年至2024年发表的原始文章、简短通讯、荟萃分析和综述文章。
药物化学家此前在DHPs和DHPMs的合成方面取得了重大进展。这些研究人员致力于开发能够有效复制当前临床使用药物药理特性的CCBs。虽然DHPMs的标准一锅法合成通常在各种反应条件下涉及三个关键成分,但也探索了更复杂的合成路线。这些方法包括酶催化过程、无溶剂反应、超声方法、传统反应、酸催化途径和微波辅助合成,每种方法都为高效生产DHPMs提供了独特的优势和潜力。DHPs一直是提高其效力和选择性的大量研究工作的重点。然而,这类化合物的一个主要局限性是其血浆半衰期短,这可能是由代谢氧化为吡啶衍生物所致。为解决这些局限性,人们探索了通过对DHP支架进行有效修饰来开发DHPMs。该研究还研究了C2 - 取代DHPMs、稠合1,4 - 二氢嘧啶、N3 - 取代DHPMs的定量构效关系(QSARs)、稠合嘧啶的生物活性作用,并与第四代CCBs进行了比较,还考虑了它们对钙通道生理学影响的药物组合。随后,我们讨论了各种正在进行临床试验的CCBs的疗效、生活方式改变以及其他改善心血管疾病的新兴技术。
对DHPs和DHPMs的持续研究极大地推进了我们对其构效关系和作为CCBs潜力的理解。已开发出多种合成方法,包括酶催化、无溶剂和微波辅助技术,提高了DHPMs的产量和药理特性。未来的研究应旨在优化DHP和DHPM支架,以提高效力、选择性和代谢稳定性。关注C2和N3取代等重大修饰可能会产生更具选择性和效力的CCBs。此外,整合QSAR模型和高通量筛选将有助于识别有前景的临床候选药物,可能会将DHPMs的治疗用途扩展到心血管疾病之外。总之,持续探索新型DHPMs和创新合成方法将是开发疗效和安全性更高的下一代钙通道阻滞剂的关键。
