恒河猴选择性抑制Nav1.8可产生镇痛和外周c纤维调节作用。

IF 5.9 1区 医学 Q1 ANESTHESIOLOGY
Joshua D Vardigan, Parul S Pall, Dillon S McDevitt, ChienJung Huang, Michelle K Clements, Yuxing Li, Richard L Kraus, Michael J Breslin, Christopher J Bungard, Mikhail I Nemenov, Mikhail Klukinov, Chritopher S Burgey, Mark E Layton, Shawn J Stachel, Henry S Lange, Alan T Savitz, Vincent P Santarelli, Darrell A Henze, Jason M Uslaner
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引用次数: 0

摘要

摘要:电压门控钠(Nav)通道为更好、更安全的止痛药物提供了尚未开发的治疗价值。Nav1.8通道异构体尤其引人关注,因为它位于外周疼痛纤维上,而且在啮齿类动物临床前疼痛和神经生理学实验中发挥着重要作用。迄今为止,该通道的抑制剂尚未被批准作为治疗人类疼痛病症的药物,这可能是因为在开发具有足够选择性的类药物分子方面存在挑战,这些分子不仅在人类身上具有必要的效力,而且在对药物发现的临床前开发路径至关重要的临床前物种中也具有必要的效力。此外,啮齿类动物疼痛试验与人类状况的相关性正受到越来越多的关注,因为许多在啮齿类动物中具有活性的机制(或至少是分子)尚未转化到人类身上,而且对疼痛纤维的直接影响尚未在体内得到证实。在本报告中,我们利用非人灵长类动物的许多生理终点来评估一种新型、强效和选择性 Nav1.8 抑制剂化合物 MSD199 的镇痛和药效学活性。这些药效学生物标志物证实了 Nav1.8 抑制对灵长类动物外周痛觉纤维的体内影响,并具有很高的临床转化潜力。因此,这些发现可能会极大地提高转化药物发现工作的成功率,从而开发出更好、更安全的止痛药物,同时也能广泛地了解灵长类对 Nav1.8 抑制作用的生物学特性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Analgesia and peripheral c-fiber modulation by selective Nav1.8 inhibition in rhesus.

Abstract: Voltage-gated sodium (Nav) channels present untapped therapeutic value for better and safer pain medications. The Nav1.8 channel isoform is of particular interest because of its location on peripheral pain fibers and demonstrated role in rodent preclinical pain and neurophysiological assays. To-date, no inhibitors of this channel have been approved as drugs for treating painful conditions in human, possibly because of challenges in developing a sufficiently selective drug-like molecule with necessary potency not only in human but also across preclinical species critical to the preclinical development path of drug discovery. In addition, the relevance of rodent pain assays to the human condition is under increasing scrutiny as a number of mechanisms (or at the very least molecules) that are active in rodents have not translated to humans, and direct impact on pain fibers has not been confirmed in vivo. In this report, we have leveraged numerous physiological end points in nonhuman primates to evaluate the analgesic and pharmacodynamic activity of a novel, potent, and selective Nav1.8 inhibitor compound, MSD199. These pharmacodynamic biomarkers provide important confirmation of the in vivo impact of Nav1.8 inhibition on peripheral pain fibers in primates and have high translational potential to the clinical setting. These findings may thus greatly improve success of translational drug discovery efforts toward better and safer pain medications, as well as the understanding of primate biology of Nav1.8 inhibition broadly.

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来源期刊
PAIN®
PAIN® 医学-临床神经学
CiteScore
12.50
自引率
8.10%
发文量
242
审稿时长
9 months
期刊介绍: PAIN® is the official publication of the International Association for the Study of Pain and publishes original research on the nature,mechanisms and treatment of pain.PAIN® provides a forum for the dissemination of research in the basic and clinical sciences of multidisciplinary interest.
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