Taking Optogenetics into the Human Brain: Opportunities and Challenges in Clinical Trial Design.

IF 1.4 Q4 MEDICINE, RESEARCH & EXPERIMENTAL Open Access Journal of Clinical Trials Pub Date : 2020-08-25 DOI:10.2147/OAJCT.S259702

Michael White, Michael Mackay, Roger Whittaker

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Abstract

Optogenetics, the use of light to control the activity of suitably sensitized cells, has led to major advances in the field of basic neuroscience since it first emerged in 2005. Already, the technique has entered clinical trials for conditions such as Retinitis Pigmentosa. A major focus of interest is the use of optogenetics within the brain, where the ability to precisely control the activity of specific subsets of neurons could lead to novel treatments for a wide range of disorders from epilepsy to schizophrenia. However, since any therapy would require both the use of gene therapy techniques to introduce non-human proteins, and implantable electronic devices to provide optical stimulation, applying this technique in the brain presents a unique set of obstacles and challenges. This review looks at the reasons why researchers are exploring the use of optogenetics within the brain. It then explores the challenges facing scientists, engineers and clinicians wanting to take this technology from the lab into the first human brain, discussing different possibilities for a first-in-human clinical trial from a sponsor, patient and regulatory perspective.

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将光遗传学带入人脑：临床试验设计的机遇与挑战》。

光遗传学是利用光来控制适当敏化细胞的活动，自 2005 年首次出现以来，已在基础神经科学领域取得了重大进展。目前，该技术已进入临床试验阶段，用于治疗视网膜色素变性等疾病。光遗传学在大脑中的应用是人们关注的一大焦点，在大脑中精确控制特定神经元子集活动的能力可为从癫痫到精神分裂症等多种疾病带来新的治疗方法。然而，由于任何疗法都需要使用基因治疗技术引入非人类蛋白质，并使用植入式电子设备提供光刺激，因此在大脑中应用这种技术面临着一系列独特的障碍和挑战。本综述探讨了研究人员探索在大脑中使用光遗传学的原因。然后，它探讨了科学家、工程师和临床医生在将这项技术从实验室应用到第一个人脑时所面临的挑战，并从赞助商、患者和监管机构的角度讨论了首次人体临床试验的各种可能性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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