Department of Chemical Engineering, Texas Tech University, Lubbock, TX, 79409, USA.
School of Chemical & Biomolecular Engineering, Georgia Institute of Technology, Atlanta, GA, 30332, USA; Department of Pharmaceutical Technology, Faculty of Pharmacy, Ege University, Izmir, 35100, Turkey.
Biomaterials. 2021 Jan;267:120491. doi: 10.1016/j.biomaterials.2020.120491. Epub 2020 Nov 5.
The powerful and intriguing idea that drives the emerging technology of microneedles-shrinking the standard needle to a micron scale-has fostered an entire field of microneedle study and subsequent exponential growth in research and product development. Originally enabled by microfabrication tools derived from the microelectronic industry, microneedles are now produced through a number of methods in a variety of forms including solid, coated, dissolvable, and hollow microneedles. They are used to deliver a broad spectrum of molecules, including small molecules, biomolecules, and vaccines, as well as various forms of energy into the skin, eye, and other tissues. Microneedles are also being exploited for use in diagnostics, as well as additional medical, cosmetic, and other applications. This review elucidates the relative roles of different aspects of microneedle technology development, as shown through scientific papers, patents, clinical studies, and internet/social media activity. Considering >1000 papers, 750 patents, and almost 80 clinical trials, we analyze different attributes of microneedles such as usage of microneedles, types of microneedles, testing environment, types of patent claims, and phases of clinical trials, as well as which institutions and people in academia and industry from different locations and in different journals are publishing, patenting, and otherwise studying the potential of microneedles. We conclude that there is robust and growing activity in the field of microneedles; the technology is rapidly developing and being used for novel applications to benefit human health and well-being.
推动微针这一新兴技术发展的一个强有力且引人入胜的观点是——将标准针缩小到微米级。这一观点催生了整个微针研究领域,并随后促进了研究和产品开发呈指数级增长。微针最初是通过源自微电子行业的微制造工具来实现的,现在可以通过多种方法以各种形式生产,包括实心、涂层、可溶解和空心微针。它们被用于将包括小分子、生物分子和疫苗在内的各种分子以及各种形式的能量递送至皮肤、眼睛和其他组织。微针也被用于诊断以及其他医疗、美容和其他应用。本文通过科学论文、专利、临床研究和互联网/社交媒体活动,阐述了微针技术发展的不同方面的相对作用。考虑到超过 1000 篇论文、750 项专利和近 80 项临床试验,我们分析了微针的不同属性,例如微针的使用、微针的类型、测试环境、专利权利要求的类型以及临床试验的阶段,以及不同地点和不同期刊的学术界和工业界的哪些机构和人员正在发表、申请专利或以其他方式研究微针的潜力。我们的结论是,微针领域的活动蓬勃发展且不断增长;该技术正在迅速发展,并被用于新的应用,以造福人类健康和福祉。