Resolution in super-resolution microscopy - facts, artifacts, technological advancements and biological applications.

IF 3.3 3区生物学 Q3 CELL BIOLOGY

Journal of cell science Pub Date : 2025-05-15 Epub Date: 2025-05-27 DOI:10.1242/jcs.263567

Kirti Prakash, David Baddeley, Christian Eggeling, Reto Fiolka, Rainer Heintzmann, Suliana Manley, Aleksandra Radenovic, Hari Shroff, Carlas Smith, Lothar Schermelleh

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Abstract

Super-resolution microscopy (SRM) has undeniable potential for scientific discovery, yet still presents many challenges that hinder its widespread adoption, including technical trade-offs between resolution, speed and photodamage, as well as limitations in imaging live samples and larger, more complex biological structures. Furthermore, SRM often requires specialized expertise and complex instrumentation, which can deter biologists from fully embracing the technology. In this Perspective, a follow-up to our recent Q&A article, we aim to demystify these challenges by addressing common questions and misconceptions surrounding SRM. Experts offer practical insights into how biologists can maximize the benefits of SRM while navigating issues such as photobleaching, image artifacts and the limitations of existing techniques. We also highlight recent developments in SRM that continue to push the boundaries of resolution. Our goal is to equip researchers with the crucial knowledge they need to harness the full potential of SRM.

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超分辨率显微镜的分辨率-事实，人工制品，技术进步和生物学应用。

超分辨率显微镜（SRM）具有不可否认的科学发现潜力，但仍然存在许多阻碍其广泛采用的挑战，包括分辨率，速度和光损伤之间的技术权衡，以及成像活体样品和更大，更复杂的生物结构的局限性。此外，SRM通常需要专门的专业知识和复杂的仪器，这可能会阻止生物学家完全接受这项技术。在我们最近的问答文章的后续文章中，我们的目标是通过解决围绕SRM的常见问题和误解来揭开这些挑战的神秘面纱。专家们为生物学家如何在解决诸如光漂白、图像伪影和现有技术局限性等问题时最大化SRM的好处提供了实际的见解。我们还强调了SRM的最新发展，这些发展继续推动解决的边界。我们的目标是为研究人员提供充分利用SRM潜力所需的关键知识。

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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