A Novel Laser-Based Method for Studying Optic Nerve Regeneration
Optic nerve regeneration is a major challenge in neurobiology due to the limited self-repair capacity of the mammalian central nervous system (CNS) and the inconsistency of traditional injury models.…
How to Image Axon Regeneration in Deep Muscle Tissue
This study highlights Dr. Aaron Lee’s research on mapping nerve regeneration in muscle grafts post-amputation. Limb loss often leads to reduced quality of life, not only from tissue loss but also due…
Capturing Developmental Dynamics in 3D
This application note showcases how the Viventis Deep dual-view light sheet microscope was successfully used by researchers for exploring high-resolution, long-term imaging of 3D multicellular models…
A Guide to Using Microscopy for Drosophila (Fruit Fly) Research
The fruit fly, typically Drosophila melanogaster, has been used as a model organism for over a century. One reason is that many disease-related genes are shared between Drosophila and humans. It is…
斑马鱼研究
为了在筛选、分拣、操作和成像过程中获取高质量结果,您需要观察细节和结构,从而为您的下一步研究做出正确的决策。
徕卡体视显微镜和透射光底座以出众的光学器件和优良的分辨率而闻名,是全世界研究学者的首选。
Improving Zebrafish-Embryo Screening with Fast, High-Contrast Imaging
Discover from this article how screening of transgenic zebrafish embryos is boosted with high-speed, high-contrast imaging using the DM6 B microscope, ensuring accurate targeting for developmental…
超薄切片介绍
对样本开展研究时,为了以纳米级分辨率显示其精细结构,通常会使用到电子显微镜。电子显微镜有两种类型:扫描电子显微镜(SEM)用于对样本表面成像,以及需要使用极薄电子透明样本的透射电子显微镜(TEM)。因此,使用电子显微镜对样本内部的精细结构进行成像时,此类技术解决方案需要制作出非常薄的样本切片。被称为超显微技术的样本制备方法可以产生具有最小伪影的超薄切片(厚度20-150nm)。在切片过程中,样本的…
如何研究胚胎发育中的基因调控网络
欢迎参加由 Ben Steventon 博士与 Andrea Boni 博士主讲的点播网络研讨会,探索光片显微镜如何革新发育生物学研究。这项先进成像技术能对三维样本进行高速、大体积的活体成像,且光毒性低。通过用户案例了解光片显微镜如何深化我们对肠道类器官与脑类器官发育的认知,并深入解析徕卡显微系统 Viventis Deep 显微镜的技术原理及其在长时间成像中的应用。
激光微切割(LMD)促进的分子生物学分析
使用激光微切割(LMD)提取生物分子、蛋白质、核酸、脂质和染色体,以及提取和操作细胞和组织,可以深入了解基因和蛋白质的功能。它在神经生物学、免疫学、发育生物学、细胞生物学和法医学等多个领域有广泛应用,例如癌症和疾病研究、基因改造、分子病理学和生物学。LMD 也有助于研究蛋白质功能、分子机制及其在转导途径中的相互作用。
