在活体动物中实现吸收分子的光学透明性。
Achieving optical transparency in live animals with absorbing molecules.
机构信息
Department of Materials Science and Engineering, Stanford University, Stanford, CA, USA.
Wu Tsai Neurosciences Institute, Stanford University, Stanford, CA, USA.
出版信息
Science. 2024 Sep 6;385(6713):eadm6869. doi: 10.1126/science.adm6869.
Abstract
Optical imaging plays a central role in biology and medicine but is hindered by light scattering in live tissue. We report the counterintuitive observation that strongly absorbing molecules can achieve optical transparency in live animals. We explored the physics behind this observation and found that when strongly absorbing molecules dissolve in water, they can modify the refractive index of the aqueous medium through the Kramers-Kronig relations to match that of high-index tissue components such as lipids. We have demonstrated that our straightforward approach can reversibly render a live mouse body transparent to allow visualization of a wide range of deep-seated structures and activities. This work suggests that the search for high-performance optical clearing agents should focus on strongly absorbing molecules.
摘要
光学成像是生物学和医学的核心领域,但活体组织中的光散射会对此造成阻碍。我们报告了一个违反直觉的观察结果,即强吸收分子可以在活体动物中实现光学透明。我们探索了这一观察结果背后的物理原理,发现当强吸收分子溶解在水中时,它们可以通过克喇末-克龙尼关系来改变水相介质的折射率,使其与高折射率的组织成分(如脂质)相匹配。我们已经证明,我们的简单方法可以使活体小鼠的身体可逆地变得透明,从而可以观察到广泛的深层结构和活动。这项工作表明,寻找高性能光学透明剂的研究应集中在强吸收分子上。
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