微尺度化学
刚度
生物材料
各向异性
材料科学
生物组织
软质材料
生物系统
机械生物学
压力(语言学)
纳米技术
模数
软物质
光学
物理
化学
复合材料
物理化学
数学教育
哲学
生物
胶体
遗传学
语言学
数学
作者
Gregor Pirnat,Matevž Marinčič,Miha Ravnik,Matjaž Humar
标识
DOI:10.1073/pnas.2314884121
摘要
Mechanical properties of biological tissues fundamentally underlie various biological processes and noncontact, local, and microscopic methods can provide fundamental insights. Here, we present an approach for quantifying the local mechanical properties of biological materials at the microscale, based on measuring the spectral shifts of the optical resonances in droplet microcavities. Specifically, the developed method allows for measurements of deformations in dye-doped oil droplets embedded in soft materials or biological tissues with an error of only 1 nm, which in turn enables measurements of anisotropic stress inside tissues as small as a few pN/μm 2 . Furthermore, by applying an external strain, Young’s modulus can be measured in the range from 1 Pa to 35 kPa, which covers most human soft tissues. Using multiple droplet microcavities, our approach could enable mapping of stiffness and forces in inhomogeneous soft tissues and could also be applied to in vivo and single-cell experiments. The developed method can potentially lead to insights into the mechanics of biological tissues.
科研通智能强力驱动
Strongly Powered by AbleSci AI