Compressible hollow microlasers in organoids for high-throughput and real-time mechanical screening
Mechanical stress within organoids is a pivotal indicator in disease modeling and pharmacokinetics, yet current tools lack the ability to rapidly and dynamically screen these mechanics. Here, we introduce biocompatible and compressible hollow microlasers that realize all-optical assessment of cellul...
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sg-ntu-dr.10356-1810682024-11-13T02:57:42Z Compressible hollow microlasers in organoids for high-throughput and real-time mechanical screening Fang, Guocheng Ho, Beatrice Xuan Xu, Hongmei Gong, Chaoyang Qiao, Zhen Liao, Yikai Zhu, Song Lu, Hongxu Nie, Ningyuan Zhou, Tian Kim, Munho Huang, Changjin Soh, Boon Seng Chen, Yu-Cheng School of Mechanical and Aerospace Engineering School of Electrical and Electronic Engineering Engineering Microlaser Organoids Mechanical stress within organoids is a pivotal indicator in disease modeling and pharmacokinetics, yet current tools lack the ability to rapidly and dynamically screen these mechanics. Here, we introduce biocompatible and compressible hollow microlasers that realize all-optical assessment of cellular stress within organoids. The laser spectroscopy yields identification of cellular deformation at the nanometer scale, corresponding to tens of pascals stress sensitivity. The compressibility enables the investigation of the isotropic component, which is the fundamental mechanics of multicellular models. By integrating with a microwell array, we demonstrate the high-throughput screening of mechanical cues in tumoroids, establishing a platform for mechano-responsive drug screening. Furthermore, we showcase the monitoring and mapping of dynamic contractile stress within human embryonic stem cell-derived cardiac organoids, revealing the internal mechanical inhomogeneity within a single organoid. This method eliminates time-consuming scanning and sample damage, providing insights into organoid mechanobiology. Agency for Science, Technology and Research (A*STAR) Nanyang Technological University This work was supported by the A*STAR MTC IRG-Grant (M21K2c0106, Singapore) and Nanyang Presidential Post-doctoral Fellowship (NTU, Singapore). 2024-11-13T02:57:42Z 2024-11-13T02:57:42Z 2024 Journal Article Fang, G., Ho, B. X., Xu, H., Gong, C., Qiao, Z., Liao, Y., Zhu, S., Lu, H., Nie, N., Zhou, T., Kim, M., Huang, C., Soh, B. S. & Chen, Y. (2024). Compressible hollow microlasers in organoids for high-throughput and real-time mechanical screening. ACS Nano, 18, 26338-26349. https://dx.doi.org/10.1021/acsnano.4c08886 1936-0851 https://hdl.handle.net/10356/181068 10.1021/acsnano.4c08886 39214618 2-s2.0-85202830592 18 26338 26349 en M21K2c0106 ACS Nano © 2024 American Chemical Society. All rights reserved. |
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| topic |
Engineering Microlaser Organoids |
| spellingShingle |
Engineering Microlaser Organoids Fang, Guocheng Ho, Beatrice Xuan Xu, Hongmei Gong, Chaoyang Qiao, Zhen Liao, Yikai Zhu, Song Lu, Hongxu Nie, Ningyuan Zhou, Tian Kim, Munho Huang, Changjin Soh, Boon Seng Chen, Yu-Cheng Compressible hollow microlasers in organoids for high-throughput and real-time mechanical screening |
| description |
Mechanical stress within organoids is a pivotal indicator in disease modeling and pharmacokinetics, yet current tools lack the ability to rapidly and dynamically screen these mechanics. Here, we introduce biocompatible and compressible hollow microlasers that realize all-optical assessment of cellular stress within organoids. The laser spectroscopy yields identification of cellular deformation at the nanometer scale, corresponding to tens of pascals stress sensitivity. The compressibility enables the investigation of the isotropic component, which is the fundamental mechanics of multicellular models. By integrating with a microwell array, we demonstrate the high-throughput screening of mechanical cues in tumoroids, establishing a platform for mechano-responsive drug screening. Furthermore, we showcase the monitoring and mapping of dynamic contractile stress within human embryonic stem cell-derived cardiac organoids, revealing the internal mechanical inhomogeneity within a single organoid. This method eliminates time-consuming scanning and sample damage, providing insights into organoid mechanobiology. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Fang, Guocheng Ho, Beatrice Xuan Xu, Hongmei Gong, Chaoyang Qiao, Zhen Liao, Yikai Zhu, Song Lu, Hongxu Nie, Ningyuan Zhou, Tian Kim, Munho Huang, Changjin Soh, Boon Seng Chen, Yu-Cheng |
| format |
Article |
| author |
Fang, Guocheng Ho, Beatrice Xuan Xu, Hongmei Gong, Chaoyang Qiao, Zhen Liao, Yikai Zhu, Song Lu, Hongxu Nie, Ningyuan Zhou, Tian Kim, Munho Huang, Changjin Soh, Boon Seng Chen, Yu-Cheng |
| author_sort |
Fang, Guocheng |
| title |
Compressible hollow microlasers in organoids for high-throughput and real-time mechanical screening |
| title_short |
Compressible hollow microlasers in organoids for high-throughput and real-time mechanical screening |
| title_full |
Compressible hollow microlasers in organoids for high-throughput and real-time mechanical screening |
| title_fullStr |
Compressible hollow microlasers in organoids for high-throughput and real-time mechanical screening |
| title_full_unstemmed |
Compressible hollow microlasers in organoids for high-throughput and real-time mechanical screening |
| title_sort |
compressible hollow microlasers in organoids for high-throughput and real-time mechanical screening |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/181068 |
| _version_ |
1816859052438716416 |