Optical time-stretch(OTS)imaging flow cytometry offers a promising solution for high-throughput and highprecision cell analysis due to its capabilities of high-speed,high-quality,and continuous imaging.Compressed sens...Optical time-stretch(OTS)imaging flow cytometry offers a promising solution for high-throughput and highprecision cell analysis due to its capabilities of high-speed,high-quality,and continuous imaging.Compressed sensing(CS)makes it practically applicable by significantly reducing the data volume while maintaining its highspeed and high-quality imaging properties.To enrich the information of the images acquired with CS-equipped OTS imaging flow cytometry,in this work we propose and experimentally demonstrate Fourier-domaincompressed OTS quantitative phase imaging flow cytometry.It is capable of acquiring intensity and quantitative phase images of cells simultaneously from the compressed data.To evaluate the performance of our method,static microparticles and a corn root cross section are experimentally measured under various compression ratios.Furthermore,to show how our method can be applied in practice,we utilize it in the drug response analysis of breast cancer cells.Experimental results show that our method can acquire high-quality intensity and quantitative phase images of flowing cells at a flowing speed of 1 m/s and a compression ratio of 30%.Combined with machine-learning-based image analysis,it can distinguish drug-treated and drug-untreated cells with an accuracy of over 95%.We believe our method can facilitate cell analysis in both scientific research and clinical settings where both high-throughput and high-content cell analysis is required.展开更多
The physical mechanism of the dynamics in laser–material interaction has been an important research area.In addition to theoretical analysis,direct imaging‐based observation of ultrafast dynamic processes is an impo...The physical mechanism of the dynamics in laser–material interaction has been an important research area.In addition to theoretical analysis,direct imaging‐based observation of ultrafast dynamic processes is an important approach to understand many fundamental issues in laser–material interaction such as inertial confinement fusion(ICF),laser accelerator construction,and advanced laser production.In this review,the principles and applications of three types of commonly used ultrafast imaging methods are introduced,including the pump–probe,X‐ray diagnosis,and single‐shot optical burst imaging.We focus on the technical features such as the spatial and temporal resolution for each technique,and present several conventional applications.展开更多
基金National Key Research and Development Program of China(2023YFF0723300)Fundamental Research Funds for the Central Universities(2042023kf0105,2042024kf0003,2042024kf1010)+6 种基金Science Fund for Distinguished Young Scholars of Hubei Province(2021CFA042)Natural Science Foundation of Hubei Province(2023AFB133)National Natural Science Foundation of China(12374295,62075200)Interdisciplinary Innovative Talents Foundation from Renmin Hospital of Wuhan University(JCRCYR-2022-006)Jiangsu Science and Technology Program(BK20221257)Shenzhen Science and Technology Program(JCYJ20220530140601003,JCYJ20230807090207014)Translational Medicine and Multidisciplinary Research Project of Zhongnan Hospital of Wuhan University(ZNJC202217)。
文摘Optical time-stretch(OTS)imaging flow cytometry offers a promising solution for high-throughput and highprecision cell analysis due to its capabilities of high-speed,high-quality,and continuous imaging.Compressed sensing(CS)makes it practically applicable by significantly reducing the data volume while maintaining its highspeed and high-quality imaging properties.To enrich the information of the images acquired with CS-equipped OTS imaging flow cytometry,in this work we propose and experimentally demonstrate Fourier-domaincompressed OTS quantitative phase imaging flow cytometry.It is capable of acquiring intensity and quantitative phase images of cells simultaneously from the compressed data.To evaluate the performance of our method,static microparticles and a corn root cross section are experimentally measured under various compression ratios.Furthermore,to show how our method can be applied in practice,we utilize it in the drug response analysis of breast cancer cells.Experimental results show that our method can acquire high-quality intensity and quantitative phase images of flowing cells at a flowing speed of 1 m/s and a compression ratio of 30%.Combined with machine-learning-based image analysis,it can distinguish drug-treated and drug-untreated cells with an accuracy of over 95%.We believe our method can facilitate cell analysis in both scientific research and clinical settings where both high-throughput and high-content cell analysis is required.
基金National Natural Science Foundation of China,Grant/Award Numbers:51727901,61905182,62075200The Hubei Provincial Major Program of Technological Innovation,Grant/Award Number:2017AAA121+7 种基金The Key Research and Development Program of Hubei province,Grant/Award Number:2020BAB005Wuhan Research Program of Application Foundation and Advanced Technology JSPS Core‐to‐Core Program White Rock Foundationsupported by the National Natural Science Foundation of China(Nos.51727901,61905182,62075200)the Hubei Provincial Major Program of Technological Innovation(No.2017AAA121)the Key Research and Development Program of Hubei province(No.2020BAB005)Wuhan Research Program of Application Foundation and Advanced TechnologyJSPS Core‐to‐Core Programthe White Rock Foundation.
文摘The physical mechanism of the dynamics in laser–material interaction has been an important research area.In addition to theoretical analysis,direct imaging‐based observation of ultrafast dynamic processes is an important approach to understand many fundamental issues in laser–material interaction such as inertial confinement fusion(ICF),laser accelerator construction,and advanced laser production.In this review,the principles and applications of three types of commonly used ultrafast imaging methods are introduced,including the pump–probe,X‐ray diagnosis,and single‐shot optical burst imaging.We focus on the technical features such as the spatial and temporal resolution for each technique,and present several conventional applications.