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1. Single-cell cytometry via multiplexed fluorescence prediction by label-free reflectance microscopy

   https://doi.org/10.1126/sciadv.abe0431  

   Cheng, Shiyi; Fu, Sipei; Kim, Yumi Mun; Song, Weiye; Li, Yunzhe; Xue, Yujia; Yi, Ji; Tian, Lei (January 2021, Science Advances)

   null (Ed.)

   Traditional imaging cytometry uses fluorescence markers to identify specific structures but is limited in throughput by the labeling process. We develop a label-free technique that alleviates the physical staining and provides multiplexed readouts via a deep learning–augmented digital labeling method. We leverage the rich structural information and superior sensitivity in reflectance microscopy and show that digital labeling predicts accurate subcellular features after training on immunofluorescence images. We demonstrate up to three times improvement in the prediction accuracy over the state of the art. Beyond fluorescence prediction, we demonstrate that single cell–level structural phenotypes of cell cycles are correctly reproduced by the digital multiplexed images, including Golgi twins, Golgi haze during mitosis, and DNA synthesis. We further show that the multiplexed readouts enable accurate multiparametric single-cell profiling across a large cell population. Our method can markedly improve the throughput for imaging cytometry toward applications for phenotyping, pathology, and high-content screening. 

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2. LucFlow: A method to measure Luciferase reporter expression in single cells

   https://doi.org/10.1371/journal.pone.0292317  

   Nooti, Sunil; Naylor, Madison; Long, Trevor; Groll, Brayden; Manu (October 2023, PLOS ONE)

   Hui, Xiaoyan (Ed.)

   Reporter assays, in which the expression of an inert protein is driven by gene regulatory elements such as promoters and enhancers, are a workhorse for investigating gene regulation. Techniques for measuring reporter gene expression vary from single-cell or single-molecule approaches having low throughput to bulk Luciferase assays that have high throughput. We developed a Luciferase Reporter Assay using Flow-Cytometry (LucFlow), which measures reporter expression in single cells immunostained for Luciferase. We optimized and tested LucFlow with a murine cell line that can be differentiated into neutrophils, into which promoter-reporter and enhancer-promoter-reporter constructs have been integrated in a site-specific manner. The single-cell measurements are comparable to bulk ones but we found that dead cells have no detectable Luciferase protein, so that bulk assays underestimate reporter expression. LucFlow is able to achieve a higher accuracy than bulk methods by excluding dead cells during flow cytometry. Prior to fixation and staining, the samples are spiked with stained cells that can be discriminated during flow cytometry and control for tube-to-tube variation in experimental conditions. Computing fold change relative to control cells allows LucFlow to achieve a high level of precision. LucFlow, therefore, enables the accurate and precise measurement of reporter expression in a high throughput manner. 

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3. 3D super-resolution live-cell imaging with radial symmetry and Fourier light-field microscopy

   https://doi.org/10.1364/BOE.471967  

   Han, Keyi; Hua, Xuanwen; Vasani, Vishwa; Kim, Ge-Ah R.; Liu, Wenhao; Takayama, Shuichi; Jia, Shu (January 2022, Biomedical Optics Express)

   Live-cell imaging reveals the phenotypes and mechanisms of cellular function and their dysfunction that underscore cell physiology, development, and pathology. Here, we report a 3D super-resolution live-cell microscopy method by integrating radiality analysis and Fourier light-field microscopy ( rad- FLFM). We demonstrated the method using various live-cell specimens, including actins in Hela cells, microtubules in mammary organoid cells, and peroxisomes in COS-7 cells. Compared with conventional wide-field microscopy, rad- FLFM realizes scanning-free, volumetric 3D live-cell imaging with sub-diffraction-limited resolution of ∼150 nm ( x-y ) and 300 nm ( z ), milliseconds volume acquisition time, six-fold extended depth of focus of ∼6 µm, and low photodamage. The method provides a promising avenue to explore spatiotemporal-challenging subcellular processes in a wide range of cell biological research. 

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4. The Benthic Underwater Microscope imaging PAM ( BUMP ): A non‐invasive tool for in situ assessment of microstructure and photosynthetic efficiency

   https://doi.org/10.1111/2041-210X.70078  

   Ben‐Zvi, Or; Roberts, Paul; Ratelle, Devin; Snider, Joseph; Lertvilai, Pichaya; Wangpraseurt, Daniel; Deheyn, Dimitri D; Smith, Jennifer E; Jaffe, Jules S (July 2025, Methods in Ecology and Evolution)

   Abstract Essential to life on Earth, assessment of marine photosynthesis is of paramount importance. Photosynthesis occurs in spatially discrete microscopic entities at various levels of biological organization, from subcellular chloroplasts to symbiotic microalgae and macroalgae, and is influenced by the surrounding conditions.As such, in situ photosynthetic efficiency mapping on appropriate scales holds great promise for learning about these processes.To achieve this goal, we designed, fabricated, and tested an underwater microscope that incorporates standard colour, epifluorescence, and variable chlorophyllafluorescence imaging with nearly micron spatial resolution that resolves the structure and photosynthetic efficiency of benthic organisms.Our results highlight coral observations with high‐resolution photosynthetic spatial variability and detailed morphology. Our imaging system therefore enables research never before possible on the health and physiology of benthic aquatic organisms in situ, placing it in the context of their physical and biological environment. 

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5. Real-Time 3D Single Particle Tracking: Towards Active Feedback Single Molecule Spectroscopy in Live Cells

   https://doi.org/10.3390/molecules24152826  

   Hou, Shangguo; Johnson, Courtney; Welsher, Kevin (August 2019, Molecules)

   Single molecule fluorescence spectroscopy has been largely implemented using methods which require tethering of molecules to a substrate in order to make high temporal resolution measurements. However, the act of tethering a molecule requires that the molecule be removed from its environment. This is especially perturbative when measuring biomolecules such as enzymes, which may rely on the non-equilibrium and crowded cellular environment for normal function. A method which may be able to un-tether single molecule fluorescence spectroscopy is real-time 3D single particle tracking (RT-3D-SPT). RT-3D-SPT uses active feedback to effectively lock-on to freely diffusing particles so they can be measured continuously with up to photon-limited temporal resolution over large axial ranges. This review gives an overview of the various active feedback 3D single particle tracking methods, highlighting specialized detection and excitation schemes which enable high-speed real-time tracking. Furthermore, the combination of these active feedback methods with simultaneous live-cell imaging is discussed. Finally, the successes in real-time 3D single molecule tracking (RT-3D-SMT) thus far and the roadmap going forward for this promising family of techniques are discussed. 

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