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1. Nondestructive, quantitative viability analysis of 3D tissue cultures using machine learning image segmentation

   https://doi.org/10.1063/5.0189222  

   Trettner, Kylie_J; Hsieh, Jeremy; Xiao, Weikun; Lee, Jerry_S_H; Armani, Andrea_M (March 2024, APL Bioengineering)

   Ascertaining the collective viability of cells in different cell culture conditions has typically relied on averaging colorimetric indicators and is often reported out in simple binary readouts. Recent research has combined viability assessment techniques with image-based deep-learning models to automate the characterization of cellular properties. However, further development of viability measurements to assess the continuity of possible cellular states and responses to perturbation across cell culture conditions is needed. In this work, we demonstrate an image processing algorithm for quantifying features associated with cellular viability in 3D cultures without the need for assay-based indicators. We show that our algorithm performs similarly to a pair of human experts in whole-well images over a range of days and culture matrix compositions. To demonstrate potential utility, we perform a longitudinal study investigating the impact of a known therapeutic on pancreatic cancer spheroids. Using images taken with a high content imaging system, the algorithm successfully tracks viability at the individual spheroid and whole-well level. The method we propose reduces analysis time by 97% in comparison with the experts. Because the method is independent of the microscope or imaging system used, this approach lays the foundation for accelerating progress in and for improving the robustness and reproducibility of 3D culture analysis across biological and clinical research. 

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2. Nondestructive, longitudinal, 3D oxygen imaging of cells in a multi-well plate using pulse electron paramagnetic resonance imaging

   https://doi.org/10.1038/s44303-024-00013-7  

   Hameed, Safa; Viswakarma, Navin; Babakhanova, Greta; Simon, Jr., Carl G.; Epel, Boris; Kotecha, Mrignayani (April 2024, npj Imaging)

   Abstract The use of oxygen by cells is an essential aspect of cell metabolism and a reliable indicator of viable and functional cells. Here, we report partial pressure oxygen (pO₂) mapping of live cells as a reliable indicator of viable and metabolically active cells. For pO₂imaging, we utilized trityl OX071-based pulse electron paramagnetic resonance oxygen imaging (EPROI), in combination with a 25 mT EPROI instrument, JIVA-25™, that provides 3D oxygen maps with high spatial, temporal, and pO₂resolution. To perform oxygen imaging in an environment-controlled apparatus, we developed a novel multi-well-plate incubator-resonator (MWIR) system that could accommodate 3 strips from a 96-well strip-well plate and image the middle 12 wells noninvasively and simultaneously. The MWIR system was able to keep a controlled environment (temperature at 37 °C, relative humidity between 70%–100%, and a controlled gas flow) during oxygen imaging and could keep cells alive for up to 24 h of measurement, providing a rare previously unseen longitudinal perspective of 3D cell metabolic activities. The robustness of MWIR was tested using an adherent cell line (HEK-293 cells), a nonadherent cell line (Jurkat cells), a cell-biomaterial construct (Jurkat cells seeded in a hydrogel), and a negative control (dead HEK-293 cells). For the first time, we demonstrated that oxygen concentration in a multi-well plate seeded with live cells reduces exponentially with the increase in cell seeding density, even if the cells are exposed to incubator-like gas conditions. For the first time, we demonstrate that 3D, longitudinal oxygen imaging can be used to assess cells seeded in a hydrogel. These results demonstrate that MWIR-based EPROI is a versatile and robust method that can be utilized to observe the cell metabolic activity nondestructively, longitudinally, and in 3D. This approach may be useful for characterizing cell therapies, tissue-engineered medical products, and other advanced therapeutics. 

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3. Fast, multiplane line-scan confocal microscopy using axially distributed slits

   https://doi.org/10.1364/BOE.417286  

   Tsang, Jean-Marc; Gritton, Howard_J; Das, Shoshana_L; Weber, Timothy_D; Chen, Christopher_S; Han, Xue; Mertz, Jerome (February 2021, Biomedical Optics Express)

   The inherent constraints on resolution, speed and field of view have hindered the development of high-speed, three-dimensional microscopy techniques over large scales. Here, we present a multiplane line-scan imaging strategy, which uses a series of axially distributed reflecting slits to probe different depths within a sample volume. Our technique enables the simultaneous imaging of an optically sectioned image stack with a single camera at frame rates of hundreds of hertz, without the need for axial scanning. We demonstrate the applicability of our system to monitor fast dynamics in biological samples by performing calcium imaging of neuronal activity in mouse brains and voltage imaging of cardiomyocytes in cardiac samples. 

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4. Tilt-angle stimulated Raman projection tomography

   https://doi.org/10.1364/OE.470527  

   Lin, Peng; Li, Chuan; Flores-Valle, Andres; Wang, Zian; Zhang, Meng; Cheng, Ran; Cheng, Ji-Xin (September 2022, Optics Express)

   Stimulated Raman projection tomography is a label-free volumetric chemical imaging technology allowing three-dimensional (3D) reconstruction of chemical distribution in a biological sample from the angle-dependent stimulated Raman scattering projection images. However, the projection image acquisition process requires rotating the sample contained in a capillary glass held by a complicated sample rotation stage, limiting the volumetric imaging speed, and inhibiting the study of living samples. Here, we report a tilt-angle stimulated Raman projection tomography (TSPRT) system which acquires angle-dependent projection images by utilizing tilt-angle beams to image the sample from different azimuth angles sequentially. The TSRPT system, which is free of sample rotation, enables rapid scanning of different views by a tailor-designed four-galvo-mirror scanning system. We present the design of the optical system, the theory, and calibration procedure for chemical tomographic reconstruction. 3D vibrational images of polystyrene beads and C. elegans are demonstrated in the C-H vibrational region. 

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5. In Situ Super‐Resolution Imaging of Organoids and Extracellular Matrix Interactions via Phototransfer by Allyl Sulfide Exchange‐Expansion Microscopy (PhASE‐ExM)

   https://doi.org/10.1002/adma.202109252  

   Blatchley, Michael_R; Günay, Kemal_Arda; Yavitt, F_Max; Hawat, Elijah_M; Dempsey, Peter_J; Anseth, Kristi_S (March 2022, Advanced Materials)

   Abstract 3D organoid models have recently seen a boom in popularity, as they can better recapitulate the complexity of multicellular organs compared to other in vitro culture systems. However, organoids are difficult to image because of the limited penetration depth of high‐resolution microscopes and depth‐dependent light attenuation, which can limit the understanding of signal transduction pathways and characterization of intimate cell‐extracellular matrix (ECM) interactions. To overcome these challenges, phototransfer by allyl sulfide exchange‐expansion microscopy (PhASE‐ExM) is developed, enabling optical clearance and super‐resolution imaging of organoids and their ECM in 3D. PhASE‐ExM uses hydrogels prepared via photoinitiated polymerization, which is advantageous as it decouples monomer diffusion into thick organoid cultures from the hydrogel fabrication. Apart from compatibility with organoids cultured in Matrigel, PhASE‐ExM enables 3.25× expansion and super‐resolution imaging of organoids cultured in synthetic poly(ethylene glycol) (PEG) hydrogels crosslinked via allyl‐sulfide groups (PEG‐AlS) through simultaneous photopolymerization and radical‐mediated chain‐transfer reactions that complete in <70 s. Further, PEG‐AlS hydrogels can be in situ softened to promote organoid crypt formation, providing a super‐resolution imaging platform both for pre‐ and post‐differentiated organoids. Overall, PhASE‐ExM is a useful tool to decipher organoid behavior by enabling sub‐micrometer scale, 3D visualization of proteins and signal transduction pathways. 

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