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1. Interfacial morphodynamics of proliferating microbial communities

   https://doi.org/10.1101/2023.10.23.563665  

   Martínez-Calvo, Alejandro; Trenado-Yuste, Carolina; Lee, Hyunseok; Gore, Jeff; Wingreen, Ned S; Datta, Sujit S (October 2023, bioRxiv)

   In microbial communities, various cell types often coexist by occupying distinct spatial domains. What determines the shape of the interface between such domains—which in turn influences the interactions between cells and overall community function? Here, we address this question by developing a continuum model of a 2D spatially-structured microbial community with two distinct cell types. We find that, depending on the balance of the different cell proliferation rates and substrate friction coefficients, the interface between domains is either stable and smooth, or unstable and develops finger-like protrusions. We establish quantitative principles describing when these different interfacial behaviors arise, and find good agreement both with the results of previous experimental reports as well as new experiments performed here. Our work thus helps to provide a biophysical basis for understanding the interfacial morphodynamics of proliferating microbial communities, as well as a broader range of proliferating active systems. 

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2. Multiphase field model of cells on a substrate: From three dimensional to two dimensional

   https://doi.org/10.1103/PhysRevE.110.044403  

   Chiang, Michael; Hopkins, Austin; Loewe, Benjamin; Marenduzzo, Davide; Marchetti, M Cristina (October 2024, Physical Review E)

   Multiphase field models have emerged as an important computational tool for understanding biological tissue while resolving single-cell properties. While they have successfully reproduced many experimentally observed behaviors of living tissue, the theoretical underpinnings have not been fully explored. We show that a two-dimensional version of the model, which is commonly employed to study tissue monolayers, can be derived from a three-dimensional version in the presence of a substrate. We also show how viscous forces, which arise from friction between different cells, can be included in the model. Finally, we numerically simulate a tissue monolayer and find that intercellular friction tends to solidify the tissue. Published by the American Physical Society2024 

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3. Do \({\mit \Lambda }_{\mathrm {CC}}\) and \(G\) Run?

   https://doi.org/10.5506/APhysPolB.55.12-A1  

   Donoghue, JF (December 2024, Acta Physica Polonica B)

   No AbstractPublished by the Jagiellonian University2024authors 

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4. Metal Halide Perovskite Solar Module Encapsulation Using Polyolefin Elastomers: The Role of Morphology in Preventing Delamination

   https://doi.org/10.1103/PRXEnergy.3.023013  

   Jiao, Haoyang; Hegde, Maruti; Li, Nengxu; Owen-Bellini, Michael; Schelhas, Laura; Dingemans, Theo J; Huang, Jinsong (June 2024, PRX Energy)

   The development of perovskite solar cells (PSCs) has ushered in a new era of solar technology, characterized by its exceptional efficiency and cost-effective production. However, the soft and fragile nature of perovskites makes module encapsulation challenging. Polyolefin elastomers (POEs) have been reported to be promising encapsulants for perovskite modules. However, little research exists on identifying criteria among different types of POEs as encapsulants. Here, two POEs with different morphologies were compared as encapsulants. The first POE crystallizes during encapsulation (crystal content ∼40%), and the resulting shrinkage or warpage leads to delamination, causing minimodule failure. In contrast, perovskite minimodules encapsulated with a mostly amorphous POE exhibited better reliability and reproducibility. The best perovskite minimodules passed the thermal cycling test for 240 cycles between −40 and 85 °C and the damp heat test for 1419 h, according to the IEC 61215 standard. This study highlights the importance of the morphology of encapsulants in achieving high-quality encapsulation. Published by the American Physical Society2024 

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5. Predicting the Morphology of Multiphase Biomolecular Condensates from Protein Interaction Networks

   https://doi.org/10.1103/PRXLife.2.023013  

   Li, Tianhao; Jacobs, William M (June 2024, PRX Life)

   Phase-separated biomolecular condensates containing proteins and RNAs can assemble into higher-order structures by forming thermodynamically stable interfaces between immiscible phases. Using a minimal model of a protein/RNA interaction network, we demonstrate how a “shared” protein species that partitions into both phases of a multiphase condensate can function as a tunable surfactant that modulates the interfacial properties. We use Monte Carlo simulations and free-energy calculations to identify conditions under which a low concentration of this shared species is sufficient to trigger a wetting transition. We also describe a numerical approach based on classical density functional theory to predict concentration profiles and surface tensions directly from the model protein/RNA interaction network. Finally, we show that the wetting phase diagrams that emerge from our calculations can be understood in terms of a simple model of selective adsorption to a fluctuating interface. Our work shows how a low-concentration protein species might function as a biological switch for regulating multiphase condensate morphologies. Published by the American Physical Society2024 

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