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1. Computer Simulation of Magnetic Resonance Imaging of the Flow of Fluidized Particles

   https://doi.org/10.1021/acs.iecr.3c01021  

   Bordbar, Alireza; Benders, Stefan; Zia, Wasif; Penn, Alexander; Boyce, Christopher M. (July 2023, Industrial & Engineering Chemistry Research)
2. Air-Fluidized Aggregates of Black Soldier fly Larvae

   https://doi.org/10.3389/fphy.2021.734447  

   Ko, Hungtang; Cassidy, Grace J.; Shishkov, Olga; Aydin, Enes; Hu, David L.; Goldman, Daniel I. (December 2021, Frontiers in Physics)

   Black soldier fly larvae are a sustainable protein source and play a vital role in the emerging food-waste recycling industry. One of the challenges of raising larvae in dense aggregations is their rise in temperature during feeding, which, if not mitigated, can become lethal to the larvae. We propose applying air-fluidization to circumvent such overheating. However, the behavior of such a system involves complex air-larva interactions and is poorly understood. In this combined experimental and numerical study, we show that the larval activity changes the behavior of the ensemble when compared to passive particles such as dead larvae. Over a cycle of increasing and then decreasing airflow, the states (pressure and height) of the live larva aggregates are single-value functions of the flow speed. In contrast, dead larva aggregates exhibit hysteresis characteristic of traditional fluidized beds, becoming more porous during the ramp down of airflow. This history-dependence for passive particles is supported by simulations that couple agent-based dynamics and computational fluid dynamics. We show that the hysteresis in height and pressure of the aggregates decreases as the activity of simulated larvae increases. To test if air fluidization can increase larval food intake, we performed feeding trials in a fluidization chamber and visualized the food consumption via x-ray imaging. Although the food mixes more rapidly in faster airflow, the consumption rate decreases. Our findings suggest that providing moderate airflow to larval aggregations may alleviate overheating of larval aggregations and evenly distribute the food without reducing feeding rates. 

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3. Metabolically intact nuclei are fluidized by the activity of the chromatin remodeling motor BRG1

   https://doi.org/10.1016/j.bpj.2024.11.3322  

   Byfield, Fitzroy J; Eftekhari, Behnaz; Kaymak-Loveless, Kaeli; Mandal, Kalpana; Li, David; Wells, Rebecca G; Chen, Wenjun; Brujic, Jasna; Bergamaschi, Giulia; Wuite, Gijs JL; et al (November 2024, Biophysical Journal)
4. Metabolically intact nuclei are fluidized by the activity of the chromatin remodeling motor BRG1

   https://doi.org/10.1101/2024.04.12.589275  

   Byfield, Fitzroy J; Eftekhari, Behnaz; Kaymak-Loveless, Kaeli; Mandal, Kalpana; Li, David; Wells, Rebecca G; Chen, Wenjun; Brujic, Jasna; Bergamaschi, Guilia; Wuite, Gijs JL; et al (April 2024, bioRxiv)

   Abstract The structure and dynamics of the cell nucleus regulate nearly every facet of the cell. Changes in nuclear shape limit cell motility and gene expression. Although the nucleus is generally seen as the stiffest organelle in the cell, cells can nevertheless deform the nucleus to large strains by small mechanical stresses. Here, we show that the mechanical response of the cell nucleus exhibits active fluidization that is driven by the BRG 1 motor of the SWI/SNF/BAF chromatin-remodeling complex. Atomic force microscopy measurements show that the nucleus alters stiffness in response to the cell substrate stiffness, which is retained after the nucleus is isolated and that the work of nuclear compression is mostly dissipated rather than elastically stored. Inhibiting BRG 1 stiffens the nucleus and eliminates dissipation and nuclear remodeling both in isolated nuclei and in intact cells. These findings demonstrate a novel link between nuclear motor activity and global nuclear mechanics. 

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5. Bubbling and mixing of vibrated and non-vibrated gas-fluidized active granular matter

   https://doi.org/10.1039/D5SM00239G  

   Punch, Oscar J; Jordan, Michael W; Moncrieffe, Angelina S; Guo, Qiang; Boyce, Christopher M (May 2025, Soft Matter)

   Numerical simulations reveal that the change in transport regimes for fluidized active granular materials is dependent on the balance of drag force, gravitational force, and active force. 

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