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1. Absorption rate governs cell transduction in dry macroporous scaffolds

   https://doi.org/10.1039/D2BM01753A  

   VanBlunk, Madelyn; Srikanth, Vishal; Pandit, Sharda S.; Kuznetsov, Andrey V.; Brudno, Yevgeny (March 2023, Biomaterials Science)

   Developing the next generation of cellular therapies will depend on fast, versatile, and efficient cellular reprogramming. Novel biomaterials will play a central role in this process by providing scaffolding and bioactive signals that shape cell fate and function. Previously, our lab reported that dry macroporous alginate scaffolds mediate retroviral transduction of primary T cells with efficiencies that rival the gold-standard clinical spinoculation procedures, which involve centrifugation on Retronectin-coated plates. This scaffold transduction required the scaffolds to be both macroporous and dry. Transduction by dry, macroporous scaffolds, termed “Drydux transduction,” provides a fast and inexpensive method for transducing cells for cellular therapy, including for the production of CAR T cells. In this study, we investigate the mechanism of action by which Drydux transduction works through exploring the impact of pore size, stiffness, viral concentration, and absorption speed on transduction efficiency. We report that Drydux scaffolds with macropores ranging from 50–230 μm and with Young's moduli ranging from 25–620 kPa all effectively transduce primary T cells, suggesting that these parameters are not central to the mechanism of action, but also demonstrating that Drydux scaffolds can be tuned without losing functionality. Increasing viral concentrations led to significantly higher transduction efficiencies, demonstrating that increased cell–virus interaction is necessary for optimal transduction. Finally, we discovered that the rate with which the cell–virus solution is absorbed into the scaffold is closely correlated to viral transduction efficiency, with faster absorption producing significantly higher transduction. A computational model of liquid flow through porous media validates this finding by showing that increased fluid flow substantially increases collisions between virus particles and cells in a porous scaffold. Taken together, we conclude that the rate of liquid flow through the scaffolds, rather than pore size or stiffness, serves as a central regulator for efficient Drydux transduction. 

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2. Cnidarian hair cell development illuminates an ancient role for the class IV POU transcription factor in defining mechanoreceptor identity

   https://doi.org/10.7554/eLife.74336  

   Ozment, Ethan; Tamvacakis, Arianna N; Zhou, Jianhong; Rosiles-Loeza, Pablo Yamild; Escobar-Hernandez, Esteban Elías; Fernandez-Valverde, Selene L; Nakanishi, Nagayasu (December 2021, eLife)

   Although specialized mechanosensory cells are found across animal phylogeny, early evolutionary histories of mechanoreceptor development remain enigmatic. Cnidaria (e.g. sea anemones and jellyfishes) is the sister group to well-studied Bilateria (e.g. flies and vertebrates), and has two mechanosensory cell types - a lineage-specific sensory-effector known as the cnidocyte, and a classical mechanosensory neuron referred to as the hair cell. While developmental genetics of cnidocytes is increasingly understood, genes essential for cnidarian hair cell development are unknown. Here we show that the class IV POU homeodomain transcription factor (POU-IV) - an indispensable regulator of mechanosensory cell differentiation in Bilateria and cnidocyte differentiation in Cnidaria - controls hair cell development in the sea anemone cnidarian Nematostella vectensis. N. vectensis POU-IV is postmitotically expressed in tentacular hair cells, and is necessary for development of the apical mechanosensory apparatus, but not of neurites, in hair cells. Moreover, it binds to deeply conserved DNA recognition elements, and turns on a unique set of effector genes - including the transmembrane-receptor-encoding gene polycystin 1 - specifically in hair cells. Our results suggest that POU-IV directs differentiation of cnidarian hair cells and cnidocytes via distinct gene regulatory mechanisms, and support an evolutionarily ancient role for POU-IV in defining the mature state of mechanosensory neurons. 

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3. Kalimba Inspired Metastructure for Frequency Selectivity

   https://doi.org/10.1115/SMASIS2024-139941  

   Gosavi, Hrishikesh; James, Evelyn; Cole, Rachel; Malladi, Vijaya_V_N Sriram (September 2024, American Society of Mechanical Engineers)

   Abstract In this study, the frequency selectivity phenomenon in the mammalian cochlea is replicated in a simulated environment. Frequency selectivity is found to be of crucial importance in the accurate perception of environmental noise. Previous studies have found that mammalian cochlea consists of basilar membrane which varies in width and stiffness along its length. This results in a gradient in mechanical properties and in turn results in a place-coding mechanism, where different frequencies of sound cause maximum displacement of the basilar membrane at specific locations along its length. The basilar membrane consists of multiple hair cells located along its length. The displacement of the basilar membrane due to sound waves causes hair cells to bend. This bending of hair cells activates ion channels, leading to the generation of electrical signals. Leveraging the principles of cochlear processing, a Kalimba-key-based broadband vibroacoustic device is developed in this study having potential implications for sensory technology and human perception enhancement. Dynamic vibration resonators (DVRs) are employed in this research to emulate the frequency-selective behavior of the mammalian cochlea where the DVRs act as hair cells. A beam structure, acting as a platform for 136 strategically placed DVRs, each corresponding to a Kalimba instrument key is considered. Upon stimulation, these Kalimba keys replicate the vibrations of the cochlear basilar membrane, enabling the recreation of frequency selectivity across a broad spectrum. To simulate the system, a Timoshenko beam is considered to consist of spatially attached Kalimba keys modeled as a Single-Degree Of Freedom (SDOF) systems. A Finite Element (FE) model of this system is developed to calculate the response of the system. Frequency selectivity for different combinations of Kalimba keys is explored in this study. This study shows promising results having potential implications extending beyond healthcare, encompassing fields such as robotics where the integration of biological cochlear principles could enhance robots’ sensory perception and interaction capabilities in diverse environments. 

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4. Evolutionary convergence of a neural mechanism in the cavefish lateral line system

   https://doi.org/10.7554/eLife.77387  

   Lunsford, Elias T; Paz, Alexandra; Keene, Alex C; Liao, James C (June 2022, eLife)

   Animals can evolve dramatic sensory functions in response to environmental constraints, but little is known about the neural mechanisms underlying these changes. The Mexican tetra, Astyanax mexicanus , is a leading model to study genetic, behavioral, and physiological evolution by comparing eyed surface populations and blind cave populations. We compared neurophysiological responses of posterior lateral line afferent neurons and motor neurons across A. mexicanus populations to reveal how shifts in sensory function may shape behavioral diversity. These studies indicate differences in intrinsic afferent signaling and gain control across populations. Elevated endogenous afferent activity identified a lower response threshold in the lateral line of blind cavefish relative to surface fish leading to increased evoked potentials during hair cell deflection in cavefish. We next measured the effect of inhibitory corollary discharges from hindbrain efferent neurons onto afferents during locomotion. We discovered that three independently derived cavefish populations have evolved persistent afferent activity during locomotion, suggesting for the first time that partial loss of function in the efferent system can be an evolutionary mechanism for neural adaptation of a vertebrate sensory system. 

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5. Corollary discharge prevents signal distortion and enhances sensing during locomotion

   https://doi.org/10.1101/2021.02.15.431323  

   Skandalis, *; Lunsford, Elias T.; Liao*, James C. (February 2021, bioRxiv)

   null (Ed.)

   Sensory feedback during movement entails sensing a mix of externally- and self-generated stimuli (respectively, exafference and reafference). In many peripheral sensory systems, a parallel copy of the motor command, a corollary discharge, is thought to eliminate sensory feedback during behaviors. However, reafference has important roles in motor control, because it provides real-time feedback on the animal’s motions through the environment. In this case, the corollary discharge must be calibrated to enable feedback while avoiding negative consequences like sensor fatigue. The undulatory motions of fishes’ bodies generate induced flows that are sensed by the lateral line sensory organ, and prior work has shown these reafferent signals contribute to the regulation of swimming kinematics. Corollary discharge to the lateral line reduces the gain for reafference, but cannot eliminate it altogether. We develop a data-driven model integrating swimming biomechanics, hair cell physiology, and corollary discharge to understand how sensory modulation is calibrated during locomotion in larval zebrafish. In the absence of corollary discharge, lateral line afferent units exhibit the highly heterogeneous habituation rates characteristic of hair cell systems, typified by decaying sensitivity and phase distortions with respect to an input stimulus. Activation of the corollary discharge prevents habituation, reduces response heterogeneity, and regulates response phases in a narrow interval around the time of the peak stimulus. This suggests a synergistic interaction between the corollary discharge and the polarization of lateral line sensors, which sharpens sensitivity along their preferred axes. Our integrative model reveals a vital role of corollary discharge for ensuring precise feedback, including proprioception, during undulatory locomotion. 

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