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   Rogowski, L.W; Kim, H; Zhang, X; Kim, M.J. (June 2018, The 15th International Conference on Ubiquitous Robots)
2. Molecular Characterization of Mucus Binding

   https://doi.org/10.1021/acs.biomac.8b01467  

   Witten, Jacob; Samad, Tahoura; Ribbeck, Katharina (February 2019, Biomacromolecules)

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3. Engineering mucus to study and influence the microbiome

   https://doi.org/10.1038/s41578-018-0079-7  

   Werlang, Caroline; Cárcarmo-Oyarce, Gerardo; Ribbeck, Katharina (February 2019, Nature Reviews Materials)

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4. Empirical and Theoretical Analysis of Particle Diffusion in Mucus

   https://doi.org/10.3389/fphy.2021.594306  

   Cobarrubia, Antonio; Tall, Jarod; Crispin-Smith, Austin; Luque, Antoni (November 2021, Frontiers in Physics)

   Mucus is a complex fluid that coats multiple organs in animals. Various physicochemical properties can alter the diffusion of microscopic particles in mucus, impacting drug delivery, virus infection, and disease development. The simultaneous effect of these physicochemical properties in particle diffusion, however, remains elusive. Here, we analyzed 106 published experiments to identify the most dominant factors controlling particle diffusion in mucus. The effective diffusion—defined using a one-second sampling time window across experiments—spanned seven orders of magnitude, from 10 –5 to 10 2  μm 2 /s. Univariate and multivariate statistical analyses identified the anomalous exponent (the logarithmic slope of the mean-squared displacement) as the strongest predictor of effective diffusion, revealing an exponential relationship that explained 89 % of the variance. A theoretical scaling analysis revealed that a stronger correlation of the anomalous exponent over the generalized diffusion constant occurs for sampling times two orders of magnitude larger than the characteristic molecular (or local) displacement time. This result predicts that at these timescales, the molecular properties controlling the anomalous exponent, like particle–mucus unbinding times or the particle to mesh size ratio, would be the most relevant physicochemical factors involved in passive microrheology of particles in mucus. Our findings contrast with the fact that only one-third of the studies measured the anomalous exponent, and most experiments did not report the associated molecular properties predicted to dominate the motion of particles in mucus. The theoretical foundation of our work can be extrapolated to other systems, providing a guide to identify dominant molecular mechanisms regulating the mobility of particles in mucus and other polymeric fluids. 

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5. Roles of mucus adhesion and cohesion in cough clearance

   https://doi.org/10.1073/pnas.1811787115  

   Button, Brian; Goodell, Henry P.; Atieh, Eyad; Chen, Yu-Cheng; Williams, Robert; Shenoy, Siddharth; Lackey, Elijah; Shenkute, Nathan T.; Cai, Li-Heng; Dennis, Robert G.; et al (November 2018, Proceedings of the National Academy of Sciences)

   Clearance of intrapulmonary mucus by the high-velocity airflow generated by cough is the major rescue clearance mechanism in subjects with mucoobstructive diseases and failed cilial-dependent mucus clearance, e.g., subjects with cystic fibrosis (CF) or chronic obstructive pulmonary disease (COPD). Previous studies have investigated the mechanical forces generated at airway surfaces by cough but have not considered the effects of mucus biophysical properties on cough efficacy. Theoretically, mucus can be cleared by cough from the lung by an adhesive failure, i.e., breaking mucus-cell surface adhesive bonds and/or by cohesive failure, i.e., directly fracturing mucus. Utilizing peel-testing technologies, mucus-epithelial surface adhesive and mucus cohesive strengths were measured. Because both mucus concentration and pH have been reported to alter mucus biophysical properties in disease, the effects of mucus concentration and pH on adhesion and cohesion were compared. Both adhesive and cohesive strengths depended on mucus concentration, but neither on physiologically relevant changes in pH nor bicarbonate concentration. Mucus from bronchial epithelial cultures and patient sputum samples exhibited similar adhesive and cohesive properties. Notably, the magnitudes of both adhesive and cohesive strength exhibited similar velocity and concentration dependencies, suggesting that viscous dissipation of energy within mucus during cough determines the efficiency of cough clearance of diseased, hyperconcentrated, mucus. Calculations of airflow-induced shear forces on airway mucus related to mucus concentration predicted substantially reduced cough clearance in small versus large airways. Studies designed to improve cough clearance in subjects with mucoobstructive diseases identified reductions of mucus concentration and viscous dissipation as key therapeutic strategies. 

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