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1. Methods for Discerning the Impact of Mucus on Host Defenses Against Viral Infection

   https://doi.org/10.1002/cpz1.70201  

   Corkran, Maria; Boboltz, Allison; Duncan, Gregg A; Scull, Margaret A (September 2025, Current Protocols)

   Abstract Mucus is an important component of airway host defenses that acts by enabling the trapping and clearance of infectious materials such as bacteria and viruses. It can be difficult, however, to design experiments that independently determine the extent to which mucus contributes to innate barrier functions in the lung. Here, we provide detailed protocols to collect mucus from human airway epithelial cultures and evaluate how the properties of mucus impact mucociliary transport and protection from viral infection. We include recommended test parameters depending on the specific research question as it relates to respiratory infectious diseases. © 2025 The Author(s). Current Protocols published by Wiley Periodicals LLC. Basic Protocol 1: Analysis of mucociliary transport and ciliary beat frequency in HAE cultures Basic Protocol 2: Collection of mucus from HAE cultures Basic Protocol 3: Transplantation of mucus to HAE cultures and infection with virus 

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2. Microrheology of gel-forming airway mucins isolated from porcine trachea

   https://doi.org/10.1039/D4SM01343C  

   Engle, Elizabeth M; Yang, Sydney; Boboltz, Allison; Kumar, Sahana; Stern, Alexa; Duncan, Gregg A (June 2025, Soft Matter)

   A method to extract gel-forming mucins from pig trachea is developed. These airway mucins form viscous gels resembling human airway mucus, making them a useful model for lung disease research. 

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3. The role of mucosal barriers in disease progression and transmission

   https://doi.org/10.1016/j.addr.2023.115008  

   Bustos, Nicole A; Ribbeck, Katharina; Wagner, Caroline E (September 2023, Advanced Drug Delivery Reviews)

   Mucus is a biological hydrogel that coats and protects all non-keratinized wet epithelial surfaces. Mucins, the primary structural components of mucus, are critical components of the gel layer that protect against invading pathogens. For communicable diseases, pathogen-mucin interactions contribute to the pathogen’s fate and the potential for disease progression in-host, as well as the potential for onward transmission. We begin by reviewing in-host mucus filtering mechanisms, including size filtering and interaction filtering, which regulate the permeability of mucus barriers to all molecules including pathogens. Next, we discuss the role of mucins in communicable diseases at the point of transmission (i.e. how the encapsulation of pathogens in emitted mucosal droplets externally to hosts may modulate pathogen infectivity and viability). Overall, mucosal barriers modulate both host susceptibility as well as the dynamics of population-level disease transmission. The study of mucins and their use in models and experimental systems are therefore crucial for understanding the mechanistic biophysical principles underlying disease transmission and the early stages of host infection. 

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4. Molecular dynamics simulations to explore the structure and rheological properties of normal and hyperconcentrated airway mucus

   https://doi.org/10.1111/sapm.12433  

   Ford, Andrew G.; Cao, Xue‐Zheng; Papanikolas, Micah J.; Kato, Takafumi; Boucher, Richard C.; Markovetz, Matthew R.; Hill, David B.; Freeman, Ronit; Forest, Mark Gregory (August 2021, Studies in Applied Mathematics)

   Abstract We develop the first molecular dynamics model of airway mucus based on the detailed physical properties and chemical structure of the predominant gel‐forming mucin MUC5B. Our airway mucus model leverages the LAMMPS open‐source code [https://lammps.sandia.gov], based on the statistical physics of polymers, from single molecules to networks. On top of the LAMMPS platform, the chemical structure of MUC5B is used to superimpose proximity‐based, noncovalent, transient interactions within and between the specific domains of MUC5B polymers. We explore feasible ranges of hydrophobic and electrostatic interaction strengths between MUC5B domains with 9 nm spatial and 1 ns temporal resolution. Our goal here is to propose and test a mechanistic hypothesis for a striking clinical observation with respect to airway mucus: a 10‐fold increase in nonswellable, dense structures called flakes during progression of cystic fibrosis disease. Among the myriad possible effects that might promote self‐organization of MUC5B networks into flake structures, we hypothesize and confirm that the clinically confirmed increase in mucin concentration, from 1.5 to 5 mg/ml, alone is sufficient to drive the structure changes observed with scanning electron microscopy images from experimental samples. We postprocess the LAMMPS simulated data sets at 1.5 and 5 mg/ml, both to image the structure transition and compare with scanning electron micrographs and to show that the 3.33‐fold increase in concentration induces closer proximity of interacting electrostatic and hydrophobic domains, thereby amplifying the proximity‐based strength of the interactions. 

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5. Magnetoactive, Kirigami-Inspired Hammocks to Probe Lung Epithelial Cell Function

   https://doi.org/10.1007/s12195-024-00808-z  

   Wei, Katherine; Roy, Avinava; Ejike, Sonia; Eiken, Madeline_K; Plaster, Eleanor_M; Shi, Alan; Shtein, Max; Loebel, Claudia (July 2024, Cellular and Molecular Bioengineering)

   Abstract IntroductionMechanical forces provide critical biological signals to cells. Within the distal lung, tensile forces act across the basement membrane and epithelial cells atop. Stretching devices have supported studies of mechanical forces in distal lung epithelium to gain mechanistic insights into pulmonary diseases. However, the integration of curvature into devices applying mechanical forces onto lung epithelial cell monolayers has remained challenging. To address this, we developed a hammock-shaped platform that offers desired curvature and mechanical forces to lung epithelial monolayers. MethodsWe developed hammocks using polyethylene terephthalate (PET)-based membranes and magnetic-particle modified silicone elastomer films within a 48-well plate that mimic the alveolar curvature and tensile forces during breathing. These hammocks were engineered and characterized for mechanical and cell-adhesive properties to facilitate cell culture. Using human small airway epithelial cells (SAECs), we measured monolayer formation and mechanosensing using F-Actin staining and immunofluorescence for cytokeratin to visualize intermediate filaments. ResultsWe demonstrate a multi-functional design that facilitates a range of curvatures along with the incorporation of magnetic elements for dynamic actuation to induce mechanical forces. Using this system, we then showed that SAECs remain viable, proliferate, and form an epithelial cell monolayer across the entire hammock. By further applying mechanical stimulation via magnetic actuation, we observed an increase in proliferation and strengthening of the cytoskeleton, suggesting an increase in mechanosensing. ConclusionThis hammock strategy provides an easily accessible and tunable cell culture platform for mimicking distal lung mechanical forces in vitro. We anticipate the promise of this culture platform for mechanistic studies, multi-modal stimulation, and drug or small molecule testing, extendable to other cell types and organ systems. 

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