Physiology and Pathophysiology of Human Airway Mucus

The mucus clearance system is the dominant mechanical host defense system of the human lung. Mucus is cleared from the lung by cilia and airflow, including both two-phase gas liquid pumping and cough-dependent mechanisms, and mucus transport rates are heavily dependent on mucus concentration. Importantly, mucus transport rates are accurately predicted by the gel-on-brush model of the mucociliary apparatus from the relative osmotic moduli of the mucus and periciliary-glycocalyceal (PCL-G) layers. The fluid available to hydrate mucus is generated by transepithelial fluid transport. Feedback interactions between mucus concentrations and cilia beating, via purinergic signaling, coordinate Na+ absorptive vs Cl- secretory rates to maintain mucus hydration in health. In disease, mucus becomes hyperconcentrated (dehydrated). Multiple mechanisms derange the ion transport pathways that normally hydrate mucus in muco-obstructive lung diseases, e.g., CF, COPD, NCFB, and PCD. A key step in muco-obstructive disease pathogenesis is the osmotic compression of the mucus layer onto the airway surface with the formation of adherent mucus plaques and plugs, particularly in distal airways. Mucus plaques create locally hypoxic conditions and produce airflow obstruction, inflammation, infection, and, ultimately, airway wall damage. Therapies to clear adherent mucus with hydrating and mucolytic agents are rational, and strategies to develop these agents are reviewed.

Abstract P417: Cardiomyopathy-associated Variant In Troponin T Tail Domain Promotes Disruption Of Both Frank-starling Mechanism And Cardiac Myofilament Performance

Missense variant Ile79Asn in human cardiac troponin T (HcTnT-I79N) tail region has been linked to familial hypertrophic cardiomyopathy (HCM), arrhythmia, and sudden cardiac death. It has been reported that inotropic stimulation with high extracellular Ca 2+ or isoproterenol led to diastolic dysfunction in both isolated and in vivo HcTnT-I79N mice hearts. Although HcTnT-I79N effects are acknowledged to be dependent on the inotropic state of the cardiac muscle, little is known about how this pathogenic variant affects the Frank-Starling law of the heart. To further investigate the functional and structural consequences of this deadly variant in a stretch-dependent manner, cardiac tissues were harvested from non-transgenic (NTg) control mice and transgenic mice bearing HcTnT-I79N. Left ventricular papillary muscle bundles were permeabilized and mounted for mechanical measurements. Sarcomere length (SL 1.9, 2.1 or 2.3 μm) was set at pCa 8 using HeNe laser diffraction and then Ca 2+ -dependence of isometric force, sinusoidal stiffness (SS, 0.2% PTP length oscillation) and rate of tension redevelopment ( k TR ) were measured. We observed that HcTnT-I79N tissue exhibited increased myofilament Ca 2+ -sensitivity of force, increased SS, slower k TR at all levels of Ca 2+ -activation, and diminished length-dependent activation (LDA). Small-angle X-ray diffraction revealed that HcTnT-I79N permeabilized cardiac muscles exhibit smaller myofilament lattice spacing at longer SLs (2.1 μm and 2.3 μm) compared to NTg. Using 3% Dextran T500 to osmotically compress the myofilament lattice (SL 2.1 μm), HcTnT-I79N showed no change in myofilament lattice spacing and little change in contractile indices associated with LDA. Interestingly, upon osmotic compression, HcTnT-I79N displayed a decrease in disordered relaxed state (DRX, ON state) of myosin and an increase in super-relaxed state (SRX, OFF state) of myosin. We conclude that altered cardiac myofilament performance, lack of responsiveness to osmotic compression, and reduced LDA observed with HcTnT-I79N are partially due to a combination of smaller myofilament lattice and disturbed ON and OFF states of myosin.

Drying paint: from micro-scale dynamics to mechanical instabilities

Charged colloidal dispersions make up the basis of a broad range of industrial and commercial products, from paints to coatings and additives in cosmetics. During drying, an initially liquid dispersion of such particles is slowly concentrated into a solid, displaying a range of mechanical instabilities in response to highly variable internal pressures. Here we summarize the current appreciation of this process by pairing an advection-diffusion model of particle motion with a Poisson–Boltzmann cell model of inter-particle interactions, to predict the concentration gradients in a drying colloidal film. We then test these predictions with osmotic compression experiments on colloidal silica, and small-angle X-ray scattering experiments on silica dispersions drying in Hele–Shaw cells. Finally, we use the details of the microscopic physics at play in these dispersions to explore how two macroscopic mechanical instabilities—shear-banding and fracture—can be controlled. This article is part of the themed issue ‘Patterning through instabilities in complex media: theory and applications.’