Loss of cell junctional components and matrix alterations drive cell desquamation and fibrotic changes in Idiopathic Pulmonary Fibrosis.

Unlabelled: The distal bronchioles in Idiopathic Pulmonary Fibrosis (IPF) exhibit histopathological abnormalities such as bronchiolization, peribronchiolar fibrosis and honeycomb cysts that contribute to the overall architectural remodeling of lung tissue seen in the disease. Here we describe an additional histopathologic finding of epithelial desquamation in patients with IPF, wherein epithelial cells detach from the basement membrane of the distal bronchioles. To understand the mechanism driving this pathology, we performed spatial transcriptomics of the epithelial cells and spatial proteomics of the basement membrane of the distal bronchioles from IPF patients and patients with no prior history of lung disease.

Pulmonary Fibrosis Ferret Model Demonstrates Sustained Fibrosis, Restrictive Physiology, and Aberrant Repair.

Rationale: The role of MUC5B mucin expression in IPF pathogenesis is unknown. Bleomycin-exposed rodent models do not exhibit sustained fibrosis or airway remodeling. Unlike mice, ferrets have human-like distribution of MUC5B expressing cell types and natively express the risk-conferring variant that induces high MUC5B expression in humans.

Action potential conduction in the mouse and rat vagus nerve is dependent on multiple voltage-gated sodium channels (Na1s).

Action potential (AP) conduction depends on voltage-gated sodium channels, of which there are nine subtypes. The vagus nerve, comprising sensory afferent fibers and efferent parasympathetic fibers, provides autonomic regulation of visceral organs, but the voltage-gated sodium channels (Na1) subtypes involved in its AP conduction are poorly defined. We studied the A- and C-waves of electrically stimulated compound action potentials (CAPs) of the mouse and rat vagus nerves with and without Na1 inhibitor administration: tetrodotoxin (TTX), PF-05089771 (mouse Na1.

Role of Na 1.7 in action potential conduction along human bronchial vagal afferent C-fibres.

Background And Purpose: The purpose of this study was to determine the role of Na 1.7 in action potential conduction in C-fibres in the bronchial branches of the human vagus nerve.

Experimental Approach: Bronchial branches of the vagus nerve were dissected from human donor tissue.

Contribution of tetrodotoxin-sensitive, voltage-gated sodium channels (Na1) to action potential discharge from mouse esophageal tension mechanoreceptors.

Action potentials depend on voltage-gated sodium channels (Na1s), which have nine α subtypes. Na1 inhibition is a target for pathologies involving excitable cells such as pain. However, because Na1 subtypes are widely expressed, inhibitors may inhibit regulatory sensory systems.

Antitussive effects of Na 1.7 blockade in Guinea pigs.

Our previous studies implicated the voltage-gated sodium channel subtype Na 1.7 in the transmission of action potentials by the vagal afferent nerves regulating cough and thus identified this channel as a rational therapeutic target for antitussive therapy. But it is presently unclear whether a systemically administered small molecule inhibitor of Na 1.

Voltage-gated sodium channels mediating conduction in vagal motor fibers innervating the esophageal striated muscle.

The vagal motor fibers innervating the esophageal striated muscle are essential for esophageal motility including swallowing and vomiting. However, it is unknown which subtypes of voltage-gated sodium channels (NaV1s) regulate action potential conduction in these efferent nerve fibers. The information on the NaV1s subtypes is necessary for understanding their potential side effects on upper gut, as novel inhibitors of NaV1s are developed for treatment of pain.

Stimulus intensity-dependent recruitment of Na1 subunits in action potential initiation in nerve terminals of vagal C-fibers innervating the esophagus.

We investigated voltage-gated sodium channel (Na1) subunits that regulate action potential initiation in the nerve terminals of vagal nodose C-fibers innervating the esophagus. Extracellular single fiber recordings were made from the nodose C-fibers, with mechanically sensitive nerve terminals in the isolated innervated guinea pig esophagus. Na1 inhibitors were selectively delivered to the tissue-containing nerve terminals.

The Prospect for Potent Sodium Voltage-Gated Channel Blockers to Relieve an Excessive Cough.

An excessive, irritable, productive or non-productive coughing associated with airway inflammation belongs to pathological cough. Increased activation of airway vagal nociceptors in pathological conditions results from dysregulation of the neural pathway that controls cough. A variety of mediators associated with airway inflammation overstimulate these vagal airway fibers including C-fibers leading to hypersensitivity and hyperreactivity.

The voltage-gated sodium channel Na1.8 blocker A-803467 inhibits cough in the guinea pig.

Cough in respiratory diseases is attributed to the activation of airway C-fibers by inflammation. Inflammatory mediators can act on multiple receptors expressed in airway C-fibers, nonetheless, the action potential initiation in C-fibers depends on a limited number of voltage-gated sodium channel (Na1) subtypes. We have recently demonstrated that Na1.