Ansa Cervicalis and Hypoglossal Nerve Stimulation in OSA

Obstructive Sleep Apnea (OSA) is a common disorder characterized by repetitive upper airway collapse during inspiration caused, in part, by a loss of neuromotor tone in specific upper airway muscles, with multiple associated health sequelae impacting millions of Americans. Patient adherence to the reference treatment, positive airway pressure (PAP), remains problematic. Despite the recent promising development of hypoglossal nerve stimulation (HNS) as a surgical therapy, its indications are limited and a proportion of eligible patients do not achieve sufficient response, leaving a critical unmet need for effective therapeutic alternatives to PAP.

This project challenges the long-held concept that the genioglossus muscle is primarily responsible for the maintenance of pharyngeal patency during sleep and proposes a novel therapeutic mechanism. It is built upon strong evidence that caudal pharyngeal traction from the trachea has a marked impact on pharyngeal patency primarily mediated through changes in lung volume. Contraction of the sternothyroid muscle, an infrahyoid cervical strap muscle that inserts onto the thyroid cartilage, also generates caudal pharyngeal traction. Our data suggest that ansa cervicalis stimulation (ACS) of the sternothyroid muscle unfolds and stretches the lateral pharyngeal walls and tensions the distal edge of the soft palate caudally, increasing airway patency.

The major hypothesis of the Investigators is that ACS overcomes specific anatomic and neuromuscular defects of upper airway control that restore pharyngeal patency in patients with OSA. This hypothesis is supported by published and preliminary data demonstrating that: (1) the degree of end-expiratory lung volume decrease in sleep correlates with observed increases in pharyngeal collapsibility, and (2) unilateral ACS increases maximum inspiratory airflow and velopharyngeal cross-sectional area during flow-limited breathing in sedated humans. These findings suggest that (3) tracheal traction, as mediated by end-expiratory lung volume (EELV), is a major contributor to airway patency in sleep. In this project, the Investigators will elucidate specific mechanisms for control of pharyngeal patency with caudal traction during drug-induced sleep endoscopy (DISE) and natural sleep (PSG). The Investigators will address these aims by characterizing (1) the effects of ACS of the sternothyroid muscle(s) on upper airway pressure-area and pressure-flow relationships, and (2) determine how subject anatomic, physiologic, and polysomnographic characteristics modulate these responses.