Abstract
Most terrestrial animals demonstrate an autonomic reflex that facilitates survival during prolonged submersion under water. This diving response is characterized by bradycardia, apnea and selective increases in peripheral vascular resistance. Stimulation of the nose and nasal passages is thought to be primarily responsible for providing the sensory afferent signals initiating this protective reflex. Consequently, the primary objective of this research was to determine the central terminal projections of nerves innervating the external nose, nasal vestibule and nasal passages of rats. We injected wheat germ agglutinin (WGA) into specific external nasal locations, into the internal nasal passages of rats both with and without intact anterior ethmoidal nerves (AENs), and directly into trigeminal nerves innervating the nose and nasal region. The central terminations of these projections within the medulla were then precisely mapped. Results indicate that the internal nasal branch of the AEN and the nasopalatine nerve, but not the infraorbital nerve (ION), provide primary innervation of the internal nasal passages. The results also suggest afferent fibers from the internal nasal passages, but not external nasal region, project to the medullary dorsal horn (MDH) in an appropriate anatomical way to cause the activation of secondary neurons within the ventral MDH that express Fos protein during diving. We conclude that innervation of the anterior nasal passages by the AEN and nasopalatine nerve is likely to provide the afferent information responsible for the activation of secondary neurons within MDH during voluntary diving in rats.
Highlights
Aquatic, semi-aquatic and even primarily terrestrial animals demonstrate an autonomic reflex that enables survival during prolonged submersion under water
Using selective injections of the tranganglionic tracer wheat germ agglutinin (WGA), we found that the central terminal projections of both the anterior ethmoidal nerve (AEN) and nasopalatine nerve are very similar to the central projections from the internal nasal passages
Similar labeling was found both when the AENs were intact or cut bilaterally. Since this labeling pattern is: (1) more lateral and dorsal compared with the labeling found after injection of WGA into the AEN; and (2) nearly identical both before and after bilateral sectioning of the AENs, these findings indicate the glabrous skin inferior to the nasal vestibule is not innervated by the external nasal branch of the AEN
Summary
Semi-aquatic and even primarily terrestrial animals (including humans) demonstrate an autonomic reflex that enables survival during prolonged submersion under water. This so-called diving response is characterized by bradycardia, apnea, and a selective increase in peripheral vascular resistance causing a redistribution of blood flow to maintain perfusion of the heart. Nasal Innervation and Diving Response and brain while limiting flow to non-exercising muscles (Butler and Jones, 1997; Panneton, 2013). These cardiorespiratory changes occur in response to submersion of the head underwater, but not to swimming on the water surface (McCulloch et al, 2010; Panneton et al, 2010b). The specific stimulus that activates this reflex is unknown, it may possibly involve activation of chemesthetic trigeminal chemoreceptors (Finger et al, 2003; Munger et al, 2009; Silver and Finger, 2009; Tizzano and Finger, 2013)
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