Evidence for macular gravity receptor modulation of hypothalamic, limbic and autonomic nuclei.

Mice lacking normal vestibular gravity reception show altered homeostatic, circadian and autonomic responses to hypergravity (+G) exposure. Using c-Fos as a marker of neuronal activation, the current study identifies CNS nuclei that may be critical for initiating and integrating such responses to changes in vestibular signaling. This experiment utilized the mutant C57BL/6JEi-het mouse (het), which lacks macular otoconia and thus gravity receptor function. Following 2 h of 2G (2x Earth's gravity) exposure (via centrifugation) the neuronal responses of the het mice were compared with wildtype mice similarly exposed to 2G, as well as het and wildtype 1G controls. Wildtype mice exposed to 2G demonstrated robust c-Fos expression in multiple autonomic, hypothalamic and limbic nuclei, including: the lateral septum, bed nucleus of the stria terminalis, amygdala, paraventricular hypothalamus, dorsomedial hypothalamus, arcuate, suprachiasmatic hypothalamus, intergeniculate leaflet, dorsal raphe, parabrachial and locus coeruleus. The het mice exposed to 2G demonstrated little to null c-Fos expression in these nuclei with a few exceptions and, in general, a similar pattern of c-Fos to 1G controls. Data from this study further support the existence of a complex and extensive influence of the neurovestibular system on homeostatic, circadian and possibly autonomic regulatory systems.

The inferior alveolar and mylohyoid nerves: an anatomic study and relationship to local anesthesia of the anterior mandibular teeth.

The distance between the branching point of the mylohyoid nerve to the entrance of the inferior alveolar nerve into the mandibular canal was studied in 37 adult human cadavers. On the average, this branching distance was 14.7 mm, which is greater than previously reported. Also found was a 43% incidence of extension of the mylohyoid nerve beyond the muscle to foramina on the lingual aspect of the mandible. If the mylohyoid nerve mediates sensory information from the anterior incisors, then the factor of an increased branching distance may become important in terms of the dilution of the anesthetic agent during diffusion and the amount of nerve length exposed to the anesthetic agent. These findings may also account in part for the purported greater success of the so-called Gow-Gates type of injection technique compared with that of the conventional mandibular block.

Cobalt iontophoresis techniques for tracing afferent and efferent connections in the vertebrate CNS.

In recent years several dye and cobalt iontophoresis techniques have been successfully used by invertebrate neurophysiologists for the localization of neuron somata and their processes. The cobalt iontophoresis technique has now been extended for use in the tracing of nerve fiber pathways and the localization of neuron somata in vertebrates. The brain and spinal cord of an animal are removed following perfusion with saline, and placed in a dish of cold saline. A suction electrode, filled with 300 mM cobalt chloride, is then placed over the cut end of the nerve trunk. Cobalt ions are then iontophoresed (by means of a voltage divider) within the nerve fibers, along their course. Following iontophoresis, the brain is bathed in an ammonium sulfide solution to precipitate the cobalt as black cobalt sulfide. The brain is then processed for histological procedures. A wide variety of vertebrates has been used, including amphibians, reptiles, aves and mammals, with uniform success. The cobalt iontophoresis technique presently in use has a wide range of applicability for neuroanatomical studies.