Swallowing movements are produced by a central pattern generator located in the medulla oblongata. It has been established on the basis of microelectrode recordings that the swallowing network includes two main groups of neurons. One group is located within the dorsal medulla and contains the generator neurons involved in triggering, shaping, and timing the sequential or rhythmic swallowing pattern. Interestingly, these generator neurons are situated within a primary sensory relay, that is, the nucleus tractus solitarii. The second group is located in the ventrolateral medulla and contains switching neurons, which distribute the swallowing drive to the various pools of motoneurons involved in swallowing. This review focuses on the brain stem mechanisms underlying the generation of sequential and rhythmic swallowing movements. It analyzes the neuronal circuitry, the cellular properties of neurons, and the neurotransmitters possibly involved, as well as the peripheral and central inputs which shape the output of the network appropriately so that the swallowing movements correspond to the bolus to be swallowed. The mechanisms possibly involved in pattern generation and the possible flexibility of the swallowing central pattern generator are discussed.
The aim of the present study was to identify the central structures involved in the organization of the swallowing reflex in the rat. Using concentric bipolar electrodes, the medulla and pons were systematically explored in order to determine which central areas responded to stimulation by inducing swallowing. These areas, which were located in the dorsal medulla oblongata, were the solitary tract, the nucleus of the solitary tract (NST) and the adjacent reticular formation. Stimulation of the ventral ponto-medullary regions was ineffective with regard to the initiation of the swallowing reflex. The activity of medullary swallowing neurons was recorded using extracellular microelectrodes. These swallowing neurons responded with a burst of spikes (swallowing activity) which was closely linked to the swallowing reflex elicited by stimulation of the superior laryngeal nerve (SLN). Under SLN stimulation, the activity of some of the swallowing neurons furthermore showed an initial response consisting of 1 or 2 spikes after a brief latency. According to their location and the latency of their initial response, swallowing neurons were divided into two groups. Group I neurons were located in a dorsal area of the medulla oblongata corresponding to the NST and the adjacent reticular formation. All these neurons exhibited an initial response with a very short latency (1 to 4 ms), the swallowing activity of most of these neurons started before the onset of the swallowing motor sequence. Group II neurons were located either in a ventral area corresponding to the nucleus ambiguus and the surrounding reticular formation or in a dorsal and medial area corresponding to the hypoglossal nucleus and its vicinity.(ABSTRACT TRUNCATED AT 250 WORDS)
Brain-derived neurotrophic factor (BDNF) has recently been implicated as an anorexigenic factor in the central control of food intake. Previous studies focused on the hypothalamus as a probable site of action for this neurotrophin. It was demonstrated that BDNF is an important downstream effector of melanocortin signaling in the ventromedial hypothalamus. In this study, we addressed whether BDNF can modulate food intake in the hindbrain autonomic integrator of food intake regulation, i.e. the dorsal vagal complex (DVC). To this end, we used two complementary methodological approaches in adult rats. First, we measured the effects of intraparenchymal infusions of exogenous BDNF within the DVC on food intake and body weight. Second, we measured the endogenous BDNF protein content in the DVC and hypothalamus after food deprivation, refeeding, or peripheral treatments by the anorexigenic hormones leptin and cholecystokinin (CCK). BDNF infusion within the DVC induced anorexia and weight loss. In the DVC, BDNF protein content decreased after 48 h food deprivation and increased after refeeding. Acute and repetitive peripheral leptin injections induced an increase of the BDNF protein content within the DVC. Moreover, peripheral CCK treatment induced a transient increase of BDNF protein content first in the DVC (30 min after CCK) and later on in the hypothalamus (2 h after CCK). Taken together, these results strongly support the view that BDNF plays a role as an anorexigenic factor in the DVC. Our data also suggest that BDNF may constitute a common downstream effector of leptin and CCK, possibly involved in their synergistic action.
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