Kazushige Sasamoto

Projections of two separate cortical areas for rhythmical jaw movements in the rat

The cortico-bulbar projection from two separate cortical areas which induce different types of rhythmical jaw movements (RJM), and the relationship between these cortical areas were studied with horseradish peroxidase tracing method. One area (A-area) corresponded to the primary jaw motor area and the other (P-area) was located in the agranular insular cortex. Separate descending pathways from two areas passed through the pyramidal tract and projected to the supratrigeminal nucleus, the intertrigeminal region, the dorsal part of the trigeminal sensory complex, and the reticular formation. In the reticular formation, the A-area projected more medially than the P-area did, and the ipsilateral projection from the P-area was more prominent than that from the A-area, although contralateral projections were dominant in the majority of regions. The two areas had only a sparse reciprocal connection. We suppose that the difference in patterns of RJM induced by the two cortical RJM areas may be due to the different projection patterns from these two areas.

Conditioned taste aversion learning in leptin-receptor-deficient db/db mice

The db/db mouse has defective leptin receptors. The defects lead to impairments of leptin regulation of food intake and body weight, and result in the expression of diabetic symptoms such as hyperinsulinemia, hyperglicemia, and extreme obesity. Recent studies have proposed that leptin may also affect memory and learning processes. To examine this possibility, we compared the ability of leptin-receptor-deficient db/db mice and their normal lean litter mates to form and extinguish a conditioned taste aversion (CTA) for saccharin. We used a short-term (10 s) lick test and a long-term (48 h) two bottle preference test for measurement of consumption of test solutions. On the first day after conditioning to avoid saccharin, the db/db mice showed preference scores for saccharin as low, and aversion thresholds for sucrose lower than that of the lean mice. During the extinction test trials beginning from the second up to the 30th day after conditioning, numbers of licks and preference scores for aversive saccharin and sucrose appeared to be larger, and recovered faster to the control levels in db/db mice. These results indicate that db/db mice with leptin-receptor-deficiency may show equal capacity to form CTAs for saccharin, greater generalization from saccharin to sucrose, and a faster rate of extinction. This suggests that disruption of leptin signalling does not inhibit acquisition of CTA learning, but impairs its extinction. This differential contribution of the leptin system on CTA processes may be due to differential distribution of leptin receptors in the CTA-related brain areas.

Amygdaloid-induced jaw opening and facilitation or inhibition of the trigeminal motoneurons in the rat

1. Repetitive stimulation of the ratse central amygdaloid (CAm) nucleus induced rhythmic masticatory jaw movements or continuous jaw opening. Both types of jaw movements were accompanied by coincidental activities of the mylohyoid (Myl) nerve. 2. The effects of CAm stimulation were examined on activities of bilateral Myl and masseteric (Mass) nerves or their motoneurons (Myl-Dig and Mass, respectively). 3. CAm stimulation induced contralaterally dominant facilitation of the Myl nerve activity as well as Myl-Dig motoneurons. These facilitatory effects were caused by EPSPs seen in Myl-Dig motoneurons. 4. One third of the Mass motoneurons were inhibited or hyperpolarized by contralateral CAm stimulation, while a few were facilitated and the majority unaffected.

Amygdaloid or cortical facilitation of antidromic activity of trigeminal motoneurons in the rat.

1. Electrical stimulation of the rats contralateral central amygdaloid (CAm) nucleus or the contralateral frontal cortex markedly augmented the antidromic field potential evoked by stimulation of mylohyoid (Myl) nerve. 2. This facilitation was shown to be due to EPSPs of the mylohyoid-anterior digastric (Myl-Dig) motoneurons. 3. In a few motoneurons, cortical EPSPs had fixed short latencies following high-frequency double stimuli and this is believed to be due to a monosynaptic pathway. 4. The amygdaloid or cortically evoked EPSPs relieved IS-SD blockade in a few motoneurons and also facilitated antidromic discharge in others which did not show any IS or M spike response to the same subthreshold antidromic stimulation. The underlying mechanisms are discussed.

Cortical control of trigeminal motoneurons in the rat

Abstract 1. 1. Cortical influence on excitation of mylohyoid (Myl) and masseteric (Mass) nerves (Nn) and their motoneurons was studied in the rat. 2. 2. The frontal cortex excited a majority of the contralateral mylohyoid-digastric (c Myl-Dig) motoneurons, about a half of the ipsilateral (i) Myl-Dig motoneurons, about a third of c Mass motoneurons and the fewest i Mass motoneurons. 3. 3. A small number of c Mass motoneurons was considered to receive inhibitory influence since cortical stimulation inhibited antidromic activity and some of orthodromic activity. 4. 4. Stimulation of these motoneuron pool induced antidromic activity in the frontal cortex and a monosynaptic pathway is possible in the cortico-c Myl-Dig excitatory projection.

Neural activities in the substantia nigra modulated by stimulation of the orofacial motor cortex and rhythmical jaw movements in the rat

Neurons related to jaw movements in the substantia nigra pars reticulata were explored by examining changes in their neural activities in response to electrical stimulation of the orofacial sensorimotor cortex and during rhythmical jaw movements induced by mechanical stimulation applied to the oral cavity in the rat. Out of 80 neurons tested, 59 showed changes in their firing patterns of activities in response to the electrical stimulation of the cortex. The responding neurons were mainly located in the dorsolateral part of the substantia nigra pars reticulata. The substantia nigra pars reticulata neurons showing responses were classified into the following five types according to their response patterns: (1) an inhibition preceded by an early excitation and followed by a late excitation (n = 26), (2) an inhibition preceded by an early excitation but not followed by a late excitation (n = 7), (3) an inhibition not preceded by an early excitation but followed by a late excitation (n = 2), (4) an inhibition without early or late excitations (n = 7) and (5) an excitation without an inhibition (n = 17). Out of 18 neurons responding to the cortical stimulation, 11 (61.1%) increased or decreased their neural activities during rhythmical jaw movements. Some of these neurons had a projection to the lateral part of the superior colliculus (n = 5) and/or to the parvicellular reticular formation (n = 2). These results provide first neurophysiological evidence for neurons in the dorsolateral part of the substantia nigra pars reticulata with inputs from and outputs to the areas related to jaw movements. These neurons may participate in the control of jaw movements in the rat.