Masaji Fukuda

Neuronal activity in the ventral tegmental area (VTA) during motivated bar press feeding in the monkey.

Neuronal activity of 58 dopaminergic (DA) and 200 non-dopaminergic (non-DA) neurons in the ventral tegmental area (VTA) of female monkeys was recorded, and correlation to bar press feeding, sensory stimulation and change in motivation was investigated. DA neurons, judged by duration of action potentials (more than 2.5 ms) and responsiveness to apomorphine, had lower firing rates (0-8 impulses/s); non-DA neurons had intermediate firing rates (10-30 impulses/s). Two-thirds of the DA and non-DA neurons responded in bar press feeding; the former with mostly tonic and the latter with phasic responses. Fifteen neurons (5%) responded phasically to arm extension toward the bar, 124 (excitation 88, inhibition 36, 45%) during bar press (BP), and 91 (excitation 32, inhibition 59, 33%) during ingestion reward (RW). Most BP responses (84/124, 68%) continued tonically throughout the BP period with no correlation to each BP movement. In 14 neurons (14/124, 11%), firing showed a specific variation: transient early BP responses shifted to tonic steady ones in palatable food trials, and the shifts correlated well with BP speed. In 20 other neurons, firing increased during BP hip lifting, and at specific vocalization to ask for food; it decreased during food ingestion, drinking and inguino-crural stimulation. Apomorphine administration decreased firing for the first 5-15 min, then increased it with frequent lip smacking, nausea, involuntary movement and vocalization. Thus VTA neurons showed mostly steady tonic responses but some specific phasic responses. They responded not only to motor events but also in close relation to changes of motivational aspects. Neuronal responses were excitation during procurement of reward and inhibition during or after perception of reward. This modulation in firing, might be important in the initiation and execution of movement and/or motivated behavior.

Rat amygdaloid neuron responses during auditory discrimination

To investigate amygdaloid contribution to stimulus-affect association and to emotional behavior, single neuron activity was recorded in the basolateral and corticomedial amygdala of the rat amygdala during discrimination of conditioned cue tones associated with positive (glucose and intracranial self-stimulation) and negative (weak electric footshock) unconditioned stimuli. Amygdaloid neurons that responded to two rewarding unconditioned stimuli responded in the same manner to both. Responses to conditioned cue tones and those to rewards were also significantly related, suggesting that amygdaloid neuronal responses to conditioned stimuli are closely related to the affective nature of the corresponding unconditioned stimulation. These might be neuronal functions that underlie stimulus-affect association in the amygdala. In random repeated trials, including acquisition to conditioned cue tones and extinction after acquisition, response plasticity was more evident in basolateral than in corticomedial neurons. Furthermore, more basolateral than corticomedial neurons differentiated glucose and its cue from intracranial self-stimulation and its cue by responding to one but not the other. More basolateral than corticomedial neurons were excited by intracranial self-stimulation and its cue and inhibited by footshock and its cue. The differences between the two nuclear groups suggest that basolateral neurons are more plastic and discriminative, and corticomedial neurons respond indiscriminately to positive and negative unconditioned or conditioned stimuli. The results indicate amygdaloid neuron involvement in stimulus-affect association. Basolateral neurons may be more involved than corticomedial neurons in discriminating and learning conditioned stimuli.

Glucoresponsive neurons in rat ventromedial hypothalamic tissue slices in vitro.

Extracellular action potentials were recorded from rat ventromedial hypothalamic nucleus (VMH) tissue slices in vitro. The identified glucoresponsive and non-glucoresponsive neurons were then visually located and observed by intracellular horseradish peroxidase staining. Glucoresponsive neurons, which were predominantly multipolar, were found near the center of the VMH, while non-glucoresponsive neurons, half of which were bipolar and half multipolar, were found randomly throughout the VMH.

Monkey lateral hypothalamic neuron response to sight of food, and during bar press and ingestion

Unit activity of 144 lateral hypothalamus (LHA) neurons was analyzed in monkey during bar pressing feeding behavior. Eighteen neurons responded only when the animal saw food, and 23 responded only during ingestion of food. Ten responded at both the sight of food and throughout the bar pressing and ingestion periods, even in high fixed ratio schedules. Three neurons responded, not at the sight of food, but at the sight of non-food. Nineteen out of a total of 54 of the above responding neurons were studied for response to differences between food and non-food. Eight responded similarly at the sight of both food and non-food, while 11 responded differently. Responses during the ingestion period were strong and lasted longer than 5--10 sec. The data indicate that some LHA neurons are involved in the discrimination of food, the drive to obtain it and the perception of reward.

Topographic Organization of Projections from the Amygdala to the Hypothalamus of the Rat

Afferent fibers from the amygdala to subdivisions of lateral, ventromedial and dorsomedial hypothalamic nuclei were investigated in rat by retrograde transport of horseradish peroxidase. Small (intranuclear size) peroxidase deposits were placed in hypothalamic nuclei by iontophoresis of a tracer solution containing poly-L-alpha-ornithine which greatly limited diffusion. The medial, central and amygdalo-hippocampal nuclei of the amygdala were found to be the major donors of amygdaloid afferent fibers to the hypothalamus, but there was also substantial labeling of somata in cortical, basomedial, basolateral and lateral amygdaloid nuclei and the intra-amygdaloid bed nucleus of the stria terminalis. No fibers projected from the posterior cortical nucleus of the amygdala to the hypothalamus. Most amygdaloid projections to the lateral hypothalamic area originated in the anterior half of the amygdala, while projections to the ventromedial hypothalamic nucleus arose along the entire length of the amygdala except the posterior cortical nucleus. The amygdalo-hippocampal area projects to the medial hypothalamus. Other amygdaloid nuclei project to both the medial and lateral hypothalamic nuclei. These topographic organizations of amygdaloid afferent fibers to various subdivisions of the hypothalamic nuclei are discussed and compared with other anatomical studies on these connections.

PLACE RECOGNITION RESPONSES OF NEURONS IN MONKEY HIPPOCAMPUS

Neuronal activity in the monkey hippocampus was recorded while the monkey sat in a rotatable cab which it could cause to move from one location to another by pressing bars, and while it was presented various visual stimulation from several horizontal directions (directional stimulation). Of 174 hippocampal neurons recorded, 20 were selective to direction of the stimulus without place relation. Responses of these neurons could be described in egocentric coordinates for some and allocentric coordinates for others. Seventy-seven neurons had place related activity (place related neurons). Of these place related neurons, 21 were also directionally selective with responses described in egocentric or allocentric coordinates or both. The results show close relations between the coding of environmental space cues in egocentric and allocentric coordinates, and place related activity in the primate hippocampus.

Role of the lateral hypothalamus and the amygdala in feeding behavior

Abstract Unit activities of the lateral hypothalamic area (LHA) and amygdala (AM) were recorded during bar pressing feeding behavior in monkeys. Out of 103 LHA neurons tested, 9 decreased its firing selectively at the sight of food and not to non-food, and most of this initial response continued all through the subsequent bar pressing period. The firing decreased again after the animal put food into mouth. The discrimination ratio of food was calculated to be 54% in the LHA. Even in the AM, some neurons responded uniquely to food, and not to non-food. This differential response became more clear in the repeated subsequent trials. The discrimination ratio of food was calculated to be 25% to 44%. Although almost all of the initial responses were not maintained during the bar pressing period, 22 neurons (18% of tested) increased firing at the reward period in the AM. These data suggest that the LHA is deeply involved in the bar pressing feeding behavior all through the perception of food, the driving mechanism to obtain food, and the final reward response, while the AM seems to be concerned in some perception and reward response.

Caudate unit activity during operant feeding behavior in monkeys and modulation by cooling prefrontal cortex

Activity was recorded from 351 neurons in the head of the caudate nucleus (CD) of monkeys during an operant feeding task consisting of: (1) food or non-food presentation (P); (2) bar pressing (B); and (3) food acquisition and ingestion (I). Of 45 neurons which responded in the P phase and were tested systematically, 27 responded to visual presentation of both food and non-food (non-specific response), and 18 responded to food presentation only (food specific response). The magnitude of food specific responses depended on the nature of the food and was inversely related to the latency of the onset of bar pressing. Thirty-five neurons responded in the B phase: 28 changed firing rate continuously with no correlation to individual bar presses, while the activity of the other 7 was related to each bar press. In the I phase, 62 neurons responded to separate events: the activity of more than half (39 neurons) was often related to chewing movement or gustatory stimuli, and that of one third (23 neurons) changed during individual arm movements. The neurons which responded in the P phase were found to be distributed widely in the head of the CD except for its central zone, while the neurons which responded in the I phase were in the medial part. Cooling of the dorsolateral prefrontal cortex abolished the continuous responses seen in the B phase, but did not abolish the feeding behavior. The data suggest that in the head of the CD there are several groups of neurons that have different functions and different distributions: food specific, sensory integration responses, non-motor responses driven by the frontal cortex, motor responses coupled to various movements, and sensory responses which apparently originate in the intra-oral cavity. These functions may arise sequentially, or in correspondence with integration of the sensory and motor systems to produce coordinated behavior.

Single neuron activity in dorsolateral prefrontal cortex of monkey during operant behavior sustained by food reward

The activity of 190 neurons was recorded from the dorsolateral prefrontal cortex of monkeys during an operant task that consisted of 3 phases: visual discrimination of food and non-food, bar pressing to gain access to the food and ingestion. In area 8, a fairly large proportion of the 49 recorded neurons responded in both the visual discrimination (37%) and motor initiation (35%) phases. Some functional heterogeneity seems evident within area 8 since visual discrimination responses were rostral, visuokinesis was central and motor initiation was in the caudal bank of the arcuate sulcus. Neurons in area 9 responded primarily (37%) during the bar pressing phase and less during the visual discrimination phase. Neurons in area 10 responded variously during most phases of the task--food discrimination, bar pressing, and ingestion. Neurons in the periprincipal sulcal area usually responded in the visual discrimination phase, but some which did not respond to food presented in front of the subject responded to meaningful visual or auditory cues that were related to food reward. The data suggest that neurons in the dorsolateral prefrontal cortex have multiple functions related to all phases of complex, learned feeding behavior. Functional roles of the prefrontal cortex and the lateral hypothalamus in development of feeding behavior are discussed.

The isochronic band hypothesis and climbing fibre regulation of motricity: an experimental study

The dynamic organization of the olivocerebellar afferent input to Purkinje cells was examined in rat cerebellar cortex. The distribution of synchronous Purkinje cell complex spike activity was characterized, bilaterally, utilizing multiple electrode recordings in crus IIa folium under ketamine anaesthesia. The results confirmed the existence of rostrocaudal complex spike isochronicity bands with a mediolateral width of 500 µm. For a given band, no finer spatial submicrostructures could be discerned at a first‐order approximation (two‐dimensional projection). Closer analysis determined that isochronicity between bands is not continuous in space but demonstrates discrete discontinuities at the mediolateral boundaries. Principal component multivariate analysis revealed that the first principal component of the spatio‐temporal variance is synchronicity along the rostrocaudal band with a decreased level of coupling in the mediolateral direction at the band boundary. Furthermore, this discrete banding isochronicity is organized by the distribution of feedback inhibition from the cerebellar nuclei on to the inferior olive nucleus. The usual multiple band structure can be dynamically altered to a single wide‐band dynamic architecture, or to other patterns of activity, as may be required by movement coordination.