The habenulo-interpeduncular and mammillothalamic tracts: early developed fiber tracts in the human fetal diencephalon.

PURPOSE: The habenulo-interpeduncular (HI) and mammillothalamic (MT) tracts are phylogenetically ancient. The clinical relevance of these tracts has recently received attention. In this work, we map the anatomy the developing HI and MT. METHODS: To investigate the topographical anatomy of developing fiber tracts in and around the diencephalon, we examined the horizontal, frontal, and sagittal serial paraffin sections of 28 human fetuses at 8-12 weeks of gestation. RESULTS: In all specimens, eosinophilic early fiber bundles were limited to the bilateral HI and MT tracts in contrast to pale-colored later developing fibers such as the thalamocortical projections and optic tract. The HI and MT tracts ran nearly parallel and sandwiched the thalamus from the dorsal and ventral sides, respectively. The nerve tract course appeared to range from 5-7 mm for the HI tract and 3-5 mm for the MT tract in 15 specimens at 11-12 weeks. The HI tract was embedded in, adjacent to, or distant from the developing parvocellular red nucleus. CONCLUSIONS: In early human fetuses, HI and MT tracts might be limited pathways for primitive cholinergic fiber connections between the ventral midbrain and epithalamic limbic system.

Deep brain stimulation of the entopeduncular nucleus in rats prevents apomorphine-induced deficient sensorimotor gating.

Pharmacologically induced stereotypies and deficient sensorimotor gating, measured as prepulse inhibition (PPI) of the acoustic startle response (ASR), are used as endophenotypes for certain symptoms common to neuropsychiatric disorders, such as schizophrenia and Tourette's syndrome (TS) among others. We here investigated whether high frequency deep brain stimulation (DBS) of the rat's entopeduncular nucleus (EPN), the equivalent to the human globus pallidus internus (GPi), would improve PPI-deficits and stereotypies induced by the dopamine receptor agonist apomorphine. Electrodes were stereotactically implanted bilaterally in the EPN of 13 Sprague-Dawley rats. After one week of recovery the rats were stimulated with an amplitude 20% below their individual threshold for side effects (130 Hz, 80 µs pulse width) or sham-stimulated for epochs of five days. At the end of each epoch the effect of ongoing stimulation or sham-stimulation on apomorphine-induced stereotypies (vehicle and 0.5 mg/kg) and deficient PPI (vehicle and 1.0 mg/kg) were tested. In nine rats, in which the full protocol could be applied and in which the electrode position was histologically confirmed in the target, EPN DBS did not affect baseline PPI but counteracted the apomorphine-induced PPI-deficit, while apomorphine-induced stereotypies were not affected by DBS. This work indicates an important role of the EPN in the modulation of apomorphine-induced deficient prepulse inhibition. This model may be useful to further investigate the pathophysiological of deficient sensorimotor gating and mechanisms of action of DBS in certain neuropsychiatric disorders.

[The organization of the efferent projections of the pedunculo-pontine tegmental nucleus to the dog pallidum ].

The study of pedunculo-pontine-pallidum projections in the dog's brain, which was performed using the method of retrograde axonal transport, has demonstrated the projections of a compact part (PPNc) and the lateral area of a diffuse part (PPNd) of midbrain pedunculo-pontine tegmental nucleus (PPN) to the globus pallidus, nucleus entopeduncularis and the ventral pallidum. PPNd medial area adjacent to decussation of the superior cerebellar peduncules, which is distinguished in other animals as the mesencephalic extrapiramydal area (MEA), projects only to the globus pallidus. In the dog, this tegmental area is not the major source of projections to striopallidum, therefore it appears not to be valid to distinguish it as an individual structure, it is reasonable to indicate only a topical organization PPNd projections to the pallidum. It was detected that the structures of pallidum received the projections from both cholinergic and non cholinergic initial PPN neurons.

[Analysis of the morphological substrate of information processing in the dog brain pallidal complex based on organizational characteristics of its afferent projections]. / Analiz morfologicheskogo substrata obrabotki informatsii v pallidarnom iadernom komplekse mozga sobaki na osnove osobennostei organizatsii ego afferentnykh proektsii.

Projections from functionally diverse cortical and subcortical structures (cortex, amygdaloid body, substantia nigra, ventral tegmental area, and thalamus) to the pallidum (globus pallidus, entopeduncular nucleus and ventral pallidum) were studied in dogs using the method of axonal transport of the retrograde markers. Anatomical aspects of both the functional heterogeneity of the pallidal structures and integrative processing of information which underlie the mechanisms of adaptive behavior, were analyzed on the basis of the results obtained.

Morphology and projection pattern of medial and dorsal pallial neurons in the frog Discoglossus pictus and the salamander Plethodon jordani.

In the frog Discoglossus pictus and the salamander Plethodon jordani, the morphology and axonal projection pattern of neurons in the medial and dorsal pallium were determined by intracellular biocytin labeling. A total of 77 pallial neurons were labeled in the frog and 58 pallial neurons in the salamander. Within the medial pallium (MP) of the frog, four types of neurons were identified on the basis of differences in their axonal projection pattern. Type I neurons have bilateral projections into telencephalic and diencephalic areas; type II neurons have bilateral projections to telencephalic areas and ipsilaterally descending projections to diencephalic regions; type III neurons have only intratelencephalic connections, and a single type IV neuron has ipsilaterally descending projections. The somata of the four types occupy four nonoverlapping zones. Neurons of the dorsal pallium (DP) project exclusively to the ipsilateral MP and to the dorsal edge of the lateral pallium. In the ventral MP of the salamander, neurons have mostly intratelencephalic projections. Neurons in the dorsal MP project bilaterally to diencephalic and telencephalic regions. Neurons in the medial DP project ipsilaterally to the MP, lateral septum, nucleus accumbens, medial amygdala, and the internal granule layer of the olfactory bulb. In five cases, fibers were found in the commissura hippocampi, but in only two cases could these fibers be followed toward the contralateral MP and septum. Neurons in the lateral DP had no contralateral projections; they projected to the ipsilateral MP and in eight cases to the ipsilateral septum as well. Based on similarities of cytoarchitecture and projection pattern in neurons of the MP and DP, it is proposed that both frogs and salamanders have an MP subdivided into a ventral and dorsal portion, and a DP subdivided into a medial and a lateral portion.

[Spatial organization of the corticopalladial projection system of dog brain]. / Prostranstvennaia organizatsiia kortiko-pallidarnoi proektsionnoi sistemy mozga sobaki.

Spatial organization of corticopallidal projectional system was studied in 11 outbred dogs by method based on horse radish peroxidase transport. It was demonstrated that globus pallidum receives projections predominantly from neocortical zones (motor, premotor, somatosensory, parietal and auditory and from insular field of mesocortex. Mesocortical (prelimbic, orbital and insular) and allocortical (entorhinal, piriform and periamygdalar) including archicortex (subicular part of hippocampal formations) fields project onto ventral pallidum. Entopeduncular nucleus receives projections from neocortical zones (motor, premotor, somatosensory, parietal and auditory), mesocortex (prelimbic, orbital, insular and cingular fields) and allocortex (entorhinal and periamygdalar fields). The data obtained indicate specificity of distribution of cortical afferent projectional fibres in each of nuclei studied which allows to consider globes pallidum as motor zone and ventral pallidum as limbic zone of paladial complex. As projections from functionally different cortical fields were revealed in entopeduncular nucleus it may be suggested that this is the exact site for interaction of functionally different information, including the one received from the cortex.