Organization of cerebral cortical afferent systems in the rat. II. Hypothalamocortical projections

Authors

  • Clifford B. Saper

    1. Departments of Neurology and Neurological Surgery (Neurology) and Anatomy and Neurobiology, Washington University School of Medicine, St. Louis, Missouri 63110
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  • Note: Due to a printing error, the first paper in this series, “Organization of cerebral cortical afferent systems in rat: I. Magnocellular basal nucleus,” J. Comp. Neurol. (1984) 222:313–342, was inadvertently marked as part II.

Abstract

The organization of hypothalamic projections to the cerebral cortex in the rat has been studied using retrograde and anterograde tracer methods. Four separate populations of hypothalamic neurons, which constitute a major source of diffuse cortical innervation, were identified:

Tuberal lateral hypothalamic (LHAt) neurons which innervate the cerebral cortex tend to cluster in the perifornical region, in the zona incerta, and along the medial edge of the cerebral peduncle, at levels roughly coextensive with the ventromedial hypothalamic nucleus. Most of these neurons project to the ipsilateral cortex; a small percentage innervate the contralateral cortex, but this varies among cortical terminal fields. The perifornical neurons are organized in a roughly topographic medial-to-lateral relationship with respect to their cortical terminal fields.

Field of Forel (FF) neurons, which project primarily to the frontal cortex of the ipsilateral hemisphere, are located just ventral to the medial edge of the medial lemniscus, at the level of the ventromedial basal thalamic nucleus. The more laterally placed neurons innervate the lateral frontal, insular and perirhinal cortex; the more medial neurons, around the mammillothalamic tract, innervate the medial frontopolar, prelimbic, infralimbic, and anterior cingulate cortex.

Posterior lateral hypothalamic (LHAp) neurons form a dense cluster spanning the lateral hypothalamus, from the cerebral peduncle to the posterior hypothalamic area at premammillary levels, and extending into the supramammillary nucleus and the adjacent ventral tegmental area. LHAp neurons innervate the entire cerebral cortex, predominantly on the ipsilateral side. Populations of LHAp neurons projecting to different cortical target areas show considerable spatial overlap, but computer plots of the centers of these populations demonstrate a strict topographic relationship with respect to the cerebral cortex.

Tuberomammillary (TMN) neurons form a sheet along the ventrolateral surface of the premammillary hypothalamus. About twice as many TMN neurons innervate the ipsilateral, as compared to the contralateral hemisphere; it is not known whether single neurons project to both hemispheres. No topographic organization of the TMN cortical projection is apparent.

Injections of different-colored fluorescent dyes into various cortical areas demonstrate that hypothalamic neurons in general have rather restricted cortical terminal fields. Only occasional neurons are found, primarily in LHAt, which are double labeled by injections into different cytoarchitectonic areas.

Anterograde tracing of fibers from LHAp, with the aid of the autoradiographic method, demonstrated two efferent pathways to cerebral cortex: a medial pathway runs through the medial forebrain bundle, traverses the diagonal band and medial septal nuclei, and enters the fornix and the cingulate bundle, from which it distributes to the hippocampal formation and to medial cortical fields, respectively. The lateral pathway runs through the lateral part of the medial forebrain bundle, then turns laterally through the substantia innominata to enter the external capsule, from which it distributes to lateral cortical fields. LHAp fibers in the hippocampus primar- ily innervate the outer part of the dentate granule cell layer; there is also a lighter projection to the CA2 and CA3a fields. In the neocortex, the densest LHAp innervation is in layer V and the deep part of layer VI, adjacent to the internal capsule. There is more sparse innervation also of layers I and 111. TMN fibers distribute in a similar, though much less dense, distribution.

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