Your search keyword '"Proximal dendrite"' showing total 2 results

1. Variation of Input-Output Properties along the Somatodendritic Axis of Pyramidal Neurons

Author

Hysell V. Oviedo and Alex D. Reyes

Subjects

Cerebral Cortex, Proximal dendrite, Patch-Clamp Techniques, Time Factors, Chemistry, Pyramidal Cells, General Neuroscience, Action Potentials, Excitatory Postsynaptic Potentials, Dose-Response Relationship, Radiation, Dendrites, Behavioral/Systems/Cognitive, In Vitro Techniques, Stimulus (physiology), Synaptic Transmission, Electric Stimulation, Rats, Bursting, medicine.anatomical_structure, nervous system, Apical dendrite, medicine, Animals, Soma, Neuroscience

Abstract

The firing evoked by injection of simulated barrages of EPSCs into the proximal dendrite of layer 5 pyramidal neurons is greater than when comparable inputs are injected into the soma. This boosting is mediated by dendritic Na+conductances. However, the presence of other active conductances in the dendrites, some of which are nonuniformly distributed, suggests that the degree of boosting may differ along the somatodendritic axis. Here, we injected EPSC barrages at the soma and at the proximal, middle, and distal segments of the apical dendrite and measured boosting of subthreshold and suprathreshold responses. We found that although boosting was maintained throughout the apical dendrite, the degree of boosting changed nonmonotonically with distance from the soma. Boosting dipped in the middle dendritic segments as a result of the deactivation of the hyperpolarization-activated cation current,Ih, but increased in the distal dendrites as a result of the activation of Ca2+conductances. In the distal dendrites, EPSC barrages evoked repetitive bursts of action potentials, and the bursting pattern changed systematically with the magnitude of the input barrages. The quantitative changes in boosting along the somatodendritic axis suggest that inputs from different classes of presynaptic cells are weighted differently, depending on the location of the synaptic contacts. Moreover, the tight coupling between burst characteristics and stimulus parameters indicate that the distal dendrites can support a coding scheme that is different from that at sites closer to the soma, consistent with the notion of a separate dendritic integration site.

Published

2005

2. Morphology of HRP-injected spinocervical tract neurons: effect of dorsal rhizotomy

Author

LM Mendell, MJ Sedivec, and JJ Capowski

Subjects

Male, Proximal dendrite, Spinothalamic Tracts, medicine.medical_treatment, Central nervous system, Dendrite, Biology, medicine, Carnivora, Animals, Horseradish Peroxidase, Motor Neurons, Neurons, Computers, General Neuroscience, Rhizotomy, Dendrites, Articles, Anatomy, medicine.anatomical_structure, Nociception, Cats, Female, Soma, Neuron, Spinal Nerve Roots, Mathematics

Abstract

Twenty-five physiologically identified spinocervical tract (SCT) neurons in the sixth lumbar segment of the cat were filled with HRP by intracellular injection. All were reconstructed from sagittal sections using the camera lucida, and a subset (n = 18) was also reconstructed using a computer reconstruction system. Thirteen cells were in intact preparations, nine were in spared root preparations (L5, L6, S1, S2 cut; L7 spared), and three were in preparations with L5 through S2 cut. Analysis of the dendritic tree of these neurons revealed little change in gross morphology after partial deafferentation despite increased proportions sensitive to nociceptive input (Sedivec et al., 1983). The dendrites still largely respected the lamina II-III border, and relatively few dendrites were directed ventrally from the cell body, although the ratio of ventral to dorsal dendrites was greater than normal. The major change was an increase in surface area and volume caused by changes in diameter (but not length) of the dendrites. Larger- than-usual maximum branch order of individual dendritic trees of some cells was also observed after chronic deafferentation. Thus, SCT cells in deafferented segments do not undergo atrophy, but show, rather, limited signs of growth and the possibility of dendritic reorganization. We have also computed correlations between different parameters of these cells (cell body size, number and size of primary dendrites, total area and length of individual dendrites) and have found that, as in motoneurons, diameter of the primary dendrite measured 30 micron from the soma is significantly correlated with total dendritic surface area and length. SCT neurons tend to have more dendrites than spinal alpha-motoneurons, but total surface area is smaller for a given diameter of a proximal dendrite.

Published

1986