Cuneate nucleus

About: Cuneate nucleus is a research topic. Over the lifetime, 614 publications have been published within this topic receiving 24859 citations. The topic is also known as: cuneate nucleus of spinal cord.

Transganglionic gracile response following limb amputation in man.

Abstract: Gracile neuroaxonal dystrophy (NAD) is an distinctive morphological alteration of central projecting axon terminals of dorsal root ganglion neurons. Experimentally, lower limb amputation has been shown to accelerate the formation of gracile NAD, suggesting that the transganglionic response to peripheral axotomy may play a role in its development. To determine if a similar response occurs in the human sensory nervous system following peripheral nerve injury, we have performed postmortem histopathological examinations of the dorsal column nuclei of three patients (aged 15, 55, and 77 years old); all of whom had undergone accidental or therapeutic unilateral limb amputation (1 year, 38 years, and 1 year 8 months prior to death, respectively). In a 15-year-old man who underwent therapeutic leg amputation, the gracile nuclei on the transected side revealed reactive gliosis and many small axonal spheroids. The spheroids and fine neurites were immunolabelled with antibodies for growth-associated protein-43, ubiquitin and neuropeptide Y (NPY). Neither routine histological nor immunohistochemical methods demonstrated comparable changes in the contralateral gracile nucleus. In a 77-year-old man who underwent leg amputation, the gracile nucleus on the amputated side was gliotic and showed several NPY and ubiquitin-immunoreactive spheroids, which were not seen in the contralateral non-transected side. A 55-year-old man with a history of accidental arm amputation showed well-developed NAD in the cuneate nucleus only on the transected side. This study clearly demonstrates the occurrence of transganglionic response to limb amputation in human dorsal column nuclei. The extent of the regenerative and/or degenerative responses may vary depending on the age of the patient and the time interval following the peripheral axotomy.

Distribution of epidermal growth factor in central nervous system of adult rhesus monkey

Abstract: OBJECTIVE To investigate the distribution of epidermal growth factor (EGF) in the CNS of adult rhesus monkey. METHODS Frozen sections were incubated in specific polyclonal anti-EGF antibody by the immunohistochemical SP method. RESULTS The EGF immunopositive reaction was observed in the plasma of neurons. The neurons with strong positive immuno-reaction signals were detected in cerebral cortex, cerebellar Purkinje cells, cerebellar nuclei, pyramidal neurons of hippocampus, caudate nucleus, lentiform nucleus, claustrum, nuclei in diencephalons, substantia nigra, cranial nerve nuclei, reticular formation in brain stem, pontine nuclei, red nucleus, superior and inferior olivary nucleus, gracile nucleus, cuneate nucleus, also the ventral horn, lateral horn, dorsal horn and the central gray matter in spinal cord. Furthermore, a few EGF immunopositive glias and fibres were observed in some white matter of central nervous system. CONCLUSION EGF immunoreactive material was extensively distributed in the CNS of the adult rhesus monkey. The results suggest that EGF may be concerned with various types of neurons and other cells.

A functional spiking neuronal network for tactile sensing pathway to process edge orientation.

Abstract: To obtain deeper insights into the tactile processing pathway from a population-level point of view, we have modeled three stages of the tactile pathway from the periphery to the cortex in response to indentation and scanned edge stimuli at different orientations. Three stages in the tactile pathway are, (1) the first-order neurons which innervate the cutaneous mechanoreceptors, (2) the cuneate nucleus in the midbrain and (3) the cortical neurons of the somatosensory area. In the proposed network, the first layer mimics the spiking patterns generated by the primary afferents. These afferents have complex skin receptive fields. In the second layer, the role of lateral inhibition on projection neurons in the cuneate nucleus is investigated. The third layer acts as a biomimetic decoder consisting of pyramidal and cortical interneurons that correspond to heterogeneous receptive fields with excitatory and inhibitory sub-regions on the skin. In this way, the activity of pyramidal neurons is tuned to the specific edge orientations. By modifying afferent receptive field size, it is observed that the larger receptive fields convey more information about edge orientation in the first spikes of cortical neurons when edge orientation stimuli move across the patch of skin. In addition, the proposed spiking neural model can detect edge orientation at any location on the simulated mechanoreceptor grid with high accuracy. The results of this research advance our knowledge about tactile information processing and can be employed in prosthetic and bio-robotic applications.