Summary
The numbers, laminar position, perikaryal and dendritic morphology, and axonal trajectories of postsynaptic cells ascending the dorsal column have been studied after implantation of HRP pellets in either the dorsal columns or dorsal column nuclei after destruction of the dorsolateral fascicle on one side. Observations made throughout the spinal cord gave estimated figures of 800–1000 and 1700–2000 cells in lumbosacral and brachial enlargements respectively on the side of the implant. The commonest type (C), centred on lamina IV, had dendritic trees greatly extended rostrocaudally and restricted mediolaterally in the lateral dorsal horn, the extension and restriction diminishing for more medial cells. Type B cells differed dramatically, with large straight dendrites in the transverse plane and large perikarya in medial lamina V. Type A cells, distinguished by both rostrocaudal and mediolateral restriction in dendritic trees, were only found medially in laminae III and IV. Outside the enlargements, in high lumbar and thoracic cord, many fewer cells were found, corresponding to Type C but with dendrites much elongated rostrocaudally and little mediolateral variation. Many small fusiform cells were found in medial lamina VI in the upper cervical cord, distinct from any of the above. A few cells were found in the cord enlargements in lamina VII of the contralateral ventral horn, with axons crossing through the ventral commissure. The axons of all cell types were tortuous, and some entered the dorsolateral fascicle before crossing into the dorsal column: collaterals were often seen but could not be followed far. A complementary study of cells with axons ascending in the dorsolateral fascicle is reported in the following paper.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Angaut-Petit D (1975a) The dorsal column system. I. Existence of long ascending postsynaptic fibres in the cat's fasciculus gracilis. Exp Brain Res 22: 457–470
Angaut-Petit D (1975b) The dorsal column system. II. Functional properties and bulbar relay of postsynaptic fibres of the cat's fasciculus gracilis. Exp Brain Res 22: 471–493
Bannatyne BA, Maxwell DJ, Brown AG (1987) Fine structure of synapses associated with characterized postsynaptic dorsal column neurons in the cat. Neuroscience 23: 597–612
Bennett GJ, Nishikawa N, Lu G-W, Hoffert MJ, Dubner R (1983) The cells of origin of the dorsal column postsynaptic projection in the lumbosacral enlargements of cats and monkeys. Somatosens Res 1: 131–149
Bennett GJ, Nishikawa N, Lu G-W, Hoffert MJ, Dubner R (1984) The morphology of dorsal column postsynaptic spinomedullary neurons in the cat. J Comp Neurol 224: 568–578
Brown AG (1973) Ascending and long spinal pathways: dorsal columns, spinocervical tract and spinothalamic tract. In: Iggo A (ed) Somatosensory system. Handbook of sensory physiology, Vol II. Springer, Berlin Heidelberg New York, pp 315–338
Brown AG (1981) Organization in the spinal cord: the anatomy and physiology of identified neurones. Springer, Berlin Heidelberg New York
Brown AG, Fyffe REW, Noble R, Rose PK, Snow PJ (1980a) The density, distribution and topographical organization of spinocervical tract neurones in the cat. J Physiol (Lond) 300: 409–428
Brown AG, Rose PK, Snow PJ (1980b) Dendritic trees and cutaneous receptive fields of adjacent spinocervical tract neurones in the cat. J Physiol (Lond) 300: 429–440
Brown AG, Fyffe REW (1981) Form and function of neurones with axons ascending the dorsal columns in cat. J Physiol (Lond) 321: 31–47
Brown AG, Noble R, Riddell JS (1986) Relations between spinocervical and post-synaptic dorsal column neurones in the cat. J Physiol (Lond) 381: 333–349
Brown PB, Fuchs JL (1975) Somatotopic representation of hindlimb skin in cat dorsal horn. J Neurophysiol 38: 1–9
Dart AM, Gordon G (1970) Excitatory and inhibitory afferent inputs to the dorsal column nuclei not involving the dorsal column. J Physiol (Lond) 211: 36–37P
Dart AM, Gordon G (1973) Some properties of the spinal connections of the cat's dorsal column nuclei which do not involve the dorsal columns. Brain Res 58: 61–68
Enevoldson TP, Gordon G (1984) Spinally projecting neurons in the dorsal column nuclei: distribution, dendritic trees and axonal projections: a retrograde HRP study in the cat. Exp Brain Res 54: 538–550
Enevoldson TP, Gordon G (1989) Spinocervical neurons and dorsal horn neurons projecting to the dorsal column nuclei through the dorsolateral fascicle: a retrograde HRP study in the cat. Exp Brain Res 75: 621–630
Enevoldson TP, Gordon G, Sanders DJ (1984) The use of retrograde transport of horseradish peroxidase for studying the dendritic trees and axonal courses of particular groups of tract cells in the spinal cord: a modified procedure and its evaluation in the cat and rat. Exp Brain Res 54: 529–537
English AW., Tigges J, Lennard PR (1985) Anatomical organization of long ascending propriospinal neurons in the cat spinal cord. J Comp Neurol 240: 349–358
Gordon G, Grant G (1972) Afferents to the dorsal column nuclei from the dorsolateral funiculus of the spinal cord. Acta Physiol Scand 84: 30–31A
Gordon G, Grant G (1982) Dorsolateral spinal afferents to some medullary sensory nuclei: an anatomical study. Exp Brain Res 46: 12–23
Koerber HR (1980) Somatotopic organization of cat brachial spinal cord. Exp Neurol 69: 481–492
Lu G-W, Bennett GJ, Nishikawa N, Dubner R (1985) Spinal neurons with branched axons, traveling in both the dorsal and dorsolateral funiculi. Exp Neurol 87: 571–577
Maxwell DJ, Fyffe REW, Brown AG (1982) Fine structure of spinocervical tract neurones and the synaptic boutons in contact with them. Brain Res 233: 394–399
Mesulam M-M (1978) Tetramethyl benzidine for horseradish peroxidase neurochemistry: a non-carcinogenic blue reaction product with superior sensitivity for visualizing neural afferents and efferents. J Histochem Cytochem 26: 106–117
Petit D (1972) Post-synaptic fibres in the dorsal columns and their relay in the nucleus gracilis. Brain Res 48: 380–384
Pompeiano O, Brodal A (1957) Spinovestibular fibres in the cat: an experimental study. J Comp Neurol 108: 353–381
Rexed B (1954) A cytoarchitectonic atlas of the spinal cord of the cat. J Comp Neurol 100: 297–379
Rossi GF, Brodal A (1956) Spinal afferents to the trigeminal sensory nuclei and the nucleus of the solitary tract. Confin Neurol 16: 321–332
Rossi GF, Brodal A (1957) Terminal distribution of spinoreticular fibres in the cat. Arch Neurol Psychiat (Chicago) 78: 439–453
Rustioni A (1973) Non-primary afferents to the gracile nucleus from the lumbar cord of the cat. Brain Res 51: 81–95
Rustioni A (1974) Non-primary afferents to the cuneate nucleus from the brachial cord of the cat. Brain Res 75: 247–259
Rustioni A, Kaufman AB (1977) Identification of cells of origin of non-primary afferents to the dorsal column nuclei of the cat. Exp Brain Res 27: 1–14
Rustioni A, Molenaar I (1975) Dorsal column nuclei afferents in the lateral funiculus of the cat: distribution pattern and absence of sprouting after chronic deafferentation. Exp Brain Res 23: 1–12
Uddenberg N (1968) Functional organization of long, secondorder afferents in the dorsal funiculus. Exp Brain Res 4: 377–382
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Enevoldson, T.P., Gordon, G. Postsynaptic dorsal column neurons in the cat: a study with retrograde transport of horseradish peroxidase. Exp Brain Res 75, 611–620 (1989). https://doi.org/10.1007/BF00249912
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00249912