Summary
The organization of the lateral reticular nucleus (LRN) of the rat was investigated by using the Golgi technique. Golgi-Cox preparations revealed neurons with shapes similar to those observed in Nissl-stained preparations. Fusiform cells possess rectilinear dendrites with secondary dendrites which are longer than the parent stem. The remaining cell types have short dendrites which branch for three or four generations and follow a tortuous course. These two types of neurons are similar to the isodendritic and allodendritic neurons which have been reported in the reticular formation. The neurons throughout the LRN form cell clusters. In Golgi preparations five to ten cells are seen in each cluster but counterstaining reveals that the clusters are made up of many more cells than the Golgi preparations suggest. Many cells lie in close apposition and the dendrites of the cells in each cluster intertwine to form dendritic plexuses. Dendritic input from both neighbouring and distant cell clusters also contributes to the plexus formations within each cell cluster. Under high magnification, the dendrites show irregularities in their contours, including warty excrescenses, bumps and an array of spines, some of which are pedunculated. The appendages are confined primarily to distal portions of the dendrites, with few spines observed on the somata and proximal dendrites. Varicosed dendrites are also in common occurrence throughout the nucleus.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Andrezik JA, King JS (1977) The lateral reticular nucleus of the opossum (Didelphis virginiana). I. Conformation, cytology and synaptology. J Comp Neurol 174:119–150
Brodal A (1943) The cerebellar connections of the nucleus reticularis lateralis (nucleus funiculi lateralis) in rabbit and cat. Experimental investigations. Acta Psychiat Neurol Scand 18:171–233
Brodal P (1975) Demonstration of a somatotopically organized projection onto the paramedian lobule and the anterior lobe from the lateral reticular nucleus: An experimental study with the horseradish peroxidase method. Brain Res 95:221–239
Bruckmoser P, Hepp-Reymond M-C, Wiesendanger M (1970a) Cortical influence on single neurons of the lateral reticular nucleus of the cat. Exp Neurol 26:239–252
Bruckmoser P, Hepp-Reymond M-C, Wiesendanger M (1970b) Effects of peripheral, rubral, and fastigial stimulation on neurons of the lateral reticular nucleus of the cat. Exp Neurol 27:388–398
Colonnier M (1964) The tangential organization of the visual cortex. J Anat (Lond) 98:327–344
Courville J (1966) Rubrobulbar fibres to the facial nucleus and the lateral reticular nucleus (nucleus of the lateral funiculus). An experimental study in the cat with silver impregnation methods. Brain Res 1:317–337
Dietrichs E, Walberg F (1979) The cerebellar projection from the lateral reticular nucleus as studied with retrograde transport of horseradish peroxidase. Anat Embryol 155:273–290
Edwards SB (1972) The ascending and descending projections of the red nucleus in the cat: An experimental study using an autoradiographic tracing method. Brain Res 48:45–63
Flumerfelt BA, Kapogianis EM, Hrycyshyn AW (1982) An ultrastructural study of the lateral reticular nucleus in the rat. Anat Embryol (submitted)
Grundfest H, Carter WB (1954) Afferent relations of inferior olivary nucleus. I. Electrophysiological demonstration of dorsal spino-olivary tract in cat. J Neurophysiol 17:72–91
Hrycyshyn AW, Flumerfelt BA (1981) Cytology and synaptology of the lateral reticular nucleus of the cat. J Comp Neurol 197:459–475
Kapogianis EM, Flumerfelt BA, Hrycyshyn AW (1982) Cytoarchitecture and cytology of the lateral reticular nucleus in the rat. Anat Embryol (submitted)
Kawamura K, Brodal A, Hoddevik G (1974) The projection of the superior colliculus onto the reticular formation of the brain stem. An experimental anatomical study in the cat. Exp Brain Res 19:1–19
Kitai ST, Hatada H, Casey W (1972) Intracellular analysis of antidromically and synaptically activated lateral reticular neurons. Brain Res 43:629–634
Kitai ST, Kennedy DT, DeFrance JF, Hatada K (1974) Electrophysiological properties of lateral reticular nucleus cells: I. Antidromic activation. Exp Brain Res 21:403–418
Künzle H (1973) The topographic organization of spinal afferents to the lateral reticular nucleus of the cat. J Comp Neurol 149:103–116
Künzle H, Wiesendanger M (1974) Pyramidal connections to the lateral reticular nucleus in the cat: a degeneration study. Acta Anat 88:105–114
Ladpli R, Brodal A (1968) Experimental studies of commissural and reticular formation projections from the vestibular nuclei in the cat. Brain Res 8:65–96
Leontovich TA, Zhukova GP (1963) The specificity of the neuronal structure and topography of the reticular formation in the brain and spinal cord of carnivora. J Comp Neurol 121:347–381
Mannen H (1966) Contribution to the morphological study of dendritic arborization in the brain stem. In: Tokizane T, Schade JP (eds) Correlative neurosciences Part A: Fundamental mechanisms. Prog Brain Res, Vol 21 A, pp 131–162
Martin GF, Andrezik J, Crutcher K, Linauts M, Panneton M (1977) The lateral reticular nucleus of the opossum. (Didelphis virginiana) II. Connections. J Comp Neurol 174:151–186
Oscarsson O (1973) Functional organization of spinocerebellar paths. In: Iggo A (ed) Handbook of sensory physiology. Vol 2. Somatosensory systems. Springer-Verlag, New York, pp 339–380
Peters A, Palay SL, Webster H de F (1976) The fine structure of the nervous system: The neurons and supporting cells. 2nd ed, WB Saunders Co, Philadelphia
Ramón-Moliner E (1968) The morphology of dendrites. In: Bovine GF (ed) Structure and function of the nervous tissue. Vol 1, Academic Press, New York, pp 205–267
Ramón-Moliner E (1970) The Golgi-Cox technique. In: Nauta WJH, Ebbesson SOE (eds) Contemporary research methods in neuroanatomy, Springer-Verlag, New York, pp 32–55
Ramón-Moliner E, Nauta WJH (1966) The isodendritic core of the brain stem. J Comp Neurol 126:311–336
Taber E (1961) The cytoarchitecture of the brain stem of the cat. I. Brain stem nuclei of cat. J Comp Neurol 116:27–69
Valverde F (1961) Reticular formation of the pons and medulla oblongata. A Golgi study. J Comp Neurol 116:71–99
Valverde F (1970) The Golgi method. A tool for comparative structural analyses. In: Nauta WJH, Ebbesson SOE (eds) Contemporary research methods in neuroanatomy, Springer-Verlag, New York, pp 12–31
Walberg F (1952) The lateral reticular nucleus of the medulla oblongata in mammals. A comparative-anatomical study. J Comp Neurol 96:283–344
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Kapogianis, E.M., Flumerfelt, B.A. & Hrycyshyn, A.W. A Golgi study of the lateral reticular nucleus in the rat. Anat Embryol 164, 243–256 (1982). https://doi.org/10.1007/BF00318508
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00318508