Afferent and efferent components of the facial nerve in the bullfrog (Rana catesbeiana).

The afferent and efferent components of the facial nerve were traced within the brain stem of Rana catesbeiana, using three different neuroanatomical techniques. Primary afferent fibers could be traced to the spinal tract of trigeminal nerve and to fasciculus solitarius as far caudally as the first or second spinal segment, using silver degeneration methods. Cobalt filling of of the entire nerve showed the same distribution of afferent fibers, as well as the filling of the cells within the mesencephalic nucleus of trigeminal, indicating the origin of a proprioceptive component of the facial nerve. Cobalt iontophoresis and horseradish perioxidase experiments showed that the motor nucleus of the facial nerve was located just ventral to the fourth ventricle, and caudal to the motor nucleus of trigeminal. The distribution of afferent fibers to fasciculus solitarius and the spinal tract of trigeminal is similar in some respects to the distribution of afferent fibers from the trigeminal and vagal nerves in the bullfrog. The afferent fibers from the three cranial nerves are found as far caudally in the brain stem as the second spinal segment.     

Localization and Central Projections of Primary Afferent Neurons That Innervate the Temporomandibular Joint in Cats

Primary afferent neurons that innervate the temporomandibular joint (TMJ) in cats were labeled by injecting a 2-5% solution of wheatgerm agglutinin bound to horseradish peroxidase into the joint capsule and capsular tissues in 14 cats and processing the brain stem and trigeminal ganglia using the tetramethylbenzidine method described by Mesulam (1978). The perikarya of ganglion cells that innervate the TMJ ranged in diameter from 15 to 109 μm and were primarily located in the posterolateral portion of the trigeminal ganglion. The central processes of these neurons entered the brain stem in middle pons and were distributed to all portions of the sensory trigeminal nuclei. However, the majority of labeled fibers and greatest density of terminal labeling were observed in the dorsal part of the main sensory nucleus and the subnucleus oralis of the spinal trigeminal nucleus. Very few labeled fibers were observed in the spinal tract of the trigeminal nerve below the obex. However, evidence for axon terminals was consistently observed in laminae I, II, and III of the medullary dorsal horn. These findings concur with physiological evidence showing that information from the TMJ influences neurons in rostral (Kawamura et al, 1967) and in caudal (Broton et al, 1985) portions of the trigeminal sensory nuclei.     

Afferent projections of the trigeminal nerve in the goldfish,Carassius auratus

The horseradish peroxidase (HRP) histochemical technique was used to examine the peripheral distribution and afferent projections of the trigeminal nerve in the goldfish, Carassius auratus. Sensory fibers of the trigeminal nerve distribute over the head via four branches. The ophthalmic branch distributes fibers to the region above the eye and naris. The maxillary and mandibular branches innervate the regions of the upper and lower lip, respectively. A fourth branch of the trigeminal nerve was demonstrated to be present in the hyomandibular trunk. Upon entering the medulla the trigeminal afferent fibers divide into a rostromedially directed bundle and a caudally directed bundle. The rostromedially directed bundle terminates in the sensory trigeminal nucleus (STN) located within the rostral medulla. The majority of fibers turn caudally, forming the descending trigeminal tract. Fibers of the descending trigeminal tract terminate within three medullary nuclei: the nucleus of the descending trigeminal tract (NDTV), the spinal trigeminal nucleus (Spv), and the medial funicular nucleus (MFn). All projections, except for those to the MFn, are ipsilateral. Contralateral projections were observed at the level of the MFn following the labeling of the ophthalmic and maxillomandibular branches. All branches of the trigeminal nerve project to all four of the trigeminal medullary nuclei. Projections to the STN and MFn were found to be topographically organized such that the afferents of the ophthalmic branch project onto the ventral portion of these nuclei, while the afferents of the maxillo- and hyomandibular branches project to the dorsal portion of these nuclei. Cells of the mesencephalic trigeminal nucleus were retrogradely labeled following HRP application to the ophthalmic, maxillary, and mandibular branches of the trigeminal nerve. In addition to demonstrating the ascending mesencephalic trigeminal root fibers, HRP application to the above-mentioned branches also revealed descending mesencephalic trigeminal fibers. The descending mesencephalic trigeminal fibers course caudally medial to the branchiomeric motor column and terminate in the ventromedial portion of the MFn.     

Corpuscular bodies in the palate of the rat. 2. Innervation and central projection.

The source of innervation of the corpuscular bodies in the palate and the central projections of the afferent fibres of the entire palate was studied in rats by transganglionic transport of horseradish peroxidase conjugated to wheat germ agglutinin (WGA-HRP) and with substance P (SP) immunohistochemistry. WGA-HRP injected into the incisal papilla was taken up by the nerve fibres that terminated in the corpuscles. Retrogradely labelled neurons were observed in the trigeminal ganglion as well as anterogradely labelled terminals in the dorsolateral part of the spinal trigeminal nucleus and in the lateral part of the nucleus of the solitary tract. No labelling could be found in the geniculate ganglion, the facial nerve and the hypoglossal nucleus. Following WGA-HRP injection in the intermolar area and in the soft palate, labelling was only restricted to the trigeminal ganglion. The lamina propria of the entire palate and the corpuscle-enriched area of the incisal papilla and the soft palate were richly innervated by SP-containing fibres. Numerous SP-containing fibres were also observed in the nerve plexus at the base of the corpuscle. In addition, SP-positive neurons were identified in the trigeminal ganglion and SP-labelled terminals in the sensory trigeminal nuclear complex and in the solitary tract nucleus. On the basis of our morphological observations we conclude that the palatal corpuscular bodies are involved in taste perception which is of trigeminal origin.     

Primary projections of the trigeminal nerve in two species of sturgeon: Acipenser oxyrhynchus and Scaphirhynchus platorynchus

Horseradish peroxidase histochemical studies of afferent and efferent projections of the trigeminal nerve in two species of chondrostean fishes revealed medial, descending and ascending projections. Entering fibers of the trigeminal sensory root project medially to terminate in the medial trigeminal nucleus, located along the medial wall of the rostral medulla. Other entering sensory fibers turn caudally within the medulla, forming the trigeminal spinal tract, and terminate within the descending trigeminal nucleus. The descending trigeminal nucleus consists of dorsal (DTNd) and ventral (DTNv) components. Fibers of the trigeminal spinal tract descend through the lateral alar medulla and into the dorsolateral cervical spinal cord. Fibers exit the spinal tract throughout its length, projecting to the ventral descending trigeminal nucleus (DTNv) in the medulla and to the funicular nucleus at the obex. Retrograde transport of HRP through sensory root fibers also revealed an ascending bundle of fibers that constitutes the neurites of the mesencephalic trigeminal nucleus, cell bodies of which are located in the rostral optic tectum. Retrograde transport of HRP through motor root fibers labeled ipsilateral cells of the trigeminal motor nucleus, located in the rostral branchiomeric motor column.     

Somatostatin-immunoreactive fiber projections into the brain stem and the spinal cord of the rat

Summary By use of the PAP-immunohistochemical staining technique with serial sections, somatostatin-immunoreactive fiber projections into the brain stem and the spinal cord are described. These projections originate in the periventricular somatostatin-immunoreactive perikarya of the hypothalamus and form three main pathways: (1) along the stria medullaris thalami and the fasciculus retroflexus into the interpeduncular nucleus; (2) along the medial forebrain bundle into the mammillary body; and (3) via the periventricular gray and the bundle of Schütz into the midbrain tegmentum. Densely arranged immunoreactive fibers and/or basket-like fiber terminals are observed within the following afferent systems: somatic afferent systems (nucleus spinalis nervi trigemini, substantia gelatinosa dorsalis of the entire spinal cord), and visceral afferent systems (nucleus solitarius, regio intermediolateralis and substantia gelatinosa of the sacral spinal cord). These projections form terminals around the perikarya of the second afferent neuron. Perikarya of the third afferent neuron are influenced by somatostatin-immunoreactive projections into the auditory system (nucleus dorsalis lemnisci lateralis, nucleus corporis trapezoidei). Furthermore, a somatostatin-immunoreactive fiber projection is found in the ventral part of the medial accessory olivary nucleus, in nuclei of the limbic system (nucleus habenularis medialis, nuclei supramamillaris and mamillaris lateralis) and in the formatio reticularis (nucleus Darkschewitsch, nuclei tegmenti lateralis and centralis, nucleus parabrachialis lateralis, as well as individual perikarya of the reticular formation). Targets of these projections are interneurons within interlocking neuronal chains.Supported by the Deutsche Forschungsgemeinschaft (Grant Nr. Kr 569/3) and Stiftung Volkswagenwerk     

Central representation of dental structures in the kitten, including projections to the mesencephalic trigeminal nucleus

Horseradish peroxidase (HRP) was injected into either a single maxillary or a single mandibular primary (deciduous) cuspid tooth of 8- to 10-week-old kittens. The large apex of the primary cuspid allowed for some leakage of the HRP from the pulpal chamber to the periodontal ligament (PDL). Thus, the injection procedure resulted in the application of HRP to the PDL as well as to the pulpal tissues. The transganglionic transport of HRP resulted in discrete terminal fields within the spinal trigeminal nucleus (STN) and the main sensory nucleus (MSN). These projections were clearly somatotopically organized within the STN, but less so within MSN. Within pars oralis (PO) and pars interpolaris (PI), mandibular cuspid dental structures (MdCDS) were represented in a dorsal position relative to the maxillary cuspid dental structures (MxCDS), whereas within pars caudalis (PC) and the adjacent reticular formation the somatotopic representation was not dorsoventral, but rather mediolateral, with the MdCDS represented more medially than the MxCDS. Areas of overlap between MxCDS and MdCDS were found within MSN and to a lesser degree within the superficial laminae of PC. In addition, the fiber pathway leading to labeled somata in the mesencephalic trigeminal (Mes V) nucleus was clearly identified. The majority of the fibers traced to the Mes V nucleus exited the spinal trigeminal tract at the level of the transition from PO to the MSN and traversed the nuclear region in a position dorsal to and separate from the trigeminal motor tract. As in STN, fibers within the caudal Mes V tract appeared to be somatotopically organized, with the fibers from the MdCDS generally more dorsal than the ones from the MxCDS. Labeled fibers, some with terminal arbors, were also identified in close association with the trigeminal motor tract. The findings show a complex pattern of central representation in the immature feline central nervous system for deciduous dental structures.     

Central Representation of Dental Structures in the Kitten,Including Projections to the Mesencephalic Trigeminal Nucleus

Horseradish peroxidase (HRP) was injected into either a single maxillary or a single mandibular primary (deciduous) cuspid tooth of 8- to 10-week-old kittens. The large apex of the primary cuspid allowed for some leakage of the HRP from the pulpal chamber to the periodontal ligament (PDL). Thus, the injection procedure resulted in the application of HRP to the PDL as well as to the pulpal tissues. The transganglionic transport of HRP resulted in discrete terminal fields within the spinal trigeminal nucleus (STN) and the main sensory nucleus (MSN). These projections were clearly somatotopically organized within the STN, but less so within MSN. Within pars oralis (PO) and pars interpolaris (PI), mandibular cuspid dental structures (MdCDS) were represented in a dorsal position relative to the maxillary cuspid dental structures (MxCDS), whereas within pars caudalis (PC) and the adjacent reticular formation the somatotopic representation was not dorsoventral, but rather mediolateral, with the MdCDS represented more medially than the MxCDS. Areas of overlap between MxCDS and MdCDS were found within MSN and to a lesser degree within the superficial laminae of PC. In addition, the fiber pathway leading to labeled somata in the mesencephalic trigeminal (Mes V) nucleus was clearly identified. The majority of the fibers traced to the Mes V nucleus exited the spinal trigeminal tract at the level of the transition from PO to the MSN and traversed the nuclear region in a position dorsal to and separate from the trigeminal motor tract. As in STN, fibers within the caudal Mes V tract appeared to be somatotopically organized, with the fibers from the MdCDS generally more dorsal than the ones from the MxCDS. Labeled fibers, some with terminal arbors, were also identified in close association with the trigeminal motor tract. The findings show a complex pattern of central representation in the immature feline central nervous system for deciduous dental structures.     

Histochemical localization of galactose-containing glycoconjugates in sensory neurons and their processes in the central and peripheral nervous system of the rat

We studied the distribution of sugar residues in the oligosaccharide chains of complex carbohydrates in tissue sections of rat spinal cord, brainstem, and sensory ganglia using twelve lectin-horseradish peroxidase conjugates. Glycoconjugates containing terminal galactose residues were localized apparently in the Golgi apparatus in a population of predominantly small B-type neurons in spinal and trigeminal ganglia. Large A-type neurons rarely showed reactivity with galactose-binding lectins. A cells stained for glycoconjugates with N-glycosidically linked oligosaccharides and glycogen. The central and peripheral processes of the small neurons, mostly unmyelinated C fibers in sensory roots and spinal nerves, contained an abundance of glycoconjugates with terminal alpha-galactose residues. The central projections and terminals of small to medium-sized primary sensory neurons in the spinal and trigeminal ganglia were visualized in Lissauer's tract and the substantia gelatinosa in the spinal cord, and in the spinal trigeminal tract and the nucleus trigeminus in the lower medulla with lectins specific for terminal alpha-galactose residues. In addition, fibers of the solitary system and the area postrema were reactive with these lectins. The peripheral and central nervous system elements with affinity for galactopyranosyl-specific lectins correspond in distribution with neuroanatomical regions thought to be involved in the transmission and relay of somatic and visceral afferent inputs such as pain and temperature. Such specific localization of a glycosubstance to a distinct subpopulation of neurons and their peripheral and central processes suggests that the particular glycoconjugate may be of physiological significance.     

NO participate in the communication between the first‐ and second‐order neurons in the trigeminal sensory tract in the dog

Histochemical, immunocytochemical and radioassay study was performed to detect the occurrence of NOS‐immunoreactive primary trigeminal sensory somata in the trigeminal ganglion, including their fiber components. Spinal trigeminal tract and sensory trigeminal nuclei were studied using the same methods. It was found that more than 30% of all somata in the trigeminal ganglion are NOS immunoreactive. Corresponding fibers were detected in the spinal trigeminal tract. NOS immunoreactive fibers of three different categories could be followed to terminate in the sensory trigeminal nuclei. Data presented here confirm that trigeminal sensory system is richly endowed with NOS and that NO is used to communicate between the first and second‐order trigeminal sensory neurons. Acknowledgements: Supported by VEGA Grant no. 2/3217/23PS9, STAA Grant no. 51‐013002 and by NIH grants NS 32794 and NS 40386 to M.M.     

大鼠口面部躯体和上消化道内脏伤害性传入汇聚于三叉神经脊束间质核含CB神经元

三叉神经脊束间质核(interstitial nucleus of the spinal trigeminal tract,INV)为位于三叉神经脊束内的一些灰质团块,经三叉神经和舌咽及迷走神经接受口面部的三叉神经躯体传入与上消化道的内脏伤害性传入。INV内含有大量含calbinding D-28k(CB)神经元,但尚不清楚支配口面部的三叉神经躯体传入与支配上消化道的内脏伤害性传入是否汇聚于INV内含CB的神经元。本文应用跨节追踪法并结合CB和Fos免疫组织化学的激光共聚焦显微镜和电镜技术,研究了下牙槽神经(interior alveolarnerve．IAN)的初级传入和上消化道伤害性信息向INV内含CB神经元的汇聚。结果如下：(1)将生物素化的葡聚糖胺(biotinylated dextran amine,BDA)和甲醛分别注入IAN和上消化道后,BDA跨节标记的浓密初级传入纤维和末梢分布于同侧INV内,在其膨大部较为集中;大量的CB和Fos免疫反应阳性神经元分布于双侧INV内,并与BDA注射侧的BDA标记末梢区相重叠：共聚焦显微镜观察显示,约半数CB免疫反应阳性的神经元同时呈Fos阳性的双标记神经元(74／153),其中部分双标神经元与IAN末梢形成紧密接触状。(2)辣根过氧化物酶(horseradish peroxidase,HRP)注射到IAN后,HRP跨节标记的纤维和末梢的分布与BDA标记的分布相似;电镜下观察到,INV内有大量CB免疫反应阳性神经元的树突和少量胞体,以及HRP标记的传入末梢,其中一些HRP标记的轴突终末分别与CB免疫反应阳性树突和胞体形成非对称型轴-树或轴-体突触。结果提示口面部躯体初级传入信息和内脏伤害性信息汇聚于INV内含CB的神经元上,可能在躯体传入信息对内脏伤害性信息的调制和内脏心血管活动中发挥重要作用。     

Projections of the central cerebellar nuclei to the intralaminar thalamic nuclei in cats

Projections of the central cerebellar nuclei to the intralaminar thalamic nuclei were studied in cats with the use of light and electron microscopy. Almost all intralaminar nuclei were shown to obtain cerebello-thalamic projections. The entire complex of the central cerebellar nuclei serves as a source of such projections; yet, involvement of different nuclei is dissimilar. Destruction of the central and, especially, caudal regions of the fastigial nucleus evoked in the intralaminar thalamic nuclei degenerative changes in the nerve fibers (from swelling and development of varicosities up to total fragmentation). Pathological phenomena could be noticed in the most caudal regions of the above thalamic nuclear group, including the medial dorsal nucleus. Projections of the cerebellar interpositus nucleus were directed toward nearly the same regions of the intralaminar nuclei; degeneration was more intensive (covered thecentrum medianum) when posterior regions of the interpositus nucleus were destroyed. Destruction of the lateral cerebellar nucleus evoked a similar pattern of pathological changes, but degeneration was also observed in some structures of the ventral and anterior nuclear groups of the thalamus. Electron microscopic examination showed that degeneration of dark and light types developed in the fiber preterminals and terminals. It can be concluded that the central cerebellar nuclei project not only to the ventral complex of the thalamic nuclei, but also to the anterior, medial, and intralaminar nuclear groups (rostral and caudal portions).     

Afferent and efferent components of the facial nerve in a frog,Rana pipiens

Summary The seventh cranial nerve in Rana pipiens is a slender nerve with limited peripheral distribution. We investigated the afferent and efferent components of this nerve by labeling its major branch, the hyomandibular, with horseradish peroxidase. The efferent portion of the seventh nerve originates from a small cell group in the upper medulla which contains two subdivisions. Afferent fibers carried in nerve VII travel in the solitary tract and the dorsolateral funiculus. The solitary component consists of a small number of ascending fibers that reach the level of the trigeminal nucleus and a large descending component that terminates slightly caudal to the obex in the commissural nuclei of the solitary complex. Afferent fibers also descend in the dorsolateral funiculus; many of these fibers cross dorsal to the central canal in the lower medulla. Most of the fibers in the dorsolateral funiculus terminate in the ipsilateral and contralateral dorsal horns and in nuclei of the dorsal column. A few ipsilateral fibers reach lower thoracic levels of the spinal cord.     

Endocannabinoids, their effect on GABA uptake in globus pallidus and relevance to Parkinson's disease

Histochemical, immunocytochemical and radioassay study was performed to detect the occurrence of NOS-immunoreactive primary trigeminal sensory somata in the trigeminal ganglion, including their fiber components. Spinal trigeminal tract and sensory trigeminal nuclei were studied using the same methods. It was found that more than 30% of all somata in the trigeminal ganglion are NOS immunoreactive. Corresponding fibers were detected in the spinal trigeminal tract. NOS immunoreactive fibers of three different categories could be followed to terminate in the sensory trigeminal nuclei. Data presented here confirm that trigeminal sensory system is richly endowed with NOS and that NO is used to communicate between the first and second-order trigeminal sensory neurons.
Acknowledgements:   Supported by VEGA Grant no. 2/3217/23PS9, STAA Grant no. 51-013002 and by NIH grants NS 32794 and NS 40386 to M.M.     

Capsaicin and potassium evoked substance P release from the nucleus tractus solitarius and spinal trigeminal nucleus invitro

The nucleus tractus solitarius and the spinal trigeminal nucleus receive peripheral sensory input from substance P containing afferent nerves. This study demonstrates that $\text{in}$$\text{vitro}$ depolarization of these nuclei in tissue slices evokes a calcium-dependent efflux of substance P immunoreactivity. Capsaicin (33μM) also elicits substance P release from the nucleus tractus solitarius and spinal trigeminal nucleus but not from the hypothalamus. The occurrence of potassium-stimulated SP release from the two medullary nuclei fulfills one of the criteria for neurotransmitter status. The capsaicin data support the contention that this agent elicits release of substance P from nuclear regions receiving peripheral afferent information in substance P nerves independent of the particular sensory modality served but is ineffective in nonsensory areas.     

Morphology of electrophysiologically identified baroreceptor afferents and second order neurones in the brainstem of the cat

Baroreceptor afferent fibres and second order baroreceptor neurones were identified by their discharge pattern and were intracellularly injected with horseradish peroxidase. Three afferent fibres and three second order neurones were reconstructed by camera lucida drawings from serial sections of the brainstem. The afferent fibres were classified as A delta-fibres and had terminal arborizations with synaptic boutons in the dorsomedial region of the nuclei of the solitary tract (TS). The afferent fibres had additional collaterals with a medial projection to the commissural nucleus and in a direction lateral to the TS. The terminals of these collaterals could not be demonstrated. The second order neurones were located in the same dorsomedial region as the synaptic boutons of the afferent fibres. Neurones were small and spindle-shaped with two primary dendrites: one dendrite projected cranially along the medial border of the TS, and the second one projected caudally and medially into the commissural nucleus. The unmyalinated axons of these neurones could be traced over a distance of 1 mm. In only one neurone could an axon collateral be detected. The axons projected dorsally around the TS in a ventrolateral direction beyond the boundaries of the nuclei of the TS. The axon collateral projected in the medial direction into the commissural nucleus. In no case were axon terminals demonstrated.     

Distribution of trigeminothalamic and spinothalamic lamina I terminations in the cat

The distribution in the thalamus of terminal projections from lamina I neurons of the trigeminal, cervical, and lumbosacral dorsal horn was investigated with the anterograde tracer Phaseolus vulgaris leucoagglutinin (PHA-L) in the cat. Iontophoretic injections were guided by single- and multi-unit physiological recordings. The injections in particular cases were essentially restricted to lamina I, whereas in others they spread across laminae I–III or laminae I–V. The trigemino- and spinothalamic (TSTT) terminations were identified immunohistochemically. In all cases, regardless of the level of the injections, terminal fibers were consistently distributed in three main locations: the submedial nucleus; the ventral aspect of the basal ventral medial nucleus and ventral posterior nuclei; and, the dorsomedial aspect of the ventral posterior medial nucleus. The terminal fields in the submedial nucleus and the ventral aspect of the ventral posterior group were topographically organized. Terminations along the ventral aspect of the ventral posterior group extended posterolaterally into the caudal part of the posterior nucleus and anteromedially into the ventromedial part of the ventral lateral nucleus. In several cases with trigeminal lamina I injections, a terminal labeling patch was observed within the core of the ventral posterior medial nucleus. In cases with spinal lamina I injections, terminations were also consistently found in the lateral habenula, the parafascicular nucleus, and the nucleus reuniens. Isolated terminal fibers were occasionally seen in the zona incerta, the dorsomedial hypothalamus, and other locations. These anatomical observations extend prior studies of TSTT projections and identify lamina I projection targets that are important for nociceptive, thermoreceptive, and homeostatic processing in the cat. The findings are consistent with evidence from physiological (single-unit and antidromic mapping) and behavioral studies. The novel identification of spinal lamina I input to the lateral habenula could be significant for homeostatic behaviors.     

Afferent connections of the cat lateral vestibular nucleus

Location within the brain of HP-labeled neurons (origins of projections to the lateral vestibular nucleus) was investigated by iontophoretic injection of this enzyme. Bilateral projections to the following midbrain structures were revealed: the field of Forel, interstitial nuclei of Cajal, oculomotor nerve nuclei, and the red nucleus — to all parts of the lateral vestibular nucleus. Bilateral projections were also shown from more caudally located structures, viz. the superior, medial and inferior (descending) vestibular nuclei, Y groups of the vestibular nuclear complex, facial nucleus and hypoglossi, nucleus prepositus nervi hypoglossi and caudal nuclei of the trigeminal tract; ipsilateral projections from crus IIa of lobulus ansiformus of the cerebellar hemisphere; contralateral projections from the bulbar lateral reticular nucleus and Deiter's nucleus. A tonic organization pattern of afferent inputs from a number of brainstem formations to the dorsal and ventral lateral vestibular nucleus is revealed and trajectories of HP-labeled fiber systems projecting to Deiter's nucleus described.L. A. Orbeli Institute of Physiology, Academy of Sciences of the Armenian SSR, Erevan. Translated from Neirofiziologiya, Vol. 20, No. 4, pp. 494–503, July–August, 1988.     

Selective deafferentation of convergent inputs to trigeminal subnucleus caudalis: effects on calcitonin gene-related peptide distribution.

Electrophysiological studies (Sessle, 1987, 1991) suggest that trigeminal deafferenting injuries can cause an "unmasking" of existing but normally suppressed convergent inputs to the spinal trigeminal nucleus, including many that arise from the cervical spinal cord. However, the spatial arrangement of this projection has not been examined, particularly with reference to nociceptive components that might become involved in pathological changes leading to chronic pain. Therefore, the purpose of this study was to apply selective interruptions of the trigeminal and/or cervical primary afferent inputs to the spinal trigeminal subnucleus caudalis (Vc) in the cat, followed by (1) demonstration and quantification of axonal degeneration in the spinal trigeminal tract to determine the extent of trigeminal-cervical primary afferent overlap; and (2) an analysis of lesion-induced alterations in the distribution of calcitonin gene-related peptide immunoreactivity (CGRP-IR) in laminae I and II of Vc, since recent evidence strongly suggests that CGRP is involved in pathophysiological elevations of central nervous system neuronal excitability. Degenerating fibers were found throughout the spinal tract following a trigeminal rhizotomy or tractotomy, with the largest numbers adjacent to the rostral two-thirds of Vc, but with a significant number extending caudally to at least the level of C2. CGRP-IR was reduced or eliminated from the rostral one-third and periobex region of Vc, except for a dorsomedial zone that was minimally affected. Retention of CGRP-IR was greater at more caudal levels. Following a combined trigmeninal and cervical tractotomy, fiber degeneration was massive throughout the spinal tract, yet a population of small myelinated fibers persisted at 60 days after surgery. Concomitantly, CGRP-IR was profoundly reduced throughout Vc, except for a small dorsomedial zone of retention, which became more extensive caudally. A cervical tractotomy resulted in moderate numbers of degenerating fibers adjacent to the caudal one-third of Vc, and this number declined rostrally; however, degenerating fibers could be seen at the level of the obex. CGRP-IR was reduced in the dorsomedial and ventrolateral zones of Vc, particularly in its caudal one-third. Electron-microscopic analysis revealed a population of CGRP-IR boutons, most of which were of the simple axodendritic type with asymmetrical contacts. A few examples of axoaxonic contacts were observed. Loss of labeled boutons observed with the electron microscope was consistent with light-microscopic quantitative results. Those boutons that were retained were variable in size and displayed simple axodendritic contacts.(ABSTRACT TRUNCATED AT 400 WORDS)     

Chemoanatomical separation of vibrissal trigeminal primary afferents in the rat: a special central representation of supraorbital vibrissae

A choleratoxin B subunit transganglionic labelling technique and NPY immunohistochemistry were applied in the rat to achieve the chemoanatomical separation of myelinated vibrissal primary afferents, previously considered to be morphologically indistinguishable. Further, a special central representation pattern of supraorbital vibrissae was observed in the trigeminal brainstem nuclear complex: (1) Choleratoxin-labelled supraorbital vibrissal primary afferents terminated densely in their appropriate barrelettes in the trigeminal principal sensory nucleus, in the spinal oral subnucleus, in the caudal part of the spinal interpolar subnucleus, and in lamina IV of the caudal part of the spinal caudal subnucleus. (2) A second population of choleratoxin-labelled vibrissal afferents was also observed, terminating only in lamina III of the caudal subnucleus. (3) After peripheral nerve transection, NPY-immunoreactive supraorbital vibrissal primary afferent fibres appeared in their appropriate barrelettes in the principal sensory nucleus and the caudal part of the interpolar subnucleus, while in the caudal part of the caudal subnucleus NPY-immunoreactive vibrissal primary afferent terminals were found exclusively in the inner part of lamina II, extending over the outer part of lamina III. NPY-immunoreactive supraorbital vibrissal primary afferents were never found in the oral subnucleus. In contrast with the rules of the central representation of the mystacial (infraorbital) vibrissae, the multiple representation of the supraorbital vibrissae in the caudal subnucleus and the dense, barrelette-like terminal arborization of the choleratoxin-labelled supraorbital vibrissal primary afferents in the oral subnucleus apparently indicate an enhanced role of supraorbital vibrissae in reflexes that protect the eyes and the head from damage.