Your search keyword '"Spinomesencephalic tract"' showing total 57 results

1. Spinomesencephalic Tract

Author

Yezierski, Robert P., Gebhart, Gerald F., editor, and Schmidt, Robert F., editor

Published

2013

2. Spinomesencephalic Tract

Author

Yezierski, Robert P., Schmidt, Robert F., editor, and Willis, William D., editor

Published

2007

3. Segmental and laminar organization of the spinothalamic neurons in cat

Author

Esther Marije Klop, Leonora J. Mouton, Gert Holstege, Faculteit Medische Wetenschappen/UMCG, and SMART Movements (SMART)

Subjects

Lamina, Spinothalamic tract, Spinothalamic Tracts, CERVICAL SPINAL-CORD, Thalamus, Cell Count, Biology, Periaqueductal gray, PERIAQUEDUCTAL GRAY, Laminar organization, thalamus, I NEURONS, Neural Pathways, medicine, Animals, Spinomesencephalic tract, DORSAL COLUMN NUCLEI, SOMATIC STIMULI, RETROGRADE TRANSPORT, lumbar, Neurons, Brain Mapping, General Neuroscience, cervical, spinal cord, HORSERADISH-PEROXIDASE, Anatomy, sacral, TRACT NEURONS, Spinal cord, medicine.anatomical_structure, nervous system, Dorsal column nuclei, Cats, SPINOMESENCEPHALIC TRACT, MECHANICAL STIMULATION, Female, Neuroscience

Abstract

The spinothalamic tract (STT), well known for its role in the relay of information about noxe, temperature, and crude touch, is usually associated with projections from lamina 1, but spinothalamic neurons in other laminae have also been reported. In cat, no complete overview exists of the precise location and number of spinal cells that project to the thalamus In the present study the laminar distribution of retrogradely labeled cells in all spinal segments (C1-Coc2) was investigated after large WGA-HRP injections in the thalamus. The results show that this distribution of STT cells differed greatly between the different spinal segments. Quantitative analysis showed that there exist at least five separate clusters of spinothalamic neurons. Lamina I neurons in cluster A and lamina V neurons in cluster B are mainly found contralaterally throughout the length of the spinal cord. Cluster C neurons are located bilaterally in the ventrolateral part of laminae VI-VII and lamina VIII of the C1-C3 spinal cord. Cluster D neurons were found contralaterally in lamina VI in the C1-C2 segments, and cluster E neurons were located mainly contralaterally in the medial part of laminae VI-VII and lamina VIII of the lumbosacral cord. Most spinothalamic neurons are not located in the enlargements and most spinothalamic neurons are not located in lamina 1, as suggested by several other authors. The location of the spinothalamic neurons shows remarkable similarities, but also differences, with the location of spino-periaqueductal gray neurons.

Published

2005

4. C1–C3 spinal cord projections to periaqueductal gray and thalamus: A quantitative retrograde tracing study in cat

Author

Esther Marije Klop, Leonora J. Mouton, Gert Holstege, and SMART Movements (SMART)

Subjects

Spinothalamic tract, Spinothalamic Tracts, LAMINA-I, Thalamus, Central nervous system, Wheat Germ Agglutinin-Horseradish Peroxidase Conjugate, Biology, Periaqueductal gray, Anterior Horn Cells, Neural Pathways, spinomesencephalic, medicine, Animals, Periaqueductal Gray, nociception, Spinomesencephalic tract, NEURONS, Molecular Biology, SPINOTHALAMIC TRACT, ORIGIN, ventral horn, General Neuroscience, Nociceptors, HORSERADISH-PEROXIDASE, Anatomy, lamina VII, Spinal cord, Retrograde tracing, COLLATERALS, medicine.anatomical_structure, Nociception, nervous system, lamina VI, CELLS, SPINOMESENCEPHALIC TRACT, Cats, Cervical Vertebrae, RAT, Female, Neurology (clinical), LATERAL THALAMUS, Developmental Biology

Abstract

By far, the strongest spinal cord projections to periaqueductal gray (PAG) and thalamus originate from the upper three cervical segments, but their precise organization and function are not known. In the present study in cat, tracer injections in PAG or in thalamus resulted in more than 2400 labeled cells, mainly contralaterally, in the first three cervical segments (C1-C3), in a 1:4 series of sections, excluding cells in the dorsal column and lateral cervical nuclei. These cells represent about 30% of all neurons in the entire spinal cord projecting to PAG and about 45% of all spinothalamic neurons. About half of the C1-C3 PAG and C1-C3 thalamic neurons were clustered laterally in the ventral horn (C1-3v1), bilaterally, with a slight ipsilateral preponderance. The highest numbers Of C1-3v1-PAG and C1-3v1-thalamic cells were found in C1, with the greatest density rostrocaudal ly in the middle part of C 1. A concept is put forward that C1-3v1 cells relay information from all levels of the cord to PAG and/or thalamus, although the processing of specific information from upper neck muscles and tendons or facet joints might also play a role. (c) 2005 Elsevier B.V. All rights reserved.

Published

2005

5. How mainly spinothalamic tract cells are there? A retrograde tracing study in cat

Author

Leonora J. Mouton, Esther Marije Klop, Gert Holstege, and SMART Movements (SMART)

Subjects

Spinothalamic tract, Spinothalamic Tracts, Time Factors, Darkschewitsch, Central nervous system, Thalamus, Wheat Germ Agglutinin-Horseradish Peroxidase Conjugate, Biology, Somatosensory system, somatosensory, thalamus, TERMINATION, medicine, Animals, pain, Spinomesencephalic tract, nociception, NEURONS, ORIGIN, General Neuroscience, spinal cord, Anatomy, Spinal cord, Retrograde tracing, Nociception, medicine.anatomical_structure, Cats, SPINOMESENCEPHALIC TRACT, RAT, SPINAL-CORD

Abstract

The spinothalamic tract, well known for its role in nociception, is the most frequently studied ascending pathway originating from the spinal cord. It is known that spinothalamic neurons are located in all segments of the spinal cord, but in most mammals the total number of spinothalamic neurons is not known. In three cats, after large wheat germ agglutinin-conjugated horseradish peroxidase injections involving all parts (one case) or almost all parts of the thalamus (two cases), the number of retrogradely labeled profiles was counted in a 1:4 series of sections of all spinal segments from C I to Coc2. After applying the correction factor of Abercrombie (Anat. Rec. 94 (1946) 239), it appears that a total of 12,000 cells in the spinal cord project to the thalamus. (C) 2004 Elsevier Ireland Ltd. All rights reserved.

Published

2004

6. Lamina I-periaqueductal gray (PAG) projections represent only a limited part of the total spinal and caudal medullary input to the PAG in the cat

Subjects

MICTURITION, LUMBOSACRAL CORD, marginal layer, ELECTRICAL-STIMULATION, AFFERENT-PROJECTIONS, ORGANIZATION, BRAIN-STEM, LACTATING RATS, MESENCEPHALON, spinomesencephalic, SPINOMESENCEPHALIC TRACT, trigeminal, nociception, nucleus caudalis, NEURONS

Abstract

The periaqueductal gray is well known for its involvement in nociception control, but it also plays an important role in the emotional motor system. To accomplish these functions the periaqueductal gray receives input from the limbic system and from the caudal brainstem and spinal cord. Earlier studies gave the impression that the majority of the periaqueductal gray projecting cells in caudal brainstem and spinal cord are located in the contralateral lamina I, which is involved in nociception. The present study in the cat, however, demonstrates that of all periaqueductal gray projecting neurons in the contralateral caudal medulla less than 7% was located in lamina I. Of the spinal periaqueductal gray projecting neurons less than 29% was located in lamina I. However, within the spinal cord large segmental differences exist: in few segments of the enlargements the lamina I-periaqueductal gray projecting neurons represent a majority. In conclusion, although the lamina I-periaqueductal gray projection is a very important nociceptive pathway, it constitutes only a limited part of the total projection from the caudal medulla and spinal cord to the periaqueductal gray. These results suggest that a targe portion of the medullo- and spino-periaqueductal gray pathways conveys information other than nociception. (C) 2001 Elsevier Science Inc.

Published

2001

7. Segmental and laminar organization of the spinal neurons projecting to the periaqueductal gray (PAG) in the cat suggests the existence of at least five separate clusters of spino-PAG neurons

Author

Leonora J. Mouton, Gert Holstege, Faculteit Medische Wetenschappen/UMCG, and SMART Movements (SMART)

Subjects

mating behavior, AFFERENT-PROJECTIONS, Biology, Periaqueductal gray, REGION, Midbrain, LACTATING RATS, Laminar organization, MIDBRAIN, FEMALE RATS, medicine, spinomesencephalic, TRANSGANGLIONIC TRANSPORT, Spinomesencephalic tract, nociception, micturition, LUMBOSACRAL CORD, General Neuroscience, HORSERADISH-PEROXIDASE, Anatomy, Spinal cord, Retrograde tracing, medicine.anatomical_structure, Nociception, nervous system, SPINOMESENCEPHALIC TRACT, LORDOSIS REFLEX, Tectum, Neuroscience

Abstract

The present retrograde tracing study in the cat describes the spinal cord projections to the periaqueductal gray (PAC), taking into account different regions of the PAG and all spinal segments. Results show that injecting different parts of the PAC leads to different laminar and segmental distributions of labeled spinal neurons. The impression was gained that at least five separate clusters of spinal neurons exist. Cluster I neurons are found in laminae I and V throughout the length of the cord and are probably involved in relaying nociceptive information to the PAG. Cluster II neurons lie in the ventrolateral part of laminae VI-VII of the C1-C4 spinal cord and were labeled by injecting the ventrolateral or lateral part of the rostrocaudal PAG or the deep tectum. Cluster III neurons are located in lamina X of the thoracic and upper lumbar cord and seem to target the PAG and the deep tectum. Cluster IV neurons are located in the medial part of laminae VI-VII of the lumbosacral cord and seem to project predominantly to the lateral and ventrolateral caudal PAC. These neurons may play a role in conveying tactile stimuli to the PAG during mating behavior. Neurons of cluster V are located in the lateral part of lamina I of L6-S2 and in laminae V-VII and X of S1-S3. They are labeled only after injections into the central portion of the lateral and ventrolateral caudal PAG and probably relay information concerning micturition and mating behavior. (C) 2000 Wiley-Liss, Inc.

Published

2000

8. Indications for coupling between feline spinocervical tract neurones and midlumbar interneurones

Author

Elzbieta Jankowska and Laiche Djouhri

Subjects

Neurons, Spinothalamic tract, General Neuroscience, Excitatory Postsynaptic Potentials, Anatomy, Biology, Inhibitory postsynaptic potential, Spinal cord, Electric Stimulation, Antidromic, medicine.anatomical_structure, Spinal Cord, nervous system, Interneurons, Postsynaptic potential, Cats, Reflex, Excitatory postsynaptic potential, medicine, Animals, Spinomesencephalic tract, Neuroscience

Abstract

The possibility of collateral segmental actions of spinocervical tract (SCT) neurones upon interneurones with input from cutaneous and group II muscle afferents was investigated in deeply anaesthetized cats. To this end, intracellular and/or extracellular recordings were made from 35 dorsal horn and 15 intermediate zone interneurones in midlumbar segments of the spinal cord and effects of stimulation of the ipsilateral dorso-lateral funiculus (DLF) at C3 and C1 levels, i.e. below and above the lateral cervical nucleus where axons of SCT cells terminate, were compared. The stimuli applied at the C3 segment were within the range of stimuli (50-100 microA) required for antidromic activation of SCT neurones in the same experiment. Those applied at the C segment (200-500 microA) were at least 3 times stronger than C3 stimuli. Under the same experimental conditions, long ascending and descending tract neurones (dorsal spino-cerebellar and rubro-spinal tract neurones) with axons in the DLF were activated at similar thresholds from the C and C3 segments. Intracellular recordings were made from 29 interneurones of which 19 (65%) were dorsal horn and 10 (35%) were intermediate zone interneurones. Excitatory postsynaptic potentials (EPSPs) evoked by single stimuli applied at the C3 segment, but not the C segment, were found in 14 (48%) of those interneurones; their latencies (3.0-5.7 ms) and frequency following with only minimal temporal facilitation were as required for potentials being evoked monosynaptically by the fastest conducting SCT neurones. Extracellular recordings were made from 30 interneurones (24 dorsal horn and 6 intermediate zone interneurones), and in these neurones spike potentials induced from the C3, but not from the C segment, were evoked only by short trains of stimuli. However, their latencies from the first effective stimulus (4.3-5.4 ms) were compatible with mono- or oligosynaptically mediated collateral actions of SCT neurones. They were found in 10 (33%) of the 30 investigated interneurones. Similar effects of C3 stimuli were found in similar proportions of dorsal horn interneurones and intermediate zone interneurones. Indications were also found for synaptic actions evoked by C3 stimuli that could not be attributed to direct collateral actions of SCT neurones. In some intracellularly recorded dorsal horn interneurones, short-latency EPSPs were evoked from the C3 segment by the 2nd or 3rd stimulus in the train, but not by single stimuli. In other dorsal horn and intermediate zone interneurones, inhibitory postsynaptic potentials (IPSPs) were evoked from the C3 segment at minimal latencies (2.7-3.2 ms), which might be too short to allow their mediation via SCT neurones. We conclude that SCT neurones might be used to forward information from muscle group II and cutaneous afferents not only to neurones in the lateral cervical nucleus and via them to thalamus and cerebral cortex but also to interneurones in spinal reflex pathways. Thereby reflex actions evoked from group II and cutaneous afferents might be co-ordinated with responses mediated by supraspinal neurones. We conclude also that dorsal horn and intermediate zone mid-lumbar interneurones might contribute to the previously reported di-and poly-synaptic excitation or inhibition of postsynaptic dorsal column (PSDC), spinothalamic tract (STT) and spinomesencephalic tract (SMT) neurones by collateral actions of SCT cells. Thereby these interneurones might contribute to the co-ordination of responses mediated by various populations of supraspinal neurones.

Published

1998

9. Spinal afferents to functionally distinct periaqueductal gray columns in the rat: An anterograde and retrograde tracing study

Author

Kevin A. Keay, Brent D. Gordon, Richard Bandler, Karsten Feil, and Horst Herbert

Subjects

Male, Afferent Pathways, Brain Mapping, Histocytochemistry, General Neuroscience, Anatomy, Biology, Spinal cord, Retrograde tracing, Periaqueductal gray, Parabrachial area, Rats, Rats, Sprague-Dawley, Laminar organization, Anterograde tracing, Lumbar, medicine.anatomical_structure, Spinal Cord, nervous system, medicine, Animals, Periaqueductal Gray, Spinomesencephalic tract, Neuroscience

Abstract

The segmental and laminar organization of spinal projections to the functionally distinct ventrolateral (vlPAG) and lateral periaqueductal gray (lPAG) columns was examined by using retrograde and anterograde tracing techniques. It was found 1) that spinal input to both vlPAG and lPAG columns arose predominantly from neurons in the upper cervical (C1-4) and sacral spinal cord; 2) that there was a topographical separation of vl-PAG projecting and lPAG-projecting neurons within the upper cervical spinal cord; but 3) that below spinal segment C4, vlPAG-projecting and lPAG-projecting spinal neurons were similarly distributed, predominantly within contralateral lamina I, the nucleus of the dorsolateral fasciculus (the lateral spinal nucleus) and the lateral (reticular) part of lamina V. Consistent with the retrograde results, the greatest density of anterograde label, within both the vlPAG and lPAG, was found after tracer injections made either in the superficial or deep dorsal horn of the upper cervical spinal cord. Tracer injections made within the thoraco-lumbar spinal cord revealed that the vlPAG column received a convergent input from both the superficial and deep dorsal horn. However, thoraco-lumbar input to the lPAG was found to arise uniquely from the superficial dorsal horn; whereas the deep dorsal horn was found to innervate the "juxta-aqueductal" PAG region rather than projecting to the lPAG. These findings suggest that similar to spino-parabrachial projections, spinal projections to the lPAG (and juxta-aqueductal PAG) are topographically organised, with distinct subgroups of spinal neurons projecting to specific lPAG or juxta-aqueductal PAG subregions. In contrast, the vlPAG receives a convergent spinal input which arises from the superficial and deep dorsal horn of cervical, thoracic, lumbar, and sacral spinal segments.

Published

1997

10. Distinct Cell Groups In The Lumbosacral Cord Of The Cat Project To Different Areas In The Periaqueductal Gray

Author

Gert Holstege, Leonora J. Mouton, Veronique G.J.M. VanderHorst, Bertil F.M. Blok, and SMART Movements (SMART)

Subjects

Lamina, Lordosis, General Neuroscience, Anatomy, Biology, medicine.disease, Periaqueductal gray, Midbrain, Nociception, medicine.anatomical_structure, nervous system, Tegmentum, medicine, Spinomesencephalic tract, Lumbosacral joint

Abstract

The periaqueductal gray (PAG) is involved in aggressive and defensive behavior, micturition, and lordosis. Especially for the latter two functions, PAG afferents from the lumbosacral cord are of vital importance because, in addition to information regarding homeostasis and thermoregulation, they convey information from the pelvic viscera and sex organs. In the present retro- and antero-grade tracing study, the projection patterns of different lumbosacral cell groups in the PAG were determined. In the retrograde study, wheatgerm agglutinin-horseradish peroxidase (WGA-HRP) injections were made in the PAG and/or adjacent tegmentum, and in the anterograde study, WGA-HRP was injected in different lumbosacral segments. The results revealed that lumbosacral-PAG neurons could be divided into three groups. The first and largest group was present in lumbar 7-sacral 3 segments (L7-S3) and consisted of small, oval, and fusiform neurons. It extended from the dorsolateral part of lamina I in L7, along the lateral part of the dorsal horn in S1, and into lamina V of S2. In the lateral part of S2, some of its neurons formed clusters with intervals of +/- 230 microns. The location of the first group overlapped extensively with the termination area of pelvic and pudendal afferents. The main midbrain target of the first group was the medial part of the lateral PAG. The second group consisted of small to large multipolar neurons in laminae VIII and medial VII of caudal L6, L7, and rostral S1. This group projected strongly to a distinct region in the lateral part of the lateral PAG and the laterally adjacent tegmentum. About 10% of the labeled neurons did not fit in the two groups. They were evenly distributed throughout lumbar 4-coccygeal 3 segments (L4-Co3) and consisted of large multipolar lamina V neurons and small lamina I neurons that projected diffusely to the lateral and dorsal PAG. The large lamina V neurons also targeted the laterally adjacent tegmentum. The possible involvement of the lumbosacral-PAG projections in micturition, lordosis, and defensive and aggressive behavior is discussed.

Published

1996

11. Deep and superficial noxious stimulation increases Fos-like immunoreactivity in different regions of the midbrain periaqueductal grey of the rat

Author

Richard Bandler and Kevin A. Keay

Subjects

Male, Central nervous system, Pain, Stimulation, Biology, Rats, Sprague-Dawley, Midbrain, Mesencephalon, Neck Muscles, Physical Stimulation, Noxious stimulus, medicine, Animals, Periaqueductal Gray, Neurons, Afferent, Spinomesencephalic tract, General Neuroscience, Spinal cord, Immunohistochemistry, Rats, Nociception, medicine.anatomical_structure, Spinal Cord, nervous system, Nociceptor, Proto-Oncogene Proteins c-fos, Neuroscience

Abstract

We have reported that the lateral region of the caudal third of the midbrain periaqueductal grey (PAG), which mediates flight and hypertension, receives inputs from lamina I and IIo and the lateral cervical nucleus (LCN) of the upper cervical spinal cord (UCC); whereas the ventrolateral PAG region, which mediates hypotension, quiescence and immobility, is targeted by cells in laminae VII, VIII and X. In the UCC the cells of laminae VII and VIII receive a significant afferent input from the deep neck muscles, whereas cells of laminae I and IIo and the LCN receive a large input from cutaneous nociceptors. Thus we investigated the hypothesis that nociceptive activation of the deep neck muscles would activate the spinal-ventrolateral PAG projection, whereas cutaneous nociceptive stimulation would activate the spinal-lateral PAG projection, by examining the expression of Fos protein. We found that deep noxious stimulation led to Fos-positive cells predominantly in the ventrolateral PAG and superficial noxious stimulation led to Fos-positive cells predominantly in the lateral PAG. The results: (i) indicate that the UCC afferent regulation of the PAG arises from topographically separable and functionally dissociable populations of neurons and (ii) raise the possibility that the ventrolateral and lateral PAG play important but different roles in mediating the distinctive affective, emotional and autonomic responses evoked by pain arising from deep or superficial structures.

Published

1993

12. Spinal and trigeminal lamina I input to the locus coeruleus anterogradely labeled with Phaseolus vulgaris leucoagglutinin (PHA-L) in the cat and the monkey

Author

A.D. (Bud) Craig

Subjects

Lamina, Hot Temperature, Central nervous system, Biology, Nerve Fibers, medicine, Carnivora, Animals, Trigeminal Nerve, Spinomesencephalic tract, Phytohemagglutinins, Molecular Biology, Histocytochemistry, General Neuroscience, Nociceptors, Phaseolus vulgaris leucoagglutinin, Anatomy, Macaca fascicularis, Nociception, medicine.anatomical_structure, Spinal Cord, Xanthenes, nervous system, Cats, Locus coeruleus, Locus Coeruleus, Neurology (clinical), Brainstem, Developmental Biology

Abstract

Terminal fibers anterogradely labeld with Phaseolus vulgaris leucoagglutinin (PHA-L) were observed in the locus coeruleus in the brainstem of the cat and the cynomolgus monkey following injections in lamina I of the spinal or medullary dorsal horn. Thus, thermoreceptive- or nociceptive-specific lamina I cells that project to the locus coeruleus could directly influence arousal, vigilance, and the descending control of spinal integration.

Published

1992

13. The ventrolateral upper cervical cell group in cat projects to all rostrocaudal levels of the periaqueductal gray matter

Author

Esther Marije Klop, Leonora J. Mouton, Ellie Eggens-Meijer, and SMART Movements (SMART)

Subjects

LAMINA-I NEURONS, Thalamus, Somatosensory, Biology, Somatosensory system, Periaqueductal gray, Anterior Horn Cell, Anterior Horn Cells, C-1-C-2 SPINAL NEURONS, Neural Pathways, FREELY MOVING RATS, medicine, TRANSGANGLIONIC TRANSPORT, Animals, Periaqueductal Gray, Spinomesencephalic tract, RETROGRADE TRANSPORT, Molecular Biology, Neuronal Tract-Tracers, Visceral, PHYSIOLOGICAL-PROPERTIES, General Neuroscience, HORSERADISH-PEROXIDASE TECHNIQUE, Neck muscle, SPINOTHALAMIC TRACT NEURONS, Anatomy, Spinal cord, Vestibular, AFFERENT PATHWAYS, medicine.anatomical_structure, Spinal Cord, nervous system, Dorsal column nuclei, Receptive field, Spinomesencephalic, Cats, Cervical Vertebrae, SPINOMESENCEPHALIC TRACT, Spinothalamic, Neurology (clinical), Neuroscience, Developmental Biology

Abstract

The lateral ventral horn. of the upper cervical (C(1-3vl)) cord in rat, cat and monkey contains many cells that project to the periaqueductal gray matter (PAG). Until now it was assumed that these cells only project to the ventrolateral part of the caudal PAG. Because the ventrolateral caudal PAG is involved in quiescence and hypotension, it was hypothesized that the C(1-3vl)-PAG projecting cells play a role in immobility behavior, possibly activated by neck muscle afferents. However, in the present anterograde and retrograde study in cat we showed that C(1-3vl) cells do not only target the caudal PAG, but terminate even more abundantly in the intermediate and rostral parts of the PAG. There, projections target the ventrolateral column, like in the caudal PAG, but also terminate in the lateral and dorsomedial columns. This finding, combined with the current, albeit limited, physiological data on C(1-3vl)-PAG and C(1-3vl)-thalamic projecting cells, sheds a new light on the possible functions of C(1-3vl) cells. it might be that the C(1-3vl) cells with complex response properties and large receptive fields have a relay function similar to cells in the dorsal column nuclei, lateral cervical or central cervical nucleus. Other C(1-3vl) cells might receive somatic or visceral input that was never tested before, or perhaps other input, like vestibular information. It might also be that these cells project to the more caudal cord to modulate visceral input, with ascending collaterals to more rostrally, located structures, including mesencephalon and thalamus. (C) 2009 Elsevier B.V. All rights reserved.

Published

2009

14. Collateral projections of neurons in laminae I, III, and IV of rat spinal cord to thalamus, periaqueductal gray matter, and lateral parabrachial area

Author

Khulood M. Al-Khater and Andrew J. Todd

Subjects

Male, Spinothalamic tract, Lamina, neurokinin 1 receptor, Thalamus, Biology, confocal microscopy, Parabrachial area, Article, spinothalamic tract, spinomesencephalic tract, medicine, Animals, Periaqueductal Gray, Spinomesencephalic tract, Rats, Wistar, Neurons, Afferent Pathways, dorsal horn, General Neuroscience, Membrane Proteins, Anatomy, Receptors, Neurokinin-1, Spinal cord, Immunohistochemistry, Rats, medicine.anatomical_structure, Nociception, nervous system, Spinal Cord, Cervical enlargement, Carrier Proteins, Neuroscience, Biomarkers

Abstract

Projection neurons in lamina I, together with those in laminae III–IV that express the neurokinin 1 receptor (NK1r), form a major route through which nociceptive information reaches the brain. Axons of these cells innervate various targets, including thalamus, periaqueductal gray matter (PAG), and lateral parabrachial area (LPb), and many cells project to more than one target. The aims of this study were to quantify projections from cervical enlargement to PAG and LPb, to determine the proportion of spinothalamic neurons at lumbar and cervical levels that were labelled from PAG and LPb, and to investigate morphological differences between projection populations. The C7 segment contained fewer lamina I spinoparabrachial cells than L4, but a similar number of spino-PAG cells. Virtually all spinothalamic lamina I neurons at both levels were labelled from LPb and between one-third and one-half from PAG. This suggests that significant numbers project to all three targets. Spinothalamic lamina I neurons differed from those labelled only from LPb in that they were generally larger, were more often multipolar, and (in cervical enlargement) had stronger NK1r immunoreactivity. Most lamina III/IV NK1r cells at both levels projected to LPb, but few were labelled from PAG. The great majority of these cells in C7 and over one-fourth of those in L4 were spinothalamic, and at each level some projected to both thalamus and LPb. These results confirm that neurons in these laminae have extensive collateral projections and suggest that different neuronal subpopulations in lamina I have characteristic patterns of supraspinal projection. J. Comp. Neurol. 515:629–646, 2009. © 2009 Wiley-Liss, Inc.

Published

2009

15. Spinal distribution of ascending lamina I axons anterogradely labeled withPhaseolus vulgaris leucoagglutinin (PHA-L) in the cat

Author

A.D. (Bud) Craig

Subjects

Lamina, Spinothalamic tract, Spinothalamic Tracts, Pain, Biology, Axonal Transport, chemistry.chemical_compound, Biocytin, medicine, Animals, Neurons, Afferent, Spinomesencephalic tract, Phytohemagglutinins, Lysine, General Neuroscience, Nociceptors, Thermoreceptors, Anatomy, Spinal cord, Axons, medicine.anatomical_structure, Nociception, chemistry, Cats, Axoplasmic transport, Lateral funiculus

Abstract

The location of the ascending axons of spinal lamina I cells was studied in cats that received injections of Phaseolus vulgaris leucoagglutinin (PHA-L) in the superficial dorsal horn of the cervical or lumbosacral enlargement. Lamina I axons that could be ascribed to the spinothalamic tract (STT) were of particular interest. The cases were divided into three sets: in seven optimal cases the injections were restricted to lamina I; in ten nominal cases the injections involved laminae I-II or laminae I-III and occasionally lamina IV; and in eight mixed cases laminae I-V were injected. Since ipsilateral propriospinal and bilateral supraspinal axons originate from laminae I and V, but only ipsilateral propriospinal axons from laminae II-IV, this categorization facilitated a comparative analysis. Ascending axons labeled immunohistochemically with avidin/Texas Red were observed in oblique transverse sections from the C1, C3/4, T6, T12, and L3/4 levels. Incidental axonal labeling occurred in the ipsilateral dorsal columns because of passing primary afferent fiber uptake and, in nominal and mixed cases with involvement of laminae III-IV, in the superficial dorsolateral funiculus at the location of the spinocervical tract. Ipsilateral ascending lamina I axons in optimal cases were located in Lissauer's tract and in the white matter adjacent to the dorsal horn. Since these appeared to terminate in lamina I, and few remained at C1, they were ascribed to propriospinal projections. Contralateral ascending lamina I axons in optimal and nominal cases were distributed throughout the dorsal and ventral portions of the lateral funiculus (LF), but, despite considerable variability between animals in their location and dispersion, they were consistently concentrated in the middle of the LF (i.e., at the level of the central canal). This concentration was observed in a slightly more ventral location at C1, and a similar but weaker concentration of lamina I axons was located slightly more dorsally in C1 on the ipsilateral side. These supraspinal lamina I projections were ascribed to the spinomesencephalic tract (SMT) and to the STT. In mixed cases, additional ascending axons ascribed to lamina V cells were labeled in the ventrolateral and ventral funiculi. Many labeled axons were found in this region following a large injection of biocytin into lumbosacral laminae V-VIII in a supplementary case. These results thus together support previous descriptions of a dorsoventral distribution of STT axons according to laminar origin, but they contradict recent reports that lamina I axons ascend in the dorsolateral funiculus.(ABSTRACT TRUNCATED AT 400 WORDS)

Published

1991

16. Origins of Spinal Ascending Pathways that Reach Central Areas Involved in Visceroception and Visceronociception in the Rat

Author

J. de Pommery and D. Menétrey

Subjects

Intercalated nucleus, General Neuroscience, Central nervous system, Anatomy, Biology, Reticular formation, Spinal cord, Retrograde tracing, Parabrachial area, medicine.anatomical_structure, Nociception, medicine, Spinomesencephalic tract, Neuroscience

Abstract

The location of spinal cells projecting rostrally to central areas that process visceroception and visceronociception were studied in rat using the retrograde transport of a protein - gold complex. Origins of afferents to the nucleus tractus solitarius (the spinosolitary tract), the parabrachial area (the spinoparabrachial tract), the hypothalamus (the spinohypothalamic tract) and the amygdala (the spinoamygdalar tract) were studied at thoracic, lumbar and sacral levels, where spinal visceroceptive areas are concentrated. All of the afore-mentioned pathways have common origins in the lateral spinal nucleus and in the reticular formation of the neck of the dorsal horn at all the levels studied, and also in the dorsal grey commissure and adjacent areas at sacral levels. The spinosolitary and the spinoparabrachial tracts are dense pathways, both of which are also characterized by afferents from the superficial layers of the dorsal horn at all the levels studied and from cells lying in close proximity to some autonomic spinal areas. These autonomic areas are the central autonomic nucleus (dorsal commissural nucleus) of lamina X at thoracolumbar levels and the parasympathetic column at sacral levels; some projections from the intermediolateral cell column at thoracic levels were also noted. Projections from all these autonomic structures to the parabrachial area have not yet been recognized. Thus, the origin of the spinoparabrachial tract closely resembles that of the spinomesencephalic tract that reaches the periaquaductal grey and adjacent areas. The spinohypothalamic and the spinoamygdalar tracts are smaller pathways. Direct spinal connections to the amygdala have not been reported previously. Both the hypothalamus and amygdala receive projections from lamina VII cells at low thoracic and upper lumbar levels in a pattern that resembles that of the preganglionic cells of the intercalated nucleus. Hypothalamic projections from the sacral parasympathetic area were also noted. The use of c-fos as a functional marker to identify spinal neurons that are activated by noxious visceral stimulation suggests that both the spinoparabrachial and the spinosolitary tracts contribute significantly to the central transmission of visceronoceptive messages. Most of the visceronociceptive ascending projections in these pathways issued from lamina I cells. The results presented here confirm previous observations regarding the spinosolitary and the spinohypothalamic tracts and also demonstrate, for the first time, the complex origin of the spinoparabrachial tract and the existence of direct spinal afferents to the amygdala. These findings suggest that rostral transmission and central integration of visceral inputs require several parallel routes. The spinosolitary and spinoparabrachial tracts clearly play a role in conveying information regarding visceronociception.

Published

1991

17. Spinal distribution and collateral projections of rat spinomesencephalic tract cells

Author

C.M. Mendez and Robert P. Yezierski

Subjects

Central nervous system, Population, Biology, Axonal Transport, Efferent Pathways, Midbrain, Mesencephalon, medicine, Animals, Spinomesencephalic tract, education, Horseradish Peroxidase, Fluorescent Dyes, Afferent Pathways, education.field_of_study, General Neuroscience, Rats, Inbred Strains, Anatomy, Marginal zone, Spinal cord, Rats, medicine.anatomical_structure, Spinal Cord, nervous system, Axoplasmic transport, Nucleus

Abstract

The distribution of cells belonging to the rat spinomesencephalic tract was studied by means of the retrograde transport of fluorescent dyes. Bilateral midbrain injections of cytoplasmic and nuclear tracers were made in order to evaluate the location of ipsilateral, contralateral, or bilaterally projecting cells. Spinal neurons with ascending projections to midbrain and descending propriospinal projections were identified by midbrain and spinal injections of different cytoplasmic labels. The locations of spinomesencephalic tract cells included seven regions of the spinal gray matter: marginal zone, lateral neck of the dorsal horn, nucleus proprius, the region around the central canal, the lateral cervical and spinal nuclei and the ventral horn. Cells projecting to the ipsilateral or contralateral midbrain had similar distributions and were frequently found in clusters with overlapping dendritic fields. Approximately 75% of spinomesencephalic cells projected to the contralateral midbrain. The largest contribution to the spinomesencephalic tract cell population was found in cervical cord segments 1-4. Cells with bilateral projections accounted for nearly 2% of all labeled cells, whereas 5% had both ascending and descending projections. Spinomesencephalic cells were found to have varying dendritic fields and morphology, e.g. fusiform, pyramidal, round/oval, and multipolar. The results of the present study lend further support to the view that the spinomesencephalic tract is a multi-component pathway with varied origins and projection targets.

Published

1991

18. Collaterals of primate spinothalamic tract neurons to the periaqueductal gray

Author

L.S. Sorkin, Susan M. Carlton, D. Zhang, and William D. Willis

Subjects

Spinothalamic tract, Spinothalamic Tracts, General Neuroscience, Action Potentials, Cell Count, Anatomy, Biology, Spinal cord, Periaqueductal gray, Electric Stimulation, Antidromic, Lumbar enlargement, Macaca fascicularis, medicine.anatomical_structure, nervous system, Cervical enlargement, medicine, Animals, Macaca, Periaqueductal Gray, Spinomesencephalic tract, Axon, Fluorescent Dyes

Abstract

Collateral projections are an important feature of the organization of ascending projections from the spinal cord to the brain. Primate spinothalamic tract (STT) neurons with collaterals to the periaqueductal gray (PAG) were studied by means of a fluorescent double-labeling method. Granular Blue and rhodamine-labeled latex microspheres were placed in the ventral posterior lateral (VPL) nucleus of the thalamus and the periaqueductal gray, respectively. Single and double labeled neurons were studied in the upper cervical cord, cervical enlargement, thoracic cord, lumbar enlargement, and sacral segments. The laminar distribution of double labeled neurons was similar to that of spinomesencephalic tract (SMT) neurons. Most double labeled (STT-SMT) neurons were located in contralateral laminae I, V, VII, and X. Relatively more lamina I STT-SMT neurons were found in the cervical enlargement and more lamina V STT-SMT neurons in the lumbar enlargement. The density of STT-SMT neurons in the upper cervical segments and cervical enlargement was almost equal. The density of STT-SMT neurons in the lumbar enlargement was 40% of that in the cervical enlargement. The thoracic and sacral segments had the lowest density of STT-SMT neurons, about 10% of that in the cervical enlargement. STT-SMT neurons constituted 14.7% of SMT neurons and 6% of STT neurons in the cervical enlargement and 15.3% of SMT neurons and 2.9% of STT neurons in the lumbar enlargement. The branch points of eight STT-SMT axons were studied electrophysiologically. The average percentage of conduction time spent in the parent axon was more than 85% for an antidromic action potential from the VPL nucleus and 91% from the PAG. Branch points of STT-SMT axons were calculated to be 9–13 mm caudal to the PAG, in the pons or rostral medulla.

Published

1990

19. Effects of midbrain and medullary stimulation on spinomesencephalic tract cells in the cat

Author

Robert P. Yezierski

Subjects

Male, Neurons, Nucleus raphe magnus, Medulla Oblongata, Midbrain reticular formation, Physiology, Chemistry, Red nucleus, General Neuroscience, Superior colliculus, Stimulation, Electric Stimulation, Midbrain, medicine.anatomical_structure, Spinal Cord, Mesencephalon, Neural Pathways, Cats, medicine, Medulla oblongata, Animals, Female, Spinomesencephalic tract, Neuroscience

Abstract

1. The effects of electrical stimulation at different rostrocaudal levels of the midbrain, and at sites in the rostral medulla ipsilateral and contralateral to spinal recording sites, were evaluated against the responses of 46 cells belonging to the cat spinomesencephalic tract (SMT). 2. Inhibitory and/or excitatory effects of brain stem stimulation were observed on SMT cells that responded best (26 cells) or exclusively (12 cells) to noxious mechanical or thermal stimuli, as well as on 7 cells responding only to tap and/or stimulation of deep tissues. Recording sites for 32 cells were located in laminae V-VIII (27 cells) and laminae I-III (5 cells). 3. Midbrain stimulation sites were located in the superior colliculus, central gray (CG), red nucleus, and the midbrain reticular formation. Both inhibitory-only and excitatory-only effects were observed, although the most common effect of midbrain stimulation was excitation followed by inhibition (mixed effects). The effects of stimulation at different midbrain levels were determined for each cell. Stimulation in the caudal, middle, or rostral midbrain was often found to exert different effects on the same SMT cell. 4. Stimulation in the rostral medulla at sites located in nucleus raphe magnus (NRM), nucleus reticularis gigantocellularis, and nucleus reticularis magnocellularis produced the same complement of effects observed with midbrain stimulation. Excitation followed by inhibition was the most common effect observed. 5. Stimulus intensities required to produce excitatory or inhibitory effects from midbrain were 114 +/- 85 (SD) microA and 210 +/- 91 microA, respectively. Stimulus currents required to produce excitatory or inhibitory effects from medullary stimulation sites were 124 +/- 56 microA and 70 +/- 60 microA, respectively. The mean currents required to produce mixed effects were 221 +/- 120 microA (midbrain) and 127 +/- 71 microA (medulla). Increasing the stimulus intensity used to evaluate brain stem effects increased the magnitude and duration of effects for 33 cells. Mixed effects were observed on 11 cells at stimulus intensities greater than those required to produce inhibitory-only effects. 6. Significant differences were found between the latencies of excitation and inhibition produced from different brain stem levels. These differences suggest that midbrain and medullary stimulation activate descending pathways with a wide range of conduction velocities and/or supraspinal and spinal connectivities. 7. The spinal trajectory of pathways contributing to the varied effects of brain stem stimulation as well as the complex receptive fields (RFs) of SMT cells were evaluated by the placement of lesions in the cervical spinal cord.(ABSTRACT TRUNCATED AT 400 WORDS)

Published

1990

20. In cat four times as many lamina I neurons project to the parabrachial nuclei and twice as many to the periaqueductal gray as to the thalamus

Author

R Hulsebosch, Gert Holstege, Esther Marije Klop, Leonora J. Mouton, J Boers, and SMART Movements (SMART)

Subjects

Lamina, Spinothalamic tract, Spinothalamic Tracts, Thalamus, Wheat Germ Agglutinin-Horseradish Peroxidase Conjugate, Cell Count, Biology, Periaqueductal gray, Functional Laterality, POSITRON-EMISSION-TOMOGRAPHY, ELECTROPHYSIOLOGICAL EVIDENCE, mesencephalon, PRIMATE SPINOTHALAMIC TRACT, Pons, Neural Pathways, medicine, Animals, Periaqueductal Gray, pain, Spinomesencephalic tract, nociception, RETROGRADE TRANSPORT, Neurons, Parabrachial Nucleus, General Neuroscience, spinal cord, marginal layer, HORSERADISH-PEROXIDASE, Anatomy, Spinal cord, medicine.anatomical_structure, Nociception, nervous system, DORSAL HORN, CELLS, Cats, SPINOMESENCEPHALIC TRACT, Female, spinothalamic, SPINAL-CORD, PAIN PROCESSES

Abstract

The spinothalamic tract, and especially its fibers originating in lamina 1, is the best known pathway for transmission of nociceptive information. On the other hand, different studies have suggested that more lamina I cells project to the parabrachial nuclei (PBN) and periaqueductal gray (PAG) than to the thalamus. The exact ratio of the number of lamina I projections to PBN, PAG and thalamus is not known, because comprehensive studies examining these three projections from all spinal segments, using the same tracers and counting methods, do not exist.In the present study, the differences in number and distribution of retrogradely labeled lamina I cells in each segment of the cat spinal cord (C1-Coc2) were determined after large wheat germ agglutinin-conjugated horseradish peroxidase (WGA-HRP) injections in either PBN, PAG or thalamus. We estimate that approximately 6000 lamina I cells project to PBN, 3000 to PAG and less than 1500 to the thalamus. Of the lamina I cells projecting to thalamus or PAG more than 80%, and of the lamina I-PBN cells approximately 60%, were located on the contralateral side. In all cases, most labeled lamina I cells were found in the upper two cervical segments and in the cervical and lumbar enlargements. (c) 2005 IBRO. Published by Elsevier Ltd. All rights reserved.

Published

2005

21. Lateral cervical nucleus projections to periaqueductal gray matter in cat

Author

Mouton, LJ, Klop, EM, Broman, J, Zhang, ML, Holstege, G, Zhang, Mengliang, Faculteit Medische Wetenschappen/UMCG, and SMART Movements (SMART)

Subjects

tectum, LAMINA-I, Thalamus, THALAMIC PROJECTIONS, AFFERENT-PROJECTIONS, Biology, Somatosensory system, SUBSTANCE-P-LIKE, somatosensory, Midbrain, spinocervical, Neural Pathways, medicine, spinomesencephalic, Animals, Periaqueductal Gray, Spinomesencephalic tract, emotional motor system, Medulla Oblongata, General Neuroscience, Superior colliculus, SPINOCERVICAL TRACT NEURONS, colliculus superior, HORSERADISH-PEROXIDASE, Anatomy, AXONAL-TRANSPORT, Spinal cord, Anterograde tracing, medicine.anatomical_structure, nervous system, CERVICOTHALAMIC TRACT, DORSAL COLUMN, SPINOMESENCEPHALIC TRACT, Cats, Cervical Vertebrae, Brainstem, Neuroscience

Abstract

The midbrain periaqueductal gray matter (PAG) integrates the basic responses necessary for survival of individuals and species. Examples are defense behaviors such as fight, flight, and freezing, but also sexual behavior, vocalization, and micturition. To control these behaviors the PAG depends on strong input from more rostrally located limbic structures, as well as from afferent input from the lower brainstem and spinal cord. Mouton and Holstege (2000, J Comp Neurol 428:389-410) showed that there exist at least five different groups of spino-PAG neurons, each of which is thought to subserve a specific function. The lateral cervical nucleus (LCN) in the upper cervical cord is not among these five groups. The LCN relays information from hair receptors and noxious information and projects strongly to the contralateral ventroposterior and posterior regions of thalamus and to intermediate and deep tectal layers. The question is whether the LCN also projects to the PAG. The present study in cat, using retrograde and anterograde tracing techniques, showed that neurons located in the lateral two-thirds of the LCN send fibers to the lateral part of the PAG, predominantly at rostrocaudal levels A0.6-P0.2. This part of the PAG is known to be involved in flight behavior. A concept is put forward according to which the LCN-PAG pathway alerts the animal about the presence of cutaneous stimuli that might represent danger, necessitating flight. J. Comp. Neurol. 471:434-445, 2004.

Published

2004

22. Estrogen receptor-alpha immunoreactive neurons in the ventrolateral periaqueductal gray receive monosynaptic input from the lumbosacral cord in the rhesus monkey

Author

Henry J. Ralston, Ei Terasawa, Veronique G.J.M. VanderHorst, and University of Groningen

Subjects

MEDIAL PREOPTIC AREA, Wheat Germ Agglutinin-Horseradish Peroxidase Conjugate, VAGINAL STIMULATION, primate, SYMPATHETIC-NERVE ACTIVITY, Sexual Behavior, Animal, PONTINE MICTURITION CENTER, spinomesencephalic tract, Neural Pathways, Periaqueductal Gray, Primate, media_common, Neurons, Lumbar Vertebrae, biology, General Neuroscience, VISCERAL PRIMARY AFFERENTS, Dextrans, analgesia, Anatomy, Immunohistochemistry, medicine.anatomical_structure, Receptors, Estrogen, Spinal Cord, Female, Sacrum, EMOTIONAL EXPRESSION, Cord, Tegmentum Mesencephali, medicine.drug_class, media_common.quotation_subject, Presynaptic Terminals, Biotin, Pain, Urination, RAT-BRAIN, Periaqueductal gray, Cardiovascular Physiological Phenomena, sexual behavior, biology.animal, medicine, Animals, OVARIECTOMIZED FEMALE CAT, Spinomesencephalic tract, cardiovascular control, micturition, Estrogen Receptor alpha, Estrogens, HORSERADISH-PEROXIDASE, Macaca mulatta, Microscopy, Electron, nervous system, Estrogen, Synapses, Estrogen receptor alpha, Neuroscience, Lumbosacral joint

Abstract

Estrogen affects female sexual behavior, analgesia, and micturition in mammals. One of the possible sites at which estrogen might exert its effect on these functions is the periaqueductal gray (PAG). The PAG is involved in each of these functions, it receives sensory input relevant to these functions from the lumbosacral cord, and contains estrogen receptor-alpha immunoreactive (ER-alpha IR) neurons. The present light (LM) and electron microscopic (EM) study seeks to determine whether there are monosynaptic projections from the lumbosacral cord to ER-alpha IR neurons in the PAG of the female rhesus monkey. Tracer was injected into the lumbosacral cord to visualize the lumbosacral-PAG projection, and the distribution of ER-alpha IR neurons in the PAG was studied immunohistochemically. The medial part of the ventrolateral caudal PAG received the densest projection from the lumbosacral cord. Another prominent projection was found in the lateral PAG at the intercollicular level. Although ER-alpha IR neurons were widely distributed throughout the PAG, approximately 40%, of ER-alpha IR PAG neurons were located as a distinct cluster in the medial portion of the ventrolateral, caudal PAG. Double labeling experiments showed that the location of this cluster precisely overlapped with the densest lumbosacral-PAG projection. EM revealed that axons from the lumbosacral cord made asymmetrical synaptic contacts with unlabeled dendrites and ER-alpha IR neuronal somata in the ventrolateral PAG. It is concluded that there exists a specific, monosynaptic pathway from lumbosacral neurons to ER-alpha expressing PAG neurons in the rhesus monkey. This pathway might be involved in the mechanism of analgesia, blood pressure, mating behavior, and micturition. J. Comp. Neurol. 443:27-42, 2002. (C) 2002 Wiley-Liss, Inc.

Published

2002

23. Lamina I-periaqueductal gray (PAG) projections represent only a limited part of the total spinal and caudal medullary input to the PAG in the cat

Author

Esther Marije Klop, Gert Holstege, Leonora J. Mouton, Faculteit Medische Wetenschappen/UMCG, and SMART Movements (SMART)

Subjects

MICTURITION, Central nervous system, Wheat Germ Agglutinin-Horseradish Peroxidase Conjugate, AFFERENT-PROJECTIONS, ORGANIZATION, Biology, Periaqueductal gray, BRAIN-STEM, Midbrain, LACTATING RATS, Limbic system, Neural Pathways, medicine, spinomesencephalic, Animals, Periaqueductal Gray, trigeminal, Spinomesencephalic tract, nociception, nucleus caudalis, Neurons, Medulla Oblongata, LUMBOSACRAL CORD, General Neuroscience, marginal layer, Anatomy, ELECTRICAL-STIMULATION, Spinal cord, Nociception, medicine.anatomical_structure, Spinal Cord, MESENCEPHALON, Molecular Probes, Medulla oblongata, SPINOMESENCEPHALIC TRACT, Cats, Female, Neuroscience

Abstract

The periaqueductal gray is well known for its involvement in nociception control, but it also plays an important role in the emotional motor system. To accomplish these functions the periaqueductal gray receives input from the limbic system and from the caudal brainstem and spinal cord. Earlier studies gave the impression that the majority of the periaqueductal gray projecting cells in caudal brainstem and spinal cord are located in the contralateral lamina I, which is involved in nociception. The present study in the cat, however, demonstrates that of all periaqueductal gray projecting neurons in the contralateral caudal medulla less than 7% was located in lamina I. Of the spinal periaqueductal gray projecting neurons less than 29% was located in lamina I. However, within the spinal cord large segmental differences exist: in few segments of the enlargements the lamina I-periaqueductal gray projecting neurons represent a majority. In conclusion, although the lamina I-periaqueductal gray projection is a very important nociceptive pathway, it constitutes only a limited part of the total projection from the caudal medulla and spinal cord to the periaqueductal gray. These results suggest that a targe portion of the medullo- and spino-periaqueductal gray pathways conveys information other than nociception. (C) 2001 Elsevier Science Inc.

Published

2001

24. Responses of primate spinomesencephalic tract cells to intradermal capsaicin

Author

F. A. Lenz, Alan R. Schwartz, and Patrick M. Dougherty

Subjects

Injections, Intradermal, Differential Threshold, Pharmacology, Inhibitory postsynaptic potential, Periaqueductal gray, Synaptic Transmission, chemistry.chemical_compound, Mesencephalon, Physical Stimulation, Neural Pathways, medicine, Animals, Periaqueductal Gray, Spinomesencephalic tract, Intradermal injection, Excitatory Amino Acid Agonist, Neurons, Chemistry, General Neuroscience, Nociceptors, Electric Stimulation, Macaca fascicularis, medicine.anatomical_structure, Nociception, Spinal Cord, Capsaicin, Excitatory postsynaptic potential, Neuroscience

Abstract

The responses of 32 spinomesencephalic tract cells to intradermal capsaicin were examined in anesthetized monkeys. Wide dynamic range (n = 20) and nociceptive specific (n = 6) cells showed two types of excitatory responses to intradermal injection of capsaicin. The first excitatory response shown by the majority of wide dynamic range (n = 13) and nociceptive specific (n = 4) cells was consistent with their sensitization by capsaicin. The cells showed an acute and prolonged increase in ongoing activity with capsaicin injection. Responses to mechanical stimuli were substantially increased after capsaicin and an expansion of receptive field was often observed. The responses of the same cells to excitatory amino acid agonists applied locally by iontophoresis also increased. All cells showing sensitization were antidromically activated from periaqueductal gray regions dorsal to the sulcus limitans. Electrical stimulation at these sites did not affect the ongoing or evoked discharges of these cells. The second excitatory response of wide dynamic range (n = 5) and nociceptive specific (n = 1) cells was a novel pattern not consistent with sensitization. These cells nevertheless showed an acute and prolonged increase in background activity after capsaicin injection. Yet, there was no change or a decrease in responses to cutaneous stimuli, no evidence for change in receptive field size and no increase in responses to locally released excitatory amino acids. These cells projected to regions in the periaqueductal gray ventral to the sulcus limitans. Electrical stimulation at these sites produced a decrease in spontaneous activity of the same cell. Low threshold mesencephalic-projecting neurons (n = 6) showed a single inhibitory pattern (n = 4) of responses to capsaicin. The injection produced an acute decrease in spontaneous activity that was sustained for at least 30 min after injection. The responses to cutaneous stimuli and to excitatory amino acids were also substantially reduced. Low threshold cells were found that projected to both dorsal-lateral and ventral-lateral regions of the periaqueductal gray. In summary, three patterns of responses shown by primate spinomesencephalic tract cells to intradermal capsaicin appear dependent on the functional regions of the periaqueductal gray to which they project. These results suggest that inputs of spinomesencephalic tract neurons to the periaqueductal gray may evoke important components of the systemic response to the neurogenic hyperalgesia produced by intradermal capsaicin.

Published

1999

25. Large segmental differences in the spinal projections to the periaqueductal gray in the cat

Author

Veronique G.J.M. VanderHorst, Leonora J. Mouton, Gert Holstege, Faculteit Medische Wetenschappen/UMCG, and SMART Movements (SMART)

Subjects

media_common.quotation_subject, Central nervous system, Wheat Germ Agglutinin-Horseradish Peroxidase Conjugate, cat, AFFERENT-PROJECTIONS, Biology, wheat germ agglutinin-conjugated horseradish peroxidase, Periaqueductal gray, Urination, Limbic system, spinomesencephalic tract, TERMINATION, medicine, Limbic System, Animals, Periaqueductal Gray, Spinomesencephalic tract, NEURONS, media_common, emotional motor system, Afferent Pathways, ORIGIN, General Neuroscience, MONKEY, Anatomy, Spinal cord, REGIONS, TRANSPORT, Nociception, medicine.anatomical_structure, nervous system, Spinal Cord, Cats, RAT, PRIMATE, Brainstem, Neuroscience, Brain Stem

Abstract

The periaqueductal gray (FAG) is involved in motor activities, such as movements of the neck, back and hind limbs, cardiovascular regulation, micturition, vocalization, and mating behavior, as well as in nociception control. To accomplish these functions the FAG uses information from other parts of the limbic system, from the lower brainstem, and from the spinal cord. To study the ascending projections from the spinal cord to the PAG, tracer was injected in different parts of the FAG, and the number of retrogradely labeled neurons were counted for each spinal segment. Results show that large segmental differences exist in the number of FAG projecting neurons throughout the length of the spinal cord and that different parts of the spinal cord project to specific areas in the FAG. (C) 1997 Elsevier Science Ireland Ltd.

Published

1998

26. Electrophysiological evidence that spinomesencephalic neurons in the cat may be excited via spinocervical tract collaterals

Author

A.G. Brown, Z. Meng, Laiche Djouhri, and A.D. Short

Subjects

Population, Neural Conduction, Postsynaptic potential, Mesencephalon, Neural Pathways, medicine, Animals, Spinomesencephalic tract, education, Neurons, education.field_of_study, Chemistry, General Neuroscience, Superior colliculus, Anatomy, Spinal cord, Electric Stimulation, Antidromic, Electrophysiology, medicine.anatomical_structure, nervous system, Spinal Cord, Excitatory postsynaptic potential, Cats, Neuroscience, Neck

Abstract

Extracellular microelectrode recordings were made from spinomesencephalic tract (SMT) neurons in the lumbosacral spinal cord of cats anaesthetized with chloralose and paralysed with gallamine triethiodide. The SMT cells were antidromically fired from the posterolateral parts of the superior colliculus and the intercollicular region, were located in laminae IV to VIII, and had response properties and axonal conduction velocities similar to those described previously. The effects of stimulating the dorsolateral funiculus of the cervical cord at C3 and rostral C1, below and above the termination of spinocervical tract (SCT) axons in the lateral cervical nucleus, were examined on 33 SMT cells. The strength of stimulation was adjusted so that at C3 it was above threshold for antidromic activation of SCT cells and at C1 was below threshold for activation of the same cells. Seven (21%) SMT neurons were excited from C3 but not from C1. The remaining 26 (79%) were excited from both C3 and rostral C1 and 23 (70% of these) were excited significantly more from C3. That is, 91% of the total sample were either excited only from C3 or more strongly from C3 than from rostral C1. We discuss the possible neuronal systems involved and conclude that the greater excitatory effects from C3 are most likely due to antidromic activation of the SCT. The shortest latency effects from C3 indicate a monosynaptic linkage between SCT cells with the fastest axons and the SMT. The longer latency actions may be due to monosynaptic connexions from SCT cells with slower conducting axons, to di- or polysynaptic actions from SCT cells with fast axons, or a combination of both. SMT cells are another population of spinal neurons, in addition to postsynaptic dorsal column, spinothalamic and dorsal horn spinocerebellar neurons, which receive excitation via SCT collaterals.

Published

1998

27. Estrogen receptor-immunoreactive neurons in the lumbosacral cord projecting to the periaqueductal gray in the ovariectomized female cat

Author

Fabienne C Schasfoort, Ellie Meijer, Veronique G.J.M. VanderHorst, Fred W. Van Leeuwen, Gert Holstege, and Faculteit Medische Wetenschappen/UMCG

Subjects

medicine.medical_specialty, medicine.drug_class, Ovariectomy, Central nervous system, Estrogen receptor, receptive behavior, midbrain, Biology, Periaqueductal gray, INTERCOLLICULAR REGION, AFFERENT, sexual behavior, spinomesencephalic tract, Internal medicine, Neural Pathways, medicine, Animals, Periaqueductal Gray, nociception, parturition, NUCLEUS, Neurons, General Neuroscience, Ovary, Lumbosacral Region, spinal cord, PUDENDAL NERVE, Spinal cord, Immunohistochemistry, medicine.anatomical_structure, Endocrinology, Nociception, Receptors, Estrogen, nervous system, Estrogen, MESENCEPHALON, CELLS, Ovariectomized rat, Cats, RAT, Female, Lumbosacral joint, TRACT

Abstract

The periaqueductal gray (FAG) plays a crucial role in reproductive behavior. The present study investigates whether lumbosacral FAG-projecting neurons contain estrogen receptors. In four ovariectomized adult female cats, injections with cholera toxin subunit (CTb) were made into the FAG to retrogradely label FAG projecting neurons in the lumbosacral cord. Estrogen receptor immunoreactive ER-IR neurons in the lumbosacral cord were identified immunohistochemically using the antibody H222, PAG-projecting neurons that were immunoreactive for the estrogen receptor were very scarce, and predominantly present in the medial part of the ventral horn. The results indicate that only very few of the neurons relaying information from the urogenital organs to the FAG contain estrogen receptors. (C) 1997 Elsevier Science Ireland Ltd.

Published

1997

28. Caudal medullary pathways to lumbosacral motoneuronal cell groups in the cat: evidence for direct projections possibly representing the final common pathway for lordosis

Author

Gert Holstege and Veronique G.J.M. VanderHorst

Subjects

VENTROMEDIAL NUCLEUS, Ventral respiratory group, Posture, Wheat Germ Agglutinin-Horseradish Peroxidase Conjugate, Biology, Motor Activity, Lumbar enlargement, HYPOTHALAMIC-LESIONS, Sexual Behavior, Animal, VENTRAL RESPIRATORY GROUP, MOTOR NUCLEI, Interneurons, Pregnancy, NUCLEUS RETROAMBIGUUS, Neural Pathways, medicine, Tegmentum, Animals, Periaqueductal Gray, Spinomesencephalic tract, Defecation, Motor Neurons, Medulla Oblongata, Labor, Obstetric, General Neuroscience, Respiration, FUNCTIONALLY COMPLEX MUSCLES, Lumbosacral Region, DECEREBRATE CATS, Anatomy, Spinal cord, LIGHT MICROSCOPY, Anterograde tracing, medicine.anatomical_structure, SPINOMESENCEPHALIC TRACT, Cats, Female, Brainstem, HINDLIMB, SPINAL-CORD, BRAIN-STEM PROJECTIONS, Neuroscience, Lumbosacral joint, FEMALE REPRODUCTIVE-BEHAVIOR

Abstract

The nucleus retroambiguus (NRA) projects to distinct brainstem and cervical and thoracic cord motoneuronal cell groups. The present paper describes NRA projections to distinct motoneuronal cell groups in the lumbar enlargement. Lumbosacral injections of wheat germ agglutinin-horseradish peroxidase (WGA-HRP) were made to localize and quantify the retrogradely labeled neurons in the caudal medullary lateral tegmentum. These injections were combined with spinal hemisections to distinguish between neurons having ipsi- or contralaterally descending axons. The NRA-lumbosacral fibers descend almost exclusively contralaterally, but neurons in areas surrounding the NRA project mainly ipsilaterally.In an anterograde tracing study, injections of WGA-HRP or tritiated leucine were made in the region of the NRA to determine the NRA. targets in the lumbosacral cord. Hemisections in C2 made it possible to distinguish between NRA projections and projections from neurons in the adjoining lateral tegmentum. The results show delicate NRA projections to distinct lumbosacral motoneuronal cell groups innervating specific hindlimb muscles (iliopsoas, adductors, and hamstrings) as well as axial muscles (medial longissimus and proximal tail muscles). The projection is bilateral, with a contralateral predominance. Ipsilaterally terminating fibers are derived from NRA neurons whose axons cross the midline at the level of the obex, descend through the contralateral spinal white matter, and recross at the level of termination. A conceptual description is presented in which the periaqueductal gray-NRA-lumbosacral projections form the final common pathway for lordosis in the cat. (C) 1995 Wiley-Liss, Inc.

Published

1995

29. Ultrastructural Evidence For A Paucity Of Projections From The Lumbosacral Cord To The Pontine Micturition Center Or M-region In The Cat: A New Concept For The Organization Of The Micturition Reflex With The Periaqueductal Gray As Central Relay

Author

Henk de Weerd, Gert Holstege, Bertil F.M. Blok, and Faculteit Medische Wetenschappen/UMCG

Subjects

MEDIAL PREOPTIC AREA, BARRINGTONS NUCLEUS, media_common.quotation_subject, Urinary Bladder, Wheat Germ Agglutinin-Horseradish Peroxidase Conjugate, Urination, Biology, Periaqueductal gray, BRAIN-STEM, URETHRAL SPHINCTER, Nerve Fibers, Pons, Reflex, medicine, Tegmentum, Animals, Periaqueductal Gray, Spinomesencephalic tract, media_common, Nerve Endings, WGA-HRP, MEDULLA-OBLONGATA, General Neuroscience, Lumbosacral Region, Anatomy, ELECTRICAL-STIMULATION, Spinal cord, LIGHT MICROSCOPY, EMOTIONAL MOTOR SYSTEM, Microscopy, Electron, ELECTRON MICROSCOPY, medicine.anatomical_structure, Spinal Cord, REACTION-PRODUCT, Medulla oblongata, Cats, SPINOMESENCEPHALIC TRACT, RAT, Barrington's Nucleus, SPINAL-CORD, URINARY-BLADDER, Neuroscience, Lumbosacral joint

Abstract

Information concerning the rate of bladder filling is determined by receptors in the bladder wall and conveyed via afferent fibers in the pelvic nerve to sensory neurons in the lumbosacral cord. It was assumed that this information is relayed from the lumbosacral cord to a medial cell group in the dorsolateral pontine tegmentum, called the M-region, the pontine micturition center, or Barrington's nucleus. The M-region, in turn, projects via long descending pathways to the sacral parasympathetic motoneurons. In the present electron microscopic study, it was investigated in cats whether monosynaptic projections from lumbosacral neurons to the M-region indeed exist. Wheat-germ agglutinin-horseradish peroxidase injections were made into the lumbosacral, cord. Many retrogradely labeled dendrites and somata were found in the M-region, but no labeled terminals were found on retrogradely labeled dendrites or somata. Only a small number of anterogradely labeled terminals, which were filled with mainly round vesicles, contacted unlabeled dendrites in the M-region. In contrast, many more anterogradely labeled terminals, which were filled with mainly round and, to a limited extent, dense core vesicles and with asymmetrical synapses, were found on dendrites in the lateral part of the periaqueductal gray (PAG). Previously (Blok and Holstege [1994] Neurosci. Lett. 166:93-96), it was demonstrated that the lateral part of the FAG contains neurons projecting to the M-region. A concept for the central organization of the micturition reflex is presented in which ascending projections from the lumbosacral cord convey information on bladder filling to the FAG. When the bladder contains so much urine that voiding is necessary, the FAG, in turn, triggers the M-region. The M-region, however, also receives afferents from the preoptic area, which might be involved in the final decision to start micturition. (C) 1995 Wiley-Liss, Inc.

Published

1995

30. Glutaminase-like immunoreactivity in rat spinomesencephalic tract cells

Author

Kenneth E. Miller, Robert P. Yezierski, and Takeshi Kaneko

Subjects

Stilbamidines, Central nervous system, Biology, Synaptic Transmission, Midbrain, Rats, Sprague-Dawley, Glutamatergic, Glutaminase, Mesencephalon, Neural Pathways, medicine, Animals, Spinomesencephalic tract, Molecular Biology, Fluorescent Dyes, Neurons, General Neuroscience, Glutamate receptor, Spinal cord, Molecular biology, Immunohistochemistry, Rats, medicine.anatomical_structure, nervous system, Spinal Cord, Axoplasmic transport, Neurology (clinical), Neuroscience, Developmental Biology

Abstract

Retrograde transport of the fluorescent tracer Fluorogold was used in combination with immunohistochemical staining for the enzyme glutaminase to identify putative glutamatergic neurons belonging to the rat spinomesencephalic tract. Glutaminase-like staining in spinal projection neurons suggests that the relay of nociceptive information from the spinal cord to midbrain may involve the excitatory amino acid glutamate.

Published

1993

31. Functional properties of spinomesencephalic tract (SMT) cells in the upper cervical spinal cord of the cat

Author

Robert P. Yezierski and James G. Broton

Subjects

Male, Serotonin, Hot Temperature, Population, Stimulation, Midbrain, Mesencephalon, Physical Stimulation, Medicine, Animals, Spinomesencephalic tract, education, Electrodes, Evoked Potentials, Neurons, education.field_of_study, business.industry, Nociceptors, Anatomy, Antidromic, Anesthesiology and Pain Medicine, Nociception, medicine.anatomical_structure, Neurology, Spinal Cord, Receptive field, Cats, Neurology (clinical), Forelimb, business

Abstract

Response and receptive field properties were evaluated for 62 spinomesencephalic tract cells in the upper cervical spinal cord (C1-C3) of cats anesthetized with sodium pentobarbital and alpha-chloralose. Recordings were made from cells in laminae I-VIII and X contralateral to antidromic stimulating electrodes positioned in the rostral, caudal and intercollicular region of the midbrain. The mean antidromic threshold for all cells was 185 +/- 132 microA, and conduction velocities ranged from 2.3 to 38.6 m/sec. Twelve cells were backfired from both midbrain and diencephalic stimulation sites. Receptive fields ranged from simple, i.e., ipsilateral forelimb or face, to complex, i.e., excitatory and/or inhibitory responses from large portions of the body. Peripheral receptive fields included muscles, joints, cornea, dura, forelimbs, hind limbs, tail, and/or testicles. Five functional classes of cells were observed: (a) wide dynamic range (14 cells); (b) high threshold (2 cells): (c) low threshold (4 cells); (d) deep/tap (11 cells); and (e) non-responsive (31 cells). Eight cells were evaluated for responses to different doses (5-150 micrograms) of intravenous (i.v.) serotonin. Two of the 8 cells exhibited excitatory effects, whereas 2 cells classified as deep/tap and 4 cells classified as non-responsive were not affected. The results of this study have shown the upper cervical component of the spinomesencephalic tract is made up of a heterogenous population of cells involved in the integration of varied inputs from large portions of the body. It is proposed that the large population of SMT cells in the upper cervical spinal cord may be involved in pain mechanisms, especially those related to the affective consequences of acute and chronic pain.

Published

1991

32. Somatosensory Input to the Periaqueductal Gray: A Spinal Relay to a Descending Control Center

Author

Robert P. Yezierski

Subjects

Physics, Thermal stimulation, medicine.anatomical_structure, Nociception, Anesthesia, medicine, Lumbosacral spinal cord, Anatomy, Spinomesencephalic tract, Somatosensory system, Periaqueductal gray

Abstract

The spinomesencephalic tract (SMT) with its varied origins (Mantyh, 1982; Menetrey et al., 1982; Swett et al., 1985; Wiberg and Blomqvist, 1984; Wiberg et al., 1987; Yezierski and Mendez, 1991; Zhang et al., 1990), spinal trajectories (Hylden et al., 1986b; Kerr, 1975; McMahon and Wall, 1985; Yezierski and Schwartz, 1986; Zemlan et al., 1978), and sites of termination (Anderson and Berry, 1959; McMahon and Wall 1985; Mehler, 1969; Morin, 1953; Bjorkeland and Boivie, 1984; Blomqvist and Craig, this volume; Yezierski, 1988) is often described as having a role in nociception (Bowsher, 1976; Mehler, 1969; Willis, 1985; Willis and Coggeshall, 1978; Yezierski, 1988). Consistent with this hypothesis are the responses of SMT cells to noxious mechanical and thermal stimuli (Hylden et al., 1986a; 1989; Menetrey et al., 1980; Yezierski and Schwartz, 1986; Yezierski et al., 1985). Furthermore, recent studies have shown SMT cells in the upper cervical and lumbosacral spinal cord respond to inputs from cutaneous and /or deep structures, including joints, muscles, and viscera (Yezierski and Broton, 1991; Yezierski and Schwartz, 1986; Yezierski et al., 1987; Yezierski, 1990). These observations as well as the varied functions associated with SMT projection targets supports a role of the SMT in sensory, motor and visceral functions.

Published

1991

33. Confirmation of the location of spinothalamic neurons in the cat and monkey by the retrograde transport of horseradish peroxidase

Author

Earl Carstens and Daniel L. Trevino

Subjects

Brain Mapping, Pathology, medicine.medical_specialty, Spinothalamic Tracts, CATS, biology, General Neuroscience, Haplorhini, biology.organism_classification, Horseradish peroxidase, medicine.anatomical_structure, Peroxidases, Thalamic Nuclei, Cats, biology.protein, medicine, Axoplasmic transport, Animals, Neurology (clinical), Spinomesencephalic tract, Molecular Biology, Developmental Biology, Peroxidase

Published

1975

34. The spinomesencephalic tract in the cat: Its cells of origin and termination pattern as demonstrated by the intraaxonal transport method

Author

Anders Blomqvist and Mikael Wiberg

Subjects

Sensation, Biology, Somatosensory system, Parabrachial area, Midbrain, Thalamus, Mesencephalon, Neural Pathways, medicine, Animals, Periaqueductal Gray, Spinomesencephalic tract, Molecular Biology, Brain Mapping, Tectum Mesencephali, General Neuroscience, Superior colliculus, Anatomy, Spinal cord, medicine.anatomical_structure, Spinal Cord, Cats, Axoplasmic transport, Neurology (clinical), Nucleus, Developmental Biology

Abstract

The cells of origin and terminal areas of the feline spinomesencephalic tract were investigated by the intraaxonal transport method. Following injection of wheat germ agglutinin-horseradish peroxidase conjugate into the cervical and lumbar enlargements, anterograde labelling was observed in several regions of the dorsal midbrain. The main terminal areas were the periaqueductal gray matter, the intercollicular nucleus, the posterior pretectal nucleus and the nucleus of Darkschewitsch. In addition, there was a sparse projection to the cuneiform nucleus and the anterior pretectal nucleus. The superior colliculus was virtually devoid of labelling except for a weak termination in the caudal part of the deep layers. Although there was a considerable overlap, the projection from the cervical spinal cord to the periaqueductal gray matter terminated more rostrally than that from the lumbar segments, indicating the presence of a somatotopic organization. The retrograde labelling seen after tracer injection into the midbrain terminal areas revealed that the cells of origin were located mainly in the upper cervical segments and in the cervical and lumbar enlargements; in the latter parts of the cord an overwhelming majority were situated in lamina I, with smaller fractions in laminae IV and V, whereas in the upper cervical segments and in the less densely labelled thoracic and sacral segments a much larger proportion of the peroxidase-positive neurons were found in the deep laminae. About 75% of the labelled cells were located contralateral to the injection site. The functional implication of the present results are discussed in relation to somatosensory activity in the mesencephalon. It is suggested that several regions of the dorsal midbrain have an important somesthetic function including that of pain.

Published

1984

35. The origin of the spinomesencephalic tract in the rat: An anatomical study using the retrograde transport of horseradish peroxidase

Author

Jean Marie Besson, D. Menetrey, A. Chaouch, and Denise Binder

Subjects

White matter, Spinothalamic tract, medicine.anatomical_structure, Dorsal column nuclei, General Neuroscience, Superior colliculus, medicine, Spinomesencephalic tract, Anatomy, Grey matter, Biology, Spinal cord, Parabrachial area

Abstract

An anatomical technique based on the retrograde transport of horseradish peroxidase (HRP) was used to investigate the projections of spinal cord neurons to the mesencephalic tegmentum in the rat. Restricted unilateral injections were confined to central grey, cuneiformis areas, and superior colliculus. Injections into all these loci produced labeling in similar spinal areas. Only quantitative differences were noted. In the spinal grey matter, numerous labeled cells were regularly encountered in the marginal zone, the lateral part of the neck of the dorsal horn, and the dorsal grey commissure. Projections from the marginal zone and neck of the dorsal horn were predominantly contralateral. In the white matter, a pronounced bilateral labeling was observed in the nucleus of the dorsolateral funiculus, thus confirming our previous electrophysiological findings (Menetrey et al., '80). This distribution of labeled cells was commonly observed throughout the whole length of the cord. Additional sites of projecting cells have also been identified at the most rostral levels (obex, C1, C2). They mostly derived from spinal extensions of the dorsal column nuclei and lateral cervical nucleus contralaterally; from the lateral ventral horns bilaterally and from the nucleus commissuralis ipsilaterally. This study is thus a clear confirmation that the mesencephalic tegmentum constitutes a target for various somatosensory inputs originating from spinal cord, dorsal column nuclei, and lateral cervical nucleus. Moreover, from these results together with those obtained for the spinothalamic tract in the rat, it appears that marginal and dorsolateral funiculus neurons preferentially project to the mesencephalic tegmentum. The importance of marginal zone projections underlines the involvement of the spinomesencephalic tract in pain mechanisms.

Published

1982

36. Laminar origins of spinal projection neurons to the periaqueductal gray of the rat

Author

Rita P.C. Liu

Subjects

Neurons, Afferent Pathways, Chemistry, General Neuroscience, Retrograde axoplasmic transport, Brain, Rats, Inbred Strains, Laminar flow, Anatomy, Axonal Transport, Periaqueductal gray, Rats, Lumbosacral region, medicine.anatomical_structure, Spinal Cord, nervous system, Projection (mathematics), medicine, Animals, Neurology (clinical), Spinomesencephalic tract, Molecular Biology, Neuroscience, Fluorescent Dyes, Developmental Biology

Abstract

Attempts were made to determine the cells of origin of the spinal projections to the PAG using retrograde axoplasmic transport techniques of HRP and fluorescent markers. Following injections limited to the lateroventral subnucleus of the PAG, labels were transported to the contralateral laminae I, III, V, VII and X primarily. A striking number of labeled neurons were found in the lumbosacral region. Discussion followed on the possible dichotomic axonal projections of the labeled spinal neurons.

Published

1983

37. Spinal and trigeminal projections to the nucleus of the solitary tract: A possible substrate for somatovisceral and viscerovisceral reflex activation

Author

D. Menétrey and Allan I. Basbaum

Subjects

Trigeminal nerve, Spinothalamic tract, General Neuroscience, Solitary nucleus, Solitary tract, Anatomy, Biology, Spinal cord, medicine.anatomical_structure, Dorsal column nuclei, medicine, Spinomesencephalic tract, Nucleus, Neuroscience

Abstract

This study used the retrograde transport of a protein-gold complex to examine the distribution of spinal cord and trigeminal nucleus caudalis neurons that project to the nucleus of the solitary tract (NST) in the rat. In the spinal grey matter, retrogradely labeled cells were common in the marginal zone (lamina I), in the lateral spinal nucleus of the dorsolateral funiculus, in the reticular part of the neck of the dorsal horn (lamina V), around the central canal (lamina X), and in the region of the thoracic and sacral autonomic cell columns. The pattern of labeling closely resembled that seen for the cells at the origin of the spinomesencephalic tract and shared some features with that of the spinoreticular and spinothalamic tracts. Labeled cells in lamina IV of the dorsal horn were only observed when injections spread dorsally, into the dorsal column nuclei, and are thus not considered to be at the origin of the spinosolitary tract. They are probably neurons of the postsynaptic fibers of the dorsal column. Retrogradely labeled cells were also numerous in the superficial laminae of the trigeminal nucleus caudalis, through its rostrocaudal extent. The pattern of marginal cell labeling appeared to be continuous with that of labeled neurons in the paratrigeminal nucleus, located in the descending tract of trigeminal nerve. Since the NST is an important relay for visceral afferents from both the glossopharyngeal and vagus nerves, we suggest that the spinal and trigeminal neurons that project to the NST may be part of a larger system that integrates somatic and visceral afferent inputs from wide areas of the body. The projections may underlie somatovisceral and/or viscerovisceral reflexes, perhaps with a significant afferent nociceptive component.

Published

1987

38. The cells of origin of the primate spinothalamic tract

Author

W. D. Willis, D. R. Kenshalo, and R. B. Leonard

Subjects

Brain Mapping, Spinothalamic tract, Spinothalamic Tracts, General Neuroscience, Thalamus, Cell Count, Haplorhini, Anatomy, Biology, Spinal cord, Midbrain, Conus medullaris, Macaca fascicularis, medicine.anatomical_structure, Species Specificity, Cats, medicine, Axoplasmic transport, Animals, Spinomesencephalic tract, Lateral funiculus

Abstract

Spinothalamic tract cells in the lumbar, sacral and caudal segments of the primate spinal cord were labelled by the retrograde transport of horseradish peroxidase (HRP) injected into the thalamus. The laminar distribution of stained spinothalamic cells in the lumbosacral enlargement differed according to whether the HRP was injected into the lateral or the medial thalamus. Lateral injections labelled cells in most laminae, but the largest numbers of cells were in laminae I and V. The highest concentrations of cells labelled from the medial thalamus were in laminae VI-VIII. Ninety percent or more of the stained spinothalamic cells in the lumbosacral enlargement were contralateral to the injection site. In the conus medullaris stained spinothalamic cells were most numerous in laminae I, V and VI following lateral thalamic injections of HRP. Many of the cells of the conus were in Stilling's nucleus. Twenty-three percent of the cells in the conus were ipsilateral to the injection site in the lateral thalamus. Only a few cells in the conus were labelled by medial thalamic injections. The total number of spinothalamic cells from L5 caudally was estimated to be at least 1,200-2,500. An injection of HRP into the midbrain resulted in a laminar distribution of labelled cells much like that produced by a lateral thalamic injection. The types of spinothalamic tract cells and the sizes of their somata were determined for different laminae. The cells types resemble those already described from Golgi and other studies of the spinal cord gray matter. The spinothalamic tract cells in lamina I included Waldeyer cells and numerous small fusiform, pyriform or triangular cells. Those in lamina II included limitrophe and central cells. Spinothalamic cells in lamina III were central cells. Most of the labelled cells in laminae IV-X were polygonal, although there were also flattened cells in these layers. The smallest spinothalamic cells were in laminae I-III, while the largest were in laminae V and VII-IX. Spinothalamic cells in the conus medullaris included cells like those in the lumbosacral enlargement, but also a special cell type in Stilling's nucleus. Some cells in the conus had dendrites that crossed the midline. Spinothalamic axons could sometimes be traced to the ventral white commissure within one or a few sections. In longitudinal sections, most labelled axons were in the ventral part of the lateral funiculus on the side of the injection, although a few were in the ventral funiculus or on the contralateral side. The axons were widely dispersed, and a few were located adjacent to the pia-glial membrane.

Published

1979

39. Physiology and morphology of the lamina i spinomesencephalic projection

Author

D. R. Haruhide Hayashi, Ronald Dubner, Gary J. Bennett, and Janice L.K. Hylden

Subjects

Afferent Pathways, Lamina, General Neuroscience, Thalamus, Neural Conduction, Nociceptors, Pain, Anatomy, Biology, Periaqueductal gray, Parabrachial area, Antidromic, Midbrain, medicine.anatomical_structure, Spinal Cord, nervous system, Mesencephalon, Receptive field, Cats, Reaction Time, medicine, Animals, Spinomesencephalic tract, Evoked Potentials, Neuroscience

Abstract

We have examined the physiological and morphological characteristics of spinal dorsal horn lamina I neurons with projections to the midbrain in the cat by combining physiological recording of neurons with the intracellular injection of HRP. Lamina I spinomesencephalic neurons were antidromically activated from the region that included the cuneiform nucleus and lateral periaqueductal gray at the intercollicular level. The majority of mesencephalic projection neurons (50 of 55) responded exclusively to noxious stimulation (nociceptive-specific) of their peripheral receptive fields. Lamina I spinomesencephalic neurons were activated from both the ipsilateral and contralateral midbrain and had slow antidromic conduction velocities (1 to 18 m/second). We identified eight cells with projections to both the midbrain and the thalamus and eight cells that were antidromically activated only from the thalamus. Intracellular injection of HRP revealed that lamina I spinomesencephalic neurons were of diverse morphological types, but generally had extensive, rostrocaudally oriented, dendritic arbors confined to lamina I and the overlying white matter. Axons were observed on nine of the HRP-filled spinomesencephalic neurons; five of the axons issued collateral branches. The morphological characteristics of these neurons did not appear to correlate with functional categories (i.e., wide-dynamic-range- or nociceptive-specific-type neurons). The large number of nociceptive-specific neurons with projections to the midbrain and the interconnections of these midbrain sites with hypothalamic and limbic structures suggest that the lamina I spinomesencephalic pathway plays an important role in the autonomic and affective responses to pain.

Published

1986

40. Spinal neurons which project to the periaqueductal gray and the medullary reticular formation via axon collaterals: a double-label fluorescence study in the rat

Author

Rita P.C. Liu and Constance M. Pechura

Subjects

Spinoreticular tract, Amidines, Reticular formation, Periaqueductal gray, Ganglia, Spinal, Neural Pathways, medicine, Animals, Periaqueductal Gray, Spinomesencephalic tract, Axon, Molecular Biology, Brain Mapping, Chemistry, Reticular Formation, General Neuroscience, Anatomy, Spinal cord, Axons, Rats, medicine.anatomical_structure, Microscopy, Fluorescence, nervous system, Axoplasmic transport, Benzimidazoles, Neurology (clinical), Neuron, Developmental Biology

Abstract

Fluorescent retrograde double-labeling methods were used in which Fast blue and Nuclear yellow or Diamidino yellow dihydrochloride were injected into the midbrain periaqueductal gray (PAG) and medullary reticular formation (MRF). Double-labeled neurons were most frequently observed in the lateral part of lamina V, in laminae VII, VIII and X and in the lateral cervical and lateral spinal nuclei. The data demonstrate that some spinal neurons project to both the PAG and the MRF via axon collaterals.

Published

1986

41. Spinomesencephalic tract: Projections from the lumbosacral spinal cord of the rat, cat, and monkey

Author

Robert P. Yezierski

Subjects

Wheat Germ Agglutinins, Red nucleus, Wheat Germ Agglutinin-Horseradish Peroxidase Conjugate, Biology, Reticular formation, Periaqueductal gray, Midbrain, Species Specificity, Mesencephalon, medicine, Animals, Spinomesencephalic tract, Pretectal area, Horseradish Peroxidase, Afferent Pathways, Brain Mapping, General Neuroscience, Superior colliculus, Anatomy, Spinal cord, Rats, Macaca fascicularis, medicine.anatomical_structure, Spinal Cord, nervous system, Cats, Neuroscience

Abstract

Anterograde transport of wheat germ agglutinin conjugated to horseradish peroxidase was used to determine the terminal domain of the projection from the lumbosacral spinal cord to the midbrain in the rat, cat, and monkey. Results have shown that several midbrain regions receiving afferent input from this level of the spinal cord are common to the three species examined. Structures innervated by this projection were located throughout the full rostrocaudal extent of the midbrain. The strongest projections were to the intercollicular region and caudal midbrain contralateral to injection sites in the spinal cord. Terminal labeling in the rostral midbrain, except that observed in the nucleus of Darkschewitsch, was substantially less than that observed at more caudal midbrain levels. Structures receiving the strongest input from the spinal cord included the central gray, nucleus cuneiformis, the deep and intermediate layers of the superior colliculus, and the intercollicular nucleus. Other structures receiving afferent input from the lumbosacral spinal cord included the anterior and posterior pretectal nuclei, red nucleus, Edinger-Westphal nucleus, interstitial nucleus of Cajal, and the mesencephalic reticular formation. It is concluded that the spinal projection to the midbrain is a multicomponent projection consisting of several pathways terminating in discrete midbrain regions. Considering the diverse functions associated with midbrain regions receiving spinal input and the response and receptive field properties of cells belonging to this pathway, the results of the present study are discussed in relation to the potential role of the spinomesencephalic tract in somatic, visceral, and motor function.

Published

1988

42. Laminar origins of spinothalamic projections in the cat as determined by the retrograde transport of horseradish peroxidase

Author

Earl Carstens and Daniel L. Trevino

Subjects

Spinothalamic tract, CATS, General Neuroscience, Thalamus, Anatomy, Biology, Horseradish peroxidase, Lumbar enlargement, medicine.anatomical_structure, nervous system, Cervical enlargement, medicine, Axoplasmic transport, biology.protein, Spinomesencephalic tract

Abstract

The method of retrograde axonal transport of horseradish peroxidase (HRP) was used to identify the locations of cells of origin of the spinothalamic tract in the cat. Injections of from 0.2–3.0 μl of 30% HRP were made unilaterally in various regions of the somatosensory thalamus. Massive injections of the caudal thalamus in several cats showed the spinothalamic cells of origin to be located mainly in laminae I, VII and VIII in the lumbar enlargement, and in laminae I, V and VII–VIII in the cervical enlargement. Small injections of HRP were made into the three major spinothalamic terminal zones in the thalamus, to determine the laminar origin(s) of the spinal projections to each zone. Neurons in lamina I in both cervical and lumbar enlargements were found to project almost exclusively to the rostral VB-caudal VL border zone. A small number of neurons in laminae VII and VIII also project there but a larger number project to the intralaminar region. Neurons projecting to the PO regions were located mainly in laminae IV and V. This anatomical segregation of thalamic afferents probably reflects a functional segregation of input, since the functional properties of spinal neurons vary according to their laminar location. Comparison of these data with the differential projection spinothalamic neurons in the rat and monkey indicate that it is unlikely that the proposed “paleo-” and “neospinothalamic” systems would arise from anatomically separate groups of spinal neurons.

Published

1978

43. The termination of spinomesencephalic fibers in cat

Author

J. Boivie and M. Björkeland

Subjects

Superior Colliculi, Embryology, Pan troglodytes, Red nucleus, Periaqueductal gray, Oculomotor nucleus, Nerve Fibers, Mesencephalon, medicine, Animals, Humans, Periaqueductal Gray, Spinomesencephalic tract, Horseradish Peroxidase, Medial geniculate nucleus, Chemistry, Superior colliculus, Haplorhini, Opossums, Cell Biology, Anatomy, Spinal cord, Inferior Colliculi, Rats, medicine.anatomical_structure, Spinal Cord, Cats, Lateral funiculus, Developmental Biology

Abstract

The projections to the midbrain from the spinal cord have been investigated in the cat with the degeneration technique and by using horseradish peroxidase (HRP) as an anterograde tracer. Two types of spinal cord lesions were performed: 1) Cordotomies at cervical or thoracic levels transecting the ventral and lateral funiculi. 2) Transections of the ventral, ventrolateral, dorsolateral or dorsal funiculus, respectively, at cervical levels. In the anterograde tracing experiments HRP was injected into the spinal cord at cervical, lumbar or sacral levels. The results show large projections to the lateral and ventrolateral parts of the periaqueductal gray (PAG1), the posterior pretectal nucleus (PP) and the nucleus of Darkschewitsch (D). More moderate projections go to the medial division of the periaqueductal gray (PAGm), the cuneiform nucleus (CF), the mesencephalic reticular formation (MRF), lateral part of the deep layer of the superior colliculus (SP) and magnocellular medial geniculate nucleus (GMmc), while scattered spinal fibers are present in the dorsal part of the periaqueductal gray (PAGd), the external inferior collicular nucleus (IX), the intermediate layer of the superior colliculus (SI), the lateral part of the red nucleus (NR) and in the Edinger-Westphal portion of the oculomotor nucleus (3). In addition a few fibers are present in the interstitial nucleus of Cajal (CA) and anterior pretectal nucleus (PAc). The results indicate that at midcervical levels most of the spinomesencephalic fibers ascend in the ventral funiculus, with only a moderate fraction ascending in the ventral half of the lateral funiculus. Almost no fibers ascend in the dorso-lateral funiculus and none appear to pass in the dorsal funiculus. No distinct somatotopic pattern was found in the spinomesencephalic projections, but more fibers from cervicobrachial segments terminate in the rostral than in the caudal parts of the terminal fields in PAG, CF, SP and IX, while the lumbar fibers were more numberous in the caudal parts. PP seems to receive spinal fibers mainly from the caudal half of the cord.

Published

1984

44. Responses of primate spinothalamic tract neurons to natural stimulation of hindlimb

Author

Joe Dan Coulter, D. L. Trevino, R. A. Maunz, and William D. Willis

Subjects

Spinothalamic tract, Spinothalamic Tracts, biology, Physiology, Muscles, General Neuroscience, Neural Conduction, Action Potentials, Stimulation, Haplorhini, Hindlimb, medicine.anatomical_structure, Physical Stimulation, biology.animal, medicine, Animals, Macaca, Primate, Spinomesencephalic tract, Diencephalon, Mechanoreceptors, Neuroscience, Skin

Published

1974

45. Lamina I Spinomesencephalic Neurons in the Cat Ascend via the Dorsolateral Funiculi

Author

Haruhide Hayashi, Janice L.K. Hylden, and Gary J. Bennett

Subjects

Male, Afferent Pathways, Lamina, biology, Physiology, General Neuroscience, Anatomy, Spinal cord, Horseradish peroxidase, Parabrachial area, Midbrain, chemistry.chemical_compound, medicine.anatomical_structure, Agglutinin, Spinal Cord, nervous system, chemistry, Mesencephalon, Cats, biology.protein, medicine, Animals, Colchicine, Female, Spinomesencephalic tract

Abstract

Spinomesencephalic tract neurons in the cat spinal cord were retrogradely labeled following injections of wheatgerm agglutinin conjugated to horseradish peroxidase into the region of the midbrain parabrachial area. Labeled cell bodies were concentrated in lamina I, bilaterally. A more scattered distribution was observed in lamina V and deeper laminae. Bilateral lesions of the dorsolateral funiculus (DLF) at thoracic levels eliminated labeling of lamina I neurons below the lesions, but had no effect on the labeling of the neurons in deeper laminae. Injections of colchicine into the spinal white matter caused the label to accumulate intra-axonally and revealed labeled axons bilaterally in the DLF and ipsilaterally in the ventrolateral and ventral funiculi.

Published

1986

46. The ventral spinothalamic tract and other ascending systems of the ventral funiculus of the spinal cord

Author

Frederick W.L. Kerr

Subjects

Spinothalamic Tracts, Red nucleus, Thalamus, Biology, Olivary Nucleus, Midbrain, Mesencephalon, Pons, medicine, Animals, Spinomesencephalic tract, Diencephalon, Medulla Oblongata, General Neuroscience, Superior colliculus, Lateral spinothalamic tract, Geniculate Bodies, Anatomy, Medial geniculate body, Spinal cord, Macaca mulatta, medicine.anatomical_structure, Spinal Cord, Thalamic Nuclei, Macaca, Neuroscience, Brain Stem

Abstract

The ascending degeneration resulting from experimental lesions of the ventral funiculus of the spinal cord of Macaca mulatta has been studied using the Nauta technique and its variants. The ventral spinothalamic tract is shown to be an independent entity with respect to the lateral spinothalamic tract; its fibers are widely distributed in the ventral funiculus and it establishes connections with the brain stem and thalamus which are analogous but not identical to those of the latter. Its role in the relay of nociceptive input is discussed in view of the similarity in hodology of the two systems and it is proposed that it may be responsible for the failure of anterolateral cordotomy to control pain on a long term basis. Other ascending systems in the ventral funiculus include the spino-olivary and spino-reticular tracts, as well as minor connections to the N. of Edinger-Westphal, the red nucleus and the superior colliculus. The projections from the ventral quadrant of the spinal cord to the brain stem are almost entirely ipsilateral until the rostral mesencephalon is reached, at which level the N. of Darkschewitz receives both ipsilateral and crossed input; the magnocellular nucleus of the medial geniculate body receives a small contribution which is mainly ipsilateral. In the thalamus the VPL receives predominantly ipsilateral projections while the input to the paralaminar nuclei is only slightly less pronounced contralaterally than ipsilaterally.

Published

1975

47. neuropeptides in long ascending spinal tract cells in the rat: evidence for parallel processing of ascending information

Author

J. Leak, J. de Pommery, and D. Menétrey

Subjects

Male, Spinothalamic tract, Afferent Pathways, Spinoreticular tract, General Neuroscience, Vasoactive intestinal peptide, Neuropeptides, Neuropeptide, Substance P, Rats, Inbred Strains, Anatomy, Dynorphin, Biology, Rats, chemistry.chemical_compound, medicine.anatomical_structure, chemistry, Spinal Cord, medicine, Axoplasmic transport, Animals, Spinomesencephalic tract, Neurons, Afferent

Abstract

A study has been made of the involvement of spinal peptidergic neurons in ascending tracts at lumbar-sacral levels in rats, by combining the retrograde transport of a protein-gold complex with immunocytochemistry. Ten neuropeptides have been considered for their presence in the cells of origin of the following six ascending tracts, including some involved in pain transmission: the spinosolitary tract, the medial and lateral spinoreticular tracts, the spinomesencephalic tract, the spinothalamic tract and the postsynaptic dorsal column tract. Although there was overlap in the distribution of several of the types of peptidergic cells and some ascending tract cells only a very small percentage of long ascending tract cells were found to contain neuropeptides. Most (90%) of those peptidergic ascending tract cells, however, were clearly congregated in two distinct spinal regions: the lateral spinal nucleus and the region surrounding the central canal (including lamina X). Ascending tract cells in both of these regions contained a wide variety of neuropeptides. Immunoreactivities for a total of seven different peptides were seen. The lateral spinal nucleus had the highest percentage of neuropeptide containing ascending tract cells; cells of all the four populations of peptidergic neurons lying in this region were involved in supraspinal projections; they stained for vasoactive intestinal polypeptide, bombesin, substance P or dynorphin and their axons projected in the spinomesencephalic, spinoreticular and spinosolitary tracts. The region surrounding the central canal contained bombesin-, enkephalin-, cholecystokinin- and somatostatin-immunoreactive ascending tract cells; these cells were found at the origin of the spinothalamic, spinomesencephalic, spinoreticular and spinosolitary tracts. In this region only the cells staining for substance P were not involved in supraspinal projections. The peptidergic ascending tract cells in other spinal regions were few; they were found in either lamina I or lateral part of lamina V. Ascending tract lamina I cells reacted for dynorphin or vasoactive intestinal polypeptide and their axons projected in the spinosolitary and spinomesencephalic tracts. Ascending tract lamina V cells reacted for somatostatin and were found at the origin of the medial component of the spinoreticular tract. It is proposed that peptidergic ascending tract cells form minor but distinct subgroups within each ascending tract. Each of the ascending tracts are divisible into peptide- and nonpeptide-containing groups of cells which convey information in a parallel fashion.(ABSTRACT TRUNCATED AT 400 WORDS)

Published

1988

48. Neurons at the origin of the medial component of the bulbopontine spinoreticular tract in the rat: an anatomical study using horseradish peroxidase retrograde transport

Author

D. Menetrey, Denise Binder, A. Chaouch, and J.M. Besson

Subjects

Nucleus raphe magnus, Spinothalamic tract, Afferent Pathways, Brain Mapping, Spinocerebellar tract, Spinoreticular tract, General Neuroscience, Reticular Formation, Rats, Inbred Strains, Anatomy, Biology, Spinal cord, Rats, Lateral reticular nucleus, medicine.anatomical_structure, Species Specificity, Spinal Cord, Pons, Reticular connective tissue, medicine, Cats, Animals, Spinomesencephalic tract

Abstract

An anatomical technique based on the retrograde transport of horseradish peroxidase (HRP) was used to investigate the projections of spinal cord neurons to the reticular formations in the rat. Both large and restricted injections were staggered all along the bulbar and pontine levels, involving the nucleus gigantocellularis, the nuclei reticularis pontis, pars oralis and caudalis and in some cases the nucleus raphe magnus. Labeled cells were constantly encountered in the reticular part of the neck of the dorsal horn throughout the whole length of the cord, mainly contralateral to the central core of the injection site. This area was taken as the equivalent of lamina V in the cat. Other labeled cells were observed in the medial parts of the intermediate and ventral horns, in areas considered similar to laminae VII and VIII in the cat. The two most rostral cervical segments were characterized by an additional bilateral projection originating from the dorsolateral part of ventral horns. Thus, this study is a clear confirmation that the bulbopontine reticular formations constitute a target for various somatosensory inputs originating in spinal cord. It demonstrates that the medial spinoreticular tract (mSRT) differs from the other main ascending tracts by the absence of projections from (1) superficial layers and nucleus of the dorsolateral funiculus contrary to the spinomesencephalic tract; (2) ventromedial zone of the lumbar dorsal horn unlike the spinothalamic tract; (3) the neck of the dorsal horn in its medial portion contrary to the spinoreticular component reaching the lateral reticular nucleus; and (4) central cervical nucleus and Clarke's columns, unlike the spinocerebellar tracts. The difficulty in demonstrating retrograde labeling from discrete injections could result from the fact that mSRT neurons have sparsely ramified collaterals on their terminal zones.

Published

1983

49. Response and receptive-field properties of spinomesencephalic tract cells in the cat

Author

Robert P. Yezierski and R. H. Schwartz

Subjects

Physiology, Pain, Biology, Periaqueductal gray, Efferent Pathways, Functional Laterality, Mesencephalon, Physical Stimulation, medicine, Animals, Spinomesencephalic tract, Neurons, Midbrain reticular formation, General Neuroscience, Superior colliculus, Electric Conductivity, Nociceptors, Spinal cord, Electric Stimulation, Antidromic, Kinetics, medicine.anatomical_structure, Nociception, Spinal Cord, Receptive field, Organ Specificity, Cats, Neuroscience

Abstract

Recordings were made from 90 identified spinomesencephalic tract (SMT) cells in the lumbosacral spinal cord of cats anesthetized with alpha-chloralose and pentobarbital sodium. Recording sites were located in laminae I-VIII. Antidromic stimulation sites were located in different regions of the rostral and caudal midbrain including the periaqueductal gray, midbrain reticular formation, and the deep layers of the superior colliculus. Twelve SMT cells were antidromically activated from more than one midbrain level or from sites in the medial thalamus. The mean conduction velocity for the population of cells sampled was 45.2 +/- 21.4 m/s. Cells were categorized based on their responses to graded intensities of mechanical stimuli and the location of excitatory and/or inhibitory receptive fields. Four major categories of cells were encountered: wide dynamic range (WDR); high threshold (HT); deep/tap; and nonresponsive. WDR and HT cells had excitatory and/or inhibitory receptive fields restricted to the ipsilateral hindlimb or extending to other parts of the body including the tail, forelimbs, and face. Some cells had long afterdischarges following noxious stimulation, whereas others had high rates of background activity that was depressed by nonnoxious and noxious stimuli. Deep/tap cells received convergent input from muscle, joint, or visceral primary afferent fibers. The placement of mechanical lesions at different rostrocaudal levels of the cervical spinal cord provided information related to the spinal trajectory of SMT axons. Six axons were located contralateral to the recording electrode in the ventrolateral/medial or lateral funiculi while two were located in the ventrolateral funiculus of the ipsilateral spinal cord. Stimulation at sites used to antidromically activate SMT cells resulted in the inhibition of background and evoked responses for 22 of 25 cells tested. Inhibitory effects were observed on responses evoked by low/high intensity cutaneous stimuli and by the activation of joint or muscle primary afferent fibers. Based on the response and receptive-field properties of SMT cells it is suggested that the SMT may have an important role in somatosensory mechanisms, particularly those related to nociception.

Published

1986

50. The ascending input to the midbrain periaqueductal gray of the primate

Author

Patrick W. Mantyh

Subjects

Superior Colliculi, Biology, Periaqueductal gray, Pons, medicine, Animals, Periaqueductal Gray, Spinomesencephalic tract, Saimiri, Nucleus raphe magnus, Neurons, Afferent Pathways, Medulla Oblongata, General Neuroscience, Superior colliculus, Reticular Formation, Spinal trigeminal nucleus, Anatomy, Spinal cord, Inferior Colliculi, medicine.anatomical_structure, Nociception, nervous system, Spinal Cord, Raphe Nuclei, Locus Coeruleus, Brainstem, Trigeminal Nucleus, Spinal, Neuroscience, Brain Stem

Abstract

To obtain a comprehensive map of the brainstem and spinal cord areas that project to the mesencephalic central gray small injections of hors-radish peroxidase were made into various regions of the periaqueductal gray in a series of monkeys. Despite the fact that different regions of the central gray were injected in separate animals, the majority of the brainstem areas containing retrogradely filled neurons remained the same. Labeled neurons were observed in the superior colliculus, periaqueductal gray, lateral parabrachial, locus coeruleus, nucleus raphe magnus and pallidus, and a variety of brainstem reticular nuclei. In contrast to labeled brainstem areas, where labeled neurons were present predominantly ipsilateral to the injection site, the spinal trigeminal nucleus pars caudalis and the spinal cord displayed labeled cells chiefly on the side contralateral to the injection. Also in contrast to the labeled brainstem sites, where medial and lateral injection sites produced a similar pattern of labeling, medial injections in the PAG labeled almost exclusively neurons in the deep laminae (V-X) in the spinal trigeminal nucleus pars caudalis and spinal cord while more lateral injections labeled neurons in both the deep (V-X) and superficial (I) laminae. No consistent differences were noted in the location of labeled neurons in either brainstem or spinal sites after dorsal vs. ventral injections or caudal vs. rostral injection sites. The present study has demonstrated that the central gray receives afferent projections from a number of brainstem and spinal areas which are known to be involved in the modulation andor conduction of nociception, while other inputs are probably involved in the regulation of visceral functions. These data support the hypothesis that the mesencephalic periaqueductal gray functions as a visceral, nociceptive, and cognitive integrator.

Published

1982