Showing papers on "Somatosensory system published in 1991"

Sensory mechanisms of the spinal cord

Abstract: 1 Introduction.- 2 Peripheral Nerves and Sensory Receptors.- 3 Dorsal Root Ganglion Cells and Their Processes.- 4 Structure of the Dorsal Horn.- 5 Functional Organization of Dorsal Horn Interneurons.- 6 Ascending Sensory Pathways in the Cord White Matter.- 7 Sensory Pathways in the Dorsal Funiculus.- 8 Sensory Pathways in the Dorsal Lateral Funiculus.- 9 Sensory Pathways in the Ventral Quadrant.- 10 The Sensory Channels.- References.

Multiple representations of pain in human cerebral cortex

Abstract: The representation of pain in the cerebral cortex is less well understood than that of any other sensory system. However, with the use of magnetic resonance imaging and positron emission tomography in humans, it has now been demonstrated that painful heat causes significant activation of the contralateral anterior cingulate, secondary somatosensory, and primary somatosensory cortices. This contrasts with the predominant activation of primary somatosensory cortex caused by vibrotactile stimuli in similar experiments. Furthermore, the unilateral cingulate activation indicates that this forebrain area, thought to regulate emotions, contains an unexpectedly specific representation of pain.

Potentials evoked in human and monkey cerebral cortex by stimulation of the median nerve. A review of scalp and intracranial recordings.

Abstract: Somatosensory evoked potentials (SEPs) are generated in afferent pathways, subcortical structures and various regions of cerebellar and cerebral cortex by stimulation of somatic receptors or electrical stimulation of peripheral nerves. This review summarizes current knowledge of SEPs generated in cerebral cortex by stimulation of the median nerve, the most common form of stimulation for human research and clinical investigations. Major sources of data for the review are intracranial recordings obtained from patients during diagnostic or neurosurgical procedures, and similar recordings in monkeys. Short-latency cortical SEPs in the 20-40 ms latency range consist of P20 and N30, recorded from motor cortex and frontal scalp; P25 and N35, recorded from cortex near the central sulcus and central scalp; and N20 and P30, recorded from somatosensory cortex and parietal scalp. Several lines of evidence including cortical surface and intracerebral recordings, neuromagnetic recordings and lesion studies in humans and monkeys, strongly support the conclusion that these potentials are generated in contralateral somatosensory cortex in areas 3b and 1, in contrast to the conclusion of many previous studies that SEPs recorded from the frontal scalp are generated in motor cortex and other frontal lobe areas. These potentials are primarily mediated by cutaneous afferents of the dorsal column-medial lemniscal system; the contribution of muscle afferents has not been completely resolved but appears to be small. There is currently no evidence that short-latency SEPs are generated in cortex other than primary somatosensory cortex. Recordings from the vicinity of the second somatosensory area, from the supplementary motor and sensory areas and from surface cortex other than sensorimotor cortex have not detected reliable short-latency activity, although some of these regions generate long-latency potentials. Consequently, short-latency SEPs recorded from the scalp are similar to those recorded from the surface of sensorimotor cortex. Old World monkeys such as Macaca mulatta and M. fascicularis provide an excellent model for human short-latency SEPs. All the potentials described above in humans have corresponding monkey analogues, with similar distributions over the cortical surface. The squirrel monkey, a New World species, exhibits the same potentials, but due to the different morphology of sensorimotor cortex, the surface distribution of SEPs is quite different.

Autonomic responses and efferent pathways from the insular cortex in the rat.

Abstract: The anatomical distribution of autonomic, particularly cardiovascular, responses originating in the insular cortex was examined by using systematic electrical microstimulation. The localization of these responses to cell bodies in the insular cortex was demonstrated by using microinjection of the excitatory amino acid, D,L-homocysteic acid. The efferents from the cardiovascular responsive sites were traced by iontophoretic injection of the anterograde axonal tracer Phaseoleus vulgaris leucoagglutinin (PHA-L). Two distinct patterns of cardiovascular response were elicited from the insular cortex: an increase in arterial pressure accompanied by tachycardia or a decrease in arterial pressure with bradycardia. The pressor responses were obtained by stimulation of the rostral half of the posterior insular cortex while depressor sites were located in the caudal part of the posterior insular area. Both types of site were primarily located in the dysgranular and agranular insular cortex. Gastric motility changes originated from a separate but adjacent region immediately rostral to the cardiovascular responsive sites in the anterior insular cortex. Tracing of efferents with PHA-L indicated a number of differences in connectivity between the pressor and depressor sites. Pressor sites had substantially more intense connections with other limbic regions including the infralimbic cortex, the amygdala, the bed nucleus of the stria terminalis and the medial dorsal and intralaminar nuclei of the thalamus. Alternatively, the depressor region of the insular cortex more heavily innervated sensory areas of the brain including layer I of the primary somatosensory cortex, a peripheral region of the sensory relay nuclei of the thalamus and the caudal spinal trigeminal nucleus. In addition, there were topographical differences in the projection to the lateral hypothalamic area, the primary site of autonomic outflow for these responses from the insular cortex. These differences in connectivity may provide the anatomic substrate for the specific cardiovascular responses and behaviors integrated in the insular cortex.

Potential of visual cortex to develop an array of functional units unique to somatosensory cortex

Abstract: The identification of specialized areas in the mammalian neocortex, such as the primary visual or somatosensory cortex, is based on distinctions in architectural and functional features. The extent to which certain features that distinguish neocortical areas in rats are prespecified or emerge as a result of epigenetic interactions was investigated. Late embryonic visual cortex transplanted to neonatal somatosensory cortex was later assayed for "barrels," anatomically identified functional units unique to somatosensory cortex, and for boundaries of glycoconjugated molecules associated with barrels. Barrels and boundaries form in transplanted visual cortex and are organized in an array that resembles the pattern in the normal barrelfield. These findings show that different regions of the developing neocortex have similar potentials to differentiate features that distinguish neocortical areas and contribute to their unique functional organizations.

Corticostriatal transformations in the primate somatosensory system. Projections from physiologically mapped body-part representations.

Abstract: 1. The basal ganglia of primates receive somatosensory input carried largely by corticostriatal fibers. To determine whether map-transformations occur in this corticostriatal system, we investigate...

Anterior and Posterior Association Cortex Contributions to the Somatosensory P300

Abstract: A P300 (P3)-evoked response is generated in a variety of mammalian species upon detection of significant environmental events. The P3 component has been proposed to index a neural system involved in attention and memory capacity. We investigated the contribution of anterior and posterior association cortex to somatosensory P3 generation. Somatosensory event-related potentials (ERPs) were recorded in controls (n = 10) and patients with unilateral lesions in temporal-parietal junction (n = 8), lateral parietal cortex (n = 8), or dorsolateral frontal cortex (n = 10). Subjects pressed a button to mechanical taps of the fifth finger (targets; p = 0.12), randomly interposed in sequences of taps to the second (standards; p = 0.76) and the third or fourth finger (tactile novels; p = 0.06). Occasional shock stimuli were delivered to the wrist (shock novels; p = 0.06). The scalp-recorded P3 was differentially affected by anterior and posterior association cortex lesions. Subjects with temporal-parietal lesions showed markedly reduced P3s to all types of stimuli at all scalp locations. The reductions were largest at the parietal electrode site over the lesioned hemisphere. Parietal patients had normal P3s for all stimulus types except for contralateral shock novels, which generated reduced P3s. Frontal lesions had reductions of the novelty P3 over frontal sites with minimal changes in the target P3. The data support the existence of multiple intracranial P3 sources. The data further indicate that association cortex in the temporal-parietal junction is critical for generating the scalp-recorded target and novelty P3s, whereas dorsolateral frontal cortex contributes preferentially to novelty P3 generation. The N2 component was reduced by parietal and frontal lesions in patients who had intact target P3s, suggesting that different neural systems underlie N2 and P3 generation.

Ontogeny of the calcium binding protein parvalbumin in the rat nervous system.

Abstract: In the adult rat brain, the calcium-binding protein parvalbumin is preferentially associated with spontaneously fast-firing, metabolically active neurons and coexists with gamma-amino-butyric acid (GABA) in cortical inhibitory interneurons. Whether this is so in developing neurons has not been explored. To this end, we have used parvalbumin immunohistochemistry to study expression of this protein in the rat nervous system during pre- and postnatal life. Our results indicate that parvalbumin first appears at embryonic day 13 in sensory system of the spinal cord, in the vestibular (VIII), the trigeminal (V) and the visuomotor (III, IV, VI) systems, and develops rapidly during the following days. In these locations the expression of parvalbumin coincides with the beginning of physiological activity in nerve cells. In the gamma-aminobutyric acid (GABA)-containing interneurons of the cerebral cortex and the hippocampus, as well as in the Purkinje cells of the cerebellum, parvalbumin only appears postnatally. It lags behind the development of GABA-immunoreactivity by 1 to 2 weeks. The beginning of its expression, in the cerebellum at least, coincides with the arrival of excitatory synaptic input and the onset of spontaneous activity. Thus, during the development of the nervous system, the expression of parvalbumin is subordinate to the establishment of physiological activity.

Constancy of central conduction delays during development in man: investigation of motor and somatosensory pathways.

Abstract: 1. A cross-sectional study has been performed on 457 normal subjects to determine changes in conduction delays with age in central and peripheral motor and somatosensory pathways to the upper limb. 2. Electromagnetic stimulation was used to investigate central and peripheral conduction in motor pathways from the cortex to biceps brachii and hypothenar muscles in 308 normal human subjects aged from 32 weeks gestation to 55 years. The responses were recorded in the surface electromyogram. 3. Somatosensory potentials evoked by electrical stimulation of the median nerve have been recorded at Erb's point and over the somatosensory cortex in 149 normal subjects aged from 34 weeks gestation to 52 years to determine central and peripheral somatosensory conduction delays. 4. The conduction delays in the central components of both motor and somatosensory pathways rapidly decrease over the first 2 years after birth and thereafter remain constant at adult values. 5. The conduction delays in the peripheral components of both motor and somatosensory pathways also decrease initially but then from the age of 5 years progressively increase in proportion to arm length. 6. The threshold stimulus intensity for evoking muscle responses following electromagnetic stimulation of the cortex is high initially and falls progressively until the age of 16 years. A linear relationship exists between the threshold intensity and height for the height range 70-180 cm. 7. The threshold stimulus intensities for exciting peripheral motor and somatosensory nerves decrease up to the age of 5 years and then reach a plateau. 8. The results support the conclusion, already reported in the literature that peripheral nerves attain maximum value for fibre diameter and conduction velocity at approximately 5 years of age. 9. In contrast, it is concluded that the maximum fibre diameters in both motor and somatosensory central pathways increase in proportion to height, leading to constant central conduction delays with growth.

Cholinergic depletion prevents expansion of topographic maps in somatosensory cortex

Abstract: Although the role of acetylcholine in processing stimuli in the cerebral cortex is becoming defined, the impact of cholinergic activity on the character of cortical maps remains unclear. In the somatosensory cortex, topographic maps appear capable of lifelong modifications in response to alterations in the periphery. One factor proposed to influence this adaptational ability is the presence of acetylcholine in the cortex. The studies presented here, using the 2-deoxyglucose technique, demonstrate that the unilateral removal of a digit in cats, followed by stimulation of an adjacent digit, produces a pattern of metabolic activity in the somatosensory cortex that is dramatically expanded when compared with the opposite (normal) hemisphere. In contrast, experiments in which the somatosensory cortex was depleted of acetylcholine and the animal received a similar amputation led not to patterns of expanded metabolic activity, but rather to reductions in the evoked metabolic distribution. These studies implicate acetylcholine in normal map formation and in the maintenance of the capacity of cortical maps to adapt to changes in the periphery.

Functional reorganization in adult monkey thalamus after peripheral nerve injury.

Abstract: Large changes in somatotopic organization can be induced in adult primate somatosensory cortex by cutting peripheral afferents. The role, if any, of the thalamus in these changes has not been investigated previously. In the present experiments, electrophysiological recording in the ventroposterior lateral nucleus (VPL) has revealed that not only can reorganization occur in the thalamus, but it may be as extensive as that revealed in the cortex of the same monkeys. Thus, for at least some types of deafferentation, the reorganization revealed in the cortex may depend largely on subcortical changes.

Injury-Induced Reorganization of Somatosensory Cortex Is Accompanied by Reductions in GABA Staining

Abstract: When a portion of primary somatosensory cortex is deprived of its normal inputs by peripheral nerve transection, intact skin surfaces represented in surrounding cortex come to activate the deprived zone within 2 months. We found that this cortical reorganization was accompanied by a marked decrease in the antibody staining of gamma-aminobutyric acid (GABA) within the deprived sector of cortex in monkeys surviving nerve injury for 2-5 months. In contrast, there were no apparent changes in cytochrome oxidase reactivity in the deprived cortex of these same monkeys. Reduced levels of inhibition could allow previously unexpressed connections to become potent. Thus, the regulation of the expression of GABA appears to be one mechanism for maintaining and altering cortical representations.

Attention modulates somatosensory cerebral blood flow response to vibrotactile stimulation as measured by positron emission tomography.

Abstract: In human primary somatosensory cortex, the cerebral blood flow response to vibrotactile stimulation of the fingers (110 Hz), as measured by positron emission tomography and H215O, was 13% higher (p < 0.025) when the subjects attended to the stimulus, compared to when they were simultaneously engaged in a distraction task. This suggests that the physiological response of a primary cortical area can be modulated by the attentive behavior of the subject.

Large-scale functional reorganization in adult monkey cortex after peripheral nerve injury.

Abstract: In adult monkeys, peripheral nerve injuries induce dramatic examples of neural plasticity in somatosensory cortex. It has been suggested that a cortical distance limit exists and that the amount of plasticity that is possible after injury is constrained by this limit. We have investigated this possibility by depriving a relatively large expanse of cortex by transecting and ligating both the median and the ulnar nerves to the hand. Electrophysiological recording in cortical areas 3b and 1 in three adult squirrel monkeys no less than 2 months after nerve transection has revealed that cutaneous responsiveness is regained throughout the deprived cortex and that a roughly normal topographic order is reestablished for the reorganized cortex.

Neuromagnetic investigation of somatotopy of human hand somatosensory cortex.

Abstract: In order to investigate functional topography of human hand somatosensory cortex we recorded somatosensory evoked fields (SEFs) on MEG during the first 40 ms after stimulation of median nerve, ulnar nerve, and the 5 digits. We applied dipole modeling to determine the three-dimensional cortial representations of different peripheral receptive fields. Median nerve and ulnar nerve SEFs exhibited the previously described N20 and P30 components with a magnetic field pattern emerging from the head superior and re-entering the head inferior for the N20 component; the magnetic field pattern of the P30 component was of reversed orientation. Reversals of field direction were oriented along the anterior-posterior axis. SEFs during digit stimulation showed analogous N22 and P32 components and similar magnetic field patterns. Reversals of field direction showed a shift from lateral inferior to medial superior for thumb to little finger. Dipole modeling yielded good fits at these peak latencies accounting for an average of 83% of the data variance. The cortical digit representations were arranged in an orderly somatotopic way from lateral inferior to medial superior in the sequence thumb, index finger, middle finger, ring finger, and little finger. Median nerve cortical representation was lateral inferior to that of ulnar nerve. Isofield maps and dipole locations for these components are consistent with neuronal activity in the posterior bank of central fissure corresponding to area 3b. We conclude that SEFs recorded on MEG in conjunction with source localization techniques are useful to investigate functional topography of human hand somatosensory cortex non-invasively.

Somatosensory Discrimination of Shape: Tactile Exploration and Cerebral Activation.

Abstract: This study of somatosensory discrimination of rectangular parallelepipeda with the right hand had three purposes: (i) to describe the exploratory finger movements; (ii) to reveal the anatomical brain structures specifically engaged in the production of exploratory finger movements; and (iii) to reveal the anatomical structures specifically engaged in the discrimination of tactually sensed shape. The thumb was the most active finger, moving with a mean exploration frequency of 2.4 Hz, as evident from videotape records of the exploratory finger movements. The cerebral structures activated during somatosensory discrimination were mapped by measurements of regional cerebral blood flow (rCBF) in six healthy male volunteers with positron emission tomography (PET) and the use of the computerized brain atlas of Greitz et al. (1991, J. Comp. Ass. Tomogr., 15, 26 - 38). The rCBF changes caused by somatosensory discrimination were compared point-to-point to a PET-study on right-hand finger movements and a PET-study on vibration stimulation of the right hand. From these results the following conclusions were drawn. The rCBF increase in the left superior parietal lobule indicated the site engaged in the analysis of shape. The rCBF increases in the left supplementary sensory area, bilaterally in premotor areas, in the left putamen, the right dentate nucleus and bilaterally in the posterior cerebellum were related to the control of the tactile exploratory finger movements. The rCBF increases in the right homologue of Broca's area, bilaterally in the superior prefrontal cortex and in the right midfrontal cortex probably resulted from working memory, the direction of attention, and the discrimination process.

Anatomic evidence of nociceptive inputs to primary somatosensory cortex: relationship between spinothalamic terminals and thalamocortical cells in squirrel monkeys.

Abstract: This study examined anatomic pathways that are likely to transmit noxious and thermal cutaneous information to the primary somatosensory cortex. Anterograde and retrograde labeling techniques were combined to investigate the relationship between spinothalamic (STT) projections and thalamocortical neurons in the squirrel monkey (Saimiri sciureus). Large injections of diamidino yellow (DY) were placed in the physiologically defined hand region of primary somatosensory cortex (hSI), and wheat germ agglutinin-horseradish peroxidase (WGA-HRP) was injected in the contralateral cervical enlargement (C5T1). Both DY-labeled neuronal cell bodies and HRP-labeled STT terminal-like structures were visualized within single thalamic sections in each animal. Quantitative analysis of the positions and numbers of retrogradely labeled neurons and anterogradely labeled terminal fields reveal that: (1) ventral posterior lateral (VPL), ventral posterior inferior (VPI), and central lateral (CL), combined, receive 87% of spinothalamic inputs originating from the cervical enlargement; (2) these three nuclei contain over 91% of all thalamocortical neurons projecting to hSI that are likely to receive STT input; and (3) these putatively contacted neurons account for less than 24% of all thalamic projections to hSI. These results suggest that three distinct spinothalamocortical pathways are capable of relaying nociceptive information to the hand somatosensory cortex. Moreover, only a small portion of thalamocortical neurons are capable of relaying STT-derived nociceptive and thermal information to the primary somatosensory cortex.

The anatomical basis of somaesthetic temporal discrimination in humans

Abstract: Somaesthetic temporal discrimination (STD) is the ability to perceive as separate two successive somaesthetic stimuli applied to the same or different parts of the body. Paired electrical stimuli were applied to the index finger, using different time-intervals, to study the STD threshold (STDT) in 84 normal subjects and 51 patients with focal cerebral lesions. Abnormal STDT values were found on the affected side of patients with a lesion of the primary somatosensory cortex, and internal capsulethalamus. Lesions which did not produce sensory impairment but caused abnormal STDT were located in the posterior parietal cortex, the head of the caudate nucleus, the putamen, the medial thalamus and the lenticular nucleus. Frontal, temporal and occipital cortex lesions did not produce any abnormality in the STDT, but one patient with a bilateral lesion of the supplementary motor area (SMA) had abnormal STDT. These results indicate that normal perception of two somaesthetic stimuli as separate in time depends not only upon the integrity of the somatosensory pathway and primary somaesthetic cortex, but also of the posterior parietal cortex, SMA and subcortical structures such as the striatum and thalamus.

C-fibres provide a source of masking inhibition to primary somatosensory cortex

Abstract: Capsaicin was applied to the exposed radial nerve of adult flying foxes (n = 5) and cats (n = 2) while recording in primary somatosensory cortex from a single neuron with a receptive field on digits 1 or 2. Within four minutes of application of capsaicin the borders of these receptive fields dramatically expanded. In a further four flying foxes it was shown, with subcutaneous delivery just proximal to the receptive fields, that capsaicin need affect only afferents from the region of a neuron's receptive field to induce expansion. Capsaicin applied directly to a nerve, or subcutaneously in high concentrations, is a selective neurotoxin that rapidly prevents the propagation of action potentials in most C-fibres. The result provides a partial explanation for experiments involving the specific and complete denervation of receptive fields of neurons in primary somatosensory cortex. Such denervation does not lead to unresponsiveness but to immediate sensitivity to stimulation of areas surrounding the original fields. Thus it appears that some subclass of capsaicin-sensitive C-fibres provides a primary source for the masking inhibition that normally limits the extent of the receptive fields of cortical neurons.

Effects of in utero ethanol exposure on the developing serotonergic system.

Abstract: Previous work in this laboratory demonstrated that the 19- and 35-day-old offspring of ethanol-fed rats have a significant deficiency of cortical serotonin (5-HT) and 5-hydroxyindoleacetic acid (5-HIAA), as well as a decrease in the number of total 5-HT1 receptors in the motor and somatosensory cortex. The present studies extend our previous reports by demonstrating that there is also a deficit of 5-HT and 5-HIAA in the motor cortex but not in the somatosensory cortex. In addition, we have shown that a deficit of 5-HTlA receptors in the motor and somatosensory cortices contributes to the deficit of total 5-HT1 receptors. In contrast, we did not observe any changes in the binding to 5-HT1B receptors in these cortical regions from the 19-day-old offspring of ethanol-fed rats. The present studies also examined the effects of in utero ethanol exposure on the early development of the serotonergic system. The results of these studies demonstrated a deficit of 5-HT and/or 5-HlAA in the brain stem as early as the 15th day of gestation (G15) and in the cortex as early as G19. In addition, we demonstrated a delay in both the normal developmental decline of 5-HT1A receptors in the brain stem and in the acquisition of cortical 5-HT1A receptors. No changes were found in the binding of [125]cyanopindolol to 5-HT1B receptors in either region of fetal or neonatal rats exposed to ethanol in utero. Given the important role of serotonin for normal central nervous system (CNS) development, it is possible that these early serotonergic abnormalities contribute to altered CNS development in ethanol-exposed rats.

Cortical somatosensory evoked potentials. II. Effects of excision of somatosensory or motor cortex in humans and monkeys.

Abstract: 1. To clarify the generators of human short-latency somatosensory evoked potentials (SEPs) thought to arise in sensorimotor cortex, we studied the effects on SEPs of surgical excision of somatosensory or motor cortex in humans and monkeys. 2. Normal median nerve SEPs (P20-N30, N20-P30, and P25-N35) were recorded from the cortical surface of a patient (G13) undergoing a cortical excision for relief of focal seizures. All SEPs were abolished both acutely and chronically after excision of the hand area of somatosensory cortex. Similarly, excision of the hand area of somatosensory cortex abolished corresponding SEPs (P10-N20, N10-P20, and P12-N25) in monkeys. Excision of the crown of monkey somatosensory cortex abolished P12-N25 while leaving P10-N20 and N10-P20 relatively unaffected. 3. After excision of the hand area of motor cortex, all SEPs were present when recorded from the cortical surface of a patient (W1) undergoing a cortical excision for relief of focal seizures. Similarly, all SEPs were present in monkeys after excision of the hand area of motor cortex. 4. Although all SEPs were present after excision of motor cortex in monkeys, variable changes were observed in SEPs after the excisions. However, these changes were not larger than the changes observed after excision of parietal cortex posterior to somatosensory cortex. We concluded that the changes were not specific to motor cortex excision. 5. These results support two major conclusions. 1) Median nerve SEPs recorded from sensorimotor cortex are produced by generators in two adjacent regions of somatosensory cortex: a tangentially oriented generator in area 3b, which produces P20-N30 (human) and P10-N20 (monkey) [recorded anterior to the central sulcus (CS)] and N20-P30 (human) and N10-P20 (monkey) posterior to the CS; and a radially oriented generator in area 1, which produces P25-N35 (human) and P12-N25 (monkey) recorded from the postcentral gyrus near the CS. 2) Motor cortex makes little or no contribution to these potentials.

Differential effects of GABA and bicuculline on rapidly- and slowly-adapting neurons in primary somatosensory cortex of primates

Abstract: In cortical area 3b of monkeys, responses of 71 single neurons to controlled indentations of glabrous skin were recorded before and during iontophoretic application of GABA and bicuculline methiodide (BMI), a GABA receptor antagonist. Constant amplitude indentations were applied to selected sites within the receptive fields of neurons representing the glabrous skin on the digits and palm. Profiles of response magnitudes across stimulation sites were used to quantify receptive field dimensions before and during antagonism of GABAergic inhibition. During administration of BMI, the receptive fields of 26 rapidly-adapting neurons were increased by 3–4 times their original size. Response latencies were substantially longer in the region of expansion than in the original receptive field, suggesting that expansion might be mediated by intracortical connections. The expansion of RFs onto adjacent digits after blockade of GABAergic inhibition suggests that somatotopic reorganization following digit amputations may be subserved by existing excitatory connections. The responses of slowly-adapting neurons were separated into two components, a “dynamic” response corresponding to activity elicited by the initial indenting ramp and a “static” response produced by the sustained indentation. Among 8 slowly-adapting neurons tested with BMI, the receptive fields of the dynamic response component increased to an extent that was similar to the change produced in rapidly-adapting neurons. By contrast, the static response component was rarely altered by BMI. Comparison of the responses to administration of GABA revealed that only 12 of 27 slowly-adapting neurons were inhibited in a dose-dependent manner, whereas 37 of 44 rapidly-adapting neurons exhibited significant reduction of responses in the presence of GABA. Hypotheses are proposed to explain the differential effect of BMI and GABA on slowly- and rapidly-adapting cortical neurons.

Patterns of sensory intermodality relationships in the cerebral cortex of the rat.

Abstract: Patterns of connections underlying cross-modality integration were studied by injecting distinguishable, retrograde tracers (Fluoro-Gold and diamidino yellow) in pairwise manner into different sensory representations (visual, somatosensory, and auditory) in the cerebral cortex of the rat. In agreement with previous single tracer studies, our results indicate that the central core of sensory areas receives projections mainly from a set of association areas located in a ringlike fashion along the margin of the cortical mantle. The visual cortex received projections from areas 48/49, area 29d, posterior agranular medial cortex (AGm), area 11, area 13, and area 35. All these areas were also connected to the auditory cortex with the exception of areas 29d and AGm. However, lateral to area 29d and posterior AGm, a band of neurons projecting to the auditory cortex was present. Somatosensory cortex was connected mainly with the more anterior aspect of the hemisphere, which included primary motor area, area 11, and area 13. The patterns of intermodality relationships revealed in the present study were of two main categories. In the anterior and lateral areas, an intermingling of cells projecting to different sensory modalities was observed. In contrast, in areas located along the medial aspect of the hemisphere, cells connected to different sensory modality representations tended to be segregated from each other. Postsubicular cortex (areas 48/49) contained both intermingled and segregated groups of cells. The incidence of clearly identified double-labeled cells concurrently projecting to two different sensory representations was extremely rare. These patterns may form a substrate for different levels of cross-modal sensory integration in the rat cortex.

Spinal and supraspinal correlates of nociception in man.

Abstract: The objective of this work was to simultaneously measure pain-related spinal and supraspinal physiological responses in humans. The sural nerve compound action potential (CAP), the spinal withdrawal reflex (RIII), the somatosensory evoked potential (SEP) and subjective magnitude ratings were elicited by electrical stimulation of the sural nerve in 10 healthy subjects. The sural nerve CAP was used to normalize the evoking stimulus current and to help identify the peripheral nerve afferent types contributing to the physiological and psychophysical responses. Normalizing stimulus current to a proportion of that which elicited a just maximal sural nerve CAP significantly reduced individual variability in magnitude ratings, the RIII and the SEP. Pain and RIII responses only occurred at stimulus levels that were greater than or equal to 1.5 x that which produced a just maximal sural nerve CAP and both responses were positively related to stimulus intensity above that level. Activity in the large diameter A beta fibers will be saturated at stimulus levels near that which produced a just maximal CAP, which implies that both the pain and RIII responses can be attributed to recruitment of the smaller diameter A delta fibers. Although the amplitudes of the P200 and P300 peaks of the SEP were significantly related to stimulation at noxious levels, both were also affected by stimulation at innocuous levels. This result implies that these peaks receive contributions from both noxious and innocuous somatosensory processes. Clearly, the non-pain-related components of these SEP peaks must be identified and isolated before their potential in measuring supraspinal nociceptive processes can be fully realized.

A quantitative study of neuronal discharge in areas 5, 2, and 4 of the monkey during fast arm movements

Abstract: 1. The properties of parietal neurons were studied in four adult rhesus monkeys during fast arm movements. The animals were trained to perform flexion or extension of the forearm about the elbow in response to specific auditory cues. Single neuron activity was recorded in 272 area 5 neurons, 81 neurons of the somatosensory cortex, and 92 neurons of the motor cortex. 2. In area 5, 42% of neuronal changes occurred before movement onset (early changes) and 58% after (late changes), with 21% before the earliest electromyogram. The range of modification in activity took place between 260 ms before movement onset and 180 ms after. Complex receptive fields were found in area 5 with a greater proportion among the late neurons (72%) than among the early neurons (32%). 3. Different patterns of activity were observed in neurons recorded in both movement directions. Reciprocal neurons represented 52% of the motor cortex neurons and 41% of the neurons in the somatosensory cortex but only 14% of the area 5 neurons. Of the remainder area 5 neurons, 46% were direction-sensitive neurons and 39% coactivated neurons. This suggests a more complex encoding of movement direction in area 5 than in area 2 or 4. 4. Temporal characteristics of the neuronal bursts were quantitatively analyzed in areas 5, 2, and 4. Neuronal burst duration was longer in area 5 than in the other areas. Above all, a variability of burst parameters, which did not depend on variable movement execution, was noticed in area 5. Therefore neuronal activity in this cortical area cannot be simply explained by a convergence of sensory and motor inputs but may depend on the behavioral context in which the movement is performed. 5. A correlation between neuronal burst duration and movement duration was found in 41% of area 2 neurons. In area 5, this correlation was observed in 20% of the late neurons and in 14% of the early neurons. A correlation between neuronal discharge frequency and movement velocity was found in 34% of area 2 neurons and 24% of area 4 neurons. About 16% of both late and early neurons in area 5 showed such a correlation. These neurons received polyarticular input, and it is suggested that they may be involved in the kinematic encoding of polyarticular movements. 6. A topographic and functional organization of area 5 was noticed. In anterior area, 5, 83% of the neurons had receptive fields and most of the reciprocal neurons and those exhibiting a correlation with movement parameters were found there.(ABSTRACT TRUNCATED AT 400 WORDS)