Abstract
The present study was designed to determine whether the transmission of cutaneous afferent information from the limbs to the medullary reticular formation is phasically modulated during locomotion. Experiments were carried out in three chronically prepared, intact cats in which nerve cuff electrodes were placed, bilaterally, on the superficial radial and the superficial peroneal nerves. Thirty-seven reticulospinal neurones (RSNs) were identified by stimulation of their axons in the lumbar spinal cord (L2); 29 of 37 of these were recorded with the cat at rest, 28 of 37 during locomotion and 20 of 37 both at rest and during locomotion. Low-threshold stimulation of the cutaneous nerves evoked excitatory responses in the majority of RSNs both at rest and during locomotion. In the 28 of 37 RSNs recorded during locomotion, it was possible to record the evoked response to stimulation of all four limb nerves, giving a total of 184 tested cases [RSNs testedxnumber of nerves stimulatedxphase of stimulation (swing or stance)]. The responses of most RSNs to cutaneous stimulation were modulated in a phase-dependent manner during locomotion. The maximal responses in most, but not all, cases were obtained during the swing phase of the limb that was stimulated and were largely independent of the discharge pattern of the cell. We interpret this result as indicating that the efficacy of transmission of the afferent information is determined more by the excitability of the spinal relay neurones than by the level of excitability of the RSNs in the brainstem. It is suggested that the base discharge pattern of RSNs might be largely determined by their central afferent input, while peripheral afferent inputs would primarily serve to modify the RSN discharge pattern in response to perturbations.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Andersson O, Forssberg H, Grillner S, Lindquist M (1978) Phasic gain control of the transmission in cutaneous reflex pathways to motoneurones during “fictive” locomotion. Brain Res 149:503–507
Apps R, Hartell NA, Armstrong DM. (1995) Step phase-related excitability changes in spinoolivocerebellar paths to the c1 and c3 zones in cat cerebellum. J Physiol (Lond) 483:687–702
Armstrong DM, Drew T (1984) Locomotor-related neuronal discharges in cat motor cortex compared with peripheral receptive fields and evoked movements. J Physiol (Lond) 346:497–517
Berman AI (1968) The brain stem of the cat. A cytoarchitectonic atlas with stereotaxic coordinates. University of Wisconsin Press, Madison
Chapin JK, Woodward DJ (1982a) Somatic sensory transmission to the cortex during movement: gating of single cell responses to touch. Exp Neurol 78:654–669
Chapin JK, Woodward DJ (1982b) Somatic sensory transmission to the cortex during movement: phasic modulation over the locomotor step cycle. Exp Neurol 78:670–684
Chapman CE (1994) Active versus passive touch: factors influencing the transmission of somatosensory signals to primary somatosensory cortex. Can J Physiol Pharmacol 72:558–570
Chapman CE, Ageranioti-Bélanger SA (1991) Discharge properties of neurones in the hand area of primary somatosensory cortex in monkeys in relation to the performance of an active tactile discrimination task. I. Areas 3b and 1. Exp Brain Res 87:319–339
Chapman CE, Jiang W, Lamarre Y (1988) Modulation of lemniscal input during conditioned arm movements in the monkey. Exp Brain Res 72:316–334
Drew T (1991) Functional organization within the medullary reticular formation of the intact unanaesthetized cat. III. Microstimulation during locomotion. J Neurophysiol 66:919–938
Drew T (1993) Motor cortical activity during voluntary gait modifications in the cat. I. Cells related to the forelimbs. J Neurophysiol 70:179–199
Drew T, Doucet S (1991) Application of circular statistics to the study of neuronal discharge during locomotion. J Neurosci Methods 38:171–181
Drew T, Rossignol S (1984) Phase dependent responses evoked in limb muscles by stimulation of the medullary reticular formation during locomotion in thalamic cats. J Neurophysiol 52:653–675
Drew T, Rossignol S (1987) A kinematic and electromyographic study of cutaneous reflexes evoked from the forelimb of unrestrained walking cats. J Neurophysiol 57:1160–1184
Drew T, Rossignol S (1990a) Functional organization within medullary reticular formation of intact, unanaesthetized cat. I. Movements evoked by microstimulation. J Neurophysiol 64:767–781
Drew T, Rossignol S (1990b) Functional organization within medullary reticular formation of intact unanaesthetized cat. II. Electromyographic activity evoked by microstimulation. J Neurophysiol 64:782–795
Drew T, Dubuc R, Rossignol S (1986) Discharge patterns of reticulospinal and other reticular neurons in chronic, unrestrained cats walking on a treadmill. J Neurophysiol 55:375–401
Drew T, Jiang W, Kably B, Lavoie S (1996) Role of the motor cortex in the control of visually-triggered gait modifications. Can J Physiol Pharmacol (in press)
Eccles JC, Nicoll RA, Schwarz DWF, Taborikova H, Willey TJ (1975) Reticulospinal neurons with and without monosynaptic inputs from cerebellar nuclei. J Neurophysiol 38:513–530
Ellaway PH (1978) Cumulative sum technique and its application to the analysis of peristimulus time histograms. Electroencephalogr Clin Neurophysiol 45:302–304
Falzett M, Moore RK, Petry HM, Powers MK (1985) A method for determining threshold from single-unit neural activity. Brain Res 347:127–131
Fields HL, Clanton CH, Anderson SD (1977) Somatosensory properties of spinoreticular neurons in the cat. Brain Res 120:49–66
Floeter MK, Sholomenko GN, Gossard J-P, Burke RE (1993) Disynaptic excitation from the medial longitudinal fasciculus to lumbosacral motoneurons: modulation by repetitive activation, descending pathways, and locomotion. Exp Brain Res 92:407–419
Gossard J-P, Cabelguen J-M, Rossignol S (1989) Intra-axonal recordings of cutaneous primary afferents during fictive locomotion in the cat. J Neurophysiol 62:1177–1188
Gossard J-P, Cabelguen J-M, Rossignol S (1990) Phase-dependent modulation of primary afferent depolarization in single cutaneous primary afferents evoked by peripheral stimulation during fictive locomotion in the cat. Brain Res 537:14–23
Jiang W, Lamarre Y, Chapman CE (1990) Modulation of cutaneous cortical evoked potentials during isometric and isotonic contractions in the monkey. Brain Res 536:69–78
Julien C, Rossignol S (1982) Electroneurographic recordings with polymer cuff electrodes in paralyzed cats. J Neurosci Methods 5:267–272
Lavoie S, McFadyen B, Drew T (1995) A kinematic and kinetic analysis of locomotion during oluntary gait modifications in the cat. Exp Brain Res 106:39–56
Lipski J (1981) Antidromic activation of neurones as a analytical tool in the study of the central nervous system. J Neurosci Methods 4:1–32
Lundberg A, Malmgren K, Schomberg ED (1987) Reflex pathways from group II muscle afferents. 1. Distribution and linkage of reflex actions to alpha-motoneurones. Exp Brain Res 65:271–281
Magni F, Willis WD (1964) Subcortical and peripheral control of brain stem reticular neurons. Arch Ital Biol 102:434–448
Matsuyama K, Ohta Y, Mori S (1988) Ascending and descending projections of the nucleus reticularis gigantocellularis in the cat demonstrated by the anterograde neural tracer Phaseolus vulgaris leucoagglutinin (PHA-L). Brain Res 460:124–141
Maunz RA, Pitts NG, Peterson BW (1978) Cat spinoreticular neurons: locations, responses and changes in responses during repetitive stimulation. Brain Res 148:365–379
Orlovsky GN (1970) Work of the reticulo-spinal neurones during locomotion. Biophysics 15:761–771
Orlovsky GN (1972) The effect of different descending systems on flexor and extensor activity during locomotion. Brain Res 40:359–371
Palmer CI, Marks WB, Bak MJ (1983) Activity of feline motor cortical units to cutaneous stimuli during locomotion and lifting, falling and landing. Exp Brain Res [Suppl] 7:309–314
Palmer CI, Marks WB, Bak MJ (1985) The responses of cat motor cortical units to electrical cutaneous stimulation during locomotion and during lifting, falling and landing. Exp Brain Res 58:102–116
Perreault M-C, Drew T, Rossignol S (1993) Activity of medullary reticulospinal neurons during fictive locomotion. J Neurophysiol 69:2232–2247
Perreault M-C, Rossignol S, Drew T (1994) Microstimulation of the medullary reticular formation during fictive locomotion. J Neurophysiol 71:229–245
Perret C (1976) Neural control of locomotion in the decorticate cat. In: Herman RM, Grillner S, Stein PSG, Stuart DG (eds) Neural control of locomotion. Plenum, New York, pp 587–615
Peterson BW, Felpel LP (1971) Excitation and inhibition of reticulospinal neurons by vestibular, cortical and cutaneous stimulation. Brain Res 27:373–376
Peterson BW, Anderson M, Filion M (1974) Responses of pontomedullary neurons to cortical, tectal and cutaneous stimuli. Exp Brain Res 21:19–44
Peterson BW, Maunz RA, Pitts NG, Mackel RG (1975) Patterns of projection and branching of reticulospinal neurons. Exp Brain Res 23:333–351
Peterson BW, Franck JI, Pitts NG, Daunton NG (1976) Changes in responses of medial pontomedullary reticular neurons during repetitive cutaneous, vestibular, cortical and tectal stimulation. J Neurophysiol 39:564–581
Rossignol, S, Lund, J, Drew, T. (1988) The role of sensory inputs in regulating patterns of rhythmical movements in higher vertebrates. In: Cohen A, Rossignol S, Grillner S (eds) Neural control of rhythmic movements in vertebrates. Wiley, NewYork, pp 201–283
Segundo JP, Takenaka T, Encabo H (1967) Somatic sensory properties of bulbar reticular neurons. J Neurophysiol 30:1221–1238
Shefchyk SJ, Jordan LM (1985) Excitatory and inhibitory postsynaptic potentials in α-motoneurons produced during fictive locomotion by stimulation of the mesencephalic locomotor region. J Neurophysiol 53:1345–1355
Shefchyk SJ, Jell RM, Jordan LM (1984) Reversible cooling of the brain stem reveals areas required for mesencephalic locomotor region evoked treadmill locomotion. Exp Brain Res 56:257–262
Shimamura M, Kogure I (1979) Reticulospinal tracts involved in the spino-bulbo-spinal reflex in cats. Brain Res 172:13–21
Shimamura M, Livingston RB (1963) Longitudinal conduction systems serving spinal and brain-stem coordination. J Physiol (Lond) 26:258–272
Shimamura M, Kogure I, Wada S-I (1982) Reticular neuron activities associated with locomotion in thalamic cats. Brain Res 231:51–62
Shimamura M, Fuwa T, Kogure I (1985) Burst discharges of pontine reticular neurons in relation to forelimb stepping of thalamic and high spinal cats. Brain Res 346:363–367
Shimamura M, Tanaka I, Fuwa T (1990) Comparison between spino-bulbo-spinal and propriospinal reflexes in thalamic cats during stepping. Neurosci Res 7:358–368
Shin H-C, Chapin JK (1990) Modulation of afferent transmission to single neurons in the ventroposterior thalamus during movement in rats. Neurosci Lett 108:116–120
Siegel JM, Tomaszewski KS (1983) Behavioural organization of reticular formation: studies in the unrestrained cat. I. Cells related to axial, limb, eye, and other movements. J Neurophysiol 50:696–716
Soja PJ, Oka J-I, Fragoso M (1993) Synaptic transmission through cat lumbar ascending sensory pathways is suppressed during active sleep. J Neurophysiol 70:1708–1712
Steeves JD, Jordan LM (1980) Localisation of a descending pathway in the spinal cord which is necessary for controlled treadmill locomotion. Neurosci Lett 20:283–288
Udo M, Kamei H, Matsukawa K, Tanaka K (1982) Interlimb coordination in cat locomotion investigated with perturbation. II. Correlates in neuronal activity of Deiter's cells of decerebrate walking cats. Exp Brain Res 46:438–447
Yen CT, Blum PS (1984) Response properties and functional organization of neurons in midline region of medullary reticular formation of cats. J Neurophysiol 52:961–979
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Drew, T., Cabana, T. & Rossignol, S. Responses of medullary reticulospinal neurones to stimulation of cutaneous limb nerves during locomotion in intact cats. Exp Brain Res 111, 153–168 (1996). https://doi.org/10.1007/BF00227294
Received:
Issue Date:
DOI: https://doi.org/10.1007/BF00227294