Summary
The spatial organization of the cutaneous input to hindlimb withdrawal reflexes was studied in spinalized, decerebrated, unanesthetized rats. Reflex activity in plantar flexors of the digits, pronators of the foot, dorsiflexors of the digits, and/or the ankle and flexors of the knee was recorded with electromyographic techniques for up to 12 h after spinalization. Graded mechanical (pinch) and thermal stimulation (CO2 laser) of the skin were used. Reflexes were absent (“spinal shock”) during approximately 10–20 min after spinalization. The reflex thresholds for pinch and CO2 laser stimulation then decreased considerably during the following 5–8 h. After this time, even mild pressure (less than 0.1 N/mm2) on the skin was sufficient to evoke a reflex in most muscles. During the period from about 0.5–3 h after spinalization, the nociceptive receptive field of each muscle usually corresponded to the area of the skin withdrawn by the muscle. Maximal responses were evoked from the area of the receptive field maximally withdrawn. During this period, responses to innocuous pinch were evoked mainly from the most sensitive area of the receptive fields. Concomitant with the decrease in reflex thresholds, the nociceptive receptive fields expanded for all muscles, often to include areas of the skin not withdrawn by the muscles. For most muscles, reflexes on tactile stimuli were eventually elicited from the entire receptive fields. The receptive fields for thermonociceptive and mechanonociceptive inputs were similar in most muscles. The interossei muscles were exceptional in that they responded very weakly to thermal stimulation. It is concluded that there are neuronal networks in the spinal cord that translate cutaneous nociceptive and tactile input into a withdrawal. However, the control exerted by descending pathways is necessary to maintain a functionally adequate excitability in these reflex pathways and an appropriate size for their receptive fields.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Babinski MJ (1896) Sur le réflexe plantaire dans certaines affections organiques du système nerveux central. C R Soc Biol Paris 3: 207–208
Behrends T, Schomburg ED, Steffens H (1983) Facilitatory interaction between cutaneous afferents from low threshold mechanoreceptors and nociceptors in segmentai reflex pathways to amotoneurons. Brain Res 260: 131–134
Bromm B, Treede R-D (1984) Nerve fibre discharges, cerebral potentials and sensations induced by CO2 laser stimulation. Human Neurobiol 3: 33–40
Burke RE, Rudomin P, Vyklicky L, Zajac FE III (1971) Primary afferent depolarization and flexion reflexes produced by radiant heat stimulation of the skin. J Physiol (Lond) 213: 185–214
Creed RS, Denny-Brown D, Eccles JC, Liddell EGT, Sherrington CS (1932) Reflex activity of the spinal cord. Oxford University Press, London, Humphrey Milford, pp 1–183
Devor M, Carmon A, Frostig R (1982) Primary afferents and spinal sensory neurons that respond to brief pulses of intense infrared laser radiation: a preliminary study in rats. Exp Neurol 76: 483–494
Dimitrijevic MR, Nathan PW (1971) Studies of spasticity in man. 3. Analysis of reflex activity evoked by noxious cutaneous stimulation. Brain 91: 349–368
Duggan AW, Morton CR (1988) Tonic descending inhibition and spinal nociceptive transmission. In: Fields HL and Besson J-M (eds) Progress in brain research, vol 77. Pain modulation. Elsevier Science Publishers, Amsterdam, pp 193–207
Ekerot C-F, Garwicz M, Schouenborg J (1991) Topography and nociceptive receptive fields of climbing fibres projecting to the cerebellar anterior lobe in the cat. J Physiol (Lond) 441: 257–274
Engberg I (1964) Reflexes to foot muscles in the cat. Acta Physiol Scand 62 [Suppl 235]: 1–64
Fleischer E, Handwerker HO, Joukhadar S (1983) Unmyelinated nociceptive units in two skin areas of the rat. Brain Res 267: 81–92
Fulton JF (1938) Physiology of the nervous system. Oxford University Press, London New York Toronto
Grimby L (1963a) Normal plantar response: integration of flexor and extensor reflex components. J Neurol Neurosurg Psychiatry 26: 39–50
Grimby L (1963b) Pathological plantar response: disturbances of the normal integration of flexor and extensor reflex components. J Neurol Neurosurg Psychiatry 26: 314–321
Hagbarth K-E (1952) Excitatory and inhibitory skin areas for flexor and extensor motoneurones. Acta Physiol Scand [Suppl] 94: 1–58
Haimi-Cohen R, Cohen A, Carmon A (1983) A model for the temperature distribution in skin noxiously stimulated by a brief pulse of CO2 laser radiation. J Neurosci Meth 8: 127–137
Handwerker HO, Anton F, Reeh PW (1987) Discharge patterns of afferent cutaneous nerve fibers from the rat's tail during prolonged noxious mechanical stimulation. Exp Brain Res 65: 493–504
Hardy JD, Jacobs I and Meixner MD (1953) Thresholds of pain and reflex contraction as related to noxious stimulation. J Appl Physiol 5: 725–739
Holmqvist B, Lundberg A (1961) Differential supraspinal control of synaptic actions evoked by volleys in the flexion reflex afferents in alpha motoneurons. Acta Physiol Scand 54 [Suppl 186]: 1–51
Kruger L, Sampogna SL, Rodin BE, Clague J, Brecha N, Yeh Y (1985) Thin-fiber cutaneous innervation and its intraepidermal contribution studied by labeling methods and neurotoxin treatment in rats. Somatosensory Res 2: 335–356
Kugelberg E, Eklund K, Grimby L (1960) An electromyographic study of the nociceptive reflexes of the lower limb: mechanism of the plantar responses. Brain 83: 394–410
Lundberg A (1982) Inhibitory control from the brain stem of transmission from primary afferents to motoneurons, primary afferent terminals and ascending pathways. In: Sjölund BH, Björklund A (eds) Brain stem control of spinal mechanisms. Elsevier Biomedical Press, Amsterdam, pp 179–224
Lynn B, Carpenter SE (1982) Primary afferent units from the hairy skin of the rat hind limb. Brain Res 238: 29–43
Megirian D (1962) Bilateral facilitatory and inhibitory skin areas of spinal motoneurones of cat. J Neurophysiol 25: 127–137
Pertovaara A, Morrow TJ, Casey KL (1988) Cutaneous pain and detection thresholds to short CO2 laser pulses in humans: evidence on afferent mechanisms and the influence of varying stimulus conditions. Pain 34: 261–269
Sabin C, Smith JL (1984) Recovery and perturbation of paw-shake responses in spinal cats. J Neurophysiol 51: 680–688
Schomburg ED (1990) Spinal sensorimotor systems and their supraspinal control. Neurosci Res 7: 265–340
Schomburg ED, Steffens H (1986) Synaptic responses of lumbar amotoneurones to selective stimulation of cutaneous nociceptors and low threshold mechanoreceptors in the spinal cat. Exp Brain Res 62: 335–342
Schouenborg J, Sjölund BH (1983) Activity evoked by A- and C-afferent fibers in rat dorsal horn and its relation to a flexion reflex. J Neurophysiol 50: 1108–1121
Schouenborg J, Dickenson AH (1985) The effects of a distant noxious stimulation on A- and C-fibre evoked flexion reflexes and neuronal activity in the dorsal horn of the rat. Brain Res 328: 23–32
Schouenborg J, Kalliomäki J (1990) Functional organization of the nociceptive withdrawal reflexes. I. Activation of hindlimb muscles in the rat. Exp Brain Res 83: 67–78
Schouenborg J, Kalliomäki J, Weng H-R (1990) Identification of putative reflex interneurones in the nociceptive withdrawal reflex paths. Acta Physiol Scand 140:25A
Schouenborg J, Holmberg H, Weng H-R (1991) Topographical organization of hindlimb nociceptive withdrawal reflexes in the spinalized rat. Abstract, Third IBRO World Congress of Neuroscience, Montreal
Sherrington CS (1906) The integrative action of the nervous system. Yale University Press, New Haven
Sherrington CS (1910) Flexion-reflex of the limb, crossed extensionreflex and reflex stepping and standing. J Physiol (Lond) 40: 28–121
Sherrington CS, Sowton SCM (1915) Observations of reflex responses to single break-shocks J Physiol 49: 331–348
Smith JL, Hoy MG, Koshland GF, Phillips DM, Zernicke RF (1985) Intralimb coordination of the paw-shake response: a novel mixed synergy. J Neurophysiol 54: 1271–1281
Walsche F (1956) The Babinski plantar response, its forms and its physiological and pathological significance. Brain 79: 529–556
Willis WD (1982) Control of nociceptive transmission in the spinal cord. In: Ottoson D (eds) Progress in sensory physiology, vol 3. Springer New York Berlin Heidelberg pp 1–159
Woolf CJ, Swett JE (1984) The cutaneous contribution to the hamstring flexor reflex in the rat: an electrophysiological and anatomical study. Brain Res 303: 299–312
Young RR, Shahani BT (1986) Spasticity in spinal cord injured patients. In: Block R, Basbaum M (eds) Management of spinal cord injuries. Williams and Wilkens, Baltimore, pp 241–283
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Schouenborg, J., Holmberg, H. & Weng, HR. Functional organization of the nociceptive withdrawal reflexes. Exp Brain Res 90, 469–478 (1992). https://doi.org/10.1007/BF00230929
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00230929