Abstract
The purpose of this study was to investigate adaptive changes in the activity of vestibular nuclei neurons unilaterally deprived of their primary afferent inputs when influenced by visual motion cues. These neuronal changes might account for the established role that vision plays in the compensation for posturo-kinetic deficits after the loss of vestibular inputs. Neuronal recordings were made in alert, non-paralysed cats that had undergone unilateral vestibular nerve sections. The unit responses collected in both Deiters' nuclei were compared to those previously recorded in intact cats. We analysed the extracellular activity of Deiters' nucleus neurons, as well as the optokinetic reflex (OKR) evoked during sinusoidal translation of a whole-field optokinetic stimulus in the vertical plane. In intact cats, we found the unit firing rate closely correlated with the visual surround translation velocity, and the relationship between the discharge rate and the motion frequency was tuned around an optimal frequency. The maximum firing rate modulation was generally below the 0.25 Hz stimulus frequency; unit responses were weak or even absent above 0.25 Hz. From the 4th day to the end of the 3rd week after ipsilateral deafferentation, a majority of cells was found to display maximum discharge modulation during vertical visual stimulation at 0.50 Hz, and even at 0.75 Hz, indicating that the frequency bandwidth of the visually induced responses of deafferented vestibular nuclei neurons had been extended. Consequently, the frequency-dependent attenuation in the sensitivity of vestibular neurons to visual inputs was much less pronounced. After the first 3 weeks postlesion, the unit response characteristics were very similar to those observed prior to the deafferentation. On the nucleus contralateral to the neurectomy, the maximum modulation of most cells was tuned to the low frequencies of optokinetic stimulation, as also seen prior to the lesion. We found, however, a subgroup of cells displaying well-developed responses above 0.50 Hz. Under all experimental conditions, the neuronal response phase still remained closely correlated with the motion velocity of the vertical sinusoidal visual pattern. We hypothesize that Deiters' neurons deprived of their primary afferents may transiently acquire the ability to code fast head movements on the basis of visual messages, thus compensating, at least partially, for the loss of dynamic vestibular inputs during the early stages of the recovery process. Since the overall vertical OKR gain was not significantly altered within the 0.0125 Hz–1 Hz range of stimulation after the unilateral neurectomy, it can be postulated that the increased sensitivity of deafferented vestibular neurons to visual motion cues was accounted for by plasticity mechanisms operating within the deafferented Deiters' nucleus. The neuroplasticity mechanisms underlying this rapid and temporary increase in neuronal sensitivity are discussed.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Barmack NH, Pettorossi VE, Erickson RG (1980) The influence of bilateral labyrinthectomy on horizontal and vertical optokinetic reflexes in the rabbit. Brain Res 196:520–524
Barthélémy J, Xerri C, Borel L, Lacour M (1988) Neuronal coding of linear motion in the vestibular nuclei of the alert cat. II. Responses characteristics to vertical optokinetic stimulation. Exp Brain Res 70:287–298
Borel L, Lacour M (1991) Eye-head coordination in normal and hemilabyrinthectomized cats. In: Berthoz A, Vidal PP, Graf W (eds) The head-neck sensory motor system. Oxford University Press, Oxford, pp 611–616
Burt A, Flohr H (1991a) Role of the visual input in recovery of function following unilateral vestibular lesion in the goldfish. I. Short-term behavioral changes. Behav Brain Res 42:201–211
Burt A, Flohr H (1991b) Role of the visual input in recovery of function following unilateral vestibular lesion in the goldfish. II. Long-term behavioral changes. Behav Brain Res 42:213–225
Cazin L, Precht W, Lannou J (1980) Optokinetic responses of vestibular nucleus neurons in the rat. Pflugers Arch 384:31–38
Courjon JH, Jeannerod M, Ossuzio I, Schmid R (1977) The role of vision in compensation of vestibulo-ocular reflex after hemilabyrinthectomy in the cat. Exp Brain Res 28:235–248
Daunton N, Thomsen D (1979) Visual modulation of otolith-dependent units in cat vestibular nuclei. Exp Brain Res 37:173–176
Dichgans J, Schmidt CL, Graf W (1973) Visual input improves the speedometer function of the vestibular nuclei in the goldfish. Exp Brain Res 18:319–322
Die GC van, Collewijn H (1982) Optokinetic nystagmus in man. Role of central and peripheral retina and occurrence of asymmetries. Hum Neurobiol 1:111–119
Dieringer N, Künzle H, Precht W (1984) Increased projection of ascending dorsal root fibers to vestibular nuclei after hemilabyrinthectomy in the frog. Exp Brain Res 55:574–578
Erway LC, Gherlarduci B, Pompeiano O, Stanojevic M (1978) Responses of cerebellar fastigial neurons to stimulation of contralateral macular labyrinthine receptors. Arch Ital Biol 116:205–224
Ewald JR (1982) Physiologische Untersuchungen uber das Endorgan des N. Oktavus. Bergmann, Wiesbaden
Fetter M, Zee DS, Proctor LR (1988) Effect of lack of vision and of occipital lobectomy upon recovery from unilateral labyrinthectomy in rhesus monkey. J Neurophysiol 59:399–407
Fukushima K, Fukushima J (1991) Otolith-visual interaction in the control of eye movement produced by sinusoidal vertical linear acceleration in alerts cats. Exp Brain Res 85:36–44
Fukushima K, Perlmutter SI, Baker JF, Peterson BW (1990) Spatial properties of second-order vestibulo-ocular relay neurons in the alert cat. Exp Brain Res 81:462–478
Gacek RR, Lyon MJ, Schoonmaker J (1989) Morphologic correlates of vestibular compensation in the cat. Ann Otolaryngol [Suppl] 462:1–16
Goldberger ME, Murray M (1974) Restitution of function and collateral sprouting in cat spinal cord: the deafferented animal. J Comp Neurol 158:37–54
Hamann KF, Lannou J (1988) Dynamic characteristics of vestibular nuclear neurons responses to vestibular and optokinetic stimulation during vestibular compensation in the rat. Acta Otolaryngol [Suppl] 455:1–19
Highstein SM, McCrea RA (1988) The anatomy of the vestibular nuclei. In: Büttner-Ennever JA (ed) Neuroanatomy of the oculomotor system. (Reviews of oculomotor research, vol 2) Elsevier, Amsterdam, pp 177–202
Hoshino K, Pompeiano O (1977) Crossed responses of lateral vestibular neurons to macular labyrinthine stimulation. Brain Res 131:152–157
Igarashi M (1984) Vestibular compensation: an overview. Acta Otolaryngol [Suppl] 406:78–82
Igarashi M, Guitierrez O (1983) Analysis of righting reflex in cats with unilateral and bilateral labyrinthectomy. Otorhinolaryngol 45:279–289
Igarashi M, Himi T, Kulecz WB, Patel S (1987) The role of saccular afferents in vertical optokinetic nystagmus in primates. A study in relation to optokinetic nystagmus in microgravity. Arch Oto Rhino Laryngol 244:143–146
Ishikawa K, Igarashi M (1985) Effect of atropine and carbachol on vestibular compensation in squirrel monkeys. Am J Otolaryngol 6:290–296
Korte GE, Friedrich VL (1979) The fine structure of the feline superior vestibular nucleus: identification and synaptology of the primary vestibular afferents. Brain Res 176:3–32
Kubo T, Matsunaga T, Igarashi M (1979) Vestibular unitary responses to visual stimulation in the rabbit. Acta Otolaryngol Stockh 88:117–121
Lacour M, Xerri C (1980) Compensation of postural reactions to fall in the vestibular neurectomized monkey. Role of the visual motion cues. Exp Brain Res 40:103–110
Lacour M, Xerri C, Hugon M (1979) Compensation of postural reactions to fall in the vestibular neurectomized monkey. Role of the remaining labyrinthine afferences. Exp Brain Res 37:563–580
Lacour M, Vidal PP, Xerri C (1981) Visual influences on vestibulospinal reflexes during linear vertical motion in normal and hemilabyrinthectomized monkeys. Exp Brain Res 43:383–394
Lacour M, Manzoni D, Pompeiano O, Xerri C (1985) Central compensation of vestibular deficits. III. Response characteristics of lateral vestibular neurons to roll tilt after contralateral labyrinthine deafferentation. J Neurophysiol 54:988–1005
Llinas R, Walton K (1979) Vestibular compensation: a distributed property of the central nervous system. In: Asanuma H, Wilson VJ (eds) Integration in the nervous system. IgakuShoin, Tokyo, pp 145–166
Maioli C, Precht W (1985) On the role of vestibulo-ocular reflex plasticity in recovery after unilateral peripheral vestibular lesions. Exp Brain Res 59:267–272
Maioli C, Precht W, Ried S (1983) Short- and long-term modification of vestibulo-ocular response dynamics following unilateral vestibular nerve lesions in the cat. Exp Brain Res 50:259–274
Matsuo V, Cohen B, Raphan T, de Jong V, Henn V (1979) Asymmetric velocity storage for upward and downward nystagmus. Brain Res 176:159–164
Matsuoka I, Fukuda N, Takaori S, Morimoto M (1971) Responses of single neurons of the vestibular nuclei to lateral tilt and caloric stimulation in the intact and hemilabyrinthectomized cats. Acta Otolaryngol 72:82–190
Mathews DA, Cotman C, Lynch G (1976) An electron microscopic study of lesion-induced synaptogenesis in the dentate gyrus of the adult rat. I. Magnitude and time course of degeneration. Brain Res 115:1–21
McWilliams JR, Lynch G (1979) Terminal proliferation in the partially deafferented dentate gyrus: time course for the appearance and removal of degeneration and the replacement of lost terminals. J Comp Neurol 187:191–198
Pompeiano O, Mergner T, Corvaja N (1978) Commissural, perihypoglossal and reticular afferent projection to the vestibular nuclei in the cat. An experimental-anatomical study with the method of retrogade transport of horseradish peroxidase. Arch Ital Biol 116:130–172
Precht W, Maioli C, Dieringer N, Cochran S (1981) Mechanisms of compensation of the vestibulo-ocular reflex after vestibular neurotomy. In: Flohr H, Precht W (eds) Lesion-induced neuronal plasticity in sensorimotor systems. Springer, Heidelberg New York, Berlin, pp 222–230
Putkonen PT, Courjon JH, Jeannerod M (1977) Compensation of postural effects of hemilabyrinthectomy in the cat. A sensory substitution process? Exp Brain Res 28:249–257
Schaefer KP, Meyer DL (1974) Compensation of vestibular lesions. In: Kornhuber HH (ed) Handbook of sensory physiology, vol 1/2. Springer, Heidelberg Berlin, New York, pp 463–490
Shimazu H (1972) Vestibulo-oculomotor relation: dynamic oculomotor reactions. Prog Brain Res 37:493–506
Shimazu H, Precht W (1966) Inhibition of central vestibular neurons from contralateral labyrinth and its mediating pathway. J Neurophysiol 29:467–472
Smith PF, Curthoys IS (1989) Mechanisms of recovery following unilateral labyrinthectomy: a review. Brain Res Rev 14:155–180
Smith PF, Darlington CL, Curthoys IS (1986) The effect of visual deprivation on vestibular compensation in the guinea pig. Brain Res 364:195–198
Vercher JL, Gauthier GM (1992) Oculo-manual coordination control: ocular and manual tracking of visual targets with delayed visual feedback of the hand motion. Exp Brain Res 90:599–609
Viéville T, Clément G, Lestienne F, Berthoz A (1985) Adaptive modifications of the optokinetic and vestibulo-ocular reflexes in microgravity. In: Keller EL, Zee DS (eds) Adaptive processes in visual and oculomotor systems. Pergamon Press, pp 111–120
Waespe W, Henn V (1977) Neuronal activity in the vestibular nuclei of the alert monkey during vestibular and optokinetic stimulation. Exp Brain Res 27:523–538
Waele C de, Vibert N, Baudrimont M, Vidal PP (1990) NMDA receptors contribute to the resting discharge of vestibular neurons in the normal and hemilabyrinthectomized guinea pig. Exp Brain Res 81:125–133
Waespe W, Schwarz U, Wolfensberger M (1992) Firing characteristics of vestibular nuclei neurons in the alert monkey after bilateral vestibular neurectomy. Exp Brain Res 89:311–322
Wilson VJ, Melvill Jones G (1979) Mammalian vestibular physiology. Plenum Press, New-York and London
Xerri C, Lacour M (1980) Compensation des déficits posturaux et cinétiques après neurectomie vestibulaire unilatérale chez le Chat. Rôle de l'activité sensorimotrice. Acta Otolaryngol 90:414–424
Xerri C, Zennou Y (1989) Sensory, functional and behavioral substitution processes in the vestibular compensation. In: Lacour M, Toupet M, Denise P (eds) Vestibular compensation: facts, theories and clinical perspectives. Elsevier, Paris, pp 35–58
Xerri C, Gianni S, Manzoni D, Pompeiano O (1983) Central compensation of vestibular deficits. I. Response characteristics of lateral vestibular neurons to roll tilt after ipsilateral labyrinth deafferentation. J Neurophysiol 50:428–448
Xerri C, Lacour M, Borel L (1988a) Multimodal sensory substitution process in vestibular compensation. In: Flohr H (ed) Postlesion neuronal plasticity. Springer, Berlin Heidelberg New York, pp 357–370
Xerri C, Barthélémy J, Borel L, Lacour M (1988b) Neuronal coding of linear motion in the vestibular nuclei of the alert cat. III. Dynamic characteristics of visual-otolith interactions. Exp Brain Res 70:299–309
Xerri C, Borel L, Barthélémy J, Lacour M (1988c) Synergistic interactions and functional working range of the visual and vestibular systems in postural control: neuronal correlates. Prog Brain Res 76:193–220
Xerri C, Barthélémy J, Harlay F, Borel L, Lacour M (1987) Neuronal coding of linear motion in the vestibular nuclei of the alert cat. I. Response characteristics to vertical otolith stimulation. Exp Brain Res 65:569–581
Zennou-Azogui Y, Borel L, Lacour M, Ez-Zaher L, Ouakrine M (1993) Recovery of head postural control following unilateral vestibular neurectomy in the cat. Acta Oto Laryngol [Suppl] 509:1–19
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Zennou-Azogui, Y., Xerri, C. & Harlay, F. Visual sensory substitution in vestibular compensation: neuronal substrates in the alert cat. Exp Brain Res 98, 457–473 (1994). https://doi.org/10.1007/BF00233983
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00233983