Massimo Barresi | Università di Catania (original) (raw)

Papers by Massimo Barresi

Brain Research Bulletin, 2009

Cats corticocerebellar units within the anterior vermis are affected by the vestibular input and ... more Cats corticocerebellar units within the anterior vermis are affected by the vestibular input and show directionally tuned responses. The aim of the study was investigating whether a similar representation of labyrinth signals was present in the rat cerebellar vermis by recording units activity during tilt and wobble rotations. The analysis of the neuronal discharge during both clockwise (CW) and counterclockwise (CCW) wobble allowed to determine the spatial (preferred direction) and temporal (response phase) response properties of the recorded neurons. Many units were affected by labyrinthine stimulation. "Bi-directional" units responded to both CW and CCW stimuli, being characterized by a direction of maximal sensitivity (theta(max)), the distribution of which covered all the sectors of the horizontal plane, with contralaterally pointing vectors more represented within the caudal part of the explored region. Differences in the amplitude of the CW and CCW responses indicated that neurons received a convergence of vestibular signals endowed with different spatial and temporal properties, a process that is expected to link their response phase with the tilt direction. Population vector analysis showed that recorded neurons coded both the amplitude and direction of head tilt during different types of rotational stimuli. In conclusion, the present results show that the processing of vestibular signals with complex spatiotemporal properties represents a general function of the mammalian cerebellar vermis, allowing accurate monitoring of head rotational movements (of the head) in vertical planes. Finally, in rats, different cerebellar regions seem to receive specific vestibular inputs.

Archives italiennes de biologie, 2013

Vestibulospinal reflexes can be elicited in humans by low amplitudes direct (galvanic) currents l... more Vestibulospinal reflexes can be elicited in humans by low amplitudes direct (galvanic) currents lasting tens of milliseconds and applied across the two mastoids bones, which can be delivered by particular stimulators. The stimulus induces a perception of body sway and a postural response appropriate to counteract the perceived sway. Both the direction of the perceived and induced body sway are modulated by the orientation of the head with respect to the body. This phenomenon is due to the fact that integration of vestibular and neck signals allows to correctly infer the direction of body sway from the labyrinthine input, which is instead related to direction of head motion. The modulation of stimulus-elicited body sway by neck rotation could be utilised for testing the effectiveness of neck proprioceptive signals in modifying the reference frame for labyrinthine signals from the head to the body. In the present experiments we showed that labyrinthine stimulation can be performed als...

Neuroscience, 2012

Vestibulospinal reflexes elicited by head displacement become appropriate for body stabilization ... more Vestibulospinal reflexes elicited by head displacement become appropriate for body stabilization owing to the integration of neck input by the cerebellar anterior vermis. Due to this integration, the preferred direction of spinal motoneurons' responses to animal tilt rotates by the same angle and by the same direction as the head over the body, which makes it dependent on the direction of body displacement rather than on head displacement. It is known that the cerebellar control of spinal motoneurons involves the reticular formation. Since the preferred directions of corticocerebellar units' responses to animal tilt are tuned by neck rotation, as occuring in spinal motoneurons, we investigated whether a similar tuning can be observed also in the intermediate station of reticular formation. In anaesthetized rats, the activity of neurons in the medullary reticular formation was recorded during wobble of the whole animal at 0.156 Hz, a stimulus that tilted the animal's head by a constant amplitude (5°), in a direction rotating clockwise or counter clockwise over the horizontal plane. The response gain and the direction of tilt eliciting the maximal activity were evaluated with the head and body axes aligned and during a maintained body-to-head displacement of 5-20°o ver the horizontal plane, in either direction. We found that the neck displacement modified the response gain and/or the average activity of most of the responsive neurons. Rotation of the response direction was observed only in a minor percentage of the recorded neurons. The modifications of reticular neurons' responses were different from those observed in the P-cells of the cerebellar anterior vermis, which rarely showed gain and activity changes and often exhibited a rotation of their response directions. In conclusion, reticular neurons take part in the neck tuning of vestibulospinal reflexes by transforming a head-driven sensory input into a body-centred postural response. The present findings prompt re-evaluation of the role played by the reticular neurons and the cerebellum in vestibulospinal reflexes. Ó

Neuroscience, 2014

Increases in firing rate induced in secondary vestibular neurons by microiontophoretic applicatio... more Increases in firing rate induced in secondary vestibular neurons by microiontophoretic application of glutamate were studied during long-lasting applications of noradrenaline (NA) and/or its antagonists and agonists. Sixty-nine percent of the tested neurons, scattered through all nuclei of the vestibular complex, modified their responsiveness to glutamate in the presence of NA. The effects were depressive in a majority (40%) and enhancing in a minority (29%) of cases. NA application depressed responses to glutamate more often than it increased them in lateral, medial and superior vestibular nuclei, while the reverse was true for the spinal nucleus. The mean intensities of NA-evoked effects were comparable in the various nuclei. The enhancing effects of NA were antagonized by application of the alpha2 receptor antagonist yohimbine, and their depressive effects were enhanced by the beta receptor antagonist timolol. It is concluded that NA exerts a control on the processing of vestibular information and that this modulation is exerted by at least two mechanisms involving alpha2 and beta noradrenergic receptors.

Neuroscience, 2013

Vestibulospinal reflexes elicited by head displacement in space depend on the direction of body d... more Vestibulospinal reflexes elicited by head displacement in space depend on the direction of body displacement, because the neuronal responses to labyrinthine stimulation are tuned by neck displacement: a directional tuning takes place in the medial cerebellum and in spinal motoneurons, while a gain and a basal activity tuning can be observed in the reticular formation, a target structure of the medial cerebellum. In the present study, we investigated whether also the response of vestibular nuclear neurons (another target of the medial cerebellum) to labyrinthine stimulation is tuned by neck displacement and which parameters of the response are modulated by it. In urethane-anaesthetized Wistar rats, single-unit activity was recorded from the vestibular nuclei at rest and during wobble of the whole animal at 0.156 Hz. This stimulus tilted the animal's head by a constant amplitude (5°), in a direction rotating at a constant velocity over the horizontal plane, either in clockwise or counter clockwise direction. The gain and the direction of neuronal responses to wobble were evaluated through Fourier analysis, in the control position (with coincident head and body axes) and following a body-to-head rotation of 5-30°over the horizontal plane, in both directions. Most of the vestibular neurons modified their response gain and/or their basal activity following body-to-head rotation, as it occurs in the reticular formation. Only few neurons modified their response direction, as occurs in the cerebellum and in spinal motoneurons. The different behaviour of cerebellar neurons and of their vestibular and reticular target cells, suggests that the role played by the cerebellum in the neck tuning of vestibulospinal reflexes has to be reconsidered. Ó

Human Movement Science, 2011

Changing the foot position modifies the mechanical action exerted by the ankle extensor and flexo... more Changing the foot position modifies the mechanical action exerted by the ankle extensor and flexor muscles over the body. We verified, in two groups of healthy subjects standing with the heels touching or apart, whether a 90°external rotation of the right leg and foot also changes the pattern of vestibulospinal reflexes elicited by electrical stimulation of the labyrinth. With the head oriented forward, leg rotation did not modify the labyrinthinedriven displacements of the center of pressure (CoP). When the head was rotated in the horizontal plane, either to the right or to the left, the CoP displacement increased along the y axis in all subjects. Changes in the x component in most instances appropriate to preserve unmodified the direction of body sway elicited by the stimulus were observed. Right leg rotation increased the basal EMG activity of ankle extensors and flexors on the left side, while the right side activity was unaffected. The EMG responses to labyrinthine stimulation were modified only on the left side, in a way appropriate to correct the effects of the altered torque pattern exerted on the body by right leg muscles. It appears, therefore, that somatosensory signals related to leg rotation and/or copy of the corresponding voluntary motor commands modify the pattern of vestibulospinal reflexes and maintain the postural response appropriate to counteract a body sway in the direction inferred by labyrinthine signals.

PLOS ONE, 2016

Several studies have demonstrated that chewing can be regarded as a preventive measure for cognit... more Several studies have demonstrated that chewing can be regarded as a preventive measure for cognitive impairment, whereas masticatory deficiency, associated with soft-diet feeding, is a risk factor for the development of dementia. At present the link between orofacial sensorimotor activity and cognitive functions is unknown. In subjects with unilateral molar loss we have shown asymmetries in both pupil size and masticatory muscles electromyographic (EMG) activity during clenching: the molar less side was characterized by a lower EMG activity and a smaller pupil. Since implant-prostheses, greatly reduced both the asymmetry in EMG activity and in pupil's size, trigeminal unbalance, leading to unbalance in the activity of the Locus Coeruleus (LC), may be responsible for the pupil's asymmetry. According to the findings obtained in animal models, we propose that the different activity of the right and left LC may induce an asymmetry in brain activity, thus leading to cognitive impairment. According to this hypothesis, prostheses improved the performance in a complex sensorimotor task and increased the mydriasis associated with haptic tasks. In conclusion, the present study indicates that the implant-prosthesis therapy, which reduces the unbalance of trigeminal proprioceptive afferents and the asymmetry in pupil's size, may improve arousal, boosting performance in a complex sensorimotor task.

Archives italiennes de biologie, 2014

We studied whether patients affected by Temporo-Mandibular Disorder (TMD), showing asymmetric ele... more We studied whether patients affected by Temporo-Mandibular Disorder (TMD), showing asymmetric electromyographic (EMG) activity of masticatory muscles also display asymmetries in pupil size. In 30 pain free TMD patients a highly significant, positive correlation was found between left-right differences in EMG and pupil size. The asymmetry in pupil size was induced by the asymmetric sensorimotor signals arising from the orofacial region, since pupils became of about the same size following orthotic correction, which greatly reduced the EMG asymmetry. Moreover, bite wearing bilaterally increased the mydriasis induced by performing haptic tasks. Finally, unbalancing the occlusion by a precontact increased the diameter of the ipsilateral pupil and abolished the mydriasis induced by haptic tasks. In conclusion, trigeminal sensorimotor signals may exert a tonic control on autonomic structures regulating pupil size at rest and during sensorimotor tasks. Since task-associated mydriasis is co...

The Cerebellum, 2012

The spatial organization of vestibulospinal (VS) reflexes, elicited by labyrinthine signals and r... more The spatial organization of vestibulospinal (VS) reflexes, elicited by labyrinthine signals and related to head motion, depends on the direction of body tilt, due to proprioceptive neck afferents acting through the cerebellar anterior vermis. The responses of Purkinje cells located within this region to labyrinthine stimulation are modulated by the head-to-body position. We investigated, in urethaneanesthetized rats, whether a 90°leg-to-trunk displacement modifies the responses of corticocerebellar and vestibular nuclear neurons to the labyrinthine input, which would indicate that VS reflexes are tuned by the leg-to-trunk position. With this aim, unit activity was recorded during "wobble" stimuli that allow evaluating the gain and spatiotemporal properties of neuronal responses. The response gain of corticocerebellar units showed a significant drop in the leg-rotated position with respect to the control one. Following a change in leg position, a proportion of the recorded neurons showed significant changes in the direction and phase of the response vector. In contrast, vestibular nuclear neurons did not show significant modifications in their response gain and direction. Thus, proprioceptive afferents signaling leg-to-trunk position seem to affect the processing of directional labyrinthine signals within the cerebellar cortex.

Neuroscience Letters, 2009

Increases in firing rate induced in secondary vestibular neurons by microiontophoretic applicatio... more Increases in firing rate induced in secondary vestibular neurons by microiontophoretic application of glutamate were studied during long-lasting applications of noradrenaline (NA) and/or its antagonists and agonists. Sixty-nine percent of the tested neurons, scattered through all nuclei of the vestibular complex, modified their responsiveness to glutamate in the presence of NA. The effects were depressive in a majority (40%) and enhancing in a minority (29%) of cases. NA application depressed responses to glutamate more often than it increased them in lateral, medial and superior vestibular nuclei, while the reverse was true for the spinal nucleus. The mean intensities of NA-evoked effects were comparable in the various nuclei. The enhancing effects of NA were antagonized by application of the alpha2 receptor antagonist yohimbine, and their depressive effects were enhanced by the beta receptor antagonist timolol. It is concluded that NA exerts a control on the processing of vestibular information and that this modulation is exerted by at least two mechanisms involving alpha2 and beta noradrenergic receptors.

European Journal of Pharmacology, 2005

Betahistine, a drug used in the treatment of vestibular disorders, speeds-up the recovery from he... more Betahistine, a drug used in the treatment of vestibular disorders, speeds-up the recovery from hemilabyrinthectomy in experimental animals, likely through the activation of histamine receptors. In order to better understand the mechanism of action of this drug we investigated, in adult, urethane anesthetized rats, whether betahistine modifies the spatial (directional) and temporal response properties of vestibular nuclear neurons to the labyrinthine input, as well as the convergence of different labyrinthine signals on single units. Extracellular single-unit activity was recorded from the caudal, spinal-projecting region of the vestibular nuclei during tilt of the animal, before and after i.p. injection of betahistine. The two orthogonal directions of maximal and minimal response to tilt, as well as the corresponding gains were determined for each neuron. Betahistine reduced the maximal response gain of units showing larger basal values of this parameter and increased it in neurons with smaller basal values, while the minimal response gain was on the average raised. These changes led to a significant decrease in the spatial specificity of the neurons, suggesting that betahistine affects the process of spatiotemporal convergence on vestibular units, likely through a rearrangement of the various inputs. This could be related to the effect of the drug on vestibular compensation.

Brain Research Bulletin, 2009

Cats corticocerebellar units within the anterior vermis are affected by the vestibular input and ... more Cats corticocerebellar units within the anterior vermis are affected by the vestibular input and show directionally tuned responses. The aim of the study was investigating whether a similar representation of labyrinth signals was present in the rat cerebellar vermis by recording units activity during tilt and wobble rotations. The analysis of the neuronal discharge during both clockwise (CW) and counterclockwise (CCW) wobble allowed to determine the spatial (preferred direction) and temporal (response phase) response properties of the recorded neurons. Many units were affected by labyrinthine stimulation. "Bi-directional" units responded to both CW and CCW stimuli, being characterized by a direction of maximal sensitivity (theta(max)), the distribution of which covered all the sectors of the horizontal plane, with contralaterally pointing vectors more represented within the caudal part of the explored region. Differences in the amplitude of the CW and CCW responses indicated that neurons received a convergence of vestibular signals endowed with different spatial and temporal properties, a process that is expected to link their response phase with the tilt direction. Population vector analysis showed that recorded neurons coded both the amplitude and direction of head tilt during different types of rotational stimuli. In conclusion, the present results show that the processing of vestibular signals with complex spatiotemporal properties represents a general function of the mammalian cerebellar vermis, allowing accurate monitoring of head rotational movements (of the head) in vertical planes. Finally, in rats, different cerebellar regions seem to receive specific vestibular inputs.

Archives italiennes de biologie, 2014

We studied whether patients affected by Temporo-Mandibular Disorder (TMD), showing asymmetric ele... more We studied whether patients affected by Temporo-Mandibular Disorder (TMD), showing asymmetric electromyographic (EMG) activity of masticatory muscles also display asymmetries in pupil size. In 30 pain free TMD patients a highly significant, positive correlation was found between left-right differences in EMG and pupil size. The asymmetry in pupil size was induced by the asymmetric sensorimotor signals arising from the orofacial region, since pupils became of about the same size following orthotic correction, which greatly reduced the EMG asymmetry. Moreover, bite wearing bilaterally increased the mydriasis induced by performing haptic tasks. Finally, unbalancing the occlusion by a precontact increased the diameter of the ipsilateral pupil and abolished the mydriasis induced by haptic tasks. In conclusion, trigeminal sensorimotor signals may exert a tonic control on autonomic structures regulating pupil size at rest and during sensorimotor tasks. Since task-associated mydriasis is co...

Brain Research Bulletin, 2009

Cats corticocerebellar units within the anterior vermis are affected by the vestibular input and ... more Cats corticocerebellar units within the anterior vermis are affected by the vestibular input and show directionally tuned responses. The aim of the study was investigating whether a similar representation of labyrinth signals was present in the rat cerebellar vermis by recording units activity during tilt and wobble rotations. The analysis of the neuronal discharge during both clockwise (CW) and counterclockwise (CCW) wobble allowed to determine the spatial (preferred direction) and temporal (response phase) response properties of the recorded neurons. Many units were affected by labyrinthine stimulation. "Bi-directional" units responded to both CW and CCW stimuli, being characterized by a direction of maximal sensitivity (theta(max)), the distribution of which covered all the sectors of the horizontal plane, with contralaterally pointing vectors more represented within the caudal part of the explored region. Differences in the amplitude of the CW and CCW responses indicated that neurons received a convergence of vestibular signals endowed with different spatial and temporal properties, a process that is expected to link their response phase with the tilt direction. Population vector analysis showed that recorded neurons coded both the amplitude and direction of head tilt during different types of rotational stimuli. In conclusion, the present results show that the processing of vestibular signals with complex spatiotemporal properties represents a general function of the mammalian cerebellar vermis, allowing accurate monitoring of head rotational movements (of the head) in vertical planes. Finally, in rats, different cerebellar regions seem to receive specific vestibular inputs.

Archives italiennes de biologie, 2013

Vestibulospinal reflexes can be elicited in humans by low amplitudes direct (galvanic) currents l... more Vestibulospinal reflexes can be elicited in humans by low amplitudes direct (galvanic) currents lasting tens of milliseconds and applied across the two mastoids bones, which can be delivered by particular stimulators. The stimulus induces a perception of body sway and a postural response appropriate to counteract the perceived sway. Both the direction of the perceived and induced body sway are modulated by the orientation of the head with respect to the body. This phenomenon is due to the fact that integration of vestibular and neck signals allows to correctly infer the direction of body sway from the labyrinthine input, which is instead related to direction of head motion. The modulation of stimulus-elicited body sway by neck rotation could be utilised for testing the effectiveness of neck proprioceptive signals in modifying the reference frame for labyrinthine signals from the head to the body. In the present experiments we showed that labyrinthine stimulation can be performed als...

Neuroscience, 2012

Vestibulospinal reflexes elicited by head displacement become appropriate for body stabilization ... more Vestibulospinal reflexes elicited by head displacement become appropriate for body stabilization owing to the integration of neck input by the cerebellar anterior vermis. Due to this integration, the preferred direction of spinal motoneurons' responses to animal tilt rotates by the same angle and by the same direction as the head over the body, which makes it dependent on the direction of body displacement rather than on head displacement. It is known that the cerebellar control of spinal motoneurons involves the reticular formation. Since the preferred directions of corticocerebellar units' responses to animal tilt are tuned by neck rotation, as occuring in spinal motoneurons, we investigated whether a similar tuning can be observed also in the intermediate station of reticular formation. In anaesthetized rats, the activity of neurons in the medullary reticular formation was recorded during wobble of the whole animal at 0.156 Hz, a stimulus that tilted the animal's head by a constant amplitude (5°), in a direction rotating clockwise or counter clockwise over the horizontal plane. The response gain and the direction of tilt eliciting the maximal activity were evaluated with the head and body axes aligned and during a maintained body-to-head displacement of 5-20°o ver the horizontal plane, in either direction. We found that the neck displacement modified the response gain and/or the average activity of most of the responsive neurons. Rotation of the response direction was observed only in a minor percentage of the recorded neurons. The modifications of reticular neurons' responses were different from those observed in the P-cells of the cerebellar anterior vermis, which rarely showed gain and activity changes and often exhibited a rotation of their response directions. In conclusion, reticular neurons take part in the neck tuning of vestibulospinal reflexes by transforming a head-driven sensory input into a body-centred postural response. The present findings prompt re-evaluation of the role played by the reticular neurons and the cerebellum in vestibulospinal reflexes. Ó

Neuroscience, 2014

Increases in firing rate induced in secondary vestibular neurons by microiontophoretic applicatio... more Increases in firing rate induced in secondary vestibular neurons by microiontophoretic application of glutamate were studied during long-lasting applications of noradrenaline (NA) and/or its antagonists and agonists. Sixty-nine percent of the tested neurons, scattered through all nuclei of the vestibular complex, modified their responsiveness to glutamate in the presence of NA. The effects were depressive in a majority (40%) and enhancing in a minority (29%) of cases. NA application depressed responses to glutamate more often than it increased them in lateral, medial and superior vestibular nuclei, while the reverse was true for the spinal nucleus. The mean intensities of NA-evoked effects were comparable in the various nuclei. The enhancing effects of NA were antagonized by application of the alpha2 receptor antagonist yohimbine, and their depressive effects were enhanced by the beta receptor antagonist timolol. It is concluded that NA exerts a control on the processing of vestibular information and that this modulation is exerted by at least two mechanisms involving alpha2 and beta noradrenergic receptors.

Neuroscience, 2013

Vestibulospinal reflexes elicited by head displacement in space depend on the direction of body d... more Vestibulospinal reflexes elicited by head displacement in space depend on the direction of body displacement, because the neuronal responses to labyrinthine stimulation are tuned by neck displacement: a directional tuning takes place in the medial cerebellum and in spinal motoneurons, while a gain and a basal activity tuning can be observed in the reticular formation, a target structure of the medial cerebellum. In the present study, we investigated whether also the response of vestibular nuclear neurons (another target of the medial cerebellum) to labyrinthine stimulation is tuned by neck displacement and which parameters of the response are modulated by it. In urethane-anaesthetized Wistar rats, single-unit activity was recorded from the vestibular nuclei at rest and during wobble of the whole animal at 0.156 Hz. This stimulus tilted the animal's head by a constant amplitude (5°), in a direction rotating at a constant velocity over the horizontal plane, either in clockwise or counter clockwise direction. The gain and the direction of neuronal responses to wobble were evaluated through Fourier analysis, in the control position (with coincident head and body axes) and following a body-to-head rotation of 5-30°over the horizontal plane, in both directions. Most of the vestibular neurons modified their response gain and/or their basal activity following body-to-head rotation, as it occurs in the reticular formation. Only few neurons modified their response direction, as occurs in the cerebellum and in spinal motoneurons. The different behaviour of cerebellar neurons and of their vestibular and reticular target cells, suggests that the role played by the cerebellum in the neck tuning of vestibulospinal reflexes has to be reconsidered. Ó

Human Movement Science, 2011

Changing the foot position modifies the mechanical action exerted by the ankle extensor and flexo... more Changing the foot position modifies the mechanical action exerted by the ankle extensor and flexor muscles over the body. We verified, in two groups of healthy subjects standing with the heels touching or apart, whether a 90°external rotation of the right leg and foot also changes the pattern of vestibulospinal reflexes elicited by electrical stimulation of the labyrinth. With the head oriented forward, leg rotation did not modify the labyrinthinedriven displacements of the center of pressure (CoP). When the head was rotated in the horizontal plane, either to the right or to the left, the CoP displacement increased along the y axis in all subjects. Changes in the x component in most instances appropriate to preserve unmodified the direction of body sway elicited by the stimulus were observed. Right leg rotation increased the basal EMG activity of ankle extensors and flexors on the left side, while the right side activity was unaffected. The EMG responses to labyrinthine stimulation were modified only on the left side, in a way appropriate to correct the effects of the altered torque pattern exerted on the body by right leg muscles. It appears, therefore, that somatosensory signals related to leg rotation and/or copy of the corresponding voluntary motor commands modify the pattern of vestibulospinal reflexes and maintain the postural response appropriate to counteract a body sway in the direction inferred by labyrinthine signals.

PLOS ONE, 2016

Several studies have demonstrated that chewing can be regarded as a preventive measure for cognit... more Several studies have demonstrated that chewing can be regarded as a preventive measure for cognitive impairment, whereas masticatory deficiency, associated with soft-diet feeding, is a risk factor for the development of dementia. At present the link between orofacial sensorimotor activity and cognitive functions is unknown. In subjects with unilateral molar loss we have shown asymmetries in both pupil size and masticatory muscles electromyographic (EMG) activity during clenching: the molar less side was characterized by a lower EMG activity and a smaller pupil. Since implant-prostheses, greatly reduced both the asymmetry in EMG activity and in pupil's size, trigeminal unbalance, leading to unbalance in the activity of the Locus Coeruleus (LC), may be responsible for the pupil's asymmetry. According to the findings obtained in animal models, we propose that the different activity of the right and left LC may induce an asymmetry in brain activity, thus leading to cognitive impairment. According to this hypothesis, prostheses improved the performance in a complex sensorimotor task and increased the mydriasis associated with haptic tasks. In conclusion, the present study indicates that the implant-prosthesis therapy, which reduces the unbalance of trigeminal proprioceptive afferents and the asymmetry in pupil's size, may improve arousal, boosting performance in a complex sensorimotor task.

Archives italiennes de biologie, 2014

We studied whether patients affected by Temporo-Mandibular Disorder (TMD), showing asymmetric ele... more We studied whether patients affected by Temporo-Mandibular Disorder (TMD), showing asymmetric electromyographic (EMG) activity of masticatory muscles also display asymmetries in pupil size. In 30 pain free TMD patients a highly significant, positive correlation was found between left-right differences in EMG and pupil size. The asymmetry in pupil size was induced by the asymmetric sensorimotor signals arising from the orofacial region, since pupils became of about the same size following orthotic correction, which greatly reduced the EMG asymmetry. Moreover, bite wearing bilaterally increased the mydriasis induced by performing haptic tasks. Finally, unbalancing the occlusion by a precontact increased the diameter of the ipsilateral pupil and abolished the mydriasis induced by haptic tasks. In conclusion, trigeminal sensorimotor signals may exert a tonic control on autonomic structures regulating pupil size at rest and during sensorimotor tasks. Since task-associated mydriasis is co...

The Cerebellum, 2012

The spatial organization of vestibulospinal (VS) reflexes, elicited by labyrinthine signals and r... more The spatial organization of vestibulospinal (VS) reflexes, elicited by labyrinthine signals and related to head motion, depends on the direction of body tilt, due to proprioceptive neck afferents acting through the cerebellar anterior vermis. The responses of Purkinje cells located within this region to labyrinthine stimulation are modulated by the head-to-body position. We investigated, in urethaneanesthetized rats, whether a 90°leg-to-trunk displacement modifies the responses of corticocerebellar and vestibular nuclear neurons to the labyrinthine input, which would indicate that VS reflexes are tuned by the leg-to-trunk position. With this aim, unit activity was recorded during "wobble" stimuli that allow evaluating the gain and spatiotemporal properties of neuronal responses. The response gain of corticocerebellar units showed a significant drop in the leg-rotated position with respect to the control one. Following a change in leg position, a proportion of the recorded neurons showed significant changes in the direction and phase of the response vector. In contrast, vestibular nuclear neurons did not show significant modifications in their response gain and direction. Thus, proprioceptive afferents signaling leg-to-trunk position seem to affect the processing of directional labyrinthine signals within the cerebellar cortex.

Neuroscience Letters, 2009

Increases in firing rate induced in secondary vestibular neurons by microiontophoretic applicatio... more Increases in firing rate induced in secondary vestibular neurons by microiontophoretic application of glutamate were studied during long-lasting applications of noradrenaline (NA) and/or its antagonists and agonists. Sixty-nine percent of the tested neurons, scattered through all nuclei of the vestibular complex, modified their responsiveness to glutamate in the presence of NA. The effects were depressive in a majority (40%) and enhancing in a minority (29%) of cases. NA application depressed responses to glutamate more often than it increased them in lateral, medial and superior vestibular nuclei, while the reverse was true for the spinal nucleus. The mean intensities of NA-evoked effects were comparable in the various nuclei. The enhancing effects of NA were antagonized by application of the alpha2 receptor antagonist yohimbine, and their depressive effects were enhanced by the beta receptor antagonist timolol. It is concluded that NA exerts a control on the processing of vestibular information and that this modulation is exerted by at least two mechanisms involving alpha2 and beta noradrenergic receptors.

European Journal of Pharmacology, 2005

Betahistine, a drug used in the treatment of vestibular disorders, speeds-up the recovery from he... more Betahistine, a drug used in the treatment of vestibular disorders, speeds-up the recovery from hemilabyrinthectomy in experimental animals, likely through the activation of histamine receptors. In order to better understand the mechanism of action of this drug we investigated, in adult, urethane anesthetized rats, whether betahistine modifies the spatial (directional) and temporal response properties of vestibular nuclear neurons to the labyrinthine input, as well as the convergence of different labyrinthine signals on single units. Extracellular single-unit activity was recorded from the caudal, spinal-projecting region of the vestibular nuclei during tilt of the animal, before and after i.p. injection of betahistine. The two orthogonal directions of maximal and minimal response to tilt, as well as the corresponding gains were determined for each neuron. Betahistine reduced the maximal response gain of units showing larger basal values of this parameter and increased it in neurons with smaller basal values, while the minimal response gain was on the average raised. These changes led to a significant decrease in the spatial specificity of the neurons, suggesting that betahistine affects the process of spatiotemporal convergence on vestibular units, likely through a rearrangement of the various inputs. This could be related to the effect of the drug on vestibular compensation.

Brain Research Bulletin, 2009

Cats corticocerebellar units within the anterior vermis are affected by the vestibular input and ... more Cats corticocerebellar units within the anterior vermis are affected by the vestibular input and show directionally tuned responses. The aim of the study was investigating whether a similar representation of labyrinth signals was present in the rat cerebellar vermis by recording units activity during tilt and wobble rotations. The analysis of the neuronal discharge during both clockwise (CW) and counterclockwise (CCW) wobble allowed to determine the spatial (preferred direction) and temporal (response phase) response properties of the recorded neurons. Many units were affected by labyrinthine stimulation. "Bi-directional" units responded to both CW and CCW stimuli, being characterized by a direction of maximal sensitivity (theta(max)), the distribution of which covered all the sectors of the horizontal plane, with contralaterally pointing vectors more represented within the caudal part of the explored region. Differences in the amplitude of the CW and CCW responses indicated that neurons received a convergence of vestibular signals endowed with different spatial and temporal properties, a process that is expected to link their response phase with the tilt direction. Population vector analysis showed that recorded neurons coded both the amplitude and direction of head tilt during different types of rotational stimuli. In conclusion, the present results show that the processing of vestibular signals with complex spatiotemporal properties represents a general function of the mammalian cerebellar vermis, allowing accurate monitoring of head rotational movements (of the head) in vertical planes. Finally, in rats, different cerebellar regions seem to receive specific vestibular inputs.

Archives italiennes de biologie, 2014

We studied whether patients affected by Temporo-Mandibular Disorder (TMD), showing asymmetric ele... more We studied whether patients affected by Temporo-Mandibular Disorder (TMD), showing asymmetric electromyographic (EMG) activity of masticatory muscles also display asymmetries in pupil size. In 30 pain free TMD patients a highly significant, positive correlation was found between left-right differences in EMG and pupil size. The asymmetry in pupil size was induced by the asymmetric sensorimotor signals arising from the orofacial region, since pupils became of about the same size following orthotic correction, which greatly reduced the EMG asymmetry. Moreover, bite wearing bilaterally increased the mydriasis induced by performing haptic tasks. Finally, unbalancing the occlusion by a precontact increased the diameter of the ipsilateral pupil and abolished the mydriasis induced by haptic tasks. In conclusion, trigeminal sensorimotor signals may exert a tonic control on autonomic structures regulating pupil size at rest and during sensorimotor tasks. Since task-associated mydriasis is co...