Évaluation du contrôle sensorimoteur chez les patients ayant une scoliose idiopathique de l'adolescent - Vers un biomarqueur des troubles sensorimoteur basé sur la stimulation vestibulaire galvanique

La scoliose est la pathologie déformante du rachis la plus courante de l’adolescence. Dans 80 % des cas, elle est idiopathique, signifiant qu’aucune cause n’a été associée. Les scolioses idiopathiques répondent à un modèle multifactoriel incluant des facteurs génétiques, environnementaux, neurologiques, hormonaux, biomécaniques et de croissance squelettique. Comme hypothèse neurologique, une anomalie vestibulaire provoquerait une asymétrie d’activation des voies vestibulospinales et des muscles paravertébraux commandés par cette voie, engendrant la déformation scoliotique. Certains modèles animaux permettent de reproduire ce mécanisme. De plus, des anomalies liées au système vestibulaire, comme des troubles de l’équilibre, sont observées chez les patients avec une scoliose. La stimulation vestibulaire galvanique permet d’explorer le contrôle sensorimoteur de l’équilibre puisqu’elle permet d’altérer les afférences vestibulaires. L’objectif de cette thèse est d’explorer le contrôle sensorimoteur en évaluant la réaction posturale provoquée par cette stimulation chez les patients et les participants contrôle. Dans la première étude, les patients sont plus déstabilisés que les contrôles et il n’y a pas de lien entre l’ampleur de l’instabilité et la sévérité de la scoliose. Dans la deuxième étude, à l’aide d’un modèle neuromécanique, un poids plus grand aux signaux vestibulaires a été attribué aux patients. Dans la troisième étude, un problème sensorimoteur est également observé chez les jeunes adultes ayant une scoliose, excluant ainsi que le problème soit dû à la maturation du système nerveux. Dans une étude subséquente, des patients opérés pour réduire leur déformation du rachis, montrent également une réaction posturale de plus grande amplitude à la stimulation comparativement à des participants contrôle. Ces résultats suggèrent que l’anomalie sensorimotrice ne serait pas secondaire à la déformation. Finalement, un algorithme a été développé pour identifier les patients ayant un problème sensorimoteur. Les patients montrant un contrôle sensorimoteur anormal ont également une réponse vestibulomotrice plus grande et attribuent plus de poids aux informations vestibulaires. Globalement, les résultats de cette thèse montrent qu’un déficit sensorimoteur expliquerait l’apparition de la scoliose mais pas sa progression. Le dysfonctionnement sensorimoteur n’est pas présent chez tous les patients. L’algorithme permettant une classification de la performance sensorimotrice pourrait être utile pour de futures études cliniques.

Cerebro-corticale und subcorticale Prozessierung vestibulärer Informationen im intakten und lädierten System der Ratte (Micro-PET-Studie)

In dieser Studie wurde anhand des Modells der Ratte das Gleichgewichtssystem auf cerebro-corticaler Ebene untersucht, und das Verhalten des Gehirns nach akuten sowie chronischen Ausfällen mit funktioneller Bildgebung untersucht. rnMit der Positronen-Emissions-Tomographie (PET) kann die Metabolismusrate bestimmter Gehirnareale gemessen werden. Narkotisierte Tiere wurden unter galvanischer vestibulärer Stimulation im PET gemessen und die Ergebnisse wurden mit Kontrollstimulations-Messungen verglichen. Es konnten verschiedene Areale, die eine erhöhte Stoffwechselaktivität aufwiesen, ermittelt werden. Dazu gehören der somatosensorische und der insuläre Cortex, Teile des auditorischen Cortexes, der anteriore cinguläre sowie der entorhinale Cortex. Subcorticale Strukturen wie der Hippocampus, die Amygdala sowie die latero-dorsalen thalamischen Kerne wiesen ebenfalls erhöhten Stoffwechsel unter vestibulärer Stimulation auf. rnBei dieser PET-Studie handelt es sich um die erste funktionell-bildgebende Studie, die Verarbeitung vestibulärer Informationen bei Ratten in vivo darstellt. Die anatomische Verbindung der gefundenen Areale wurde mit anterograden und retrograden neuronalen Tracings unterstützt. rnDarüber hinaus wurde markiertes Gewebe, welches die Verbindung zwischen thalamischen und cerebro-corticalen Kernen der vestibulären Verschaltung aufweist, immunhistochemisch auf dessen Neurotransmission hin untersucht. Das katecholaminergen und dem opioidergen System wurde untersucht. Eine Beteiligung katecholaminerger Transmitter konnte nicht nachgewiesen werden. Neurone im somatosensorischen Cortex, die positiv auf einen Opioid-Rezeptor-Antikörper getestet wurden erhalten anterograd markierte Terminale aus dem thalamischen Kern LDDM, der mittels der PET als vestibulär identifiziert werden konnte. rnBasierend auf den Ergebnissen der ersten bildgebenden Studie wurde in einer zweiten funktionell-bildgebenden Studie die zentral-vestibuläre Verschaltung unterbrochen, indem relevante thalamische Kerngebiete (LDDM, LDVL) elektrolytisch zerstört wurden. Die Stoffwechselaktivität wurde anschließend bei diesen Tieren an verschiedenen Zeitpunkten nach der Läsion im PET unter vestibulärer Stimulation gemessen. Die Stoffwechselaktivität dieser Tiere wurde mit der Stoffwechselaktivität von Kontroll-Tieren verglichen. rnBei dieser Studie wurde zum ersten Mal, mittels funktioneller Bildgebung gezeigt, welche Bereiche des Gehirns nach akuter und chronischer Läsion des vestibulären Systems an Kompensationsmechanismen beteiligt sind. Alle Gehirnareale, die in verschiedenen Zeitfenstern (1, 3, 7 und 20 Tage nach Läsion) erhöhten Metabolismus aufweisen, sind Teil der vestibulären Verschaltung. Es handelt sich dabei um Areale der Okulomotorik und des räumlichen Gedächtnisses: das Postsubiculum, den Colliculus superior, das mediale Corpus geniculatum, den entorhinalen Cortex sowie die Zona incerta.rn

Changes in head and neck position affect elbow joint position sense

Changes in the position of the head and neck have been shown to introduce a systematic deviation in the end-point error of an upper limb pointing task. Although previous authors have attributed this to alteration of perceived target location, no studies have explored the effect of changes in head and neck position on the perception of limb position. This study investigated whether changes in head and neck position affect a specific component of movement performance, that is, the accuracy of joint position sense (JPS) at the elbow. Elbow JPS was tested with the neck in four positions: neutral, flexion, rotation and combined flexion/rotation. A target angle was presented passively with the neck in neutral, after a rest period; this angle was reproduced actively with the head and neck in one of the test positions. The potential effects of distraction from head movement were controlled for by performing a movement control in which the head and neck were in neutral for the presentation and reproduction of the target angle, but moved into flexion during the rest period. The absolute and variable joint position errors (JPE) were greater when the target angle was reproduced with the neck in the flexion, rotation, and combined flexion/rotation than when the head and neck were in neutral. This study suggests that the reduced accuracy previously seen in pointing tasks with changes in head position may be partly because of errors in the interpretation of arm position.

Do you know where your arm is if you think your head has moved?

Reproduction of a previously presented elbow position is affected by changes in head position. As movement of the head is associated with local biomechanical changes, the aim of the present study was to determine if illusory changes in head position could induce similar effects on the reproduction of elbow position. Galvanic vestibular stimulation (GVS) was applied to healthy subjects in supine lying. The stimulus was applied during the presentation of an elbow position, which the subject then reproduced without stimulation. In the first study, 13 subjects received 1.5 mA stimuli, which caused postural sway in standing, confirming that the firing of vestibular afferents was affected, but no illusory changes in head position were reported. In the second study, 13 subjects received 2.0-3.0 mA GVS. Six out of 13 subjects reported consistent illusory changes in head position, away from the side of the anode. In these subjects, anode right stimulation induced illusory left lateral flexion and elbow joint position error towards extension (p=0.03), while anode left tended to have the opposite effect (p=0.16). The GVS had no effect on error in subjects who did not experience illusory head movement with either 1.5 mA stimulus (p=0.8) or 2.0-3.0 mA stimulus (p=0.7). This study demonstrates that the accuracy of elbow repositioning is affected by illusory changes in head position. These results support the hypothesis that the perceived position of proximal body segments is used in the planning and performance of accurate upper limb movements.

Les interactions vestibulo-corticales qui sous-tendent le contrôle de la posture chez les sujets sains

Le système vestibulaire et le cortex moteur participent au contrôle de la posture, mais la nature de leurs interactions est peu documentée. Afin de caractériser les interactions vestibulo-corticales qui sous-tendent le contrôle de l’équilibre en position debout, l’activité électromyographique (EMG) du soléaire (SOL), du tibial antérieur (TA) et du péronier long (PERL) de la jambe droite a été enregistrée chez 14 sujets sains. La stimulation galvanique vestibulaire (GVS) a été appliquée avec la cathode derrière l’oreille droite ou gauche à différents intervalles inter-stimulus (ISIs) avant ou après la stimulation magnétique transcrânienne induisant des potentiels moteurs évoqués (MEPs) au niveau des muscles enregistrés. Lorsque que la cathode était à droite, une inhibition des MEPs a été observée au niveau du SOL à un ISI de 40 et 130 ms et une facilitation des MEPS a été observée au niveau TA à un ISI de 110 ms. Lorsque la cathode était à gauche, une facilitation des MEPs a été observée au niveau du SOL, du TA et du PERL à un ISI de 50, -10 et 0 ms respectivement. L’emplacement de ces interactions sur l’axe neural a été estimé en fonction des ISIs et en comparant l’effet de la GVS sur les MEPs à son effet sur l’EMG de base et sur le réflexe-H. Selon ces analyses, les modulations observées peuvent avoir lieu au niveau spinal ou au niveau supraspinal. Ces résultats suggèrent que les commandes de la voie corticospinale peuvent être modulées par le système vestibulaire à différents niveaux de l’axe neuronal.

Les interactions vestibulo-corticales qui sous-tendent le contrôle de la posture chez les sujets sains

Le système vestibulaire et le cortex moteur participent au contrôle de la posture, mais la nature de leurs interactions est peu documentée. Afin de caractériser les interactions vestibulo-corticales qui sous-tendent le contrôle de l’équilibre en position debout, l’activité électromyographique (EMG) du soléaire (SOL), du tibial antérieur (TA) et du péronier long (PERL) de la jambe droite a été enregistrée chez 14 sujets sains. La stimulation galvanique vestibulaire (GVS) a été appliquée avec la cathode derrière l’oreille droite ou gauche à différents intervalles inter-stimulus (ISIs) avant ou après la stimulation magnétique transcrânienne induisant des potentiels moteurs évoqués (MEPs) au niveau des muscles enregistrés. Lorsque que la cathode était à droite, une inhibition des MEPs a été observée au niveau du SOL à un ISI de 40 et 130 ms et une facilitation des MEPS a été observée au niveau TA à un ISI de 110 ms. Lorsque la cathode était à gauche, une facilitation des MEPs a été observée au niveau du SOL, du TA et du PERL à un ISI de 50, -10 et 0 ms respectivement. L’emplacement de ces interactions sur l’axe neural a été estimé en fonction des ISIs et en comparant l’effet de la GVS sur les MEPs à son effet sur l’EMG de base et sur le réflexe-H. Selon ces analyses, les modulations observées peuvent avoir lieu au niveau spinal ou au niveau supraspinal. Ces résultats suggèrent que les commandes de la voie corticospinale peuvent être modulées par le système vestibulaire à différents niveaux de l’axe neuronal.

Avaliação vestibular em indivíduos com cinetose

A cinetose tem elevada prevalência mundial, sendo mais frequente na infância e no sexo feminino, mas também pode acometer adultos. Resulta de um conflito vestíbulo-visual que incide durante a locomoção em diversos meios de transporte, como carro, ônibus, avião e barco. A forma mais dramática ocorre no transporte marítimo. Ocasiona náusea, vômito, sudorese, aumento da salivação, redução do apetite, hipotensão e mal-estar. Geralmente é produzida por estímulo vestibular, mas também pode ser induzida por estímulo visual. Tanto as acelerações lineares quanto angulares geram cinetose se persistirem por longo período em indivíduos susceptíveis. Recentemente ocorre maior interesse nessa afecção devido ao crescente uso de tecnologia de simulação de vôo e direção automobilística. O objetivo do estudo foi analisar as alterações vestibulares nos indivíduos adultos com cinetose. Trata-se de um estudo prospectivo, tipo série de casos. Os pacientes do ambulatório do Hospital Universitário Pedro Ernesto-UERJ foram avaliados através de anamnese geral e dirigida e exame fisico geral e otorrinolaringológico. Aqueles com histórico de doença otológica foram excluídos. Posteriormente realizaram audiometria e testes vestibulares com o registro gráfico dos nistagmos através da vectoeletronistagmografia. Nos resultados das provas calóricas encontramos 3,33% de pacientes com alteração de predomínio direcional, 6,67% com alteração de predomínio labiríntico, 3,33% com hiperreflexia esquerda, 3,33% com hiporreflexia direita e 3,33% com hiporreflexia esquerda. Encontrados algumas variações na análise dos movimentos sacádicos, nistagmo optocinético e rastreio pendular. Os resultados foram de encontro aos achados da literatura. Diante dos achados, foi observado que o exame otoneurológico com registro gráfico da cinetose mostrou-se muito importante para a avaliação dos pacientes com essa afecção. O estudo traz benefícios por contribuir para o melhor entendimento da cinetose e estimular novas pesquisas na área.

Balancing the mind: vestibular induced facilitation of egocentric mental transformations

The body schema is a key component in accomplishing egocentric mental transformations, which rely on bodily reference frames. These reference frames are based on a plurality of different cognitive and sensory cues among which the vestibular system plays a prominent role. We investigated whether a bottom-up influence of vestibular stimulation modulates the ability to perform egocentric mental transformations. Participants were significantly faster to make correct spatial judgments during vestibular stimulation as compared to sham stimulation. Interestingly, no such effects were found for mental transformation of hand stimuli or during mental transformations of letters, thus showing a selective influence of vestibular stimulation on the rotation of whole-body reference frames. Furthermore, we found an interaction with the angle of rotation and vestibular stimulation demonstrating an increase in facilitation during mental body rotations in a direction congruent with rightward vestibular afferents. We propose that facilitation reflects a convergence in shared brain areas that process bottom-up vestibular signals and top-down imagined whole-body rotations, including the precuneus and tempero-parietal junction. Ultimately, our results show that vestibular information can influence higher-order cognitive processes, such as the body schema and mental imagery.

Spatial cognition, body representation and affective processes: the role of vestibular information beyond ocular reflexes and control of posture

A growing number of studies in humans demonstrate the involvement of vestibular information in tasks that are seemingly remote from well-known functions such as space constancy or postural control. In this review article we point out three emerging streams of research highlighting the importance of vestibular input: (1) Spatial Cognition: Modulation of vestibular signals can induce specific changes in spatial cognitive tasks like mental imagery and the processing of numbers. This has been shown in studies manipulating body orientation (changing the input from the otoliths), body rotation (changing the input from the semicircular canals), in clinical findings with vestibular patients, and in studies carried out in microgravity. There is also an effect in the reverse direction; top-down processes can affect perception of vestibular stimuli. (2) Body Representation: Numerous studies demonstrate that vestibular stimulation changes the representation of body parts, and sensitivity to tactile input or pain. Thus, the vestibular system plays an integral role in multisensory coordination of body representation. (3) Affective Processes and Disorders: Studies in psychiatric patients and patients with a vestibular disorder report a high comorbidity of vestibular dysfunctions and psychiatric symptoms. Recent studies investigated the beneficial effect of vestibular stimulation on psychiatric disorders, and how vestibular input can change mood and affect. These three emerging streams of research in vestibular science are—at least in part—associated with different neuronal core mechanisms. Spatial transformations draw on parietal areas, body representation is associated with somatosensory areas, and affective processes involve insular and cingulate cortices, all of which receive vestibular input. Even though a wide range of different vestibular cortical projection areas has been ascertained, their functionality still is scarcely understood.

Negative emotional stimuli enhance vestibular processing

Recent studies have shown that vestibular stimulation can influence affective processes. In the present study, we examined whether emotional information can also modulate vestibular perception. Participants performed a vestibular discrimination task on a motion platform while viewing emotional pictures. Six different picture categories were taken from the International Affective Picture System: mutilation, threat, snakes, neutral objects, sports and erotic pictures. Using a Bayesian hierarchical approach we were able to show that vestibular discrimination improved when participants viewed emotionally negative pictures (mutilation, threat, snake) when compared to neutral objects. There was no difference in vestibular discrimination while viewing emotionally positive compared to neutral pictures. We conclude that some of the mechanisms involved in the processing of vestibular information are also sensitive to emotional content. Emotional information signals importance and mobilizes the body for action. In case of danger, a successful motor response requires precise vestibular processing. Therefore, negative emotional information improves processing of vestibular information.

Negative emotional stimuli enhance vestibular processing

Recent studies have shown that vestibular stimulation can influence affective processes. In the present study, we examined whether emotional information can also modulate vestibular perception. Participants performed a vestibular discrimination task on a motion platform while viewing emotional pictures. Six different picture categories were taken from the International Affective Picture System: mutilation, threat, snakes, neutral objects, sports and erotic pictures. Using a Bayesian hierarchical approach we were able to show that vestibular discrimination improved when participants viewed emotionally negative pictures (mutilation, threat, snake) when compared to neutral objects. There was no difference in vestibular discrimination while viewing emotionally positive compared to neutral pictures. We conclude that some of the mechanisms involved in the processing of vestibular information are also sensitive to emotional content. Emotional information signals importance and mobilizes the body for action. In case of danger, a successful motor response requires precise vestibular processing. Therefore, negative emotional information improves processing of vestibular information.

Negative Emotional Stimuli Enhance Vestibular Processing

Recent studies have shown that vestibular stimulation can influence affective processes. In the present study, we examined whether emotional information can also modulate vestibular perception. Participants performed a vestibular discrimination task on a motion platform while viewing emotional pictures. Six different picture categories were taken from the International Affective Picture System: mutilation, threat, snakes, neutral objects, sports, and erotic pictures. Using a Bayesian hierarchical approach, we were able to show that vestibular discrimination improved when participants viewed emotionally negative pictures (mutilation, threat, snake) when compared to neutral/positive objects. We conclude that some of the mechanisms involved in the processing of vestibular information are also sensitive to emotional content. Emotional information signals importance and mobilizes the body for action. In case of danger, a successful motor response requires precise vestibular processing. Therefore, negative emotional information improves processing of vestibular information.

Differential effect of elevated intralabyrinthine pressure on ocular vestibular evoked myogenic potentials elicited by air conducted sound and bone conducted vibration

Recently, ocular vestibular evoked myogenic potentials (oVEMP) have emerged as a tool for assessment of utricular function. They are short-latency myogenic potentials which can be elicited in response to vestibular stimulation, e.g. by air-conducted sound (ACS) or bone-conducted vibration (BCV) (reviewed in (Kantner and Gurkov, 2012)). Otolithic afferent neurons trigger reflexive electromyographic activity of the extraocular muscles which can be recorded beneath the eye contralateral to the stimulated ear by use of surface electrodes.

The Effect of Increasing Intracranial Pressure on Ocular Vestibular-Evoked Myogenic Potential Frequency Tuning.

OBJECTIVE Ocular vestibular-evoked myogenic potentials (oVEMPs) represent extraocular muscle activity in response to vestibular stimulation. The authors sought to investigate whether posture-induced increase of the intracranial pressure (ICP) modulated oVEMP frequency tuning, that is, the amplitude ratio between 500-Hz and 1000-Hz stimuli. DESIGN Ten healthy subjects were enrolled in this study. The subjects were positioned in the horizontal plane (0 degree) and in a 30-degree head-downwards position to elevate the ICP. In both positions, oVEMPs were recorded using 500-Hz and 1000-Hz air-conducted tone bursts. RESULTS When tilting the subject from the horizontal plane to the 30-degree head-down position, oVEMP amplitudes in response to 500-Hz tone bursts distinctly decreased (3.40 μV versus 2.06 μV; p < 0.001), whereas amplitudes to 1000 Hz were only slightly diminished (2.74 μV versus 2.48 μV; p = 0.251). Correspondingly, the 500/1000-Hz amplitude ratio significantly decreased when tilting the subjects from 0- to 30-degree inclination (1.59 versus 1.05; p = 0.029). Latencies were not modulated by head-down position. CONCLUSIONS Increasing ICP systematically alters oVEMPs in terms of absolute amplitudes and frequency tuning characteristics. oVEMPs are therefore in principle suited for noninvasive ICP monitoring.