Elaboração de curva brasileira de normalidade de excitabilidade cortical / Normative data of cortical excitability in a Brazilian population

Moscoso, Ana Sofia Cueva

15 January 2013

INTRODUÇÃO: A obtenção de medidas de excitabilidade cortical mediante a estimulação magnética transcraniana tem surgido nos últimos anos como método de avaliação da integridade funcional do trato cortico-spinal e rede interneuronal no córtex primário motor, abrindo perspectiva de utilizá-la na prática clínica. Alterações nos parâmetros de excitabilidade cortical tem sido relatados na síndrome fibromiálgica e outras síndromes dolorosas, se correlacionando com a gravidade de diferentes componentes dessas síndromes e mudando conforme o tratamento. Entretanto, apesar do seu potencial benefício, existe uma pequena quantidade de estudos disponíveis na literatura que tenham proposto a obtenção de dados de normalidade para esses parâmetros, com casuísticas pequenas, não pareadas por fatores que potencialmente alteraram seus valores. O presente estudo procurou montar uma curva de normalidade de parâmetros de excitabilidade cortical com cálculo de amostra, pareamento por idade e sexo, com estudo dos efeitos da lateralidade hemisférica e dominância, fase do ciclo menstrual e variabilidade inter e intraexaminador. MÉTODOS: Após cálculo amostral, foram convocados voluntários saudáveis do sexo masculino e feminino, pareados por idade. No total, 216 voluntários completaram o estudo. O potencial evocado motor, inibição intracortical e facilitação intracortical foram medidas no músculo primeiro interósseo dorsal após estímulo dos córtices motor primário bilateral. O grupo de 15 mulheres fez a primeira medição do uso de anticoncepcional oral e a segunda medição na fase de descanso do mesmo. A variabilidade interexaminador e intraexaminador foi aferida em 20 voluntários para cada uma das situações. RESULTADOS: A comparação entre os parâmetros de voluntários menores que 50 anos e maiores que 50 anos mostrou diferenças significativas. Foram obtidos os valores de normalidade para menores de 50 anos e maiores de 50 anos (média e desvio padrão): 1.Menores ou igual que 50 anos: LMR: 49 ± 9,39%; PEM 120%: 587,63±779,52 V; MEP 140%: 1413,08±1343,18 V; MEP 120/140%: 3,83±5,39 V; IIC 2ms: 0,40 ±0,44 V; IIC 4ms: 0,61± 0,84 V; IIC: 0,56± 0,63 V; FIC 10ms: 1,95 ±1,82 V; FIC 15ms: 1,80±1,73 V; FIC: 1,87±1,64 V. 2. Maiores de 50 anos: LMR: 49,1 ± 9.58%; PEM 120%:467,71±650,61 V; PEM 140%:1172,43±1158,47 V; PEM 120/140%: 4,04±4,27 V; IIC2ms: 0,73± 1,26 V; IIC 4ms: 1,04±1,67 V; IIC:0,81±1,03 V; FIC 10ms:2,46±3,85 V; FIC 15ms: 2,12±3,05 V; FIC: 2,28±3,32 V. Houve semelhança entre homens e mulheres( p>0,3). Os córtices motores direito e esquerdo apresentaram parâmetros semelhantes de excitabilidade cortical (p>0,25) para todas as análises. Assim, os valores para o hemisfério direito e esquerdo e os dados de homens e mulheres foram agrupados. Não houve diferença estatística significativa entre destros e sinistros (p>0,20). A variabilidade inter e intraexaminador é alta para a maior parte dos parâmetros, porém, com alta correlação para o limiar motor em repouso e potenciais evocados motores. A inibição e facilitação cortical tiveram baixa correlação, mas confiabilidade aceitável. Não houve diferença importante entre a quantidade de medidas anormais obtidas entre as fases do ciclo menstrual com ou sem o uso do anticoncepcional oral. CONCLUSÕES: Foram levantados os parâmetros de normalidade para adultos saudáveis acima e abaixo de 50 anos. A idade não tem um efeito linear sobre a excitabilidade cortical. Não há diferenças significativas entre sexo, lateralidade de hemisfério ou dominância sobre parâmetros de excitabilidade cortical. Não há correlação significativa entre as fases de uso de anticoncepcional oral e do seu descanso (período menstrual) com as medidas de excitabilidade cortical / BACKGROUND AND AIMS: Measures of cortical excitability parameters by transcranial magnetic stimulation have gained increasing interest as a way to obtain information on the functional integrity of the cortico-spinal tract and interneuronal networks within the primary motor cortex. Changes in cortical excitability parameters have been reported in fibromyalgia and neuropathic pain syndromes showing correlation with the severity of different symptoms of these pain syndromes, and seeming to change during treatment. Despite its potential use, there is a paucity of normative data for cortical excitability parameters. We aimed to obtain normative data for cortical excitability in healthy volunteers. METHODS: A sample size of men and women were matched according to age. In total 216 healthy volunteers completed the study. Rest motor threshold (RMT), motor evoked potentials (MEP), intracortical inhibition (ICI) and facilitation (ICF) were measured in the first dorsal interosseous muscle for both primary motor cortex A group of 15 women were measured twice, first during use of oral contraceptive and a second measure was obtained when not in use of it (menstruations phase). The inter and intrainvestigator variability was assessed in a sample of 20 healthy volunteers. RESULTS: The comparison between the cortical excitability parameters from volunteers younger than 50 years old and volunteers older than 50 years showed significant differences. Normative data for younger than 50 years and older than 50 years were obtained (mean and standard deviation): 1. Age of 50 years or younger: RMT: 49 ±9.39%; MEP120%: 587.63±779.52 V; MEP140%: 1413.08±1343.18 V; MEP120/140%: 3.83±5.39 V; ICI2ms: 0.40 ±0.44; ICI4ms: 0.61 ±0.84 V; ICI: 0.56±0.63 V; ICF10ms: 1.95 ±1.82 V; ICF15ms: 1.80±1.73 V; ICF: 1.87±1.64 V. 2. Older than 50 years: RMT: 49.1±9.58%; MEP120%: 467.71±650.61 V; MEP140%: 1172.43±1158.47 V; MEP120/140%: 4.04±4.27V; ICI2ms: 0.73± 1.26 V; ICI4ms: 1.04±1.67 V; ICI: 0.81±1.03 V; ICF10ms:2.46±3.85 V; ICF15ms: 2.12±3.05 V; ICF: 2.28±3.32 V. There was similarity between genders (p>0,3.) There was no difference between left and right hemispheres (p>0,25). Consequently data from both hemispheres and genders were grouped. There was no significant statistical difference between handedness. We found a good inter/intrainvestigator correlation for RMT and MEP. ICI and ICF had low correlations but an acceptable reliability. CONCLUSIONS: We reported normative data for cortical excitability in adult individuals younger and older than 50 years old. Age has a non-linear effect on cortical excitability. We found no left-right cortex asymmetries or differences related to gender or handedness. We found no correlation between the phases of contraceptive use and the menstruation phase and the cortical excitability parameters

Córtex motor

Cortical excitability

Estimulação magnética transcraniana

Evoked potentials

Excitabilidade cortical

Motor cortex

Potencial evocado

Reference values

Transcranial magnetic stimulation

Valores normais

Efeitos da estimulação magnética transcraniana de repetição nas alucinações auditivas de pacientes com esquizofrenia super-refratária ao tratamento / Effects of repetitive transcranial magnetic stimulation on auditory hallucinations of patients with schizophrenia refractory to treatment

Rosa, Marina Odebrecht

04 July 2006

Onze pacientes com diagnóstico de esquizofrenia pelo DSM-IV-TR e alucinações auditivas mesmo em uso de clozapina foram distribuídos aleatoriamente para receber estimulação magnética transcraniana de repetição (EMTr) ativa (n=6) ou inativa (n=5) no córtex têmporo-parietal esquerdo. Um total de 160 minutos de EMTr a 1 Hz foi administrada ao longo de 10 dias, 90% do limiar motor, com desenho paralelo, com pacientes e avaliadores cegos, em desenho controlado com grupo inativo. Houve um efeito de grupo significativo nos escores da escala de alucinações (realidade e influência: p=0,0360 e p=0,0493 respectivamente) e no subitem sintomas positivos da PANSS. A EMTr ativa em associação com clozapina pode ser administrada com segurança para tratar as alucinações auditivas. Embora a amostra consistia de pacientes extremamente refratários, estes resultados sugerem haver alguns efeitos da EMTr a 1 Hz no córtex têmporo-parietal esquerdo. / Eleven schizophrenics patients according to DSM-IV-TR criteria and experiencing auditory hallucinations in spite of treatment with clozapine were randomly allocated to receive repetitive transcranial magnetic stimulation (rTMS) (n=6) or sham stimulation (n=5) over left temporo-parietal cortex. A total of 160 minutes of 1 Hz rTMS was administered over 10 days at 90% motor threshold, with patients and raters blind to treatment modality, using a sham-controlled, parallel design. There was a significant group effect for the Auditory Hallucinations Rating Scale scores (reality and attencional salience: p=0.0360 and p=0.0493 respectively) and the sub item positive symptoms of PANSS. Active rTMS in association with clozapine can be administered safely to treat auditory hallucinations. Although the sample consisted of extremely refractory patients, the results suggest some effects of 1 Hz rTMS over Left temporoparietal.

Alucinações

Auditory cortex

Clozapina

Clozapine

Córtex auditivo

Córtex motor

Electric stimulation therapy

Esquizofrenia

Hallucinations

Motor cortex

Schizophrenia

Terapia por estimulação elétrica

Estratégia terapêutica após contusão da medula espinhal: recuperação funcional e estabilidade cortical sensório-motora / Therapeutic strategy after spinal cord contusion: functional recovery and sensorimotor cortical stability

Miranda, Taisa Amoroso Bortolato

18 August 2011

A lesão medular (LM) promove uma condição devastadora que resulta em déficits sensorial e motor, impedindo o desempenho funcional do indivíduo. Modelos experimentais de lesão medular têm sido utilizados na investigação do funcionamento do sistema sensório-motor e da reorganização promovida por meio de tratamentos, podendo corroborar com aplicações clínicas atuais e futuras. Este trabalho tem como objetivos verificar a recuperação funcional e a dinâmica da reorganização cortical do sistema sensório-motor de ratos Wistar lesados medulares submetidos a treinamento motor. 17 ratos foram divididos aleatoriamente em três grupos: treinado (n = 6), controle (n = 7) e sham (n = 4). Todos os animais receberam um implante de matriz de 32 micro-elétrodos no córtex sensório-motor. Os animais do grupo treinado e controle foram submetidos à LM contusa e os do grupo sham somente ao procedimento cirúrgico sem a LM. Foram realizadas as avaliações comportamentais motoras, de dor neuropática (alodínea e hiperalgesia mecânica), de dor térmica e eletrofisiológica antes da LM e nos 1º, 3º, 5º, 7º, 14º, 21º, 28º, 35º, 42º, 49º e 56º dias pós-operatórios (dPO) da lesão. O grupo treinado realizou treinamento motor em uma esteira com velocidade controlada, tendo início no 5º dPO e foi realizado por 15 minutos, cinco vezes na semana até o final do experimento. Os outros dois grupos ficaram sem treinamento. No 57º dPO, os animais foram sacrificados, e as medulas espinhais e os encéfalos foram coletados para análise histológica. Os resultados mostraram melhora motora significativa do grupo treinado em relação ao controle. Ao final do experimento, os animais treinados foram capazes de realizar passos plantares coordenados consistentes de forma independente. Ambos os grupos lesados apresentaram alodínea após a LM, mas somente o controle apresentou aumento da dor mecânica. Os dados eletrofisiológicos revelaram alterações na atividade cortical sensório-motora no 1º dPO e ao longo do tempo. Foi identificado que o aumento da potência da banda beta contribuiu para a melhora motora do grupo treinado e o aumento da potência delta contribuiu para a recuperação motora limitada do grupo controle. Na análise histológica os grupos não diferiram em relação ao tamanho da lesão, mas foi identificada uma diminuição significativa dos neurônios do corno ventral da medula espinhal, no segmento caudal à lesão para os animais controles. O treinamento na esteira potencializou a recuperação funcional e parece ter facilitado a reorganização do córtex sensório-motor após a lesão. Esses resultados podem servir de base para futuras aplicações clínicas em pacientes lesados medulares / Spinal cord injury (SCI) results in a devastating condition, which leads to motor and sensory deficits that impair the injured person functional performance. Spinal cord injury experimental models are used in sensory-motor functioning and reorganization or plasticity promoted by trainings investigation. Thus, these studies can corroborate with current and future clinical approaches. This work aims to verify the functional recovery and the sensorimotor cortical reorganization dynamics in Wistar rats with spinal cord injury submitted to motor training. 17 rats were randomly divided into 3 groups: trained (n = 6), control (n = 7) and sham (n = 4). All animals received a 32 microelectrodes array in the sensorimotor cortex. Control and trained animals were submitted to contusive SCI and the sham group only to the surgical procedure without the contusion. Motor behavior, neuropathic pain (allodynia and mechanical hyperalgesia), thermal pain and electrophysiological assessments were accomplished before SCI and on the 1st, 3rd, 5th, 7th, 14th, 21st, 28th, 35th, 42nd, 49th and 56th post-operative days (POd). The trained group performed the motor training on a treadmill with controlled speed, starting on the 5th post-operative day and it was done for 15 minutes, five times per week till the end of the experiment. The other two groups did not receive any training. Soon after SCI the animals completely lost the hindlimbs movements. On the 57th POd, the animals were sacrificed and the spinal cords and brains were collected for histological analysis. Results showed significant motor improvement of the trained group. In the end of the experiment, these animals were able to perform consistent coordinated plantar steps on their own. Both injured groups showed allodynia after the SCI, but only the control group presented increased mechanical pain. Electrophysiological data revealed sensorimotor cortical activity changes on the 1st POd and over time. It was indentified that an increase in beta power contributed to the trained group motor improvement and that an increase in delta power contributed to the limited motor recovery of the control group. In the histological analysis the groups did not differ concerning the lesion size, but a significant spinal cord ventral horn neurons decrease in the lesion caudal segment compared to the controlled animals was identified. The treadmill training enhanced functional recovery and seemed to facilitate sensorimotor reorganization after injury. These results can be applied for future clinical interventions in spinal cord injured patients. Spinal cord injury (SCI) results in a devastating condition, which leads to motor and sensory deficits that impair the injured person functional performance. Spinal cord injury experimental models are used in sensory-motor functioning and reorganization or plasticity promoted by trainings investigation. Thus, these studies can corroborate with current and future clinical approaches. This work aims to verify the functional recovery and the sensorimotor cortical reorganization dynamics in Wistar rats with spinal cord injury submitted to motor training. 17 rats were randomly divided into 3 groups: trained (n = 6), control (n = 7) and sham (n = 4). All animals received a 32 microelectrodes array in the sensorimotor cortex. Control and trained animals were submitted to contusive SCI and the sham group only to the surgical procedure without the contusion. Motor behavior, neuropathic pain (allodynia and mechanical hyperalgesia), thermal pain and electrophysiological assessments were accomplished before SCI and on the 1st, 3rd, 5th, 7th, 14th, 21st, 28th, 35th, 42nd, 49th and 56th post-operative days (POd). The trained group performed the motor training on a treadmill with controlled speed, starting on the 5th post-operative day and it was done for 15 minutes, five times per week till the end of the experiment. The other two groups did not receive any training. Soon after SCI the animals completely lost the hindlimbs movements. On the 57th POd, the animals were sacrificed and the spinal cords and brains were collected for histological analysis. Results showed significant motor improvement of the trained group. In the end of the experiment, these animals were able to perform consistent coordinated plantar steps on their own. Both injured groups showed allodynia after the SCI, but only the control group presented increased mechanical pain. Electrophysiological data revealed sensorimotor cortical activity changes on the 1st POd and over time. It was indentified that an increase in beta power contributed to the trained group motor improvement and that an increase in delta power contributed to the limited motor recovery of the control group. In the histological analysis the groups did not differ concerning the lesion size, but a significant spinal cord ventral horn neurons decrease in the lesion caudal segment compared to the controlled animals was identified. The treadmill training enhanced functional recovery and seemed to facilitate sensorimotor reorganization after injury. These results can be applied for future clinical interventions in spinal cord injured patients

Córtex motor

Córtex somatossensorial

Dor

Lesão medular

Motor cortex

Pain

Reabilitação

Recuperação motora e sensorial

Rehabilitation

Sensorial cortex

Sensory and motor recovery

Spinal cord injury

Efeitos da estimulação elétrica do córtex motor na modulação da dor: análise comportamental e eletrofisiológica em ratos / Effects of electrical stimulation of motor cortex on pain modulation: behavior and electrophysiological study in rats.

Fonoff, Erich Talamoni

14 September 2007

Introdução. Nos últimos a função motora vem sendo associada com a atenuação sensitiva e de dor, logo antes, durante e apos a contração muscular. No entanto as vias anatômicas e funcionais deste fenômeno não são conhecidas. O objetivo deste estudo é o de criar um modelo animal e investigar o efeito da estimulação subliminar do córtex motor (ECM) no limiar nociceptivo e na atividade neuronal subcortical. Método. O limiar nociceptivo foi avaliado por teste plantar e reflexo de retirada da cauda antes e após o implante dos eletródios epidurais sobre o córtex motor da pata posterior orientado por mapa funcional na mesma cepa de ratos. Os mesmos testes foram repetidos antes, durante e após a ECM. Antagonismo sistêmico do por naloxona foi incluído neste protocolo para investigar a relação com mediação opióide. O registro neuronal multiunitário do núcleo centro mediano (CM) e ventral posterolateral (VPL) do tálamo e da substância periaqüeductal (SPM) foi realizado antes, durante e após ECM ipso e contralateral. Resultados. O implante per se não causou alterações no limiar nociceptivo. ECM induziu significativa antinocicepção seletiva na pata contralateral mas não na ipsolateral. Este efeito não mais foi observado 15 minutos após o término da estimulação. Nenhuma alteração motora e comportamental foi observada nos testes de campo aberto. A mesma estimulação no córtex sensitivo e parietal posterior não causou quaisquer alterações de limiar nociceptivo. Administração sistêmica de naloxone reverteu completamente o efeito antes observado com a ECM. O registro neuronal multiunitário evidenciou diminuição na atividade do CM durante e após a ECM contra e ipsolateral. O ritmo de disparos neuronais no VPL também mostrou diminuição apenas com a ECM ipsolateral. No entanto os neurônios da SPM aumentaram significativamente a freqüência de disparos com ECM ipsolateral e não com a contralateral. Conclusão. A ECM subliminar está relacionada consistentemente com a atenuação sensitiva durante o comportamento, provavelmente mediado por inibição talâmica e ativação da SPM. / Background. The motor function has been associated to sensory and pain attenuation, before during and shortly after the muscle activity. How ever the anatomical and functional basis of this phenomenon is not yet defined. The present study was designed to set an animal model and investigate the effect of subthreshold electrical stimulation of motor cortex (MCS) on pain threshold and neuron activity of thalamus and periaqüedutal gray. Method. Nociceptive thresholds of hind paws and the tail flick reflex were evaluated before and after surgical placement of epidural electrodes; before during and after electrical stimulation of motor cortex. Opioid antagonism was also included in this protocol in order to define neurotransmitter mediation of this process. Multiunit recording of thalamic median center (CM) and ventral posterolateral nuclei (VPL) and lateral periaqüedutal gray (SPM) were performed before and after electrical stimulation of ipso and contralateral motor cortex. Results. The procedure itself did not induce any threshold changes. MCS induced selective antinociception of contralateral paw, but no changes were detected in the nociceptive threshold of the ipsolateral side. This effect disappeared completely 15 minutes after the stimulation was ceased. No behavioral or motor impairment were observed during and after the stimulation session in the open field test. The same stimulation on sensory and posterior parietal cortex did not elicit any changes in behavioral and nociceptive tests. Systemic administration of naloxone completely reversed the previous observed antinociceptive effect. Multiunit recording evidenced decrease in spontaneous neuron firing in CM with short recovery time during ipso and contralateral MCS. Neuron activity in VPL was also significantly decreased during ipsolateral MCS but not with contralateral stimulation. How ever, neuron firing in SPM was significantly increased during and long after ipsolateral MCS but not with contralateral stimulation. Conclusion. Subthreshold MCS is consistently related to sensory attenuation during behavior, probably through thalamic inhibition and SPM activation.

Action potentials

Animal models.

Behavior

Comportamento

Córtex motor/fisiologia

Dor

Electrical stimulation

Estimulação elétrica

Modelos animais

Motor cortex/physiology

Neurônios

Neurons

Pain

Potenciais de ação

Tálamo

Thalamus

Physiopathologie des déficits moteurs dans les troubles du spectre autistique : approche neuroanatomique dans deux modèles environnementaux / Physiopathology of motor impairments in autism spectrum disorders : neuroanatomical approach in two environmental models.

Haida, Obélia

07 December 2018

Les troubles du spectre autistique (TSA) sont une pathologie psychiatrique neurodéveloppementale dont les premiers signes apparaissent dès l’enfance et persistent tout au long de la vie. Leur étiologie complexe reste encore très mal connue et les données actuelles n’ont pas permis à ce jour de développer des traitements curatifs.L’objectif de cette thèse était d’identifier les réseaux neuronaux impliqués dans les symptômes moteurs afin de proposer une nouvelle piste diagnostique et d’ouvrir de nouvelles voies thérapeutiques ciblant ces réseaux. Nous avons donc exploré par une approche neuroanatomique, les régions contribuant au contrôle moteur : le cervelet, la substance noire pars compacta, le striatum et le cortex moteur. Cette étude a été réalisée sur deux modèles murins environnementaux liés à une exposition in utero soit à une molécule pharmacologique utilisée comme traitement antiépileptique : l’acide valproïque, soit à un agent pathogène mimant une infection virale : l’acide polyinosinique:polycytidylique. Nos résultats indiquent des pertes neuronales restrictives dans le cervelet et dans le cortex moteur qui dépendent du sexe des animaux et du modèle. Ils reflètent alors l’hétérogénéité retrouvée chez les patients selon les syndromes ainsi que les différences entre les hommes et les femmes. Nous avons également montré que cette perte neuronale pouvait être liée à la fois aux déficits moteurs et sociaux. Ainsi, ces régions cérébrales pourraient servir de cible thérapeutique pour pallier à ces symptômes des TSA. / Autism spectrum disorders (ASD) are psychiatric and neurodevelopmental disabilities that begins early in childhood and lasts throughout a person's life. The complex etiology is currently unknown and does not allow to develop new therapeutical strategies. The aim of this thesis was to identify the neuronal network involved in motor symptoms and propose new diagnostic tools and new therapeutical approaches focusing this linkage. We anatomically investigated the different regions responsible for motor control: the cerebellum, the substantia nigra pars compacta, the striatum and the motor cortex. This study has been performed using two environmental mouse models, prenatally exposed to either an anticonvulsant drug: the valproic acid, either an immunostimulant mimicking a viral infection: the polyinosinic:polycytidylic acid.Our results have indicated restricted neuronal losses in the cerebellum and in the motor cortex, which were model- and sex-dependent. These data also point out the heterogeneity found according to the different syndromes and the sex ratio in patients. Furthermore, we have also shown that the neuronal loss could be associated to as well the motor and the social deficits. Interestingly, these brain regions could be used as therapeutical target to reverse both ASD symptoms.

Cervelet

Cellules de Purkinje

Cortex moteur

Acide valproïque

Poly I:C

Cerebellum

Purkinje cells

Motor cortex

Valproic acid

Poly I:C

616.858 82

612.8

Associative plasticity and afferent regulation of corticospinal excitability in uninjured individuals and after incomplete spinal cord injury

Roy, Francois D.

11 1900

Cortical representations are plastic and are allocated based on the proportional use or disuse of a pathway. A steady stream of sensory input maintains the integrity of cortical networks; while in contrast, alterations in afferent activation promote sensorimotor reorganization. After an incomplete spinal cord injury (SCI), damage to the ascending and/or descending pathways induces widespread modifications to the sensorimotor system. Strengthening these spared sensorimotor pathways may be therapeutic by promoting functional recovery after injury. Using a technique called transcranial magnetic stimulation (TMS), we show that the leg motor cortex is facilitated by peripheral sensory inputs via disinhibition and potentiation of excitatory intracortical circuits. Hence, in addition to its crucial role in sensory perception, excitation from peripheral sensory afferents can reinforce muscle activity by engaging, and possibly shaping, the activity of the human motor cortex. After SCI, the amount of excitation produced by afferent stimulation reaching the motor cortex is expectantly reduced and delayed. This reduction of sensory inflow to the motor cortex may contribute to our findings that cortical inhibition is down-regulated after SCI, and this compensation may aid in the recruitment of excitatory networks in the motor cortex as a result of the damage to its output neurons. By repeatedly pairing sensory inputs from a peripheral nerve in the leg with direct cortical activation by TMS, in an intervention called paired associative stimulation, we show that the motor system can be potentiated in both uninjured individuals and after SCI. In the uninjured subjects, we show that in order to produce associative facilitation, the time window required for coincident activation of the motor cortex by TMS and peripheral sensory inputs is not as narrow as previously thought (~100 vs. ~20 ms), likely due to the persistent activation of cortical neurons following activation by TMS. The potential to condition the nervous system with convergent afferent and cortical inputs suggests that paired associative stimulation may serve as a priming tool for motor plasticity and rehabilitation following SCI.

plasticity

spinal cord injury

transcranial magnetic stimulation

peripheral nerve stimulation

motor cortex

sensory input

corticospinal tract

tibialis anterior muscle

intracortical inhibition

motor evoked potential

human

leg

Sensory information to motor cortices: Effects of motor execution in the upper-limb contralateral to sensory input.

Legon, Wynn

22 September 2009

Performance of efficient and precise motor output requires proper planning of movement parameters as well as integration of sensory feedback. Peripheral sensory information is projected not only to parietal somatosensory areas but also to cortical motor areas, particularly the supplementary motor area (SMA). These afferent sensory pathways to the frontal cortices are likely involved in the integration of sensory information for assistance in motor program planning and execution. It is not well understood how and where sensory information from the limb contralateral to motor output is modulated, but the SMA is a potential cortical source as it is active both before and during motor output and is particularly involved in movements that require coordination and bilateral upper-limb selection and use. A promising physiological index of sensory inflow to the SMA is the frontal N30 component of the median nerve (MN) somatosensory-evoked potential (SEP), which is generated in the SMA. The SMA has strong connections with ipsilateral areas 2, 5 and secondary somatosensory cortex (S2) as well as ipsilateral primary motor cortex (M1). As such, the SMA proves a fruitful candidate to assess how sensory information is modulated across the upper-limbs during the various stages of motor output. This thesis inquires into how somatosensory information is modulated in both the SMA and primary somatosensory cortical areas (S1) during the planning and execution of a motor output contralateral to sensory input across the upper-limbs, and further, how and what effect ipsilateral primary motor cortex (iM1) has upon modulation of sensory inputs to the SMA.

Sensory information to motor cortices: Effects of motor execution in the upper-limb contralateral to sensory input.

Legon, Wynn

22 September 2009

Performance of efficient and precise motor output requires proper planning of movement parameters as well as integration of sensory feedback. Peripheral sensory information is projected not only to parietal somatosensory areas but also to cortical motor areas, particularly the supplementary motor area (SMA). These afferent sensory pathways to the frontal cortices are likely involved in the integration of sensory information for assistance in motor program planning and execution. It is not well understood how and where sensory information from the limb contralateral to motor output is modulated, but the SMA is a potential cortical source as it is active both before and during motor output and is particularly involved in movements that require coordination and bilateral upper-limb selection and use. A promising physiological index of sensory inflow to the SMA is the frontal N30 component of the median nerve (MN) somatosensory-evoked potential (SEP), which is generated in the SMA. The SMA has strong connections with ipsilateral areas 2, 5 and secondary somatosensory cortex (S2) as well as ipsilateral primary motor cortex (M1). As such, the SMA proves a fruitful candidate to assess how sensory information is modulated across the upper-limbs during the various stages of motor output. This thesis inquires into how somatosensory information is modulated in both the SMA and primary somatosensory cortical areas (S1) during the planning and execution of a motor output contralateral to sensory input across the upper-limbs, and further, how and what effect ipsilateral primary motor cortex (iM1) has upon modulation of sensory inputs to the SMA.

Excitabilité du système miroir : une étude de stimulation magnétique transcrânienne sur le chant et le langage

Royal, Isabelle

09 1900

La perception de mouvements est associée à une augmentation de l’excitabilité du cortex moteur humain. Ce système appelé « miroir » sous-tendrait notre habileté à comprendre les gestes posés par une tierce personne puisqu’il est impliqué dans la reconnaissance, la compréhension et l’imitation de ces gestes. Dans cette étude, nous examinons de quelle façon ce système miroir s’implique et se latéralise dans la perception du chant et de la parole. Une stimulation magnétique transcrânienne (TMS) à impulsion unique a été appliquée sur la représentation de la bouche du cortex moteur de 11 participants. La réponse motrice engendrée a été mesurée sous la forme de potentiels évoqués moteurs (PÉMs), enregistrés à partir du muscle de la bouche. Ceux-ci ont été comparés lors de la perception de chant et de parole, dans chaque hémisphère cérébral. Afin d’examiner l’activation de ce système moteur dans le temps, les impulsions de la TMS ont été envoyées aléatoirement à l’intérieur de 7 fenêtres temporelles (500-3500 ms). Les stimuli pour la tâche de perception du chant correspondaient à des vidéos de 4 secondes dans lesquelles une chanteuse produisait un intervalle ascendant de deux notes que les participants devaient juger comme correspondant ou non à un intervalle écrit. Pour la tâche de perception de la parole, les participants regardaient des vidéos de 4 secondes montrant une personne expliquant un proverbe et devaient juger si cette explication correspondait bien à un proverbe écrit. Les résultats de cette étude montrent que les amplitudes des PÉMs recueillis dans la tâche de perception de chant étaient plus grandes après stimulation de l’hémisphère droit que de l’hémisphère gauche, surtout lorsque l’impulsion était envoyée entre 1000 et 1500 ms. Aucun effet significatif n’est ressorti de la condition de perception de la parole. Ces résultats suggèrent que le système miroir de l’hémisphère droit s’active davantage après une présentation motrice audio-visuelle, en comparaison de l’hémisphère gauche. / The perception of movements is associated with increased activity in the human motor cortex. This system underlies our ability to understand one’s actions, as it is implicated in the recognition, understanding and imitation of actions. In this study, we investigated the involvement and lateralization of this “mirror neuron” system (MNS) in the perception of singing and speech. Transcranial magnetic stimulation (TMS) was applied over the mouth representation of the motor cortex in 11 participants. The generated motor response was measured in the form of motor evoked potentials (MEPs), recorded from the mouth muscle. The MEPs were compared for the singing and speech conditions in each cerebral hemisphere. Furthermore, to investigate the time course of the MNS activation, TMS pulses were randomly emitted in 7 time windows (ranging from 500 to 3500 milliseconds after stimulus onset). The stimuli for the singing condition consisted in 4-second videos of singers producing a 2-note ascending interval. Participants had to judge whether the sung interval matched a written interval, previously presented on the screen. For the speech condition, 4-second videos of a person explaining a proverb were shown. Participants had to decide whether this explanation matched a written proverb previously displayed on the screen. Results show that the MEP amplitudes were higher after stimulation of the right hemisphere in the singing condition. More specifically, sending TMS pulses between 1000 and 1500 milliseconds over the right hemisphere yielded higher MEPs as compared to the left hemisphere. No effect was found in the speech condition. These results suggest that the right MNS is more activated after an audiovisual motor presentation compared to the left hemisphere.

Système miroir

Mirror neuron system

Stimulation magnétique transcrânienne

Transcranial magnetic stimulation

Cortex moteur

Motor cortex

Chant

Singing

Parole

Speech

Latéralisation

Lateralization

Associative plasticity and afferent regulation of corticospinal excitability in uninjured individuals and after incomplete spinal cord injury

Roy, Francois D.

Unknown Date

No description available.

plasticity

spinal cord injury

transcranial magnetic stimulation

peripheral nerve stimulation

motor cortex

sensory input

corticospinal tract

tibialis anterior muscle

intracortical inhibition

motor evoked potential

human

leg