6533b829fe1ef96bd128ae1f
RESEARCH PRODUCT
Spinal plasticity with motor imagery practice.
Charalambos PapaxanthisAlain MartinFlorent LebonSidney Grosprêtresubject
0301 basic medicineMalemental-imageryPhysiologypathwaysStimulationIsometric exerciseD1 presynaptic inhibitionSynaptic TransmissionH-Reflex0302 clinical medicineNeuronal PlasticityMotor Cortexmodulationmedicine.anatomical_structureSpinal Cordtriceps surae[SDV.NEU]Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC]FemaleFemoral NerveMuscle ContractionAdultia afferentsheteronymous Ia facilitationMovementSensory systemfacilitation03 medical and health sciencesMotor imageryexcitabilityNeuroplasticitymedicineHumansNeurons AfferentMuscle Skeletalsoleusinterneuronsbusiness.industryPeroneal NerveNeural Inhibitionpresynaptic inhibitionSpinal cordElectric StimulationSpine030104 developmental biologyactivationH-reflexbusinessNeuroscience030217 neurology & neurosurgeryCommon peroneal nerveNeurosciencedescription
KEY POINTS: While a consensus has now been reached on the effect of motor imagery (MI) – the mental simulation of an action – on motor cortical areas, less is known about its impact on spinal structures. The current study, using H‐reflex conditioning paradigms, examined the effect of a 20 min MI practice on several spinal mechanisms of the plantar flexor muscles. We observed modulations of spinal presynaptic circuitry while imagining, which was even more pronounced following an acute session of MI practice. We suggested that the small cortical output generated during MI may reach specific spinal circuits and that repeating MI may increase the sensitivity of the spinal cord to its effects. The short‐term plasticity induced by MI practice may include spinal network modulation in addition to cortical reorganization. ABSTRACT: Kinesthetic motor imagery (MI) is the mental simulation of a movement with its sensory consequences but without its concomitant execution. While the effect of MI practice on cortical areas is well known, its influence on spinal circuitry remains unclear. Here, we assessed plastic changes in spinal structures following an acute MI practice. Thirteen young healthy participants accomplished two experimental sessions: a 20 min MI training consisting of four blocks of 25 imagined maximal isometric plantar flexions, and a 20 min rest (control session). The level of spinal presynaptic inhibition was assessed by conditioning the triceps surae spinal H‐reflex with two methods: (i) the stimulation of the common peroneal nerve that induced D1 presynaptic inhibition (H(PSI) response), and (ii) the stimulation of the femoral nerve that induced heteronymous Ia facilitation (H(FAC) response). We then compared the effects of MI on unconditioned (H(TEST)) and conditioned (H(PSI) and H(FAC)) responses before, immediately after and 10 min after the 20 min session. After resting for 20 min, no changes were observed on the recorded parameters. After MI practice, the amplitude of rest H(TEST) was unchanged, while H(PSI) and H(FAC) significantly increased, showing a reduction of presynaptic inhibition with no impact on the afferent‐motoneuronal synapse. The current results revealed the acute effect of MI practice on baseline spinal presynaptic inhibition, increasing the sensitivity of the spinal circuitry to MI. These findings will help in understanding the mechanisms of neural plasticity following chronic practice.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2019-02-01 | The Journal of physiology |