From Movement Preparation to Gait Execution in ALS (GAITALS)

Compared to other movement disorders, such as Parkinson Disease (PD), the mechanisms of movement impairment in Amyotrophic Lateral Sclerosis (ALS) have not been a focus of great interest. It is at least partly related to the classical assumption that impairment of movement in ALS simply reflects a dysfunction of the final motor pathways. However, the concept that ALS purely involves upper and lower motor neuron has been definitively challenged. Accumulating evidence for the concept that ALS is a multisystem degenerative disease is supported by histological, neurophysiological and neuroimaging studies. Clinically, lower limb stiffness is associated with extrapyramidal rigidity and postural instability in 69% of ALS patients. These latter may also display abnormalities of movement initiation impairing walking, such as gait initiation failure, usually reported in PD patients. All these data support the hypothesis that some balance troubles in ALS patients may result from an additional dysfunction and/or lesion of the basal ganglia circuitry and/or of its output structures, such as the cortex or the midbrain.

In PD patients, which represent a model of basal ganglia system dysfunction, length and velocity of the first step during gait initiation are known to be reduced and improved by dopaminergic therapy whereas postural instability is less sensitive to the treatment suggesting the involvement of other brain structures dysfunction and/or lesion. One way to evaluate the postural control during the gait initiation process is to measure the vertical velocity of the centre of gravity by using a force platform. In healthy adults, during the single support phase, a forward fall of the centre of gravity occurs and is actively reversed by the stance leg soleus muscle activation prior foot contact. In parkinsonian patients with postural instability, this phenomenon, called active braking, is altered. It is assumed that this postural instability results from additional lesions and/or dysfunction in the basal ganglia output structures, especially in the midbrain, containing the pedunculopontine nucleus and the mesencephalic locomotor region, two structures known to participate to the control of locomotion and posture in animals.

This research program will focus on gait initiation and postural control in ALS patients, by comparing patients with vs without postural instability (but also in comparison to controls), by using a multidisciplinary approach which combines neurophysiological and neuroimaging analyses.

After clinical evaluation, two groups of ALS patients, defined upon the feature of postural instability, and one group of healthy subjects (n=25 for each group of patients and 20 for healthy subjects) will be included in the study.

The neurophysiological evaluation will be performed through a gait initiation assessment, which will alow us to collect biomechanical and electromyographical data, such as the braking index.

The neuroradiological evaluation will include first an fMRI analysis. A study of specific circuits in networks will be performed which will provide the first description of neural network dynamics associated with the preparation and execution of movement in ALS patients.

If the investigators get a deeper understanding of the neural substrates underlying the hypothetical impairment of gait initiation and postural control, the investigators will then be able to develop adequate therapeutical strategies (pharmacological interventions, surgical therapies, rehabilitation programs) aimed at improving movement preparation and gait execution in ALS patients