[VIVOPTIM: Feedback of an e-Health experimental program of primary prevention of cardiovascular risk on 30 to 70 years old volunteers]. / VIVOPTIM : retour d'expérience d'un programme expérimental de e-santé et de prévention primaire du risque cardiovasculaire global chez des sujets volontaires âgés de 30 à 70 ans.

Today by the e-health and the telemedicine, many people are more and more interested by the improvement of disease knowledge on cardiovascular diseases and associated risk factors, personalized self management support follow-up and e-Health monitoring. MGEN is a not-for-profit complementary health insurance gave itself the ways to use the new digital tools in health. MGEN developed an original and personalized program VIVOPTIM for the primary prevention of the cardiovascular risks for their members. The VIVOPTIM Pilot program is based upon digital services and was experimented by November 2015 to December, 2017 with 8000 members of the MGEN, from 30 to 70 years old and resident in two French areas (Occitanie and Bourgogne Franche-Comté). The assessment of the experiment VIVOPTIM e -health program was positive for the personalized cardiovascular support and for their health. Therefore, the MGEN generalized the VIVOPTIM program of cardiovascular prevention, to the whole France on July 11th, 2018.

Step-to-step reproducibility and asymmetry to study gait auto-optimization in healthy and cerebral palsied subjects.

OBJECTIVE: The purpose of our study was to compare plantar pressure asymmetry and step-to-step reproducibility in both able-bodied persons and two groups of hemiplegics. The relevance of the research was to determine the efficiency of asymmetry and reproducibility as indexes for diagnosis and rehabilitation processes. MATERIAL AND METHOD: This study comprised 31 healthy young subjects and 20 young subjects suffering from cerebral palsy hemiplegia assigned to two groups of 10 subjects according to the severity of their musculoskeletal disorders. The peaks of plantar pressure and the time to peak pressure were recorded with an in-shoe measurement system. The intra-individual coefficient of variability was calculated to indicate the consistency of plantar pressure during walking and to define gait stability. The effect size was computed to quantify the asymmetry and measurements were conducted at eight footprint locations. RESULTS: Results indicated few differences in step-to-step reproducibility between the healthy group and the less spastic group while the most affected group showed a more asymmetrical and unstable gait. CONCLUSION: From the concept of self-optimisation and depending on the neuromotor disorders the organism could make priorities based on pain, mobility, stability or energy expenditure to develop the best gait auto-optimisation.

[Development and test of a new plantar pressure control device for foot unloading]. / Elaboration et validation d'un nouveau dispositif de surveillance des pressions plantaires: application à la décharge du pied.

OBJECTIVE: To validate a new plantar pressure control device able to detect excessive plantar pressure on-line and to improve the subject's awareness of the gait pattern in order to correct and optimize the load distribution patterns. The aim of this study was to verify the feasibility of a deliberate and partial unload of the first metatarsal head. MATERIAL AND METHOD: Eight healthy subjects were equipped with the plantar pressure sensors integrated in customized insoles. They were told to unload the first metatarsal head of the right foot by 5%. During the trials, the auditory and visual signals inform the subject of an excessive, insufficient or correct unload. RESULTS: Five subjects over eight succeeding in modifying significantly their gait pattern and in unloading by 5% the first metatarsal head. The unload is effective in 70.7% of the trials. However, the subjects were spontaneously inclined to reduce peak pressure under the first metatarsal head beyond the critical peak plantar pressure threshold (48.2% of the trials). DISCUSSION - CONCLUSION: The results showed the feasibility of a partial and deliberate foot unloading in using biofeedback device but emphasized the subject's difficulty to control a discriminated and accurate unload of the first metatarsal head. That points out the necessity of learning period. The baropodometric biofeedback rehabilitation focuses on the subject's capacities to modify its own locomotor pattern. It would be used as primary and secondary prevention means of diabetic foot ulceration.

[Asymmetries in dynamic plantar pressure distribution measurement in able-bodied gait: application to the study of the gait asymmetries in children with hemiplegic cerebral palsy]. / Analyse des asymétries baropodométriques lors de la marche chez le sujet valide : application à létude des asymétries chez lenfant infirme moteur cérébral.

OBJECTIVES: The aim of this study was to analyse, firstly, the plantar pressure distribution in healthy subjects in order to validate or invalidate the previous studies results on the asymmetrical profile of the stance phase. The studies of asymmetries was based on the identification of a propulsive foot and a loading foot from a concept introduced by Viel. Secondly, the approach was applied to the study of gait asymmetries in two children with hemiplegic cerebral plasy. MATERIAL AND METHOD: Thirty healthy control subjects and two hemiplegic children (H1 and H2) performed a walking test at self selected speed. The recordings of dynamic parameters were realized thanks to an in-shoe plantar pressure analysis system (Parotec, by Paromed Medizintechnik, GMBH, Germany). The pressure peaks were determined from the recording of pressures under eight footprint locations. A program calculated the sum of forces under the heel and determined the loading foot. By defect, the second foot is the propulsive foot. RESULTS: The asymmetrical profile of the human normal stance phase was validated. Under the heel, the pressure peaks lower by 28 % were noticed beneath the loading foot compared to the propulsive foot. Inversely, under the metatarsal heads and the hallux, the pressure peaks were greater by 32 % beneath the propulsive foot. For the two hemiplegic children, the plantar pressure profile equally highlighted significant differences between the unaffected and affected feet. The pressure peaks under the affected heel were respectively lower by 21 % and 97 % for H1 and H2. The loading function was found and associated to the affected limb. The propulsive function was not systematically found under the unaffected foot. DISCUSSION: The analysis of plantar pressure measurements during able-bodied gait showed differences between the two lower limbs. These dynamic asymmetries are the results of a natural functional organization of the supports differentiating a loading foot and a propulsive foot and corroborating the concept proposed by Viel. The hemiplegic gait also presented dynamic asymmetries partially agreement with a personalized functional logic of loading and propulsion. However, the asymmetrical profile can also result a gait self-optimization strategy compensating biomechanical, anatomical and physiological disorders linked to the cerebral deficiency.

[Spasticity and dynamic plantar pressure distribution measurements in hemiplegic spastic children]. / Spasticité et distribution des pressions plantaires chez des enfants atteints d'hémiplégie cérébrale infantile.

OBJECTIVE: The aim of this study was to analyse the plantar pressure distribution in nine hemiplegic spastic children to illustrate the dynamic alteration during stance phase linked spasticity grade. MATERIAL AND METHODS: The graduation of the lower limbs muscle tone related to the Aschworth spasticity scale enabled us to identify two groups of hemiplegics subjects. The groups Asch 1 and Asch 3 have respectively presented a low and a strong spasticity. The peak pressures during consecutive gait cycles were determined under the feet of 30 healthy subjects and two cerebral palsy groups using a wearable footprint analysis system. RESULTS: A statistical study showed a similarity between the two disabled groups. Peak pressures under the midfoot were significantly higher compared to the control group. While the plantar pressure distribution profile was specific for each group under all other anatomical structures. The significant alterations were observed under the forefoot and hallux. DISCUSSION-CONCLUSION: Spasticity modifies the foot contact to ground and leads to a specific plantar pressure distribution profile linked to the spasticity grade. The equinovarus with clawed toes deformity due to higher spasticity seems to be an important factor in terminal stance phase perturbations. However spastic hemiplegic subjects seem to adopt a gait pattern in agreement with stability optimization criteria.