Effect of the Atalante Exoskeleton on Standing and Walking in Individuals With Paraplegia: A Prospective Controlled-Environment Study in a Rehabilitation Context (APPEX)

Background and Rationale Complete paraplegia, resulting from spinal cord injury, is a major neurological condition involving irreversible loss of lower limb function. Given the limitations of neuromotor re-education in such contexts, rehabilitation aims to restore autonomy and social participation by leveraging residual capacities and assistive technologies. Robotic exoskeletons represent a promising technological innovation in this domain by offering assisted locomotion that compensates for loss of mobility.

Among these devices, Atalante (Wandercraft, Paris, France) is a next-generation, self-stabilizing exoskeleton designed to enable dynamic walking without manual support, through a fully motorized lower limb system. Unlike conventional devices that require crutches or canes, Atalante provides active stabilization, offering new perspectives in terms of autonomy, safety, comfort, and quality of life.

While the potential benefits of exoskeletons in motor recovery have been explored, their use in a functional rehabilitation context remains under-investigated. This project therefore aims to evaluate the Atalante exoskeleton as an assistive tool for autonomy within a structured intensive protocol in a safe clinical environment.

Primary Objective To evaluate the feasibility, safety, and acceptability of intensive use of the Atalante exoskeleton in a functional rehabilitation context among adults with chronic complete paraplegia.

Secondary Objectives To determine the number of sessions required to reach operational familiarization with the exoskeleton.

To describe technical incidents and their impact on comfort and perceived safety.

To assess the energy cost of assisted locomotion.

To identify potential bone contraindication criteria based on bone mineral density (T-score).

To measure the evolution of user satisfaction throughout the protocol.

Investigational Device: Atalante Exoskeleton

The Atalante exoskeleton is an active robotic system with 12 powered degrees of freedom symmetrically distributed across both lower limbs (3 at the hip, 1 at the knee, 2 at the ankle). It enables:

Biomimetic joint movements,

Active postural control,

Self-stabilized dynamic walking without external support.

Its hybrid control system (continuous/discrete time) is based on Hybrid Zero Dynamics algorithms, which optimize movement trajectories and ensure real-time dynamic balance. The user interface allows switching between multiple modes (sit-to-stand, walk, stop) via remote control. Inertial sensors, angular encoders, and pressure sensors detect the user's intention to move.

Study Design Type: Prospective, single-center, longitudinal, non-randomized study.

Intervention duration: 6 weeks (60 sessions per participant).

Location: Centre de Médecine Physique et Réadaptation APAJH, Pionsat (France).

Safety setup: Overhead rail system with active fall protection, non-interfering with device operation.

Population Participants will be adults with complete paraplegia (ASIA A), lesion level ≤ T6, with stabilized spinal cord injury. They must present anthropometric parameters compatible with the exoskeleton (height, weight, joint mobility). Selection will be based on strict eligibility criteria (see "Eligibility" section).

Intervention Protocol

Each participant will undergo:

2 sessions/day, 5 days/week for 6 weeks.

Each session includes:

Assisted verticalization (sit-to-stand),

Orthostatic stabilization (upright stance without support),

Assisted locomotion (stabilized walking).

Sessions will be supervised by trained professionals. A session will be considered valid if the participant completes a 40-meter round trip without incident. The intensity of the program is designed to simulate realistic sustained home use.

Evaluation Domains

1. Biomedical Safety

   Monitoring of adverse events (major and minor): fractures, skin abrasions, orthostatic hypotension, pain.

   Metabolic analysis (VO₂, cost of transport, perceived exertion via Borg scale) during sessions 21 and 60.

   Exploratory contraindication: T-score < -3.5 at the hip (severe osteoporosis).

2. Techno-Functional Usability

   Donning and doffing times (sessions 1 to 60),

   Number and type of technical incidents: unexpected stops, deviations, backward perturbations, software bugs.

   Functional familiarization assessment (Elbow Curve method).

3. Perceived Confidence and Acceptability

Session-end assessments via:

Visual analog scales (VAS): general comfort, thoracic harness comfort, safety while standing, walking, and during transitions.

QUEST 2.0 questionnaire at the end of the protocol.

Data Analysis Methodology Quantitative data will be expressed as means ± standard deviation or medians (interquartile ranges).

Intra-subject pre/post comparisons: Student's t-test for parametric data, Wilcoxon test otherwise.

Longitudinal follow-up: progression curves for donning time, technical incidents, and VAS scores.

Effect size and significance thresholds: p < 0.05; 95% confidence intervals.

Ethics The study will be conducted in accordance with the principles of the Declaration of Helsinki. It has received approval from the Ethics Committee (CPP) and the French Medicines Agency (ANSM). All participants will sign informed consent. French CPP : 2016-A01221-50.

Expected Outcomes

The results of this study could:

Confirm the relevance of Atalante in a functional rehabilitation approach,

Provide practical recommendations for safe clinical use,

Prepare future multicenter studies in real-life environments (home, urban spaces),

Contribute to the development of eligibility criteria for prescribing exoskeletons as assistive mobility devices.