KAFO Orthoses Versus the ABLE Exoskeleton

The primary objective of this study is determining the energy efficiency through gases exchange and kinematic gait analysis to compare the standard of assistance (KAFO type orthoses) and the ABLE Exoskeleton, a robotic gait assistance device, in patients with spinal cord injury (SCI) in a hospital setting.

The secondary objectives are to compare the performance of KAFO-type orthoses with that of the ABLE Exoskeleton device by:

• Kinematic analysis of gait and spatiotemporal gait parameters.
• Evaluation of the time and effort required to learn to use the device (usability).
• Evaluation of the impact that physical activity has on participants after gait training.
• Evaluation of the level of satisfaction of the participants.

In addition to these objectives, the safety of the ABLE Exoskeleton as an assistive device for gait rehabilitation in SCI patients will be evaluated throughout the study.

Participants will perform 2 training sessions per week of approximately 90 minutes duration for 5 weeks with each of the devices, completing a total of 10 sessions with KAFO type orthoses and 10 sessions with the ABLE Exoskeleton. Before starting the training period, the physical capacity of the participants will be measured. During the training period sessions, different measurements of the level of assistance, spatiotemporal gait variables and usability will be taken. Standardized clinical assessments will also be performed during sessions 5 and 10 (assessment sessions). At the end of the training period, a post-training assessment will be performed, consisting of 1 session where the physical capacity of the participants will be measured. After finishing the training period with one of the devices, participants will have a rest period of 2 weeks, after which they will change devices and repeat the whole process.

The main hypothesis of the study is that gait efficiency in patients with SCI is improved (lower energy consumption) when using the ABLE Exoskeleton device in comparison with KAFO-type orthoses. The increase in gait efficiency encourages patients to stand and walk for longer periods instead of using the wheelchair, which boosts their rehabilitation and improves their health.

Secondary hypotheses are:

• The ABLE Exoskeleton device will improve the kinematics and spatiotemporal parameters of gait (more closely resemble the gait pattern of a healthy individual), relative to KAFO-type orthoses.
• The ABLE Exoskeleton device will have a more positive impact on the mobility and psychosocial health of participants with SCI in the study, with respect to KAFO-type orthoses.
• The ABLE Exoskeleton device is a safe device to use in a hospital setting as an assistive device during gait rehabilitation in SCI patients.