Current Trends and Challenges in Pediatric Access to Sensorless and Sensor-Based Upper Limb Exoskeletons
Abstract
:1. Introduction
2. Upper Limb Biomechanics and Diagnoses in Pediatrics
2.1. Upper Limb Biomechanics
2.2. Diagnoses in Pediatrics
2.2.1. Cerebral Palsy
2.2.2. Muscular Dystrophy
2.2.3. Spinal Muscular Atrophy
2.2.4. Arthrogryposis Multiplex Congenita
2.2.5. Brachial Plexus Palsy
2.2.6. Transitioning to Adulthood
3. Classification of Sensorless and Sensor-Based Upper Limb Exoskeletons
4. Upper Limb Exoskeleton in Pediatrics
4.1. Sensorless Exoskeletons
4.1.1. Dynamic Orthosis
4.1.2. Elbow Flexion Assist Orthosis
4.1.3. Playskin Lift
4.1.4. Playskin Air
4.1.5. Wilmington Robotic EXoskeleton (WREX) and P-WREX+
4.2. Sensor-Based Exoskeletons
4.2.1. Armeo Spring
4.2.2. ChARMin
4.2.3. CT-DEA-Based Exoskeleton
4.2.4. Hand Exoskeleton
4.2.5. IOTA
4.2.6. MyoPal
4.2.7. PEXO
4.2.8. Soft Exoskeleton
4.3. Current Trends
5. Discussion
5.1. Rehabilitation Exoskeletons
5.2. Assistance Exoskeletons
5.3. Challenges for Pediatric Access
6. Conclusions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Device Name | Application Domain | Motorization Solution | Targeted Population(s) | Degrees of Freedom | Supported Movement(s) | Company/Reference(s) |
---|---|---|---|---|---|---|
Dynamic Orthosis | Assistance | Passive–SMA | Other | 3 | Elbow–FE Wrist–FE Thumb and Digits–FE | Garavaglia et al. [54] |
Elbow Flexion Assist Orthosis | Assistance | Passive–Springs | AMC | 1 | Elbow–FE | Wee et al. [55] |
Playskin Lift | Assistance | Passive–Wire | AMC, BPP, Other | 1 | Shoulder–FE | Hall et Lobo [56] |
Playskin Air | Assistance | Active–Soft | AMC, BPP, Other | 1 | Shoulder–AA | Li et al. [57] |
P-WREX+ | Assistance | Passive–Springs | AMC, BPP, Other | 4 | Shoulder–FE, AA Elbow–FE | Rahman et al. [58] |
WREX | Assistance | Passive–Springs | DMD, AMC, CP, SMA | 4 | Shoulder–FE, AA Elbow–FE | Gunn et al. [59], Shank et al. [60] |
Device Name | Application Domain | Motorization Solution | Type of Sensor(s) | Targeted Population(s) | Degrees of Freedom | Supported Movement(s) | Company/Reference(s) |
---|---|---|---|---|---|---|---|
Armeo Spring | Rehabilitation | Passive–Springs | Position, Pressure | CP, Other | 6 | Shoulder–FE, AA, IE Elbow–FE Forearm–PS Wrist–FE | Hocoma [61], Cimolin et al. [62], Peri et al. [63] |
ChARMin | Rehabilitation | Active–Electric | Position | CP, Other | 6 | Shoulder–FE, AA, IE Elbow–FE Forearm–PS Wrist–FE | Keller et al. [13,22,41] |
CT-DEA-Based Exoskeleton | Assistance | Active–Soft | Position, Force | N/A | 1 | Elbow–FE | Behboodi et al. [64] |
Hand Exoskeleton | Assistance | Active–Electric | Position | CP | 2 | Digits–FE | Bianchi et al. [65] |
Isolated Orthosis for Thumb Actuation | Rehabilitation | Active–Electric | Position, Bend | CP, Other | 2 | Thumb–FE, AA | Aubin et al. [66] |
MyoPal | Assistance | Active–Electric | EMG, Position | BPP, CP, Other | 2 | Elbow–FE Thumb and Digits–FE | Myomo [67] |
PEXO | Assistance | Active–Electric | EMG, Position | CP, Other | 3 | Thumb and Digits–FE | Bützer et al. [68] |
Soft Exoskeleton | Assistance | Active–Soft | EMG | CP, Other | 4 | Shoulder–AA Elbow–FE | Kokkoni et al. [69] |
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Gaudet, G.; Raison, M.; Achiche, S. Current Trends and Challenges in Pediatric Access to Sensorless and Sensor-Based Upper Limb Exoskeletons. Sensors 2021, 21, 3561. https://doi.org/10.3390/s21103561
Gaudet G, Raison M, Achiche S. Current Trends and Challenges in Pediatric Access to Sensorless and Sensor-Based Upper Limb Exoskeletons. Sensors. 2021; 21(10):3561. https://doi.org/10.3390/s21103561
Chicago/Turabian StyleGaudet, Guillaume, Maxime Raison, and Sofiane Achiche. 2021. "Current Trends and Challenges in Pediatric Access to Sensorless and Sensor-Based Upper Limb Exoskeletons" Sensors 21, no. 10: 3561. https://doi.org/10.3390/s21103561
APA StyleGaudet, G., Raison, M., & Achiche, S. (2021). Current Trends and Challenges in Pediatric Access to Sensorless and Sensor-Based Upper Limb Exoskeletons. Sensors, 21(10), 3561. https://doi.org/10.3390/s21103561