Biofeedback Systems for Gait Rehabilitation of Individuals with Lower-Limb Amputation: A Systematic Review
Abstract
:1. Introduction
2. Methods
2.1. Search Strategy
2.2. Inclusion and Exclusion Criteria
2.3. Screening and Data Extraction
2.4. Risk of Bias (Quality) Assessment
3. Results
3.1. Search Results
3.2. Quality of Reviewed Articles
3.3. Key Data Extracted from Reviewed Articles
4. Discussion
4.1. Sample Size
4.2. User Demographicss
4.3. Level of Amputation
4.4. Prosthetic Experience and Time Since Amputation
4.5. BFB Intervention (Experimental Protocol)
4.6. Treadmill vs. Overground Walking
4.7. BFB Parameter Measurements
4.8. BFB Modality
4.9. Feedback Strategies
4.10. Other BFB design and Application Considerations
4.11. Limitations of the Systematic Review
5. Conclusions
Supplementary Materials
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
References
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Biofeedback | Gait | Amputation | ||
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biofeedback.mp. OR feedback.kf,tw. OR (feedback adj3 sensory).mp. OR (wearable adj3 feedback).mp. OR (biomechanical adj3 feedback).mp. OR prosthesis design.tw,kf. | AND | gait.mp. OR walk*.mp. | AND | amput*.mp. OR prosthe*.tw,kf. OR (lower adj3 limb*).mp. OR (artificial adj3 limb*).mp. OR (artificial adj3 leg*).mp. OR (prosthe* adj3 leg*).mp. OR (prosthe* adj3 limb*).mp. OR knee prosthe*.mp. OR (prosthe* adj3 joint*).mp. OR (artificial adj3 joint*).mp. OR (lower adj3 extrtemit*).tw,kf. OR amputation/or disarticulation/or hemipelvectomy/ OR disarticulation.mp. OR hemipelvectomy.mp. OR (partial* adj3 amput*).mp. |
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Biofeedback application |
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Question |
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1. Were the research objectives of the study clearly stated? 2. Was the study design clearly described? 3. Were the subject’s characteristics and details clearly provided? 4. Was biofeedback modality (e.g., visual, auditory, haptic) and application clearly stated? 5. Was equipment design and setup clearly described? 6. Was the experimental protocol/subject intervention clearly defined? 7. Were the methods for statistical analysis clearly described? 8. Were the main outcomes measures clearly stated? 9. Were key findings supported by the results? 10. Were limitations of the study clearly described? 11. Were key findings supported by other literature? 12. Were conclusions drawn from the study clearly stated? |
Study, Author | Year | Question | Total Score | Overall Percentage | |||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | 10 | 11 | 12 | ||||
[59] Petrini et al. | 2019 | 1 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | 1 | 22/24 | 92 |
[57] Fiedler et al. | 2019 | 2 | 2 | 2 | 2 | 2 | 2 | 0 | 1 | 2 | 2 | 1 | 2 | 23/24 | 96 |
[80] Petrini et al. | 2019 | 2 | 2 | 1 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | 1 | 22/24 | 92 |
[35] Brandt et al. | 2019 | 2 | 2 | 2 | 2 | 2 | 1 | 2 | 2 | 2 | 2 | 2 | 2 | 23/24 | 96 |
[86] Dietrich et al. | 2018 | 2 | 2 | 2 | 2 | 2 | 1 | 2 | 2 | 2 | 2 | 2 | 2 | 23/24 | 96 |
[34] Esposito et al. | 2017 | 2 | 2 | 1 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | 23/24 | 96 |
[87] Maldonado et al. | 2017 | 2 | 2 | 1 | 2 | 2 | 2 | 1 | 2 | 2 | 1 | 0 | 2 | 19/24 | 79 |
[58] Crea et al. | 2017 | 2 | 2 | 1 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | 23/24 | 96 |
[28] Plauche et al. | 2016 | 2 | 2 | 2 | 2 | 2 | 2 | 0 | 2 | 2 | 2 | 2 | 1 | 21/24 | 88 |
[84] Pagel et al. | 2016 | 2 | 2 | 2 | 2 | 2 | 1 | 2 | 2 | 2 | 2 | 2 | 2 | 23/24 | 96 |
[82] Huang et al. | 2016 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | 1 | 2 | 23/24 | 96 |
[30] Crea et al. | 2015 | 2 | 2 | 1 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | 23/24 | 96 |
[77] Lee et al. | 2013 | 2 | 2 | 2 | 2 | 2 | 1 | 0 | 2 | 1 | 1 | 1 | 2 | 18/24 | 75 |
[88] Redd et al. | 2012 | 2 | 2 | 1 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | 23/24 | 96 |
[36] Yang et al. | 2012 | 2 | 2 | 2 | 2 | 2 | 1 | 1 | 2 | 2 | 2 | 0 | 2 | 20/24 | 83 |
[81] Darter et al. | 2011 | 2 | 2 | 2 | 2 | 2 | 2 | 0 | 2 | 2 | 2 | 2 | 2 | 22/24 | 92 |
[76] Lee et al. | 2010 | 2 | 2 | 2 | 2 | 2 | 1 | 0 | 2 | 1 | 1 | 1 | 2 | 18/24 | 75 |
[75] Lee et al. | 2009 | 2 | 2 | 2 | 2 | 2 | 1 | 0 | 2 | 1 | 1 | 1 | 2 | 18/24 | 75 |
[74] Lee et al. | 2008 | 2 | 2 | 2 | 2 | 2 | 1 | 0 | 2 | 1 | 1 | 1 | 2 | 18/24 | 75 |
[56] Lee et al. | 2007 | 2 | 2 | 2 | 2 | 2 | 1 | 0 | 2 | 1 | 1 | 1 | 2 | 18/24 | 75 |
[66] Isakov et al. | 2007 | 2 | 2 | 2 | 1 | 2 | 2 | 2 | 2 | 2 | 0 | 0 | 2 | 19/24 | 79 |
[89] Davis et al. | 2004 | 2 | 2 | 2 | 1 | 1 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | 22/24 | 92 |
[90] Chow et al. | 2000 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | 1 | 1 | 2 | 22/24 | 92 |
[91] Dingwell et al. | 1996 | 2 | 2 | 1 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | 23/24 | 96 |
[83] Sabolich et al. | 1994 | 2 | 2 | 2 | 2 | 2 | 2 | 1 | 2 | 2 | 1 | 0 | 2 | 20/24 | 83 |
[17] Flowers et al. | 1986 | 2 | 1 | 1 | 2 | 2 | 0 | 0 | 1 | 2 | 2 | 0 | 2 | 15/24 | 63 |
[92] Clippinger et al. | 1982 | 1 | 1 | 2 | 2 | 2 | 2 | 0 | 1 | 1 | 0 | 1 | 1 | 14/24 | 58 |
[93] Gapsis et al. | 1982 | 2 | 1 | 2 | 2 | 2 | 1 | 1 | 1 | 1 | 1 | 1 | 1 | 16/24 | 67 |
[85] Fernie et al. | 1978 | 1 | 1 | 1 | 1 | 1 | 1 | 0 | 1 | 1 | 1 | 0 | 1 | 10/24 | 42 |
[94] Zimnicki et al. | 1976 | 1 | 1 | 1 | 2 | 2 | 2 | 0 | 1 | 1 | 1 | 0 | 1 | 13/24 | 54 |
[95] Warren et al. | 1975 | 2 | 1 | 1 | 1 | 1 | 2 | 0 | 1 | 1 | 1 | 1 | 1 | 13/24 | 54 |
Study Characteristics | Participant’s Characteristics | Biofeedback (BFB) Design | Testing Conditions | Outcome Measures | Intervention Protocol Summary | Key Findings | ||
---|---|---|---|---|---|---|---|---|
Gait Parameters | Physical, Physiological and Other Parameters | Questionnaire | ||||||
[59] Petrini et al. 2019 Real-time intraneural stimulation to restore sensory feedback of transfemoral amputees | 2 TF Cause: trauma Age: 49 yrs, 35 yrs PE: N/D TSA: 3 yrs, 12 yrs | FM: Intraneural stimulation (touch, pressure, or vibration) FD: Surgical implanted electrodes FS: Concurrent S/T: Insole pressure sensors, knee encoder | Lab & Field, Treadmill & Overground | Heel-strike, flat foot, toe-off, knee angle, walking speed | Metabolic consumption (VO2), mental effort, phantom limb pain | Neuropathic Pain Symptom Inventory (NPSI), Visual Analog Scale (VAS) | Walking speed and mental effort: 6 min outdoor (sand) walking x 2 sessions per condition (with/without feedback + dual task), Metabolic cost: Indoors: (i) 15 min treadmill walking with increasing speed, (ii) outdoors (grass): 3 min baseline x 6 min walking at SS speed | Walking speed and self-reported confidence increased. Mental and physical fatigue decreased, including reduced phantom limb pain with feedback |
[57] Fiedler et al. 2019 Mobile visual feedback system for gait rehabilitation in everyday-life environment | 1 TT Cause: N/D Age: 61 yrs PE: 12 yrs TSA: N/D | FM: Visual FD: Smart glasses FS: Concurrent S/T: Load cell | Lab, Overground | Stance/step ratio, gait symmetry index | N/A | N/A | 30 m walking (repeatedly) at SS speed within 1-hr | A strong correlation found between stance/step ratio (the feedback variable) and gait symmetry index |
[80] Petrini et al. 2019 Real-time tactile and proprioceptive feedback to increase prosthesis embodiment and to improve mobility of transfemoral amputees | 3 TF Cause: trauma Age: N/D PE: N/D TSA: 3 yrs, 7 yrs, 12 yrs | FM: Intraneural stimulation (touch, pressure, or vibration) FD: Surgical implanted electrodes FS: Concurrent S/T: Insole pressure sensors, knee encoder | Lab, Overground | Heel-strike, flat foot, toe-off, knee angle, walking speed | Error walking on a line (walking agility), proprioceptive displacement, cognitive load (dual-task paradigm) | Embodiment questionnaire | Nine 5 m walking trials with/without feedback over a straight line (one foot after the other without stepping outside the line) | Improved mobility, ease of cognitive effort, and increased embodiment of prosthesis with feedback |
[35] Brandt et al. 2019 Visual feedback to increase stance time on the prosthetic limb. Compare powered versus passive knee prostheses | 5 TF or knee disarticulation Cause: trauma/cancer/congenital Age: 19–59 yrs PE: 6 mos.–6 yrs TSA: 4–47 yrs | FM: Visual FD: Computer monitor FS: Concurrent S/T: Instrumented treadmill (dual belt) with force plates, motion capture system | Lab, Treadmill | Stance time, swing time, stance time asymmetry, peak anterior-posterior ground reaction forces, peak anterior propulsive asymmetry | N/A | Likert scale (perceived difficulty) | Twelve 1.5 min walking trials at SS speed with 2 min of rest between trials over 3 sessions of 3 h each. Fitting and training provided during prior sessions. | Stance time symmetry and peak propulsion symmetry significantly improved with both prosthesis by increasing prosthetic stance time via feedback |
[86] Dietrich et al. 2018 Assess whether prostheses with somatosensory feedback can reduce phantom limb pain and increase ambulation | 14 TT Cause: trauma/embolism Age: 27–76 yrs (56.3 ± 11.6 yrs) PE: N/D TSA: 1–54 yrs | FM: Electrocutaneous FD: Electrodes FS: Concurrent S/T: Insole pressure sensors | Field, Overground | Stance time | Walking distance, walking speed, phantom limb pain | Likert scale (discrimination performance), Houghton Score Questionnaire (HSQ), Locomotor Capability Index (LCI), Trinity Amputation and Experience Scales (TAPES), Amputee Body Image Scale (ABIS), Pain questionnaires, and pain daily reports | 10 days of training (walking at level ground and uneven terrains) over 2 weeks, 2 sessions per day, 2 h per session with 30–60 min of rest between daily sessions. | Reduction of phantom limb pain, larger walking distances, stable walking and better posture control on uneven ground with feedback |
[34] Esposito et al. 2017 Assess whether visual feedback can reduce center of mass sway and metabolic consumption during gait retraining | Study group: 8 TT Cause: trauma Age: 32.9 ± 5.7 yrs PE: 29 ± 38 mos. TSA: N/D Control group: 8 H Cause: N/A Age: 29.4 ± 3.8 yrs PE: N/A TSA: N/A | FM: Visual (virtual reality) FD: CAREN (Computer Assisted Rehabilitation Environment) FS: Concurrent S/T: Bipolar surface electrodes, motion capture system | Lab, Treadmill | Center of mass sway | Metabolic rate (VO2), heart rate, thigh muscle activation magnitudes and duration, quadriceps and hamstrings muscle activity | N/A | Baseline: 10 min in seated position (VO2 baseline). Acclimation: 4 min practice receiving visual feedback and verbal cues (PT). Data collection: 8 min walking (with/without visual feedback) at standardized speed | Visual feedback decreased center of mass sway and quadriceps activity. Thigh muscle co-contraction indices unchanged. Metabolic rate was not significantly affected by feedback |
[87] Maldonado et al. 2017 BFB system developed as a training tool to sense perturbations to perform corrective actions to avoid falls | 2 TT Cause: N/D Age: 49 yrs, 67 yrs PE: N/D TSA: N/D | FM: Vibrotactile FD: Vibrating motors, solenoid FS: Concurrent S/T: Electrogoniometer | Lab, Overground | Knee angle | Reaction times, subject’s response to stimulus | N/A | Six 1 h to 2 h training sessions over 3 weeks, receiving only vibrotactile feedback. One 2 h session, vibrotactile and solenoid feedback (retention and transfer test) | Subjects performed the corrective movement in response to feedback. No conclusive results for retention and transfer tests. |
[58] Crea et al. 2017 BFB system developed to improve temporal gait symmetry of elderly transfemoral amputees | 3 TF Cause: N/D Age: > 60 yrs PE: N/D TSA: > 1 year | FM: Vibrotactile, Visual FD: Vibrating motors, display screen FS: Concurrent S/T: Pressure-sensitive insoles | Lab, Treadmill | Stance time, symmetry index, cadence | Heart rate, breathing rate, skin temperature, skin conductance, cognitive load | National Aeronautics and Space Administration Task Load Index (NASA-TLX34), System Usability Scale (SUS) | Within a week: Pre- and Post-training, 1 session each (only vibrotactile). 3 sessions training (vibrotactile + visual feedback). Follow-up a week after (only vibrotactile) | Feedback improved symmetry index and lower cadence promoting longer strides. Cognitive load did not increase with feedback. No signs of negative psychophysiological effects. |
[28] Plauche et al. 2016 Develop a BFB system to asses gait performance under different vibrotactile feedback strategies on able-bodied subjects walking with a prosthetic adaptor | 9 H (above-knee prosthetic adaptor) Cause: N/A Age: 25.6 ± 2 yrs PE: N/A TSA: N/A | FM: Vibrotactile FD: Vibrating motors FS: Concurrent S/T: Force sensing resistors (FSRs) sensors | Lab, Treadmill | Stride length step width, trunk sway, including their variabilities | N/A | Likert scale (feedback strategies) | Walking 30 s at SS speed on a treadmill (10 trials per condition) with/without feedback and with/without prosthesis adaptor | Improved gait stability as the variability of stride length, step width and trunk sway decreased. |
[84] Pagel et al. 2016 Develop a BFB system to improve gait symmetry by providing feedback from foot center of pressure and knee flexion angle | 3 TF Cause: trauma/cancer Age: 21 yrs, 54 yrs, 73 yrs PE: 1 yrs, 36 yrs, 53 yrs TSA: 1 yrs, 52 yrs, 53 yrs | FM: Electrotactile FD: Electrodes FS: Concurrent S/T: Force/moment sensor, goniometer-gyroscope sensor | Lab, Treadmill | Stance time, step length, stance time ratio, step length ratio, ground reaction forces, center of pressure (CoP), knee flexion angle | N/A | User’s feedback experience questionnaire | 2 min walking per condition (no feedback, CoP feedback, and knee angle feedback), SS speed | No persistent positive effect but improved step length for one participant. Subjects felt more benefited from knee angle feedback than CoP feedback. |
[82] Huang et al. 2016 Utilize visual feedback to alter prosthetic ankle performance while using a powered prosthesis with myoelectric controlled | 5 TT Cause: trauma/cancer Age: 23–70 yrs (55.4 ± 18.6 yrs) PE: N/D TSA: 4–44 yrs (22.6 ± 19 yrs) | FM: Visual FD: Computer monitor FS: Concurrent S/T: Motion capture system, force plates, electromyography (EMG) sensors | Lab, Treadmill | Peak ankle power, total ankle work, positive ankle work, negative ankle work | Residual limb muscle activation patterns | N/A | 5 min to 10 min walking trial with prescribed and powered prosthesis with/without feedback, speed 1.0 m/s. An average of 3.5 h of training in total over 2 months. | Adapted muscle activation patterns due to visual feedback. Increased peak ankle power and positive ankle work. |
[30] Crea et al. 2015 BFB system to provide vibrotactile feedback during gait-phase transitions | 10 H Cause: N/A Age: 27 ± 1.8 yrs PE: N/A TSA: N/A | FM: Vibrotactile FD: Vibrating motors FS: Concurrent S/T: Pressure-sensitive insoles | Lab, Treadmill | Stance time, swing time, step cadence, vertical ground reaction force, center of pressure | N/A | Self-assessment questionnaire (cognitive effort) | 6 min walking per condition (missing stimuli, delay stimuli: 200 s & 500 s, and wrong stimuli). | Accuracy in stimuli detection decreased if delay increased. Good usability, feedback is readily perceived by participants. |
[77] Lee et al. 2013 Evaluate a BFB system using subsensory stimulation and visual-auditory feedback to improve postural sway and dynamic weight shifting stability | 7 TT Cause: N/D Age: 24–60 yrs (38.8 ± 14.08 yrs) PE: > 2 yrs (8.5 ± 6.12 yrs) TSA: N/D | FM: Auditory, Visual FD: PC speaker, computer monitor FS: Concurrent S/T: Force sensing resistors (FSRs) sensors | Lab, Treadmill | Double support time symmetry index, constant time step number index, single support time symmetry index, gait phase time ratio index | Heart rate | N/A | 20 min each test session (5 min warm up, 10 min training and 5 min cool down). Walking speed increased each minute as tolerated (starting at SS speed) | Improvement in weight shifting stability indices. Most subjects easily adapted to auditory rather than visual biofeedback. |
[88] Redd et al. 2012 Assess the ability of a BFB system to alter gait symmetry under visual, auditory and vibrotactile feedback | 12 H Cause: N/A Age: N/D PE: N/A TSA: N/A | FM: Auditory, Vibrotactile, Visual FD: Smartphone FS: Concurrent S/T: Force sensing resistors (FSRs) sensors | Lab, Overground | Stance time symmetry ratio | N/A | Usability survey | Six 200 ft walking trials (one trial per feedback modality and 3 trials with the preferred feedback modality) | BFB altered gait of user without supervision from a specialist. Visual was the preferred feedback modality. |
[36] Yang et al. 2012 Evaluate the performance of a BFB device to improve gait symmetry of prosthetic users | 3 TT Cause: infection/embolism Age: 22–65 yrs (49.7 ± 19.6 yrs) PE: N/D TSA: 7 mos.–5.5 yrs | FM: Auditory FD: BFB buzzer FS: Concurrent S/T: Force sensing resistors (FSRs) sensors, motion capture system, force plates | Lab, N/D | Stance time, symmetry ratio, trunk sway | N/A | N/A | Pre-test 1 week before, six 30 min training, post-test 1 week after. PT set trial duration (avg. 30s–240s) and feedback thresholds. | 2 of 3 subjects improved symmetry ratio and trunk sway |
[81] Darter et al. 2011 Assess biomechanical and physiological effects of gait training using virtual reality | 1 TF Cause: trauma Age: 24 yrs PE: 2 yrs TSA: N/D | FM: Visual (virtual reality) FD: CAREN (Computer Assisted Rehabilitation Environment) FS: Concurrent, verbal cues (PT) S/T: Motion capture system, force plates | Lab, Treadmill & Overground | Frontal-plane trunk motion, frontal plane hip, pelvis and trunk angles, walking speed, step length, stance time, step width | VO2 consumption | N/A | Twelve 30 min walking sessions within 3 weeks. Follow-up: 3 weeks after training. PT involved during first BFB sessions | Training effective in improving frontal plane hip, pelvis and trunk motion, with decreases in oxygen consumption during overground walking. Retention found at 3 weeks after training |
[76] Lee et al. 2010 Asses a BFB system using subsensory stimulation and visual-auditory feedback to improve postural sway and dynamic weight shifting stability | 7 TT Cause: N/D Age: 24–60 yrs (38.8 ± 14.08 yrs) PE > 2 yrs (8.5 ± 6.12 yrs) TSA: N/D | FM: Auditory, Visual FD: PC speaker, computer monitor FS: Concurrent S/T: Force sensing resistors (FSRs) sensors | Lab, Treadmill | Double support time symmetry index, constant time step number index, single support time symmetry index, gait phase time ratio index | Heart rate | N/A | 20 min each test session (5 min warm up, 10 min training and 5 min cool down). Walking speed increased each minute as tolerated (starting at SS speed) | Improvement in weight shifting stability indices. Most subjects easily adapted to auditory rather than visual feedback |
[75] Lee et al. 2009 Assess a BFB system using subsensory stimulation and visual-auditory feedback to improve postural sway and dynamic weight shifting stability | 7 TT Cause: N/D Age: 24–60 yrs (38.8 ± 14.08 yrs) PE: > 2 yrs (8.5 ± 6.12 yrs) TSA: N/D | FM: Auditory, Visual FD: PC speaker, computer monitor FS: Concurrent S/T: Force sensing resistors (FSRs) sensors | Lab, Treadmill | Double support time symmetry index, constant time step number index, single support time symmetry index, gait phase time ratio index | Heart rate | N/A | 20 min each test session (5 min warm up, 10 min training and 5 min cool down).Walking speed increased each minute as tolerated (starting at SS speed) | Improvement in weight shifting stability indices. Most subjects easily adapted to auditory rather than visual feedback |
[74] Lee et al. 2008 Evaluate a computerized foot pressure BFB system using subsensory electrical stimulation and visual-auditory feedback to improve gait and balance of transtibial amputees | 5 TT Cause: N/D Age: 24–48 yrs (37.4 ± 11.57 yrs) PE: >2 yrs TSA: N/D | FM: Auditory, Visual FD: PC speaker, computer monitor FS: Concurrent S/T: Force sensing resistors (FSRs) sensors | Lab, Treadmill | Double support time index, constant time cadence index, single support time index, stance/swing phase index | Heart rate | N/A | 20 min each test session (5 min warm up, 10 min training and 5 min cool down). Walking speed increased each minute as tolerated (starting at SS speed) | Improvement in all dynamic gait performance indices. Most subjects easily adapted to auditory rather than visual feedback |
[56] Lee et al. 2007 Assess a computerized foot pressure BFB system using low-level electrical stimulation and visual-auditory feedback to improve gait and balance | 7 TT Cause: N/D Age: 24–60 yrs (38.8 ± 14.08 yrs) PE: > 2 yrs (8.5 ± 6.12 yrs) TSA: N/D | FM: Auditory, Visual FD: PC speaker, computer monitor FS: Concurrent S/T: Force sensing resistors (FSRs) sensors | Lab, Treadmill | Double support period, constant time cadence, single support period, stance/swing ratio | N/A | N/A | 20 min each test session (5 min warm up, 10 min training and 5 min cool down). Walking speed increased each minute as tolerated (starting at SS speed) | Improvement in all dynamic gait performance measures. Most subjects easily adapted to auditory rather than visual feedback |
[66] Isakov et al. 2007 Evaluate the effectiveness of a BFB system compare to traditional training (control group) to improve full weight-bearing of lower-limb amputees | 42 LLA (TF, TT, hip and knee replacement, femoral neck fracture), (n = 22 study, n = 20 control group) Cause: N/D Age: avg. 62 yrs (study), 66 yrs (control) PE: N/D TSA: N/D | FM: Auditory (study), Verbal cues (control) FD: SmartSte™ (audio) FS: Concurrent (study), Physiotherapy (control) S/T: Pressure sensors (study) | N/D, N/D | Prosthetic weight-bearing | N/A | N/A | Both groups: 10 m walking at SS speed. Four 30 min sessions within 14 days. | Weight-bearing on the prosthetic limb was statistically significant increased while using BFB |
[89] Davis et al. 2004 Evaluate whether a BFB system is capable to reduce oxygen consumption by improving gait symmetry of lower-limb amputees | 11 TF/TT Cause: trauma/diabetes Age: 36–58 yrs PE: N/D TSA: N/D | FM: Visual FD: Computer monitor FS: Concurrent S/T: Instrumented treadmill with force plates | Lab, Treadmill | Stance/swing ratios, foot propulsive forces, shear foot forces | Heart rate, VO2 consumption, tidal volume | N/A | Five 4 min tests with/without feedback per each target gait parameter (stance/swing ratio, foot propulsive forces, and shear foot forces) | Real-time visual feedback results in immediate symmetry improvements. Significant reductions in heart rate and oxygen consumption with feedback |
[90] Chow et al. 2000 Evaluate the effects of BFB on weight-bearing patterns of TT amputees at early postoperative period | 6 TT Cause: diabetes/peripheral vascular disease Age: 66–78 yrs PE: N/D TSA: N/D | FM: Auditory FD: BFB buzzer FS: Concurrent S/T: Load-monitoring device (pair of single-axis strain gauges) | Lab, Overground | Prosthetic weight-bearing | N/A | N/A | 4 randomized walking trials (5m length) with/without feedback over 5 sessions at SS speed | Feedback prevents overloading of the residual limb beyond the pre-set load target |
[91] Dingwell et al. 1996 Reduce gait asymmetries of TT amputees via real-time visual feedback | 6 H Age: 33–54 yrs (avg. 42.7 yrs); 6 TT Cause: trauma/cancer/peripheral vascular disease Age: 31–69 yrs (avg. 41.7 yrs) PE: 6 mos.–21 yrs (avg. 6 yrs) TSA: N/D | FM: Visual FD: Computer monitor FS: Concurrent S/T: Instrumented treadmill with force plates | Lab, Treadmill | Centre of pressure (CoP), stance time (%), push off forces, symmetry index, single support time | N/A | N/A | 4 min of acclimation (no feedback), 5 min of training with each feedback parameter (CoP, stance time percentage, and symmetry index), SS speed | Asymmetrical gait patterns were significantly reduced after providing visual feedback |
[83] Sabolich et al. 1994 Improve balance and gait by restoring sensory perception at the residual limb/socket interface via transcutaneous electrical neural stimulation | 12 TF, 12 TT Cause: trauma/cancer/dysvascular disease/infection Age: 21–68 yrs (39.5 ± 13.3 yrs) PE: 3 mos.–31 yrs (8.1 ± 9.4 yrs) TSA: N/D | FM: Electrical neural stimulation FD: Transcutaneous electrodes FS: Concurrent S/T: Pressure transducers | Lab, N/D | Symmetry of weight distribution, single limb standing balance, step length symmetry, stance time symmetry | N/A | N/A | 5 h to 6 h walking with/without feedback (10 min intervals per 20 min rest) | Both populations increased weight distribution symmetry, step length symmetry. Stance time symmetry and standing balance improved mainly for TF amputees. |
[17] Flowers et al. 1986 Develop and evaluate a BFB system to improve prosthetic weight-bearing and hip extension | 5 TF Cause: N/D Age: 19–68 yrs PE: N/D TSA: N/D | FM: Auditory FD: Earphones or BFB speakers FS: Concurrent S/T: Load cell (or weight bearing transducers), goniometer | Lab, Overground | Weight bearing, hip extension angle, steps count | N/A | N/A | 30 min to 1h sessions over 4 months (BFB device used during PT sessions) | Subjects with diminished awareness of their bodies and reduced strength benefited more from feedback. BFB improved hip extension and flexion at the beginning of stance phase |
[92] Clippinger et al. 1982 Enhance sensory feedback after lower limb amputation by providing electrical stimulation | 13 LLA (5 Hip disarticulation, 7 TF, 1 bilateral TT) Cause: N/D Age: N/D PE: N/D TSA: 3 days–4 yrs | FM: Afferent sensory feedback FD: Surgically implanted electrodes FS: Concurrent S/T: Piezoelectric crystal, strain gauges | N/D, N/D | Weight bearing | N/A | N/A | 3 h to 12 h of daily stimulation ranging from 8 months to 6 years | Implanted electrodes were tolerated by all patients without discomfort. Postoperative pain reduced and stump healing improved by stimulating the sciatic nerve |
[93] Gapsis et al. 1982 Evaluate a limb load monitor for controlling weight bearing of lower-limb amputees | 20 LLA (n = 10 study, n = 10 control group) Cause: ND Age: 47–78 yrs (avg. 62.5 yrs) PE: N/D TSA: N/D | FM: Auditory FD: BFB buzzer FS: Concurrent S/T: Load sensitive transducer | Lab, Overground | Weight bearing (prosthetic limb load) | Total body weight | N/A | 5 min for acclimation period, feedback system used during patient’s daily ambulation therapy | Control and study group reached goals. Study group reached goals twice as fast with feedback |
[85] Fernie et al. 1978 BFB device designed to promote knee extension at stance phase | 19 TF Cause: ND Age: 46–84 yrs (avg. 70 yrs) PE: N/D TSA: N/D | FM: Auditory FD: BFB buzzer FS: Concurrent S/T: Foot and knee switch | N/D, N/D | Knee flexion/extension angle, steps count | Percentage of errors (i.e., bending the knee and loading the limb simultaneously) | N/A | 3 weeks of training. PT involved at early BFB stages. | Feedback system encouraged knee flexion than knee extension. Audio signal too annoying to use.One participant showed a period of retention in the 3rd week of training |
[94] Zimnicki et al. 1976 BFB system developed for geriatric above-knee amputees to achieve an adequate knee extension during walking | 13 TF Cause: N/D Age: 53–84 yrs (avg. 72 yrs) PE: N/D TSA: N/D | FM: Auditory FD: BFB buzzer FS: Concurrent S/T: Pylon switch | N/D, N/D | Knee flexion/extension angle, body weight pressure | N/A | N/A | 5 progressive training stages over 5 or more sessions. PT involved to reinforce BFB training | BFB found to be more helpful for participants who had difficulty in following or concentrating on verbal instructions and for those one who appeared to understand but were enabled to elicit the appropriate motor responses |
[95] Warren et al. 1975 Evaluate the effectiveness of a BFB system in comparison to a Bathroom scale to improve weight-bearing | 10 H Cause: N/A Age: 18–26 yrs PE: N/A TSA: N/A | FM: Auditory, Visual FD: BFB alarm FS: Concurrent S/T: Force plates, pressure sensitive insoles | Lab, Overground | Weight-bearing | N/A | N/A | Bathroom scale: two times - four steps on monitored leg. Three training levels with/without feedback (trying to reproduce target loading threshold) | BFB training was of limited value due to time lag between feedback and motor response |
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Escamilla-Nunez, R.; Michelini, A.; Andrysek, J. Biofeedback Systems for Gait Rehabilitation of Individuals with Lower-Limb Amputation: A Systematic Review. Sensors 2020, 20, 1628. https://doi.org/10.3390/s20061628
Escamilla-Nunez R, Michelini A, Andrysek J. Biofeedback Systems for Gait Rehabilitation of Individuals with Lower-Limb Amputation: A Systematic Review. Sensors. 2020; 20(6):1628. https://doi.org/10.3390/s20061628
Chicago/Turabian StyleEscamilla-Nunez, Rafael, Alexandria Michelini, and Jan Andrysek. 2020. "Biofeedback Systems for Gait Rehabilitation of Individuals with Lower-Limb Amputation: A Systematic Review" Sensors 20, no. 6: 1628. https://doi.org/10.3390/s20061628
APA StyleEscamilla-Nunez, R., Michelini, A., & Andrysek, J. (2020). Biofeedback Systems for Gait Rehabilitation of Individuals with Lower-Limb Amputation: A Systematic Review. Sensors, 20(6), 1628. https://doi.org/10.3390/s20061628