Motorized Biomechatronic Upper and Lower Limb Prostheses—Clinically Relevant Outcomes

Lechler, Knut; Frossard, Bertrand; Whelan, Lynsay; Langlois, David; Müller, Roy; Kristjánsson, Kristleifur

doi:10.1016/j.pmrj.2018.06.015

Cited by 14 publications

(11 citation statements)

References 117 publications

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“…The Tukey window significantly reduced ringing from Gibbs phenomena at the window edge compared to rectangular window, Fig 5c, [19], respectively. However, windowing introduces a delay between occurrence of the neural event and its extraction, which, in the context of neural prosthetics, has direct influence on user experience through intentional binding effects [29], and practical repercussions on prosthetics control and user acceptance rates [30].…”

Section: Discussionmentioning

confidence: 99%

Extracting impedance changes from a frequency multiplexed signal during neural activity in sciatic nerve of rat: preliminary study in vitro

et al. 2019

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Objective: Establish suitable frequency spacing and demodulation steps to use when extracting impedance changes from frequency division multiplexed (FDM) carrier signals in peripheral nerve.Approach: Experiments were performed in-vitro on cadavers immediately following euthanasia. Neural activity was evoked via stimulation of nerves in the hind paw, while carrier signals were injected, and recordings obtained, with a dual ring nerve cuff implanted on the sciatic nerve. Frequency analysis of recorded compound action potentials (CAPs) and extracted impedance changes, with the latter obtained using established demodulation methods, were used to determine suitable frequency spacing of carrier signals, and bandpass filter (BPF) bandwidth and order, for a frequency multiplexed signal.Main results: CAPs and impedance changes were dominant in the frequency band 200 -500 Hz and 100 -200 Hz, respectively. A Tukey window was introduced to remove ringing from Gibbs phenomena. A +/-750 Hz BPF bandwidth was selected to encompass 99.99% of the frequency power of the impedance change. Modelling predicted a minimum BPF order of 16 for 2 kHz spacing, and 10 for 4 kHz spacing, were required to avoid ringing from the neighbouring carrier signal, while FDM experiments verified BPF orders of 12 and 8, respectively, were required. With a notch filter centred on the neighbouring signal, a BPF order of at least 6 or 4 was required for 2 and 4 kHz, respectively. Significance:The results establish drive frequency spacing and demodulation settings for use in FDM electrical impedance tomography (EIT) experiments, as well as a framework for their selection, and, for the first time, demonstrates the viability of FDM-EIT of neural activity on peripheral nerve, which will be a central aspect of future real-time neural-EIT systems and EIT-based neural prosthetics interfaces.

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Section: Discussionmentioning

confidence: 99%

Extracting impedance changes from a frequency multiplexed signal during neural activity in sciatic nerve of rat: preliminary study in vitro

et al. 2019

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“…In these additional readings, one can learn more about upper limb prosthetics [46] including an advanced prosthetic called the DEKA arm [47,48] and other advances funded by defense advanced research projects agency (DARPA), [49] interfaces involved in control of prosthetics, [50][51][52][53][54] exoskeletons, [55] and considerations for different levels of amputation [56].…”

Section: Robotic Limbs and Brain-machine Interfaces (Additional Reading)mentioning

confidence: 99%

“…Topic overview [46] A review including technological advances in prosthetics for upper limb amputees [47] A case series studying the DEKA arm-a prosthetic upper limb with active wrist control [48] An article exploring the various DEKA arm models created through funding from DARPA [49] A review discussing DARPA-funded peripheral nerve interfaces including a focus on provision of motor control and sensory feedback to prosthetic limbs [50] A review summarizing biosignal processing of BMIs that utilize EEG and EMG signals, as well as a discussion of sensors, features, and classifiers for upper limb prosthetics [51] A review investigating the impact of biomechatronic technology on amputee rehabilitation outcomes, including upper limb amputees [52] This book chapter discusses the way electromyography (EMG) is used to create pattern-based myoelectric movements of upper limb prosthetics [53] A clinical trial studying the use of Utah Slanted Electrode Arrays (USEAs) to provide more degrees of freedom in movement and increased proprioception for prosthetic hand users [54] A review of the state-of-the-art and the limitations of myoelectric signal control methods of upper limb prostheses [55] A systematic review of EEG used in BMIs for control of human limb exoskeletons, including background on upper limb exoskeletons [56] A review exploring exoprosthetic limb replacement considering different severities of amputation to the upper limb…”

Section: Referencementioning

confidence: 99%

Frontiers of Brachial Plexus Injury: Future Revolutions in the Field

Rosen¹,

Hong²,

Klaudt-Moreau³

et al. 2022

Brachial Plexus Injury - New Techniques and Ideas

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The field of brachial plexus surgery has undergone dramatic changes in the past 40 years. Most of these have been incremental in nature. We have seen increased use of nerve grafts and nerve transfers. We have seen the introduction of robotic limb replacements for the most severe flail limbs where surgical intervention has failed. In some cases, we have seen an increase in the use of computer simulation and virtual reality to train surgeons to plan and execute surgeries. More recently, we have seen the introduction of technologies derived from regenerative medicine research.

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“…Recent technological breakthroughs have evolved toward motorized prostheses (Martinez-Villalpando et al, 2011;Simon et al, 2013Simon et al, , 2014Takahashi et al, 2015;Wu et al, 2017). Although some devices (e.g., the Power Knee from Össur, Reykjavik, Iceland) already reached the market, they are still underprescribed and under-utilized due to the large costs of product development and customization (Lechler et al, 2018). Moreover, current motorized prostheses mainly focus on improving walking abilities, whereas emphasis on other daily activities is also of highly importance (Ghillebert et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

Performance of the CYBERLEGs motorized lower limb prosthetic device during simulated daily activities

et al. 2021

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Background The CYBERLEGs-gamma (CLs-ɣ) prosthesis has been developed to investigate the possibilities of powerful active prosthetics in restoring human gait capabilities after lower limb amputation. Objective The objective of this study was to determine the performance of the CLs-ɣ prosthesis during simulated daily activities. Methods Eight participants with a transfemoral amputation (age: 55 ± 15 years, K-level 3, registered under: NCT03376919) performed a familiarization session, an experimental session with their current prosthesis, three training sessions with the CLs-ɣ prosthesis and another experimental session with the CLs-ɣ prosthesis. Participants completed a stair-climbing-test, a timed-up-and-go-test, a sit-to stand-test, a 2-min dual-task and a 6-min treadmill walk test. Results Comparisons between the two experimental sessions showed that stride length significantly increased during walking with the CLs-ɣ prosthesis (p = .012) due to a greater step length of the amputated leg (p = .035). Although a training period with the prototype was included, preferred walking speed was significantly slower (p = .018), the metabolic cost of transport was significantly higher (p = .028) and reaction times significantly worsened (p = .012) when walking with the CLs-ɣ compared to the current prosthesis. Conclusions It can be stated that a higher physical and cognitive effort were required when wearing the CLs-ɣ prosthesis. Positive outcomes were observed regarding stride length and stair ambulation. Future prosthetics development should minimize the weight of the device and integrate customized control systems. A recommendation for future research is to include several shorter training periods or a prolonged adaptation period.

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Motorized Biomechatronic Upper and Lower Limb Prostheses—Clinically Relevant Outcomes

Cited by 14 publications

References 117 publications

Extracting impedance changes from a frequency multiplexed signal during neural activity in sciatic nerve of rat: preliminary study in vitro

Extracting impedance changes from a frequency multiplexed signal during neural activity in sciatic nerve of rat: preliminary study in vitro

Frontiers of Brachial Plexus Injury: Future Revolutions in the Field

Performance of the CYBERLEGs motorized lower limb prosthetic device during simulated daily activities

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