Development of Soft sEMG Sensing Structures Using 3D-Printing Technologies

Development of Soft sEMG Sensing Structures Using 3D-Printing Technologies

3D printing of soft EMG sensing structures enables the creation of personalized sensing structures that can be potentially integrated in prosthetic, assistive and other devices. We developed and characterized flexible carbon-black doped TPU-based sEMG sensing structures. The structures are directly...

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Main Authors: Gerjan Wolterink, Pedro Dias, Remco G.P. Sanders, Frodo Muijzer, Bert-Jan van Beijnum, Peter Veltink, Gijs Krijnen
Format: Article
Language:English
Published: MDPI AG 2020-07-01
Series:Sensors
Subjects:
3D-printing
thermoplactic polyurethane (TPU)
conductive
flexible
soft
EMG
Online Access:https://www.mdpi.com/1424-8220/20/15/4292
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spelling doaj-fa6c83df38d64c2aad4e7b39d3e1fe502020-11-25T03:22:20ZengMDPI AGSensors1424-82202020-07-01204292429210.3390/s20154292Development of Soft sEMG Sensing Structures Using 3D-Printing TechnologiesGerjan Wolterink0Pedro Dias1Remco G.P. Sanders2Frodo Muijzer3Bert-Jan van Beijnum4Peter Veltink5Gijs Krijnen6Robotics And Mechatronics group (RAM), University of Twente, 7500 AE Enschede, The NetherlandsRobotics And Mechatronics group (RAM), University of Twente, 7500 AE Enschede, The NetherlandsRobotics And Mechatronics group (RAM), University of Twente, 7500 AE Enschede, The NetherlandsTwente Medical Systems International B.V. (TMSi), 7575 EJ Oldenzaal, The NetherlandsBiomedical Signals and Systems (BSS), University of Twente, 7500 AE Enschede, The NetherlandsBiomedical Signals and Systems (BSS), University of Twente, 7500 AE Enschede, The NetherlandsRobotics And Mechatronics group (RAM), University of Twente, 7500 AE Enschede, The Netherlands3D printing of soft EMG sensing structures enables the creation of personalized sensing structures that can be potentially integrated in prosthetic, assistive and other devices. We developed and characterized flexible carbon-black doped TPU-based sEMG sensing structures. The structures are directly 3D-printed without the need for an additional post-processing step using a low-cost, consumer grade multi-material FDM printer. A comparison between the gold standard Ag/AgCl gel electrodes and the 3D-printed EMG electrodes with a comparable contact area shows that there is no significant difference in the EMG signals’ amplitude. The sensors are capable of distinguishing a variable level of muscle activity of the biceps brachii. Furthermore, as a proof of principle, sEMG data of a 3D-printed 8-electrode band are analyzed using a patten recognition algorithm to recognize hand gestures. This work shows that 3D-printed sEMG electrodes have great potential in practical applications.https://www.mdpi.com/1424-8220/20/15/42923D-printingthermoplactic polyurethane (TPU)conductiveflexiblesoftEMG
collection DOAJ
language English
format Article
sources DOAJ
author Gerjan Wolterink
Pedro Dias
Remco G.P. Sanders
Frodo Muijzer
Bert-Jan van Beijnum
Peter Veltink
Gijs Krijnen
spellingShingle Gerjan Wolterink
Pedro Dias
Remco G.P. Sanders
Frodo Muijzer
Bert-Jan van Beijnum
Peter Veltink
Gijs Krijnen
Development of Soft sEMG Sensing Structures Using 3D-Printing Technologies
Sensors
3D-printing
thermoplactic polyurethane (TPU)
conductive
flexible
soft
EMG
author_facet Gerjan Wolterink
Pedro Dias
Remco G.P. Sanders
Frodo Muijzer
Bert-Jan van Beijnum
Peter Veltink
Gijs Krijnen
author_sort Gerjan Wolterink
title Development of Soft sEMG Sensing Structures Using 3D-Printing Technologies
title_short Development of Soft sEMG Sensing Structures Using 3D-Printing Technologies
title_full Development of Soft sEMG Sensing Structures Using 3D-Printing Technologies
title_fullStr Development of Soft sEMG Sensing Structures Using 3D-Printing Technologies
title_full_unstemmed Development of Soft sEMG Sensing Structures Using 3D-Printing Technologies
title_sort development of soft semg sensing structures using 3d-printing technologies
publisher MDPI AG
series Sensors
issn 1424-8220
publishDate 2020-07-01
description 3D printing of soft EMG sensing structures enables the creation of personalized sensing structures that can be potentially integrated in prosthetic, assistive and other devices. We developed and characterized flexible carbon-black doped TPU-based sEMG sensing structures. The structures are directly 3D-printed without the need for an additional post-processing step using a low-cost, consumer grade multi-material FDM printer. A comparison between the gold standard Ag/AgCl gel electrodes and the 3D-printed EMG electrodes with a comparable contact area shows that there is no significant difference in the EMG signals’ amplitude. The sensors are capable of distinguishing a variable level of muscle activity of the biceps brachii. Furthermore, as a proof of principle, sEMG data of a 3D-printed 8-electrode band are analyzed using a patten recognition algorithm to recognize hand gestures. This work shows that 3D-printed sEMG electrodes have great potential in practical applications.
topic 3D-printing
thermoplactic polyurethane (TPU)
conductive
flexible
soft
EMG
url https://www.mdpi.com/1424-8220/20/15/4292
work_keys_str_mv AT gerjanwolterink developmentofsoftsemgsensingstructuresusing3dprintingtechnologies
AT pedrodias developmentofsoftsemgsensingstructuresusing3dprintingtechnologies
AT remcogpsanders developmentofsoftsemgsensingstructuresusing3dprintingtechnologies
AT frodomuijzer developmentofsoftsemgsensingstructuresusing3dprintingtechnologies
AT bertjanvanbeijnum developmentofsoftsemgsensingstructuresusing3dprintingtechnologies
AT peterveltink developmentofsoftsemgsensingstructuresusing3dprintingtechnologies
AT gijskrijnen developmentofsoftsemgsensingstructuresusing3dprintingtechnologies
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