Bio-Mechatronics Development of Robotic Exoskeleton System With Mobile-Prismatic Joint Mechanism for Passive Hand Wearable-Rehabilitation

Mariela Vargas; J. Mayorga; B. Oscco; V. Cuyotupac; A. Nacarino; D. Allcca; L. Gamarra-Vásquez; G. Tejada-Marroquin; M. Reategui; R. R. Maldonado-Gómez; Y. Vasquez; Daira de la Barra; P. Tapia-Yanayaco; Sandra Charapaqui; Milton V. Rivera; R. Palomares; M. Ramirez-Chipana; Jorge Cornejo; José Cornejo; Jhony A. De La Cruz-Vargas

doi:10.28991/ESJ-2024-08-06-02

Bio-Mechatronics Development of Robotic Exoskeleton System With Mobile-Prismatic Joint Mechanism for Passive Hand Wearable-Rehabilitation

Mariela Vargas, J. Mayorga, B. Oscco, V. Cuyotupac, A. Nacarino, D. Allcca, L. Gamarra-Vásquez, G. Tejada-Marroquin, M. Reategui, R. R. Maldonado-Gómez, Y. Vasquez, Daira de la Barra, P. Tapia-Yanayaco, Sandra Charapaqui, Milton V. Rivera, R. Palomares, M. Ramirez-Chipana, Jorge Cornejo, José Cornejo^*, Jhony A. De La Cruz-Vargas

^*Autor correspondiente de este trabajo

Producción científica: Contribución a una revista › Artículo › revisión exhaustiva

Resumen

The World Health Organization (WHO) estimates that 15 million people are affected by stroke each year, causing deterioration of the upper limb, which is reflected in 70-80% of them, decreasing the performance of daily activities and quality of life, mainly affecting hand functions. Thus, the purpose of this study is to present a high-quality alternative to recover muscle tone and mobility, consisting of a hand-exoskeleton for passive rehabilitation. It covers a motion protocol for each finger and pressure sensors to give a safety pressure range during the gripping function. The bio-design method covers standards (ISO 13485 and VDI 2206) based on biomechanic and anthropometric fundamentals, where Fusion 360 was used for mechanical development and electrical-electronic circuit schematics. The prototyping process was based on 3D printing using polylactic acid (PLA); also, the actuators were servomotors DS3218, the pressure sensors were RP-C7.6-LT, and the microcontroller was Arduino Nano. The system has been validated by the Institute of Research in Biomedical Sciences (INICIB) at the Ricardo Palma University, where the novelty of this work lies in the introduction of a new mobile-prismatic joint mechanism. In conclusion, favorable results were achieved regarding the complete flexion and extension of the fingers (91.6% acceptance rate, tested in 100 subjects), so the next step proposes that the wearable device will be used in the Physical Medicine and Rehabilitation Departments of Medical Centers.

Idioma original	Inglés
Páginas (desde-hasta)	2144-2172
Número de páginas	29
Publicación	Emerging Science Journal
Volumen	8
N.º	6
DOI	https://doi.org/10.28991/ESJ-2024-08-06-02
Estado	Publicada - 2024
Publicado de forma externa	Sí

ODS de las Naciones Unidas

Este resultado contribuye a los siguientes Objetivos de Desarrollo Sostenible

Acceder al documento

10.28991/ESJ-2024-08-06-02

Otros archivos y enlaces

Enlace a la publicación en Scopus

Citar esto

Vargas, M., Mayorga, J., Oscco, B., Cuyotupac, V., Nacarino, A., Allcca, D., Gamarra-Vásquez, L., Tejada-Marroquin, G., Reategui, M., Maldonado-Gómez, R. R., Vasquez, Y., de la Barra, D., Tapia-Yanayaco, P., Charapaqui, S., Rivera, M. V., Palomares, R., Ramirez-Chipana, M., Cornejo, J., Cornejo, J., & De La Cruz-Vargas, J. A. (2024). Bio-Mechatronics Development of Robotic Exoskeleton System With Mobile-Prismatic Joint Mechanism for Passive Hand Wearable-Rehabilitation. Emerging Science Journal, 8(6), 2144-2172. https://doi.org/10.28991/ESJ-2024-08-06-02

@article{d5b5ba1412d842249cc2c47d4dd7187a,

title = "Bio-Mechatronics Development of Robotic Exoskeleton System With Mobile-Prismatic Joint Mechanism for Passive Hand Wearable-Rehabilitation",

abstract = "The World Health Organization (WHO) estimates that 15 million people are affected by stroke each year, causing deterioration of the upper limb, which is reflected in 70-80% of them, decreasing the performance of daily activities and quality of life, mainly affecting hand functions. Thus, the purpose of this study is to present a high-quality alternative to recover muscle tone and mobility, consisting of a hand-exoskeleton for passive rehabilitation. It covers a motion protocol for each finger and pressure sensors to give a safety pressure range during the gripping function. The bio-design method covers standards (ISO 13485 and VDI 2206) based on biomechanic and anthropometric fundamentals, where Fusion 360 was used for mechanical development and electrical-electronic circuit schematics. The prototyping process was based on 3D printing using polylactic acid (PLA); also, the actuators were servomotors DS3218, the pressure sensors were RP-C7.6-LT, and the microcontroller was Arduino Nano. The system has been validated by the Institute of Research in Biomedical Sciences (INICIB) at the Ricardo Palma University, where the novelty of this work lies in the introduction of a new mobile-prismatic joint mechanism. In conclusion, favorable results were achieved regarding the complete flexion and extension of the fingers (91.6% acceptance rate, tested in 100 subjects), so the next step proposes that the wearable device will be used in the Physical Medicine and Rehabilitation Departments of Medical Centers.",

keywords = "Engineering Design, Exoskeleton, Hand Rehabilitation, Medical Mechatronics, Stroke",

author = "Mariela Vargas and J. Mayorga and B. Oscco and V. Cuyotupac and A. Nacarino and D. Allcca and L. Gamarra-V{\'a}squez and G. Tejada-Marroquin and M. Reategui and Maldonado-G{\'o}mez, {R. R.} and Y. Vasquez and {de la Barra}, Daira and P. Tapia-Yanayaco and Sandra Charapaqui and Rivera, {Milton V.} and R. Palomares and M. Ramirez-Chipana and Jorge Cornejo and Jos{\'e} Cornejo and {De La Cruz-Vargas}, {Jhony A.}",

note = "Publisher Copyright: {\textcopyright} 2024 by the authors.",

year = "2024",

doi = "10.28991/ESJ-2024-08-06-02",

language = "Ingl{\'e}s",

volume = "8",

pages = "2144--2172",

journal = "Emerging Science Journal",

issn = "2610-9182",

publisher = "Ital Publication",

number = "6",

}

Vargas, M, Mayorga, J, Oscco, B, Cuyotupac, V, Nacarino, A, Allcca, D, Gamarra-Vásquez, L, Tejada-Marroquin, G, Reategui, M, Maldonado-Gómez, RR, Vasquez, Y, de la Barra, D, Tapia-Yanayaco, P, Charapaqui, S, Rivera, MV, Palomares, R, Ramirez-Chipana, M, Cornejo, J, Cornejo, J & De La Cruz-Vargas, JA 2024, 'Bio-Mechatronics Development of Robotic Exoskeleton System With Mobile-Prismatic Joint Mechanism for Passive Hand Wearable-Rehabilitation', Emerging Science Journal, vol. 8, n.º 6, pp. 2144-2172. https://doi.org/10.28991/ESJ-2024-08-06-02

TY - JOUR

T1 - Bio-Mechatronics Development of Robotic Exoskeleton System With Mobile-Prismatic Joint Mechanism for Passive Hand Wearable-Rehabilitation

AU - Vargas, Mariela

AU - Mayorga, J.

AU - Oscco, B.

AU - Cuyotupac, V.

AU - Nacarino, A.

AU - Allcca, D.

AU - Gamarra-Vásquez, L.

AU - Tejada-Marroquin, G.

AU - Reategui, M.

AU - Maldonado-Gómez, R. R.

AU - Vasquez, Y.

AU - de la Barra, Daira

AU - Tapia-Yanayaco, P.

AU - Charapaqui, Sandra

AU - Rivera, Milton V.

AU - Palomares, R.

AU - Ramirez-Chipana, M.

AU - Cornejo, Jorge

AU - Cornejo, José

AU - De La Cruz-Vargas, Jhony A.

PY - 2024

Y1 - 2024

N2 - The World Health Organization (WHO) estimates that 15 million people are affected by stroke each year, causing deterioration of the upper limb, which is reflected in 70-80% of them, decreasing the performance of daily activities and quality of life, mainly affecting hand functions. Thus, the purpose of this study is to present a high-quality alternative to recover muscle tone and mobility, consisting of a hand-exoskeleton for passive rehabilitation. It covers a motion protocol for each finger and pressure sensors to give a safety pressure range during the gripping function. The bio-design method covers standards (ISO 13485 and VDI 2206) based on biomechanic and anthropometric fundamentals, where Fusion 360 was used for mechanical development and electrical-electronic circuit schematics. The prototyping process was based on 3D printing using polylactic acid (PLA); also, the actuators were servomotors DS3218, the pressure sensors were RP-C7.6-LT, and the microcontroller was Arduino Nano. The system has been validated by the Institute of Research in Biomedical Sciences (INICIB) at the Ricardo Palma University, where the novelty of this work lies in the introduction of a new mobile-prismatic joint mechanism. In conclusion, favorable results were achieved regarding the complete flexion and extension of the fingers (91.6% acceptance rate, tested in 100 subjects), so the next step proposes that the wearable device will be used in the Physical Medicine and Rehabilitation Departments of Medical Centers.

AB - The World Health Organization (WHO) estimates that 15 million people are affected by stroke each year, causing deterioration of the upper limb, which is reflected in 70-80% of them, decreasing the performance of daily activities and quality of life, mainly affecting hand functions. Thus, the purpose of this study is to present a high-quality alternative to recover muscle tone and mobility, consisting of a hand-exoskeleton for passive rehabilitation. It covers a motion protocol for each finger and pressure sensors to give a safety pressure range during the gripping function. The bio-design method covers standards (ISO 13485 and VDI 2206) based on biomechanic and anthropometric fundamentals, where Fusion 360 was used for mechanical development and electrical-electronic circuit schematics. The prototyping process was based on 3D printing using polylactic acid (PLA); also, the actuators were servomotors DS3218, the pressure sensors were RP-C7.6-LT, and the microcontroller was Arduino Nano. The system has been validated by the Institute of Research in Biomedical Sciences (INICIB) at the Ricardo Palma University, where the novelty of this work lies in the introduction of a new mobile-prismatic joint mechanism. In conclusion, favorable results were achieved regarding the complete flexion and extension of the fingers (91.6% acceptance rate, tested in 100 subjects), so the next step proposes that the wearable device will be used in the Physical Medicine and Rehabilitation Departments of Medical Centers.

KW - Engineering Design

KW - Exoskeleton

KW - Hand Rehabilitation

KW - Medical Mechatronics

KW - Stroke

UR - http://www.scopus.com/inward/record.url?scp=85212687775&partnerID=8YFLogxK

U2 - 10.28991/ESJ-2024-08-06-02

DO - 10.28991/ESJ-2024-08-06-02

M3 - Artículo

AN - SCOPUS:85212687775

SN - 2610-9182

VL - 8

SP - 2144

EP - 2172

JO - Emerging Science Journal

JF - Emerging Science Journal

IS - 6

ER -

Bio-Mechatronics Development of Robotic Exoskeleton System With Mobile-Prismatic Joint Mechanism for Passive Hand Wearable-Rehabilitation

Resumen

ODS de las Naciones Unidas

Acceder al documento

Otros archivos y enlaces

Huella

Citar esto