Remote motion capture protocol for transferring 3D motion data to remote locations in real time:  Real-time remote 3D motion data transfer protocol

Irie, Shun; Kobori, Takashi; Sumi, Kazuki; Tachibana, Atsumichi; Qian, Yihan; Makifuji, Kaori

doi:10.51094/jxiv.831

##article.authors##

Irie, Shun Division for Smart Healthcare Research, Dokkyo Medical University https://researchmap.jp/shun_irie
Kobori, Takashi Division for Smart Healthcare Research, Dokkyo Medical University
Sumi, Kazuki Division for Smart Healthcare Research, Dokkyo Medical University
Tachibana, Atsumichi Depertment of Anatomy, Dokkyo Medical University https://researchmap.jp/rc166
Qian, Yihan e-skin Business division, Xenoma Inc.
Makifuji, Kaori e-skin Business division, Xenoma Inc.

DOI:

https://doi.org/10.51094/jxiv.831

キーワード:

remote motion capture、 3D motion data、 telemedicine

抄録

The demand for telemedicine systems has increased following the COVID-19 pandemic. Conventional telemedicine systems provide video and acoustic transferring functions using smartphones and other communication systems. However, it is difficult to use conventional telemedicine systems in rehabilitation fields because they require real-time motion data from patients. Here, we suggest a novel system for transferring three-dimensional (3D) motion data to remote places in real time, which is named the “remote motion capture protocol (RMCP).” The RMCP runs on the conventional game engine and multiple operation systems, such as Windows, Mac OS, and Android. It can transfer the 3D motion data of users to remote locations with a delay of less than 500 ms using remote procedure calling. Additionally, any type of motion capture is available in this system if it is compatible with the conventional game engine. This technical note describes the basis of the system, sample applications, and usages of RMCP.

利益相反に関する開示

Shun Irie received a grant donated by Dokkyo Medical University as research funding for studies conducted on the application of wearable e-textiles in healthcare fields from Xenoma Inc. on July 31, 2021.

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引用文献

Jagarapu J, Savani RC: A brief history of telemedicine and the evolution of teleneonatology. Semin Perinatol 45(5), 151416, 2021.

Grundy BL, Crawford P, Jones PK, Kiley ML, Reisman A, Pao YH, Wilkerson EL, Gravenstein JS: Telemedicine in critical care: An experiment in health care delivery. J Am College Emergency Phys. 6(10), 439–44, 1997.

Murphy RL, Bird KT: Telediagnosis: a new community health resource. Observations on the feasibility of telediagnosis based on 1000 patient transactions. Am J Public Health. 64(2), 113–119, 1974.

MacKinnon GE, Brittain EL: Mobile health technologies in cardiopulmonary disease. Chest. 157(3), 654–664, 2020.

Palmdorf S, Stark AL, Nadolny S, Eliaß G, Karlheim C, Kreisel SH, Gruschka T, Trompetter E, Dockweiler C: Technology-assisted home care for people with dementia and their relatives: Scoping review. JMIR Aging. 4(1), e25307, 2021.

Van Den Heuvel JF, Groenhof TK, Veerbeek JH, Van Solinge WW, Lely AT, Franx A, Bekker MN: eHealth as the next-generation perinatal care: an overview of the literature. J Med Internet Res. 20(6), e202, 2018.

Farias FA, Dagostini CM, Bicca YD, Falavigna VF, Falavigna A: Remote patient monitoring: A systematic review. Telemed e-Health. 26(5), 576–583, 2020.

Agostini M, Moja L, Banzi R, Pistotti V, Tonin P, Venneri A, Turolla A: Telerehabilitation and recovery of motor function: a systematic review and meta-analysis. J Telemed Telecare. 21(4), 202–213, 2015.

Kenis-Coskun O, Imamoglu S, Karamancioglu B, Kurt K, Ozturk G, Karadag-Saygi E: Comparison of telerehabilitation versus home-based video exercise in patients with Duchenne muscular dystrophy: A single-blind randomized study. Acta Neurol Belg. 122(5), 1269–1280, 2022.

Özden F, Sarı Z, Karaman ÖN, Aydoğmuş H: The effect of video exercise-based telerehabilitation on clinical outcomes, expectation, satisfaction, and motivation in patients with chronic low back pain. Irish J Med Sci. 191(3), 1229–1239, 2022.

Berton A, Longo UG, Candela V, Fioravanti S, Giannone L, Arcangeli V, Alciati V, Berton C, Facchinetti G, Marchetti A, Schena E: Virtual reality, augmented reality, gamification, and telerehabilitation: psychological impact on orthopedic patients’ rehabilitation. J Clini Med. 9(8), 2567, 2020.

Truijen S, Abdullahi A, Bijsterbosch D, van Zoest E, Conijn M, Wang Y, Struyf N, Saeys W: Effect of home-based virtual reality training and telerehabilitation on balance in individuals with Parkinson disease, multiple sclerosis, and stroke: A systematic review and meta-analysis. Neurol Sci. 43(5), 2995–3006, 2022.

Fukuoka T, Irie S, Watanabe Y, Kutsuna T, Abe A: The relationship between spatiotemporal gait parameters and cognitive function in healthy adults: protocol for a cross-sectional study. Pilot Feasibility Stud. 8(1), 1–3, 2022.

Boland JE, Fonseca P, Mermelstein I, Williamson M: Zoom disrupts the rhythm of conversation. J Exp Psychol: General. 151(6), 1272, 2022.

Remote motion capture protocol for transferring 3D motion data to remote locations in real time

Real-time remote 3D motion data transfer protocol