Sage Journals: Discover world-class research

Abstract

Soft robotic hand/gloves for hand rehabilitation can aid the performance of activities of daily living (ADL). Although existing soft robotic hands can assist with finger flexion, few have addressed finger extension, which is a challenging task for stroke patients due to poststroke spasticity. In this article, we describe the design of a composite actuator, the soft-elastic composite actuator (SECA), to facilitate both finger flexion and extension. A double-segmented SECA comprising two serially connected fiber-reinforced actuators with two bottom torque-compensating layers was fabricated. The SECA bends and extends by pneumatic actuation, and the torque-compensating layers offer an assistive bending moment to configure the bending moment inside the SECA. The principles associated with selection of the torque-compensating layer are described. Analytical models were established to quantify the input pressure and the bending angle of SECA with free bending and when placed on a model compromised hand. The analytical models were validated experimentally and by the finite element method. Moreover, a stroke survivor was recruited to test the new robotic glove integrated with the multiple double-segmented SECA. The robotic glove facilitated hand opening and closing by the patient, and successfully assisted with grasp of a Chinese chess piece and twisting of a towel.

Get full access to this article

View all access options for this article.

References

Benjamin

, Blaha

, Chiuve

et al. Heart disease and stroke statistics—2017 update: a report from the American Heart Association. Circulation, 2017; 135:e146–e603.

Lee

, Lim

, Kim

et al. Six-month functional recovery of stroke patients: a multi-time-point study. Int J Rehabil Res, 2015; 38:173–180.

Gerloff

, Corwell

, Chen

, et al. The role of the human motor cortex in the control of complex and simple finger movement sequences. Brain, 1998; 121 (Pt 9):1695–1709.

Taub

, Uswatte

, Mark

et al. The learned nonuse phenomenon: implications for rehabilitation. Eura Medicophys, 2006; 42:241–256.

Butefisch

, Hummelsheim

, Denzler

, et al. Repetitive training of isolated movements improves the outcome of motor rehabilitation of the centrally paretic hand. J Neurol Sci, 1995; 130:59–68.

Schaechter

. Motor rehabilitation and brain plasticity after hemiparetic stroke. Prog Neurobiol, 2004; 73:61–72.

Carey

, Kimberley

, Lewis

et al. Analysis of fMRI and finger tracking training in subjects with chronic stroke. Brain, 2002; 125:773–788.

Heo

, Gu

, Lee

, et al. Current hand exoskeleton technologies for rehabilitation and assistive engineering. Int J Precis Eng Manuf, 2012; 13:807–824.

Maciejasz

, Eschweiler

, Gerlach-Hahn

, et al. A survey on robotic devices for upperlimb rehabilitation. J Neuroeng Rehabil, 2014; 11:3.

10.

Polygerinos

, Wang

, Galloway

et al. Soft robotic glove for combined assistance and at-home rehabilitation. Robot Auton Syst, 2015; 73:135–143.

11.

, Tong

, Hu

et al. An EMG-driven exoskeleton hand robotic training device on chronic stroke subjects: task training system for stroke rehabilitation. IEEE Int Conf Rehabil Robot, 2011; 2011:5975340.

12.

Yamaura

, Matsushita

, Kato

, et al. Development of hand rehabilitation system for paralysis patient–universal design using wire-driven mechanism. Conf Proc IEEE Eng Med Biol Soc, 2009; 2009:7122–7125.

13.

Dellon

, Matsuoka

. Prosthetics, exoskeletons, and rehabilitation [grand challenges of robotics]. IEEE Robot Autom Mag, 2007; 14:30–34.

14.

Rus

, Tolley

. Design, fabrication and control of soft robots. Nature, 2015; 521:467–475.

15.

Yap

, Lim

, Nasrallah

, et al. A soft exoskeleton for hand assistive and rehabilitation application using pneumatic actuators with variable stiffness. Conf Proc IEEE Robot, 2015; 2015:4967–4972.

16.

Polygerinos

, Wang

, Overvelde

JTB

, et al. Modeling of soft fiber-reinforced bending actuators. IEEE Trans Rob, 2015; 31:778–789.

17.

Connolly

, Walsh

, Bertoldi

. Automatic design of fiber-reinforced soft actuators for trajectory matching. Proc Natl Acad Sci U S A, 2017; 114:51–56.

18.

Thibaut

, Chatelle

, Ziegler

, et al. Spasticity after stroke: physiology, assessment and treatment. Brain Inj, 2013; 27:1093–1105.

19.

Yap

, Khin

, Koh

. et al. A fully fabric-based bidirectional soft robotic glove for assistance and rehabilitation of hand impaired patients. IEEE Robot Autom Let, 2017; 2; 1383–1390.

20.

Dragon Skin Series. Available at: https://www.smooth-on.com/tb/files/DRAGON_SKIN_SERIES_TB.pdf (accessed September 25, 2017).

21.

Heung

, Chiu

, Li

. Design and prototyping of a soft earthworm-like robot targeted for GI tract inspection. Proc IEEE Int Conf Rob Biomimetics, 2016; 2016:497–502.

22.

Zupko

. A Dictionary of Weights and Measures for the British Isles: The Middle Ages to the Twentieth Century. Philadelphia, PA: American Philosophical Society, 1985, pp. 109–110.

23.

Peters

, Mackenzie

, Bryden

. Finger length and distal finger extent patterns in humans. Am J Phys Anthropol, 2002; 117:209–217.

24.

Sparks

, Vavalle

, Kasting

et al. Use of silicone materials to simulate tissue biomechanics as related to deep tissue injury. Adv Skin Wound Care, 2015; 28:59–68.

25.

Turcotte

, Schubert

. Geodynamics, 2nd Edition. Cambridge, United Kingdom: Cambridge University Press, 2002.

26.

Kamper

, George Hornby

, Rymer

. Extrinsic flexor muscles generate concurrent flexion of all three finger joints. J Biomech, 2002; 35:1581–1589.

27.

Woods

, Lawrence

. Modeling and Simulation of Dynamic Systems. London, United Kingdom: Prentice Hall, 1997.

28.

Kamper

, Rymer

. Quantitative features of the stretch response of extrinsic finger muscles in hemiparetic stroke. Muscle Nerve, 2000; 23:954–961.

29.

Prosser

. Splinting in the management of proximal interphalangeal joint flexion contracture. J Hand Ther, 1996; 9:378–386.

30.

Elsayed

, Vincensi

, Lekakou

, et al. Finite element analysis and design optimization of a pneumatically actuating silicone module for robotic surgery applications. Soft Robot, 2014; 1:255–262.

31.

Yap

, Ng

, Yeow

. High-force soft printable pneumatics for soft robotic applications. Soft Robot, 2016; 3:144–158.

32.

Holland

, Park

, Polygerinos

, et al. The soft robotics toolkit: shared resources for research and design. Soft Robot, 2014; 1:224–230.

33.

Leibovic

, Bowers

. Anatomy of the proximal interphalangeal joint. Hand Clin, 1994; 10:169–178.

34.

Tong

, Ho

, Pang

et al. An intention driven hand functions task training robotic system. Conf Proc IEEE Eng Med Biol Soc, 2010; 2010:3406–3409.

35.

Esteki

, Mansour

. An experimentally based nonlinear viscoelastic model of joint passive moment. J Biomech, 1996; 29:443–450.

36.

Dionysian

, Kabo

, Dorey

et al. Proximal interphalangeal joint stiffness: measurement and analysis. J Hand Surg Am, 2005; 30:573–579.

37.

Lyle

. A performance test for assessment of upper limb function in physical rehabilitation treatment and research. Int J Rehabil Res, 1981; 4:483–492.

38.

Lang

, Wagner

, Dromerick

et al. Measurement of upper-extremity function early after stroke: properties of the action research arm test. Arch Phys Med Rehabil, 2006; 87:1605–1610.

39.

Van der Lee

, Roorda

, Beckerman

, et al. Improving the action research arm test: a unidimensional hierarchical scale. Clin Rehabil, 2002; 16:646–653.

40.

Ansari

, Naghdi

, Arab

et al. The interrater and intrarater reliability of the Modified Ashworth Scale in the assessment of muscle spasticity: limb and muscle group effect. NeuroRehabilitation, 2008; 23:231–237.

41.

Cauraugh

, Kim

. Two coupled motor recovery protocols are better than one: electromyogram-triggered neuromuscular stimulation and bilateral movements. Stroke, 2002; 33:1589–1594.

42.

Summers

, Kagerer

, Garry

et al. Bilateral and unilateral movement training on upper limb function in chronic stroke patients: a TMS study. J Neurol Sci, 2007; 252:76–82.

43.

Stroke Association. Available at: https://www.stroke.org.uk/sites/default/files/occupational_therapy_atter_stroke.pdf (accessed June 8, 2018).

44.

Jiralerspong

, Heung

, Tong

. et al. A novel soft robotic glove for daily life assistance. In: IEEE RAS/EMBS International Conference on Biomedical Robotics and Biomechatronics (BioRob 2018), August 26–29, 2018, Enschede, Netherlands.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

87.10 MB

0.00 MB

Robotic Glove with Soft-Elastic Composite Actuators for Assisting Activities of Daily Living

Abstract

Abstract

Get full access to this article

References

Supplementary Material