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Abstract

Flexible manipulators offer significant advantages over traditional rigid manipulators in minimally invasive surgery, because they can flexibly navigate around obstacles and pass cramped or tortuous paths. However, due to the inherent low stiffness, the ability to control/obtain higher stiffness when required remains to be further explored. In this article, we propose a flexible manipulator that exploits the phase transformation property of low-melting-point alloy to hydraulically drive and change the stiffness by heating and cooling. A prototype was fabricated, and experiments were conducted to evaluate the motion characteristics, stiffness performance, and rigid-flexible transition efficiency. The experimental results demonstrate that the proposed manipulator can freely adjust heading direction in the three-dimensional space. The experimental results also indicate that it took 9.2–10.3 s for the manipulator to transform from a rigid state to a flexible state and 15.4 s to transform from a flexible state to a rigid state. The lateral stiffness and flexural stiffness of the manipulator were 95.54 and 372.1 Ncm² in the rigid state and 7.26 and 0.78 Ncm² in the flexible state. The gain of the lateral stiffness and flexural stiffness was 13.15 and 477.05, respectively. In the rigid state, the ultimate force without shape deformation was more than 0.98 N in the straight condition (0°) and 1.36 N in the bending condition (90°). By assembling flexible surgical tools, the manipulator can enrich the diagnosis or treatment functions, which demonstrated the potential clinical value of the proposed manipulator.

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References

Kumar

, Yadav

, Singh

, et al. Minimally invasive (endoscopic-computer assisted) surgery: technique and review. Ann Maxillofac Surg, 2016; 6:159.

Yoshiki

. Review of transvaginal natural orifice transluminal endoscopic surgery in gynecology. Gynecol Minim Invasive Ther, 2017; 6:1–5.

Loeve

, Breedveld

, Dankelman

. Scopes too flexible… and too stiff. IEEE Pulse, 2010; 1:26–41.

Peters

, Armijo

, Krause

, et al. Review of emerging surgical robotic technology. Surg Endosc, 2018; 32:1636–1655.

Lee

, Kim

, et al. Soft robot review. Int J Control Autom Syst, 2017; 15:3–15.

Liu

, Bergeles

, Yang

. Design and analysis of a wire-driven flexible manipulator for bronchoscopic interventions. In: Okamura A, (Ed). 2016 IEEE International Conference on Robotics and Automation (ICRA). Stockholm: IEEE, 2016, pp. 4058–4063.

Zhang

, Fan

, Yang

, et al. Worm-like soft robot for complicated tubular environments. Soft Robot, 2019; 6:399–413.

Decroly

, Mertens

, Lambert

, et al. Design, characterization and optimization of a soft fluidic actuator for minimally invasive surgery. Int J Comput Assist Radiol Surg, 2020; 15:333–340.

Alfalahi

, Renda

, Stefanini

. Concentric tube robots for minimally invasive surgery: current applications and future opportunities. IEEE Trans Med Robot Bionics, 2020; 2:410–424.

10.

Patel

, Seneci

, Yang

, et al. Flexible platforms for natural orifice transluminal and endoluminal surgery. Endosc Int Open, 2014; 2:E117–E123.

11.

Blanc

, Delchambre

, Lambert

. Flexible medical devices: review of controllable stiffness solutions. Actuators, 2017; 6:23.

12.

Cianchetti

, Ranzani

, Gerboni

, et al. Soft robotics technologies to address shortcomings in today's minimally invasive surgery: the STIFF-FLOP approach. Soft Robot, 2014; 1:122–131.

13.

Brancadoro

, Manti

, Tognarelli

, et al. Fiber jamming transition as a stiffening mechanism for soft robotics. Soft Robot, 2020; 7:663–674.

14.

Zuo

, Iijima

, Tokumiya

, et al. Variable stiffness outer sheath with “Dragon skin” structure and negative pneumatic shape-locking mechanism. Int J Comput Assist Radiol Surg, 2014; 9:857–865.

15.

Kim

, Cheng

, Kim

, et al. A novel layer jamming mechanism with tunable stiffness capability for minimally invasive surgery. IEEE Trans Robot, 2013; 29:1031–1042.

16.

Manti

, Cacucciolo

, Cianchetti

. Stiffening in soft robotics: a review of the state of the art. IEEE Robot Autom Mag, 2016; 23:93–106.

17.

Abdel-Wahab

, Murmu

, Olabi

. Applications of magnetorheological (MR) fluids in the biomedical field. In: Hashmi S, (Ed). Reference Module in Materials Science and Materials Engineering. UK: Elsevier, 2018, pp. 1–25.

18.

Yin

, Wang

, Zuo

. Water-jet outer sheath with braided shape memory polymer tubes for upper gastrointestinal tract screening. Int J Med Robot, 2018; 14:e1944.

19.

, Phan

, Lin

, et al. A temperature-dependent, variable-stiffness endoscopic robotic manipulator with active heating and cooling. Ann Biomed Eng, 2020; 48:1837–1849.

20.

Cheng

, Kim

, Desai

. Modeling and characterization of shape memory alloy springs with water cooling strategy in a neurosurgical robot. J Intel Mat Syst Str, 2017; 28:2167–2183.

21.

Cheng

, Gopinath

, Wang

, et al. Thermally tunable, self-healing composites for soft robotic applications. Maromol Mater Eng, 2014; 299:1279–1284.

22.

Goia

, ChaudharyG, Fantucci

. Modelling and experimental validation of an algorithm for simulation of hysteresis effects in phase change materials for building components. Enger Buildings, 2018; 174:54–67.

23.

Shameli

, Alasty

, Salaarieh

. Stability analysis and nonlinear control of a miniature shape memory alloy actuator for precise applications. Mechatronics, 2005; 15:471–486.

24.

Alambeigi

, Seifabadi

, Armand

. A continuum manipulator with phase changing alloy. In: Okamura A, (Ed). 2016 IEEE International Conference on Robotics and Automation (ICRA). Stockholm: IEEE, 2016, pp. 758–764.

25.

Baetens

, Jelle

, Gustavsen

. Phase change materials for building applications: a state-of-the-art review. Enger Build, 2010; 42:1361–1368.

26.

Sadati

, Sullivan

, Walker

, et al. Three-dimensional-printable thermoactive helical interface with decentralized morphological stiffness control for continuum manipulators. IEEE Robot Autom Let, 2018; 3:2283–2290.

27.

Zhao

, Yao

, Luo

. Development of a variable stiffness over tube based on low-melting-point-alloy for endoscopic surgery. J Med Device, 2016; 10:021002.

28.

, Li

, Wang

, et al. Design and evaluation of a variable stiffness manual operating platform for laparoendoscopic single site surgery (LESS). Int J Med Robot, 2017; 13:e1797.

29.

Van Meerbeek

, Mac Murray

, Kim

, et al. Morphing metal and elastomer bicontinuous foams for reversible stiffness, shape memory, and self-healing soft machines. Adv Mater, 2016; 8:2801–2806.

30.

Zappetti

, Jeong

, Shintake

, et al. Phase changing materials-based variable-stiffness tensegrity structures. Soft Robot, 2020; 7:362–369.

31.

Peters

, Nolan

, Wiese

, et al. Actuation and stiffening in fluid-driven soft robots using low-melting-point material. In: Maciejewski T, (Ed). 2019 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS 2019). Macau: IEEE, 2019.

32.

Liu

, Yin

, Chandler

, et al. A dual-bending endoscope with shape-lockable hydraulic actuation and water-jet propulsion for gastrointestinal tract screening. Int J Med Robot, 2021; 17:1–13.

33.

Rus

, Tolley

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

34.

Vithani

, Goyanes

, Jannin

, et al. An overview of 3D printing technologies for soft materials and potential opportunities for lipid-based drug delivery systems. Pharm Res-dordr, 2016; 36:4.

35.

, Lee

, Folch

. Mail-order microfluidics: evaluation of stereolithography for the production of microfluidic devices. Lab Chip, 2014; 14:1294–1301.

36.

IARC Working Group. IARC Monographs on the Evaluation of Carcinogenic Risks to Humans, Vol 116: Drinking Coffee, Mate, and Very Hot Beveragesed. Lyon, France: International Agency for Research on Cancer, 2018.

37.

Babaee

, Pajovic

, Kirtane

, et al. Temperature-responsive biometamaterials for gastrointestinal applications. Sci Transl Med, 2019; 11:eaau8581.

38.

Lee

, O'Mahony

. At what temperatures do consumers like to drink coffee?: Mixing methods. J Food Sci, 2020; 67:2774–2777.

39.

Wehrmeyer

, Barthel

, Roth

, et al. Colonoscope flexural rigidity measurement. Med Biol Eng Comput, 1998; 36:475–479.

40.

Chautems

, Tonazzini

, Boehler

, et al. Magnetic continuum device with variable stiffness for minimally invasive surgery. Adv Intell Syst, 2019; 2:1900086.

41.

Tonazzini

, Mintchev

, Schubert

, et al. Variable stiffness fiber with self-healing capability. Adv Mat, 2016; 28:10142–10148.

42.

, Ho

, Lee

, et al. Interfacing soft and hard: a spring reinforced actuator. Soft Robot, 2020; 7:44–58.

43.

Kerschbaumer

, Stieger

, Gschwandl

, et al. Comparison of steady-state and transient thermal conductivity testing methods using different industrial rubber compounds. Polym Test, 2019; 80:106121.

44.

Gong

, Cheng

, Chen, et al. A bio-inspired soft robotic arm: kinematic modeling and hydrodynamic experiments. J Bionic Eng, 2018; 15:204–219.

45.

Mustaza

, Elsayed

, Lekakou

, et al. Dynamic modeling of fiber-reinforced soft manipulator: a visco-hyperelastic material-based continuum mechanics approach. Soft Robot, 2019; 6:305–317.

46.

Wang

, Yang

, Chen

, et al. Controllable and reversible tuning of material rigidity for robot applications. Mater Today, 2018; 21:563–576.

47.

Friedel

, Stavropoulos

. Introduction of endoscopic submucosal dissection in the West. World J Gastrointest Endosc, 2018; 10:225.

48.

Schubert

, Floreano

. Variable stiffness material based on rigid low-melting-point-alloy microstructures embedded in soft poly (dimethylsiloxane) (PDMS). RSC Adv, 2013; 3:24671–24679.

49.

Wei

, Wang

, Li

, et al. Novel integrated helical design of single optic fiber for shape sensing of flexible robot. IEEE Sens J, 2017; 17:6627–6636.

50.

Ryu

S C

, Dupont

. FBG-based shape sensing tubes for continuum robots. In: Parker L, (Ed). 2014 IEEE International Conference on Robotics and Automation (ICRA). Hong Kong: IEEE, 2014, pp. 3531–. 3537.

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Flexible Manipulator with Low-Melting-Point Alloy Actuation and Variable Stiffness

Abstract

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Supplementary Material