Lin et al. Soft Sci 2023;3:14  https://dx.doi.org/10.20517/ss.2023.05           Page 25 of 25

               162.      Li Z, Kidambi N, Wang L, Wang K. Uncovering rotational multifunctionalities of coupled Kresling modular structures. Extreme
                    Mech Lett 2020;39:100795.  DOI
               163.      Kaufmann J, Bhovad P, Li S. Harnessing the multistability of kresling origami for reconfigurable articulation in soft robotic arms.
                    Soft Robot 2022;9:212-23.  DOI  PubMed
               164.      Alapan Y, Karacakol AC, Guzelhan SN, Isik I, Sitti M. Reprogrammable shape morphing of magnetic soft machines. Sci Adv 2020:6.
                    DOI  PubMed  PMC
               165.      Tang J, Sun B. Reprogrammable shape transformation of magnetic soft robots enabled by magnetothermal effect. Appl Phys Lett
                    2022;120:244101.  DOI
               166.      Tang Z, Xu Z, Bo X, et al. Magnetically controlled flexible micro-robots based on magnetic particle arrangement. Mater Adv
                    2023;4:1314-25.  DOI
               167.      Schmauch MM, Mishra SR, Evans BA, Velev OD, Tracy JB. Chained iron microparticles for directionally controlled actuation of
                    soft robots. ACS Appl Mater Interfaces 2017;9:11895-901.  DOI  PubMed
               168.      Bayaniahangar R, Bayani Ahangar S, Zhang Z, Lee BP, Pearce JM. 3-D printed soft magnetic helical coil actuators of iron oxide
                    embedded polydimethylsiloxane. Sens Actuators B Chem 2021;326:128781.  DOI
               169.      Maria-Hormigos R, Mayorga-Martinez CC, Pumera M. Soft magnetic microrobots for photoactive pollutant removal. Small Methods
                    2023;7:e2201014.  DOI  PubMed
               170.      Tan R, Yang X, Lu H, et al. Nanofiber-based biodegradable millirobot with controllable anchoring and adaptive stepwise release
                    functions. Matter 2022;5:1277-95.  DOI
               171.      Lu H, Zhang M, Yang Y, et al. A bioinspired multilegged soft millirobot that functions in both dry and wet conditions. Nat Commun
                    2018;9:3944.  DOI  PubMed  PMC
               172.      Li M, Ostrovsky-snider NA, Sitti M, Omenetto FG. Cutting the cord: progress in untethered soft robotics and actuators. MRS
                    Advances 2019;4:2787-804.  DOI
               173.      Sitti M, Wiersma DS. Pros and cons: magnetic versus optical microrobots. Adv Mater 2020;32:e1906766.  DOI  PubMed
               174.      Li L, Xin C, Hu Y, et al. On-demand maneuver of millirobots with reprogrammable motility by a hard-magnetic coating. ACS Appl
                    Mater Interfaces 2022;14:52370-8.  DOI
               175.      Zhao R, Dai H, Yao H, Shi Y, Zhou G. Shape programmable magnetic pixel soft robot. Heliyon 2022;8:e11415.  DOI  PubMed  PMC
               176.      Li H, Go G, Ko SY, Park J, Park S. Magnetic actuated pH-responsive hydrogel-based soft micro-robot for targeted drug delivery.
                    Smart Mater Struct 2016;25:027001.  DOI
               177.      Goudu SR, Yasa IC, Hu X, Ceylan H, Hu W, Sitti M. Biodegradable untethered magnetic hydrogel milli grippers. Adv Funct Mater
                    2020;30:2004975.  DOI
               178.      Ze Q, Kuang X, Wu S, et al. Magnetic shape memory polymers with integrated multifunctional shape manipulation. Adv Mater
                    2020;32:e1906657.  DOI  PubMed
               179.      Zhao Y, Hua M, Yan Y, Wu S, Alsaid Y, He X. Stimuli-responsive polymers for soft robotics. Annu Rev Control Robot Auton Syst
                    2022;5:515-45.  DOI
               180.      Zhang S, Ke X, Jiang Q, Ding H, Wu Z. Programmable and reprocessable multifunctional elastomeric sheets for soft origami robots.
                    Sci Robot 2021;6:eabd6107.  DOI
               181.      Magdanz V, Khalil ISM, Simmchen J, et al. IRONSperm: Sperm-templated soft magnetic microrobots. Sci Adv 2020;6:eaba5855.
                    DOI  PubMed  PMC
               182.      Liu Z, Li M, Dong X, Ren Z, Hu W, Sitti M. Creating three-dimensional magnetic functional microdevices via molding-integrated
                    direct laser writing. Nat Commun 2022;13:2016.  DOI  PubMed  PMC
               183.      Ermolli M, Menné C, Pozzi G, Serra MA, Clerici LA. Nickel, cobalt and chromium-induced cytotoxicity and intracellular
                    accumulation in human hacat keratinocytes. Toxicology 2001;159:23-31.  DOI  PubMed
               184.      Lü X, Bao X, Huang Y, Qu Y, Lu H, Lu Z. Mechanisms of cytotoxicity of nickel ions based on gene expression profiles.
                    Biomaterials 2009;30:141-8.  DOI  PubMed
               185.      Ahamed M. Toxic response of nickel nanoparticles in human lung epithelial A549 cells. Toxicol In Vitro 2011;25:930-6.  DOI
                    PubMed
               186.      Magaye R, Zhao J, Bowman L, Ding M. Genotoxicity and carcinogenicity of cobalt-, nickel- and copper-based nanoparticles. Exp
                    Ther Med 2012;4:551-61.  DOI  PubMed  PMC
               187.      Cabot A, Puntes VF, Shevchenko E, et al. Vacancy coalescence during oxidation of iron nanoparticles. J Am Chem Soc
                    2007;129:10358-60.  DOI
               188.      Sun YP, Li XQ, Cao J, Zhang WX, Wang HP. Characterization of zero-valent iron nanoparticles. Adv Colloid Interface Sci
                    2006;120:47-56.  DOI  PubMed
               189.      Kadiri VM, Bussi C, Holle AW, et al. Biocompatible Magnetic Micro- and Nanodevices: Fabrication of FePt Nanopropellers and Cell
                    Transfection. Adv Mater 2020;32:e2001114.  DOI  PubMed
               190.      Rafsanjani A, Bertoldi K, Studart AR. Programming soft robots with flexible mechanical metamaterials. Sci Robot 2019;4:eaav7874.
                    DOI  PubMed
               191.      Han M, Guo X, Chen X, et al. Submillimeter-scale multimaterial terrestrial robots. Sci Robot 2022;7:eabn0602.  DOI