| 442 | 1 | 54 |
| 下载次数 | 被引频次 | 阅读次数 |
简单阐述了微纳米马达及相关领域的发展历程,详细介绍了在微纳米马达驱动技术的基础上调控微纳米马达发生聚集,重点阐述了通过化学驱动和物理驱动等一系列驱动方式使微纳米马达之间相互发生作用、产生运动并在可控的情况下表现出的聚集行为。从聚集现象能有效提升微纳米马达执行任务的效率、增强完成复杂任务能力的角度出发,归纳了通过化学能、声能、磁能、电能、光能来驱动微纳米马达进而实现聚集的研究成果,总结了近年来微纳米马达在聚集领域的研究进展,以及在生物医学中对相关疾病治疗的成功应用。最后,对微纳米马达聚集现象的未来发展方向与面临的挑战进行了展望。
Abstract:The development processes of micro/nanomotors and related fields are briefly described, and the aggregation of micro/nanomotors on the basis of micro/nanomotor driving technologies is introduced in detail. The focus is on the micro/nanomotors interact with each other through a series of driving methods, such as chemical driving and physical driving, and produce movement and show the aggregation behavior under controlled conditions. From the point of view that the aggregation phenomena can effectively improve the efficiency of the micro/nanomotor to perform tasks and enhance the ability to complete complex tasks, the research results of the micro/nanomotors are driven by chemical energy, acoustic energy, magnetic energy, electric energy and light energy to achieve aggregation are summarized, and the recent research progresses of micro/nanomotors in the field of aggregation and the successful application for related diseases treatment in biomedicine are summarized. Finally, the future development directions and challenges of micro/nanomotor aggregation phenomena are prospected.
[1] YANG L,CHEN X X,WANG L,et al.Targeted single-cell therapeutics with magnetic tubular micromotor by one-step exposure of structured femtosecond optical vortices[J].Advanced Functional Materials,2019,29(45):1905745.
[2] ZHANG Z L,YAN H,LI S,et al.Janus rod-like micromotors to promote the tumor accumulation and cell internalization of therapeutic agents[J].Chemical Engineering Journal,2021,404(1):127073.
[3] LIN Z H,FAN X J,SUN M M,et al.Magnetically actuated peanut colloid motors for cell manipulation and patterning[J].ACS Nano,2018,12(3):2539-2545.
[4] ISMAGILOV R,SCHWARTZ A,BOWDEN N,et al.Autonomous movement and self-assembly[J].Angewandte Chemie International Edition,2002,41(4):652-654.
[5] PAXTON W F,KISTLER K C,OLMEDA C C,et al.Catalytic nanomotors:autonomous movement of striped nanorods[J].Journal of the American Chemical Society,2004,126(41):13424-13431.
[6] CATCHMARK J M,SUBRAMANIAN S,SEN A.Directed rotational motion of microscale objects using interfacial tension gradients continually generated via catalytic reactions[J].Small,2005,1(2):202-206.
[7] LAOCHAROENSUK R,BURDICK J,WANG J.Carbon-nanotube-induced acceleration of catalytic nanomotors[J].ACS Nano,2008,2(5):1069-1075.
[8] ZHANG L,ABBOTT J J,DONG L X,et al.Characterizing the swimming properties of artificial bacterial flagella[J].Nano Letters,2009,9(10):3663-3667.
[9] WU Y J,WU Z G,LIN X K,et al.Autonomous movement of controllable assembled Janus capsule motors[J].ACS Nano,2012,6(12):10910-10916.
[10] WU Y J,LIN X K,WU Z G,et al.Self-propelled polymer multilayer Janus capsules for effective drug delivery and light-triggered release [J].ACS Applied Materials & Interfaces,2014,6(13):10476-10481.
[11] LI T L,LI J X,ZHANG H T,et al.Magnetically propelled fish-like nanoswimmers[J].Small,2016,12(44):6098-6105.
[12] TANG S S,ZHANG F Y,GONG H,et al.Enzyme-powered Janus platelet cell robots for active and targeted drug delivery[J].Science Robotics,2020,5(43):eaba6137.
[13] CAO S P,SHAO J X,WU H L,et al.Photoactivated nanomotors via aggregation induced emission for enhanced photothe-rapy[J].Nature Communications,2021,12(1):2077.
[14] HU L X,MIAO J M,GRUBER G.Temperature effects on disk-like gold-nickel-platinum nanoswimmer's propulsion fuelled by hydrogen peroxide[J].Sensors and Actuators:B,2017,239:586-596.
[15] AGHAKHANI A,YASA O,WREDE P,et al.Acoustically powered surface-slipping mobile microrobots[J].Proceedings of the National Academy of Sciences of the United States of America,2020,117(7):3469-3477.
[16] KAGAN D,BALASUBRAMANIAN S,WANG J.Chemically triggered swarming of gold microparticles[J].Angewandte Chemie,2011,50(2):503-506.
[17] DUAN W T,LIU R,SEN A.Transition between collective behaviors of micromotors in response to different stimuli[J].Journal of the American Chemical Society,2013,135(4):1280-1283.
[18] GAO W,PEI A,DONG R F,et al.Catalytic iridium-based Janus micromotors powered by ultralow levels of chemical fuels[J].Journal of the American Chemical Society,2014,136(6):2276-2279.
[19] ESPLANDIU M J,AFSHAR FARNIYA A,BACHTOLD A.Silicon-based chemical motors:an efficient pump for triggering and guiding fluid motion using visible light[J].ACS Nano,2015,9(11):11234-11240.
[20] LIU J,WU Y J,LI Y,et al.Rotary biomolecular motor-powered supramolecular colloidal motor[J].Science Advances,2023,9(8):eabg3015.
[21] XU T L,XU L P,ZHANG X J.Ultrasound propulsion of micro-/nanomotors[J].Applied Materials Today,2017,9:493-503.
[22] XU T L,SOTO F,GAO W,et al.Reversible swarming and separation of self-propelled chemically powered nanomotors under acoustic fields[J].Journal of the American Chemical Society,2015,137(6):2163-2166.
[23] MENG F L,MATSUNAGA D,GOLESTANIAN R.Clustering of magnetic swimmers in a Poiseuille flow[J].Physical Review Letters,2018,120(18):188101.
[24] OULMAS A,ANDREFF N,REGNIER S.3D closed-loop swimming at low Reynolds numbers[J].International Journal of Robotics Research,2018,37(11):1359-1375.
[25] QIU F M,FUJITA S,MHANNA R,et al.Magnetic helical microswimmers functionalized with lipoplexes for targeted gene delivery[J].Advanced Functional Materials,2015,25(11):1666-1671.
[26] SU Y C,QIU T,SONG W,et al.Melt electrospinning writing of magnetic microrobots[J].Advanced Science,2021,8(3):2003177.
[27] YU J F,WANG B,DU X Z,et al.Ultra-extensible ribbon-like magnetic microswarm[J].Nature Communications,2018,9(1):3260.
[28] VILFAN M,OSTERMAN N,VILFAN A.Magnetically driven omnidirectional artificial microswimmers[J].Soft Matter,2018,14(17):3415-3422.
[29] JI F T,JIN D D,WANG B,et al.Light-driven hovering of a magnetic microswarm in fluid[J].ACS Nano,2020,14(6):6990-6998.
[30] SAPOZHNIKOV M V,TOLMACHEV Y V,ARANSON I S,et al.Dynamic self-assembly and patterns in electrostatically driven granular media[J].Physical Review Letters,2003,90(11):114301.
[31] WU Y,FU A,YOSSIFON G.Active particles as mobile microelectrodes for selective bacteria electroporation and transport[J].Science Advances,2020,6(5):eaay4412.
[32] IBELE M,MALLOUK T E,SEN A.Schooling behavior of light-powered autonomous micromotors in water[J].Angewandte Chemie,2009,48(18):3308-3312.
[33] SINGH D P,CHOUDHURY U,FISCHER P,et al.Non-equilibrium assembly of light-activated colloidal mixtures[J].Advanced Materials,2017,29(32):1701328.
[34] GAO Y R,MOU F Z,FENG Y Z,et al.Dynamic colloidal molecules maneuvered by light-controlled Janus micromotors[J].ACS Applied Materials & Interfaces,2017,9(27):22704-22712.
[35] AUBRET A,YOUSSEF M,SACANNA S,et al.Targeted assembly and synchronization of self-spinning microgears[J].Nature Physics,2018,14(11):1114-1118.
[36] LIANG X,MOU F Z,HUANG Z,et al.Hierarchical microswarms with leader-follower-like structures:electrohydrodynamic self-organization and multimode collective photoresponses[J].Advanced Functional Materials,2020,30(16):1908602.
[37] YU L X,YANG M Y,GUAN J G,et al.Ultrasmall Fe2O3 tubular nanomotors:the first example of swarming photocatalytic nanomotors operating in high-electrolyte media[J].Nanomaterials,2023,13(8):1370.
[38] ZHOU X,HUANG X H,WANG B C,et al.Light/gas cascade-propelled Janus micromotors that actively overcome sequential and multi-staged biological barriers for precise drug delivery[J].Chemical Engineering Journal,2021,408:127897.
[39] XING Y,DU X,XU T L,et al.Janus dendritic silica/carbon@Pt nanomotors with multiengines for H2O2,near-infrared light and lipase powered propulsion[J].Soft Matter,2020,16(41):9553-9558.
[40] XIAO Z Y,DUAN S F,XU P Z,et al.Synergistic speed enhancement of an electric-photochemical hybrid micromotor by tilt rectification[J].ACS Nano,2020,14(7):8658-8667.
[41] TANG S S,ZHANG F Y,ZHAO J,et al.Structure-dependent optical modulation of propulsion and collective behavior of acoustic/light-driven hybrid microbowls[J].Advanced Functional Materials,2019,29(23):1809003.
[42] ZHOU D K,GAO Y,YANG J J,et al.Light-ultrasound driven collective "firework" behavior of nanomotors[J].Advanced Science,2018,5(7):1800122.
[43] SRIDHAR V,PARK B W,SITTI M.Light-driven Janus hollow mesoporous TiO2-Au microswimmers[J].Advanced Functional Materials,2018,28(25):1704902.
[44] WANG B,CHAN K F,YU J F,et al.Reconfigurable swarms of ferromagnetic colloids for enhanced local hyperthermia[J].Advanced Functional Materials,2018,28(25):1705701.
[45] CHEN C R,MOU F Z,XU L L,et al.Light-steered isotropic semiconductor micromotors[J].Advanced Mate-rials,2017,29(3):1603374.
[46] XU L L,MOU F Z,GONG H T,et al.Light-driven micro/nanomotors:from fundamentals to applications[J].Chemical Society Reviews,2017,46(22):6905-6926.
[47] WANG J Z,XIONG Z,ZHENG J,et al.Light-driven micro/nanomotor for promising biomedical tools:principle,challenge,and prospect[J].Accounts of Chemical Research,2018,51(9):1957-1965.
[48] CHOI H,LEE G H,KIM K S,et al.Light-guided nanomotor systems for autonomous photothermal cancer therapy[J].ACS Applied Materials & Interfaces,2018,10(3):2338-2346.
[49] VINCENTI B,RAMOS G,CORDERO M L,et al.Magnetotactic bacteria in a droplet self-assemble into a rotary motor[J].Nature Communications,2019,10(1):5082.
[50] MOU F Z,ZHANG J H,WU Z,et al.Phototactic flocking of photochemical micromotors[J].Iscience,2019,19:415-424.
[51] DONG Y,WANG L,YUAN K,et al.Magnetic microswarm composed of porous nanocatalysts for targeted elimination of biofilm occlusion[J].ACS Nano,2021,15(3):5056-5067.
[52] SUN M M,CHAN K F,ZHANG Z F,et al.Magnetic microswarm and fluoroscopy-guided platform for biofilm eradication in biliary stents[J].Advanced Materials,2022,34(34):2201888.
基本信息:
DOI:10.13250/j.cnki.wndz.24050102
中图分类号:TB383.1
引用信息:
[1]于家明,戴运鹏,王兢,等.微纳米马达聚集的驱动方式以及应用研究现状[J].微纳电子技术,2024,61(05):38-48.DOI:10.13250/j.cnki.wndz.24050102.
基金信息:
国家自然科学基金(51502168,11504227)
2024-04-29
2024-04-29
2024-04-29