Wireless Power Transfer for Implantable Ventricular Assistance:A Review
Yin Chengke1,2, Hsu Polin1,2
1.School of Mechanical and Electrical Engineering Soochow University Suzhou 215021 China 2.Artificial Organ Technology Laboratory Soochow University Suzhou 215021 China
Abstract:Implantable ventricular assistance has been rapidly developed in recent years and become a therapeutic option for end-stage heart failure patients in many developed countries.However,infection caused by the percutaneous cable remains a severe clinical complication.Wireless power transfer could be an ideal solution for power supply to implanted mechanical ventricular assistance.Nevertheless,problems with current wireless power transfer technology,such as transfer distance,position and orientation sensitivity,implantability,and long term reliability in situ,must be solved before it can be used for long-term implantable devices.This paper reviews the evolution of wireless power transfer technology for clinical use,summarizes the pros and cons of existing wireless power transfer methods for ventricular assistance,and discusses the direction for future development.
[1] Bellumkonda L,Bonde P.Ventricular assist device therapy for heart failure——past,present,and future[J].International Anesthesiology Clinics,2012,50(3):123-145. [2] Molina E J,Boyce S W.Current status of left ventricular assist device technology[J].Seminars in Thoracic and Cardiovascular Surgery,2013,25(1):56-63. [3] Birati E Y,Rame J E.Left ventricular assist device management and complications[J].Critical Care Clinics,2014,30(3):607-627. [4] Abshire M,Himmelfarb C R D,Russell S D.Functional status in left ventricular assist device-supported patients:a literature review[J].Journal of Card Fail,2014,20(12):973-983. [5] Parnis S M,Akay M H,Frazier O H.Newer-Generation Rotary Blood Pumps[M].New York:Springer,2013. [6] Maher T R,Butler K C,Poirier V L,et al.HeartMate left ventricular assist devices:a multigeneration of implanted blood pumps[J].Artif Organs,2001,25(5):422-426. [7] Milano C A,Simeone A A.Mechanical circulatory support:devices,outcomes and complications[J].Heart Fail Reviews,2013,18(1):35-53. [8] Sharma V,Deo S V,Stulak J M,et al.Driveline infections in left ventricular assist devices:implications for destination therapy[J].The Annals of Thoracic Surgery,2012,94(5):1381-1386. [9] Heinrich S,Martin S,Thomas S,et al.Repair of left ventricular assist device driveline damage directly at the transcutaneous exit site[J].Artificial Organs,2014,38(5):422-425. [10]Spiliopoulos S,Tenderich M,Guersoy D A,et al.Repair of left ventricular driveline tear in a SynCardia-total artificial heart patient[J].Journal of Cardiothoracic Surgery,2014,9(1):7-7. [11]Iv E I C,Weis R A,Ramakrishna H.Emergent reconnection of a transected left ventricular assist device driveline[J].The Journal of Emergency Medicine,2014,47(5):546-551. [12]Pereda D,Conte J V.Left ventricular assist device driveline infections[J].Cardiology Clinics,2011,29(4):515-527. [13]黄学良,谭林林,陈中,等.无线电能传输技术研究与应用综述[J].电工技术学报,2013,28(10):1-11. Huang Xueliang,Tan Linlin,Chen Zhong,et al.Review and research progress on wireless power transfer technology[J].Transactions of China Electrotechnical Society,2013,28(10):1-11. [14]Affeld K,Grosshauser J,Reiter K,et al.How can we achieve infection-resistant percutaneous energy transfer?[J].Artificial Organs,2011,35(8):800-806. [15]Frazier O H,Myers T J,Jarvik R K,et al.Research and development of an implantable,axial-flow left ventricular assist device:the Jarvik 2000 heart[J].The Annals of Thoracic Surgery,2001,71(3):S125-S132. [16]Mcspadden J O,Mankins J C.Space solar power programs and microwave wireless power transmission technology[J].IEEE Microwave Magazine,2002,3(4):46-57. [17]Dowling R D,Jr L a G,Etoch S W,et al.The AbioCor implantable replacement heart[J].The Annals of Thoracic Surgery,2003,75(6):93-99. [18]Sale S M,Smedira N G.Total artificial heart[J].Best Practice & Research Clinical Anaesthesiology,2012,26(2):147-165. [19]Schuder J C.Powering an artificial heart:birth of the inductively coupled-radio frequency system in 1960[J].Artificial Organs,2002,26(11):909-915. [20]Mehta S M,Jr W E P,Rosenberg G,et al.The LionHeart LVD-2000:a completely implanted left ventricular assist device for chronic circulatory support[J].The Annals of Thoracic Surgery,2001,71(3):S156-S161. [21]Rintoul T C,Dolgin A.Thoratec transcutaneous energy transformer system:a review and update[J].Asaio Journal,2004,50(4):397-400. [22]Ma Jimei,Yang Qingxin,Chen Haiyan.Transcutaneous energy and information transmission system with optimized transformer parameters for the artificial heart[J].IEEE Transactions on Applied Superconductivity,2010,20(3):798-801. [23]Yu L J.Finite element analysis of a contactless power transformer with metamaterial[J].TELKOMNIKA Indonesian Journal of Electrical Engineering,2014,12(1):678-684. [24]周煜,于歆杰,程锦闽,等.用于心脏起搏器的经皮能量传输系统[J].电工技术学报,2010,25(3):48-53,60. Zhou Yu,Yu Xinjie,Cheng Jinmin,et al.Transcutaneous energy transmission system for cardiac pacemaker[J].Transactions of China Electrotechnical Society,2010,25(3):48-53,60. [25]Chen Qianhong,Wong S C,Tse C K,et al.Analysis,design,and control of a transcutaneous power regulator for artificial hearts[J].IEEE Transactions on Biomedical Circuits and Systems,2009,3(1):23-31. [26]Slaughter M S,Myer T J.Transcutaneous energy transmission for mechanical circulatory support systems:history,current status,and future prospects[J].Journal of Cardiac Surgery,2010,25(4):484-489. [27]Kurs A,Karalis A,Moffatt R,et al.Wireless power transfer via strongly coupled magnetic resonances[J].Science,2007,317(5834):83-86. [28]Waters B H,Sample A P,Bonde P,et al.Powering a ventricular assist device (vad) with the free-range resonant electrical energy delivery (free-d) system[J].Proceedings of the IEEE,2012,100(1):138-149. [29]Waters B H,Reed J T,Kagi K R,et al.A Portable Transmitter for Wirelessly Powering a Ventricular Assist Device Using the Free-Range Resonant Electrical Energy Delivery (FREE-D) System[M].New York:Springer,2013. [30]Waters B H,Smith J R,Bonde P.Innovative free-range resonant electrical energy delivery system (FREE-D System) for a ventricular assist device using wireless power[J].Asaio Journal,2014,60(1):31-37. [31]Asgari S S,Bonde P.Implantable physiologic controller for left ventricular assist devices with telemetry capability[J].The Journal of Thoracic and Cardiovascular Surgery,2014,147(1):192-202. [32]Hui S Y R,Zhong W X,Lee C K.A critical review of recent progress in mid-range wireless power transfer[J].IEEE Transactions on Power Electron,2013,29(9):4500-4511. [33]Wei Xuezhe,Wang Zhenshi,Dai Haifeng.A critical review of wireless power transfer via strongly coupled magnetic resonances[J].Energies,2014,7(7):4316-4341. [34]李阳,杨庆新,闫卓,等.无线电能有效传输距离及其影响因素分析[J].电工技术学报,2013,28(1):106-112. Li Yang,Yang Qingxin,Yan Zhuo,et al.Analysis on effective range of wireless power transfer and its impact factors[J].Transactions of China Electrotechnical Society,2013,28(1):106-112. [35]李阳,杨庆新,闫卓,等.磁耦合谐振式无线电能传输方向性分析与验证[J].电工技术学报,2014,29(2):197-203. Li Yang,Yang Qingxin,Yan Zhuo,et al.Analysis and validation on characteristic of orientation in wireless power transfer system via coupled magnetic resonances[J].Transactions of China Electrotechnical Society,2014,29(2):197-203. [36]陈琛,黄学良,孙文慧,等.金属障碍物对磁耦合谐振无线电能传输系统的影响[J].电工技术学报,2014,29(9):22-26. Chen Chen,Huang Xueliang,Sun Wenhui,et al.Impact of metal obstacles on wireless power transmission system based coupled resonance[J].Transactions of China Electrotechnical Society,2014,29(9):22-26.
2015, Vol. 30 
