[1]	Peng C L. Principles and Applications of Biomedical Sensors, Beijing: Higher Education Press. 2000 (in Chinese)

[2]	Engin M, Demirel A, Engin E Z, Fedakar M. Recent developments and trends in biomedical sensors. Measurement, 2005, 37(2): 173–188 CrossRef Google scholar

[3]	Österlund L, Gustafson I, Vikholm-Lundin I. Foresight biomedical sensors. 2007. From http://www.sintef.no/project/FOBIS/FOBIS_final%20report_web.pdf [access time: 12th July 2010]

[4]	Schwiebert L, Gupta S K S, Weinmann J. Research challenges in wireless networks of biomedical sensors. 2001. From http://newslab.cs.wayne.edu/mobicom-camera-ready.pdf [access time: 12th July 2010]

[5]	Chung W Y, Yau C L, Shin K S, A cell phone based health monitoring system with self analysis processor using wireless sensor network technology. 29th Annual International Conference of the IEEE. Engineering in Medicine and Biology Society, 2007: 3705–3708

[6]	Song S K, Jang J, Park S. A phone for human activity recognition using triaxial acceleration sensor. Consumer Electronics, 2008: 1–2

[7]	Neuman M R. Biomedical Sensors. CRC Press LLC., 2000, 5: 47–51

[8]	Mohanty S P, Kougianos E. Biosensors: A tutorial review. IEEE Potentials, 2006, 25(2): 35–40 CrossRef Google scholar

[9]	Huntera G W, Xu J C, Wardb B J, Makel D B, Dutta P, Liu C C, Dweik R A. Smart sensor systems for aerospace and biomedical applications. 2009 From https://www.electrochem.org/meetings/scheduler/abstracts/216/3105.pdf [access time: 12th July 2010]

[10]	Mirtaheri P, Grimnes S, Martinsen O G, Tønnessen T I. A new biomedical sensor for measuring PCO2. Physiological Measurement, 2004, 25(2): 421–436 CrossRef Pubmed Google scholar

[11]	Fonseca M A, Allen M G, Kroh J. Flexible wireless passive pressure sensors for biomedical applications. Solid-State Sensors, Actuators, and Microsystems Workshop, 2006: 37–42

[12]	Tohyama O, Kohashi M, Fukui M, Itoh H. A fiber-optic pressure microsensor for biomedical applications. Solid State Sensors and Actuators, 1997, 2: 1489–1492

[13]	Chatzandroulisa S, Goustouridisa D, Normanda P, Tsoukalas D. A solid-state pressure-sensing microsystem for biomedical applications. Sensors and Actuators. A, Physical, 1997, 62(1-3): 551–555 CrossRef Google scholar

[14]	Neuman M R. Microfabricated sensors for biomedical applications. Engineering in Medicine and Biology Society, 2004, 7: 5218 Pubmed

[15]	Huang X, Li S Q, Schultz J S, Wang Q, Lin Q. A dielectric affinity microbiosensor. Applied Physics Letters, 2010, 96(3): 033701–033703 CrossRef Google scholar

[16]	Lam Y Z, Atkinson J K. Biomedical sensor using thick film technology for transcutaneous oxygen measurement. Medical Engineering & Physics, 2007, 29(3): 291–297 CrossRef Pubmed Google scholar

[17]	Narayanana S, Nikkhaha M, Stroblb J S, Agah M. Analysis of the passivation layer by testing and modeling a cell impedance micro-sensor. Sensors and Actuators. A, Physical, 2010, 159(2): 241–247 CrossRef Google scholar

[18]	Liu H, Dharmatilleke S, Tay A A O. A chip scale nanofluidic pump using electrically controllable hydrophobicity. Microsystem Technologies, 2010, 16(4): 561–570 CrossRef Google scholar

[19]	Woltman S J, Jay G D, Crawford G P. Liquid-crystal materials find a new order in biomedical applications. Nature Materials, 2007, 6(12): 929–938 CrossRef Pubmed Google scholar

[20]	Chaterji S, Kwon I K, Park K. Smart polymeric gels: Redefining the limits of biomedical devices. Progress in Polymer Science, 2007, 32(8-9): 1083–1122 CrossRef Pubmed Google scholar

[21]	Deligkaris K, Tadele T S, Olthuis W, van den Berg A. Hydrogel-based devices for biomedical applications. Sensors and Actuators. B, Chemical, 2010, 147(2): 765–774 CrossRef Google scholar

[22]	Lin G, Chang S, Kuo C H, Magda J, Solzbacher F. Free swelling and confined smart hydrogels for applications in chemomechanical sensors for physiological monitoring. Sensors and Actuators. B, Chemical, 2009, 136(1): 186–195 CrossRef Pubmed Google scholar

[23]	Gao F, Yin J, Yao Z, Li M, Wang L. A nanocomposite modified electrode: electrocatalytic properties and its sensing applications to hydrogen peroxide and glucose. Journal of the Electrochemical Society, 2010, 157(3): 35–39 CrossRef Google scholar

[24]	Kumar S A, Cheng H W, Chen S M. Preparation and characterization of copper nanoparticles/zinc oxide composite modified electrode and its application to glucose sensing. Materials Science & Engineering C-Materials for Biological Applications, 2010, 30(1): 86–91

[25]

Chen C W, Wang C H, Wei C M, Hsieh C Y, Chen Y T, Chen Y F, Lai C W, Liu C L, Hsieh C C, Chou P T. Highly sensitive emission sensor based on surface plasmon enhanced energy transfer between gold nanoclusters and silver nanoparticles. Journal of Physical Chemistry C, 2010, 114(2): 799–802 CrossRef Google scholar

[26]	Bekiroglu E, Daldal N. Remote control of an ultrasonic motor by using a GSM mobile phone. Sensors and Actuators. A, Physical, 2005, 120(2): 536–542 CrossRef Google scholar

[27]	Yanase Y, Araki A, Suzuki H, Tsutsui T, Kimura T, Okamoto K, Nakatani T, Hiragun T, Hide M. Development of an optical fiber SPR sensor for living cell activation. Biosensors & Bioelectronics, 2010, 25(5): 1244–1247 CrossRef Pubmed Google scholar

[28]	Sharma A K, Jha R, Pattanaik H S. Design considerations for surface plasmon resonance based detection of human blood group in near infrared. Journal of Applied Physics, 2010, 107(3): 034701–034707 CrossRef Google scholar

[29]	Duun S B, Haahr R G, Birkelund K, Thomsen E V. A ring-shaped photodiode designed for use in a reflectance pulse oximetry sensor in wireless health monitoring applications. IEEE Sensors Journal, 2010, 10(2): 261–268 CrossRef Google scholar

[30]	Cox M P, Ma H T, Bahlke M E, Beck J H, Schwartz T H, Kymissis I. LED-based optical eevice for chronic in vivo cerebral blood volume measurement. IEEE Transactions on Electron Devices, 2010, 57(1): 174–177 CrossRef Google scholar

[31]

Coyle S, Lau K T, Moyna N, O’Gorman D, Diamond D, Di Francesco F, Costanzo D, Salvo P, Trivella M G, De Rossi D E, Taccini N, Paradiso R, Porchet J A, Ridolfi A, Luprano J, Chuzel C, Lanier T, Revol-Cavalier F, Schoumacker S, Mourier V, Chartier I, Convert R, De-Moncuit H, Bini C. BIOTEX—biosensing textiles for personalised healthcare management. Information Technology in Biomedicine, 2010, 14(2): 364–370 CrossRef Pubmed Google scholar

[32]	Saraoglu H M, Kocan M. Determination of blood glucose level-based breath analysis by a quartz crystal microbalance sensor array. IEEE Sensors Journal, 2010, 10(1): 104–109 CrossRef Google scholar

[33]	Neri G, Bonavita A, Micali G, Donato N. Design and development of a breath acetone MOS sensor for ketogenic diets control. IEEE Sensors Journal, 2010, 10(1): 131–136 CrossRef Google scholar

[34]	Njagi J, Erlichman J S, Aston J W, Leiter J C, Andreescu S. A sensitive electrochemical sensor based on chitosan and electropolymerized Meldola blue for monitoring NO in brain slices. Sensors and Actuators. B, Chemical, 2010, 143(2): 673–680 CrossRef Google scholar

[35]	Ko J, Gao T, Rothman R, Terzis A. Wireless sensing systems in clinical environments: improving the efficiency of the patient monitoring process. IEEE Engineering in Medicine and Biology Magazine, 2010, 29(2): 103–109 CrossRef Pubmed Google scholar

[36]	Corchado J M, Bajo J, Tapia D I, Abraham A. Using heterogeneous wireless sensor networks in a telemonitoring system for healthcare. IEEE Transactions on Information Technology in Biomedicine, 2010, 14(2): 234–240 CrossRef Pubmed Google scholar

[37]	Patel M, Wang J F. Applications, challenges, and prospective in emerging body area networking technologies. IEEE Wireless Communications, 2010, 17(1): 80–88 CrossRef Google scholar

[38]	Camilo T, Oscar R, Carlos L. Biomedical signal monitoring using wireless sensor networks. 2009 IEEE Latin-American Conference on Communications (Latincom 2009), 2009, 34–39

[39]	Junnila S, Kailanto H, Merilahti J, Vainio A M, Vehkaoja A, Zakrzewski M, Hyttinen J. Wireless, multipurpose in-home health monitoring platform: two case trials. IEEE Transactions on Information Technology in Biomedicine, 2010, 14(2): 447–455 CrossRef Pubmed Google scholar

[40]	Pham M L, Ramstad T A, Balasingham I. Poster abstract: ultra wideband biomedical wireless sensor neworks using wavelet lifting for image transmission. Information Processing in Sensor Networks, 2009: 385–386

[41]	Burchfield T R, Venkatesan S. Accelerometer-based human abnormal movement detection in wireless sensor networks. Proceedings of the 1st ACM SIGMOBILE International Workshop, 2007: 67–69

[42]	Wegmuller M S. Intra-body communication for biomedical sensor networks. 2007. From http://e-collection.ethbib.ethz.ch/eserv/eth:29911/eth-29911-02.pdf [access time: 12th September 2010]

[43]	Fort A, Keshmiri F, Crusats G R, Craeye C, Oestges C. A body area propagation model derived from fundamental principles: analytical analysis and comparison with measurements. IEEE Transactions on Antennas and Propagation, 2010, 58(2): 503–514 CrossRef Google scholar

[44]	Ren Y, Pazzi R W N, Boukerche A. Monitoring patients via a secure and mobile healthcare system. IEEE Wireless Communications, 2010, 17(1): 59–65 CrossRef Google scholar

[45]	Ghasemzadeh H, Jafari R, Prabhakaran B. A body sensor network with electromyogram and inertial sensors: Multimodal interpretation of muscular activities. IEEE Transactions on Information Technology in Biomedicine, 2010, 14(2): 198–206 CrossRef Pubmed Google scholar

[46]	Zhang X Y, Jiang H J, Zhang L W, Zhang C, Wang Z H, Chen X K. An energy-efficient ASIC for wireless body sensor networks in medical applications. IEEE Transactions on Biomedical Circuits and Systems, 2010, 4(1): 11–18 CrossRef Google scholar

[47]	Stanton C, Williams M A. An innovative interactive web-enabled learning space for exploring intelligent mobile sensor networks and their business applications. ICMB 2005: International Conference on Mobile Business, 2005: 249–254

[48]	Kim J H, Haw R, Hong C S. Development of a framework to support network-based mobility of 6LoWPAN sensor device for mobile healthcare system Consumer Electronics (ICCE), 2010: 359–360

[49]	Massey T, Marfia G, Potkonjak M, Sarrafzadeh M. Experimental analysis of a mobile health system for mood disorders. IEEE Transactions on Information Technology in Biomedicine, 2010, 14(2): 241–247 CrossRef Pubmed Google scholar

[50]	Chen X, Ho C T, Lim E T. Cellular phone based online ECG processing for ambulatory and continuous detection. Computers in Cardiology, 2007, 1-2: 653–656

[51]	Tseng S Y, Tsai C H, Lai Y S. A wireless biomedical sensor network using IEEE802.15.4. Life Science Systems and Applications Workshop, 2009: 183–186

[52]	Kim J, Lim K, Hu J. A study on the implementation of the IEEE1451 on a biomedical sensor network for e-Health. Advanced Communication Technology, 2006, 1: 519–522

[53]	Shaban H A, Abou el-Nasr M, Buehrer R M. Toward a highly accurate ambulatory system for clinical gait analysis via UWB radios. IEEE Transactions on Information Technology in Biomedicine, 2010, 14(2): 284–291 CrossRef Pubmed Google scholar

[54]	Guo C, Prasad R V, Jacobsson M. Packet forwarding with minimum energy consumption in body area sensor networks. 2010 7th IEEE Consumer Communications and Networking Conference-Ccnc, 2010: 397–402

[55]	Moh M, Culpepper B J, Dung L. On data gathering protocols for in-body biomedical sensor networks. GLOBECOM '05: IEEE Global Telecommunications Conference, 2005, 1-6: 2991–2996

[56]	Li H M, Tan J D. Heartbeat-driven medium-access control for body sensor networks. IEEE Transactions on Information Technology in Biomedicine, 2010, 14(1): 44–51 CrossRef Pubmed Google scholar

[57]	Bag A, Bassiouni M A. Routing algorithm for network of homogeneous and id-less biomedical sensor nodes (RAIN). 2008 IEEE Sensors Applications Symposium, 2008: 68–73

[58]	Fleury A, Vacher M, Noury N. SVM-based multimodal classification of activities of daily living in Health Smart Homes: Sensors, algorithms, and first experimental results. IEEE Transactions on Information Technology in Biomedicine, 2010, 14(2): 274–283 CrossRef Pubmed Google scholar

[59]	Ren H, Meng M Q H, Chen X. Physiological information acquisition through wireless biomedical sensor networks. Proceedings of the 2005 IEEE International Conference on Information Acquisition, 2005: 483–488

[60]	Ren H, Meng M Q H. Bioeffects control in wireless biomedical sensor networks. Sensor and Ad Hoc Communications and Networks, 2006, 3: 896–904

[61]	Rashid R A, Arifin S H S, Abd Rahim M R. Home healthcare via wireless biomedical sensor network. 2008 IEEE International Rf and Microwave Conference, Proceedings, 2008: 507–510

[62]

Fletcher R R, Dobson K, Goodwin M S, Eydgahi H, Wilder-Smith O, Fernholz D, Kuboyama Y, Hedman E B, Poh M Z, Picard R W. iCalm: wearable sensor and network architecture for wirelessly communicating and logging autonomic activity. IEEE Transactions on Information Technology in Biomedicine, 2010, 14(2): 215–223 CrossRef Pubmed Google scholar

[63]	Rai P, Kumar P S, Varadan V K. Integration of OLEDs in biomedical sensor systems: design and feasibility analysis. Nano Sensors and Actuators, 2010, 7646: 76460Z 1–7

[64]	Hegarty M S, Grant E, Reid L Jr. An overview of technologies related to care for venous leg ulcers. IEEE Transactions on Information Technology in Biomedicine, 2010, 14(2): 387–393 CrossRef Pubmed Google scholar

[65]	Mandal S, Turicchia L, Sarpeshkar R. A low-power, battery-free tag for body sensor networks. IEEE Pervasive Computing / IEEE Computer Society [and] IEEE Communications Society, 2010, 9(1): 71–77 CrossRef Google scholar

[66]	Vaz A, Ubarretxena A, Zalbide I, Pardo D, Solar H, Garcia-Alonso A, Berenguer R. Full passive UHF tag with a temperature sensor suitable for human body temperature monitoring. IEEE Transactions on Circuits and Wystems. II, Express Briefs, 2010, 57(2): 95–99 CrossRef Google scholar

[67]	Occhiuzzi C, Marrocco G. The RFID technology for neurosciences: feasibility of limbs’ monitoring in sleep diseases. Information Technology in Biomedicine, 2010, 14(1): 37–43 CrossRef Pubmed Google scholar

[68]	Gouma P, Kalyanasundaram K, Yun X, Stanacevic M, Wang L. Nanosensor and breath analyzer for ammonia detection in exhaled human breath. IEEE Sensors Journal, 2010, 10(1): 49–53 CrossRef Google scholar

[69]	Ono Y, Liu Q, Kobayashi M. A piezoelectric membrane sensor for biomedical monitoring. In: Proceedings of 2006 IEEE Ultrasonics Symposium, 2006, 1-5: 800–803

[70]	Carta R, Jourand P, Hermans B, Thoné J, Brosteaux D, Vervust T, Bossuyt F, Axisa F, Vanfleteren J, Puers R. Design and implementation of advanced systems in a flexible-stretchable technology for biomedical applications. Sensors and Actuators. A, Physical, 2009, 156(1): 79–87 CrossRef Google scholar

[71]	Sungmee P, Jayaraman S. Smart textile-based wearable biomedical systems: a transition plan for research to reality. IEEE Transactions on Information Technology in Biomedicine, 2010, 14(1): 86–92 CrossRef Pubmed Google scholar

[72]	Lane N D, Miluzzo E, Lu H, Peebles D, Choudhury T, Campbell A. A survey of mobile phone sensing. IEEE Communications Magazine, 2010, 48(9): 140–150 CrossRef Google scholar

[73]	Demirbas M, Rudra C, Rudra A. iMAP: Indirect measurement of air pollution with cellphones. 2009 IEEE International Conference on Pervasive Computing and Communications (Percom), 2009, 1-2: 542–547

[74]	Honicky R, Brewer E A, Paulos E. N-smarts: Networked suite of mobile atmospheric real-time sensors. Proceedings of the Second ACM SIGCOMM Workshop on Networked Systems for Developing Regions, 2008: 25–29

[75]	http://www.ce.cn/cysc/communications/smssxw/200708/20/t20070820_12611892.shtml [access time: 1st November 2010]

[76]	http://news.weixiuwang.com/mobile/2004-10/2004E10Y13;213130E96687731_2.htm [access time: 1st November 2010]

[77]	http://www.pcpop.com/doc/0/554/554374.shtml [access time: 1st November 2010].

[78]	Quero J M, Tarrida C L, Ermolov V. Health care applications based on mobile phone centric smart sensor network. 2007 Annual International Conference of the IEEE Engineering in Medicine and Biology Society 2007; 1-16: 6299–6302

[79]	Chung W Y, Yau C L, Shin K S. A cell phone based health monitoring system with self analysis processor using wireless sensor network technology. 2007 Annual International Conference of the Ieee Engineering in Medicine and Biology Society 2007, 1-16: 3705–3708

[80]	http://tech.163.com/digi/10/0618/10/69F1I1P900162OUT.html [access time: 1st November 2010]

[81]	[access time: 1st November 2010]

[82]	Okumura F, Kubota A, Hatori Y. A study on biometric authentication based on arm sweep action with acceleration sensor. 2006 International Symposium on Intelligent Signal Processing and Communications, 2006, 1-2: 195–198

[83]	http://fashion.cnmo.com/5/53123.html [access time: 1st November 2010]

[84]	http://news.wustl.edu/news/Pages/13928.aspx [access time: 1st November 2010]

[85]	Granot Y, Ivorra A, Rubinsky B. A new concept for medical imaging centered on cellular phone technology. PLoS ONE, 2008, 3(4): e2075 CrossRef Pubmed Google scholar

[86]	Breslauer D N, Maamari R N, Switz N A, Lam W A, Fletcher D A. Mobile phone based clinical microscopy for global health applications. PLoS ONE, 2009, 4(7): e6320 CrossRef Pubmed Google scholar

[87]	Jang W, Kwak B, Kim J. An image signal processor for ultra small HD video sensor with 3A in camera phones. 2009 IEEE International Conference on Consumer Electronics, 2009; 391–392

[88]	Jeong H, Kim J, Choi W. Image quality enhancement by real-time gamma correction for a CMOS image sensor in mobile phones. Isocc: 2008 International Soc Design Conference, 2008, 1-3: 560–563

[89]	Iso T, Kawasaki N, Kurakake S. Personal context extractor with multiple sensor on a cell phone. From http://www.ctr.kcl.ac.uk/mwcn2005./Paper/C200525.pdf [access time: 2nd November 2010]

[90]	Pering T, Zhang P, Chaudhri R. The PSI board: realizing a phone-centric body sensor network. 4th International Workshop on Wearable and Implantable Body Sensor Networks (BSN 2007), 2007, 13: 53–58

[91]	Zhong L, Sinclair M, Bittner P. A phone-centered body sensor network platform: Cost, energy efficiency & user interface. BSN 2006: International Workshop on Wearable and Implantable Body Sensor Networks, Proceedings, 2006: 179–182

[92]	Nakazawa J, Yura J, Iwamoto T. Bridging sensor networks and the Internet on cellular phones: Towards richer and easier-to-use sensor network applications for end-users Networked Sensing Systems (INSS), 2009: 1–4

[93]	Kansal A, Goraczko M, Zhao F. Building a sensor network of mobile phones. Proceedings of the Sixth International Symposium on Information Processing in Sensor Networks, 2007: 547–548

[94]	Jones V, Gay V, Leijdekkers P. Body sensor networks for mobile health monitoring experience in europe and australia. Fourth International Conference on Digital Society: Icds 2010, Proceedings, 2010: 204–209

[95]	Campbell A T. After motes and multihop: Mobile phones and the global mobile sensor network. 2009 IEEE International Conference on Pervasive Computing and Communications (Percom), 2009; 1-2: 421

[96]	Sarela A, Korhonen I, Salminen J. A home-based care model for outpatient cardiac rehabilitation based on mobile technologies. Pervasive Computing Technologies for Healthcare, 2009: 1–8

[97]	Zao J K, Fan S C, Yang B S. Custos remote on-demand healthcare aided with wireless sensors and mobile phones. 2008 IEEE International Conference on Systems, Man and Cybernetics (Smc), 2008; 1-6: 2263–2268

[98]	Sharma C. Mobile Services Evolution 2008-2018. Making the eHealth Connection, 2008: 1–11

[99]	Chueh H T, Hatfield J V. A real-time data acquisition system for a hand-held electronic nose ((HEN)-E-2). Sensors and Actuators. B, Chemical, 2002, 83(1-3): 262–269 CrossRef Google scholar

[100]

Wang P, Liu Q J, Xu Y, Cai H, Li Y. Olfactory and taste cell sensor and its applications in biomedicine. Sensors and Actuators. A, Physical, 2007, 139(1-2): 131–138 CrossRef Google scholar

[101]

Bai Y W, Li W T, Yeh C H. Design and implementation of an embedded monitor system for body breath detection by using image processing methods. Consumer Electronics (ICCE), 2010: 193–194

[102]

Shin J H, Chee Y J, Jeong D U, Park K S. Nonconstrained sleep monitoring system and algorithms using air-mattress with balancing tube method. IEEE Transactions on Information Technology in Biomedicine, 2010, 14(1): 147–156 CrossRef Pubmed Google scholar

[103]

Tanaka M. Electronic scale and a processor for the care of weight change. US_20100089665_A1

[104]

Lim E T, Chen X, Ho C T. Smart phone-based automatic QT interval measurement. Computers in Cardiology, 2007, 1-2: 645–648

[105]

Aziz A A, Besar R. Application of mobile phone in medical image transmission. 4th National Conference on Telecommunication Technology, Proceedings, 2003: 80–83

[106]

Miluzzo E, Zheng X, Fodor K, Campbell A T. Radio characterization of 802.15.4 and its impact on the design of mobile sensor networks. Wireless Sensor Networks, 2008, 4913: 171–188 CrossRef Google scholar

[107]

http://www.readwriteweb.com/archives/2010_trend_sensors_mobile_phones.php [access time: 3rd November 2010]

[108]

Zhang Y, Xiao H N. Bluetooth-based sensor networks for remotely monitoring the physiological signals of a patient. IEEE Transactions on Information Technology in Biomedicine, 2009, 13(6): 1040–1048 CrossRef Pubmed Google scholar

[109]

Chung M J, Yee Y H, Ahn W H. Development of compact camera module having auto focus actuator and mechanical shutter system for mobile phone. In: International Conference on Control, Automation and Systems 2007. COEX, Seoul. Korea & World Affairs, 2007, (10): 17–20

[110]

Quevy E, Galayko D, Legrand B. IF MEMS filters for mobile communication. Proceedings of 8th IEEE International Conference on Emerging Technologies and Factory Automation, 2001, 2: 733–736

[111]

Hannan N, Kujala A, Mohan V. Investigation of different options of pre-applied CSP underfill for mechanical reliability enhancements in mobile phones. Proceedings of 54th Electronic Components and Technology Conference, 2004, 1: 770–774