Compact helical antenna for smart implant applications

NPG Asia Materials

Volumn 7, Issue 6, 2015, Pages

  Karnaushenko, Dmitriy D ^a   Karnaushenko, Daniil ^a   Makarov, Denys ^a   Schmidt, Oliver G ^a,b  

^a IFW DRESDEN   (Germany)

^b CHEMNITZ UNIVERSITY OF TECHNOLOGY   (Germany)

Author keywords

[No Author keywords available]

Indexed keywords

ANTENNA ARRAYS; DENTAL PROSTHESES; MHEALTH; MICROWAVE ANTENNAS; MOBILE ANTENNAS; SELF ASSEMBLY;

HIGH VOLUMES; MEDICAL DOCTORS; NORMAL MODE HELICAL ANTENNAS; PERSONAL HEALTH CARE; PHYSIOLOGICAL PROCESS; SELF ASSEMBLY PROCESS; TIME-EFFICIENT; WOUND HEALING;

HELICAL ANTENNAS;

EID: 84990922146     PISSN: 18844049     EISSN: 18844057     Source Type: Journal    
DOI: 10.1038/am.2015.53     Document Type: Article

References (49)

1. Cao, H., Rao, S., Tang, S. J., Tibbals, H. F., Spechler, S. & Chiao, J. C Batteryless implantable dual-sensor capsule for esophageal reflux monitoring. Gastrointest. Endosc. 77, 649-653 (2013).
2. Young, D. J. Development of wireless batteryless implantable blood pressure-EKG-core body temperature sensing microsystem for genetically engineered mice real time monitoring. IEEE Int. Conf. Nano/Molecular Medicine and Engineering (NANOMED) 259-264 (2009).
3. Mannoor, M. S., Tao, H., Clayton, J. D., Sengupta, A., Kaplan, D. L., Naik, R. R., Verma, N., Omenetto, F. G. & McAlpine, M. C Graphene-based wireless bacteria detection on tooth enamel. Nat. Commun 3, 763 (2012).
4. Farra, R., Sheppard, N. F. Jr, McCabe, L., Neer, R. M., Anderson, J. M., Santini, J. T. Jr, Cima, M. J. & Langer, R. First-in-human testing of a wirelessly controlled drug delivery microchip. Sci. Transl. Med. 4, 122ra21 (2012).
5. Wilson, B. S. & Dorman, M. F. Cochlear implants: current designs and future possibilities. J. Rehabil. Res. Dev. 45, 695-730 (2008).
6. Hodgins, D., Bertsch, A., Post, N., Frischholz, M., Volckaerts, B., Spensley, J., Wasikiewicz, J. M., Higgins, H., Stetten, F. & Kenney, L. Healthy aims: developing new medical implants and diagnostic equipment. Pervasive Comput 7, 14-21 (2008).
7. Chen, G., Ghaed, H., Haque, R., Wieckowski, M., Yejoong, K., Gyouho, K., Fick, D., Daeyeon, K., Mingoo, S., Wise, K., Blaauw, D. & Sylvester, D. A cubic-millimeter energy-autonomous wireless intraocular pressure monitor. IEEE Int. Solid-State Circuits Conf. Digest of Technical Papers (ISSCC) 310-312 (2011).
8. Rogers, J. A., Someya, T. & Huang, Y. Materials and mechanics for stretchable electronics. Science 327, 1603-1607 (2010).
9. Rizzo, J., Shire, D. B., Kelly, S. K., Troyk, P., Gingerich, M., McKee, B., Priplata, A., Chen, J., Drohan, W., Doyle, P., Mendoza, O., Theogarajan, L., Cogan, S. & Wyatt, J. L. Development of the Boston retinal prosthesis. Conf. Proc. IEEE Eng. Med. Biol. Soc 2011, 3135-3142 (2011).
10. Li, Y., Alam, M., Guo, S., Ting, K. & He, J. Electronic bypass of spinal lesions: activation of lower motor neurons directly driven by cortical neural signals. J. Neuroeng. Rehabil. 11, 107 (2014).
11. Borton, D. A., Yin, M., Aceros, J. & Nurmikko, A. An implantable wireless neural interface for recording cortical circuit dynamics in moving primates. J. Neural Eng. 10, 026010 (2013).
12. Hochberg, L. R., Bacher, D., Jarosiewicz, B., Masse, N. Y., Simeral, J. D., Vogel, J., Haddadin, S., Liu, J., Cash, S. S., van der Smagt, P. & Donoghue, J. P. Reach and grasp by people with tetraplegia using a neurally controlled robotic arm. Nature 485, 372-375 (2012).
13. Lebedev, M. A. & Nicolelis, M. A. Brain-machine interfaces: past, present and future. Trends Neurosci. 29, 536-546 (2006).
14. Bazaka, K. & Jacob, M. V. Implantable devices: issues and challenges. Electronics 2, 1-34 (2013).
15. Kumar, V., Sharma, A., Kumar, A., Ahmad, M. & Gupta, G. Interaction of mobile phone waves with tissues of skeletal muscles and bone of human beings. J. Pharm. Biol. Sci 1, 2278-3008 (2012).
16. Swerdlow, A. J. Health Effects from Radiofrequency Electromagnetic Fields, Health Protection Agency, (2012).
17. Skrivervik, A., Zurcher, J.-F., Staub, O. & Mosig, J. PCS antenna design: the challenge of miniaturization. IEEE Antennas Propag. Mag. 43, 12-27 (2001).
18. Balanis, C. A. in Modern Antenna Handbook 1203-1204 (John Wiley & Sons, 2011).
19. Kraus, J. D. Antennas (McGraw-Hill, Inc., 1988).
20. Mizuno, H., Takahashi, M., Saito, K., Haga, N. & Ito, K. Design of a helical folded dipole antenna for biomedical implantsin Proc. 5th European Conf. Antennas and Propagation (EUCAP) 3484-3487, IEEE, (2011).
21. Adams, J. J., Duoss, E. B., Malkowski, T. F., Motala, M. J., Ahn, B. Y., Nuzzo, R. G., Bernhard, J. T. & Lewis, J. A. Conformal printing of electrically small antennas on threedimensional surfaces. Adv. Mater. 23, 1335-1340 (2011).
22. Rogers, J. A., Jackman, R. J., Whitesides, G. M., Olson, D. L. & Sweedler, J. V. Using microcontact printing to fabricate microcoils on capillaries for high resolution proton nuclear magnetic resonance on nanoliter volumes. Appl. Phys. Lett. 70, 2464-2466 (1997).
23. Jackman, R. J., Rogers, J. A. & Whitesides, G. M. Fabrication of small-scale cylindrical articles. Patent: US 5951881 A (1999).
24. Bell, D. J., Dong, L., Nelson, B. J., Golling, M., Zhang, L. & Grützmacher, D. Fabrication and characterization of three-dimensional InGaAs/GaAs nanosprings. Nano Lett. 6, 725-729 (2006).
25. Huang, T., Liu, Z., Huang, G., Liu, R. & Mei, Y. Grating-structured metallic microsprings. Nanoscale 6, 9428-9435 (2014).
26. Mei, Y., Thurmer, D. J., Deneke, C., Kiravittaya, S., Chen, Y. F., Dadgar, A., Bertram, F., Bastek, B., Krost, A., Christen, J., Reindl, T., Stoffel, M., Coric, E. & Schmidt, O. G. Fabrication, self-assembly, and properties of ultrathin AlN/GaN porous crystalline nanomembranes: tubes, spirals, and curved sheets. ACS Nano 3, 1663-1668 (2009).
27. Smith, E. J., Makarov, D., Sanchez, S., Fomin, V. M. & Schmidt, O. G. Magnetic microhelix coil structures. Phys. Rev. Lett. 107, 097204 (2011).
28. Schmidt, O. G., Deneke, C., Kiravittaya, S., Songmuang, R., Heidemeyer, H., Nakamura, Y., Zapf-Gottwick, R., Müller, C. & Jin-Phillipp, N. Y. Self-assembled nanoholes, lateral quantum-dot molecules, and rolled-up nanotubes. IEEE J. Select. Top. Quantum Electron. 8, 1025-1034 (2002).
29. Yang, Z., Zhang, Y., Itoh, T. & Maeda, R. Flexible implantable microtemperature sensor fabricated on polymer capillary by programmable UV lithography with multilayer alignment for biomedical applications. J. Microelectromech. Syst 23, 21-29 (2014).
30. Anacleto, P., Mendes, P., Gultepe, E. & Gracias, D. 3D small antenna for energy harvesting applications on implantable micro-devicesin Antennas and Propagation Conference (LAPC), 2012 Loughborough 1-4 IEEE, (2012).
31. Schmidt, O. G. & Eberl, K. Nanotechnology: Thin solid films roll up into nanotubes. Nature 410, 168 (2001).
32. Prinz, V. Y., Seleznev, V. A., Gutakovsky, A. K., Chehovskiy, A. V., Preobrazhenskii, V. V., Putyato, M. A. & Gavrilova, T. A. Free-standing and overgrown InGaAs/GaAs nanotubes, nanohelices and their arrays. Phys. E Low Dimens. Syst. Nanostruct 6, 828-831 (2000).
33. Luchnikov, V., Sydorenko, O. & Stamm, M. Self-rolled polymer and composite polymer/ metal micro- and nanotubes with patterned inner walls. Adv. Mater. 17, 1177-1182 (2005).
34. Bassik, N., Abebe, B. T., Laflin, K. E. & Gracias, D. H. Photolithographically patterned smart hydrogel based bilayer actuators. Polymer 51, 6093-6098 (2010).
35. Troyk, P. R. Injectable electronic identification, monitoring, and stimulation systems. Annu. Rev. Biomed. Eng. 1, 177-209 (1999).
36. Melzer, M., Karnaushenko, D., Lin, G., Baunack, S., Makarov, D. & Schmidt, O. G. Direct transfer of magnetic sensor devices to elastomeric supports for stretchable electronics. Adv. Mater. 27, 1333-1338 (2015).
37. Mei, Y. F., Huang, G., Solovev, A. A., Bermúdez-Ureña, E., Mönch, I., Die, F., Reindl, T., Fu, R. K. Y., Chu, P. K. & Schmidt, O. G. Adv. Mater. 20, 4085 (2008).
38. Bof Bufon, C. C., Gonzlez, J. D. C., Thurmer, D. J., Grimm, D., Bauer, M. & Schmidt, O. G. Self-assembled ultra-compact energy storage elements based on hybrid nanomembranes. Nano Lett. 10, 2506 (2010).
39. Grimm, D., Bof Bufon, C. C., Deneke, C., Atkinson, P., Thurmer, D. J., Schäffel, F., Gorantla, S., Bachmatiuk, A. & Schmidt, O. G. Rolled-up nanomembranes as compact 3D architectures for field effect transistors and fluidic sensing applications. Nano Lett. 13, 213 (2013).
40. Böttner, S., Li, S., Jorgensen, M. R. & Schmidt, O. G. Vertically aligned rolled-up SiO2 optical microcavities in add-drop configuration. Appl. Phys. Lett. 102, 251119 (2013).
41. Martinez-Cisneros, C. S., Sanchez, S., Xi, W. & Schmidt, O. G. Ultracompact threedimensional tubular conductivity microsensors for ionic and biosensing applications. Nano Lett. 14, 2219-2224 (2014).
42. Dastjerdi, M. H. T., Djavid, M. & Mi, Z. An electrically injected rolled-up semiconductor tube laser. Appl. Phys. Lett. 106, 021114 (2015).
43. Jamal, M., Zarafshar, A. M. & Gracias, D. H. Differentially photo-crosslinked polymers enable self-assembling microfluidics. Nature Commun 2, 527 (2011).
44. Bansal, R. in Handbook of Engineering Electromagnetics 259 (Springer Science & Business, 2004).
45. Slobozhanyuk, A., Lapine, M., Powell, D. A., Shadrivov, I. V., Kivshar, Y. S., McPhedran, R. C. & Belov, P. A. Flexible helices for nonlinear metamaterials. Adv. Mater. 25, 3409 (2013).
46. Yan, C., Xi, W., Si, W., Deng, J. & Schmidt, O. G. Highly conductive and strain-released hybrid multilayer Ge/Ti nanomembranes with enhanced lithium-ion-storage capability. Adv. Mater. 25, 539 (2013).
47. Deng, J., Ji, H., Yan, C., Zhang, J., Si, W., Baunack, S., Oswald, S., Mei, Y. & Schmidt, O. G. Naturally rolled-up C/Si/C trilayer nanomembranes as stable anodes for lithium-ion batteries with remarkable cycling performance. Angew. Chem. 125, 2382-2386 (2013).
48. Mönch, I., Makarov, D., Koseva, R., Baraban, L., Karnaushenko, D., Kaiser, C., Arndt, K. F. & Schmidt, O. G. Rolled-up magnetic sensor: nanomembrane architecture for in-flow detection of magnetic objects. ACS Nano 5, 7436 (2011).
49. Mei, Y., Solovev, A. A., Sanchez, S. & Schmidt, O. G. Rolled-up nanotech on polymers: from basic perception to self-propelled catalytic microengines. Chem. Soc. Rev. 40, 2109-2119 (2011).