Clinical research

IIS aims at organizing closer collaborative research system and establishing medical-engineering research and education system with Swiss Federal Institute of Technology in Lausanne which conducts advanced biotechnology research by applying MEMS censor, ultra-precision machining technology and polymer soft materials. In particular, we conduct research on minimally invasive diagnostic devices for various infections　and development of medical devices required in response to the paradigm shift from treatment to preventive medicine, focusing on development of wearable devices for detecting infectious disease-causing pathogens at the point-of-care.

Publications

2019

1. Meng Su, Juergen Brugger and Beomjoon Kim: Simply Structured Wearable Triboelectric Nanogenerator Based on a Hybrid Composition of Carbon Nanotubes and Polymer Layer, Journal of Precision Engineering and Manufacturing-Green Technology (IJPEM-GT), 2020, Vol.7, pp.683–698, https://link.springer.com/article/10.1007/s40684-020-00212-8

2020

2. Saeko Tachikawa, Jose Ordonez-Miranda, Yunhui Wu, Laurent Jalabert, Roman Anufriev, Sebastian Volz and Masahiro Nomura: High Surface Phonon-Polariton in-Plane Thermal Conductance along Coupled Films, Nanomaterials, 2020, 1383, doi:10.3390/nano10071383
3. Meng Su and Beomjoon Kim: Silk Fibroin-Carbon Nanotube Composites based Fiber Substrated Wearable Triboelectric Nanogenerator, ACS Applied Nano Materials, 2020, 3, pp.9759−9770, https://doi.org/10.1021/acsanm.0c01854
4. Marc Bescond and Kazuhiko Hirakawa: High-Performance Thermionic Cooling Devices Based on Tilted-Barrier Semiconductor Heterostructures, Physical Review Applied, 2020, 14, 064022, https://doi.org/10.1103/PhysRevApplied.14.064022
5. Denis Damiron, Pierre E. Allain, Dai Kobayashi, Naruo Sasaki and Hideki Kawakatsu: Bottom-tracking – the possibilities and physical meaning of keeping the bottom of the frequency shift in atomic force microscopy, Japanese Journal of Applied Physics, 2020, 59, SN1012, https://doi.org/10.35848/1347-4065/ab9231
6. Kobayashi and H. Kawakatsu: High slew rate circuit for high rigidity friction-drive, Japanese Journal of Applied Physics, 2020, 59, SN1008, https://doi.org/10.35848/1347-4065/ab8871

2021

7. Libo Wu, Jongho Park, Yuto Kamaki and Beomjoon Kim: Optimization of the fused deposition modeling-based fabrication process for polylactic acid microneedles, Microsystems & Nanoengineeing, 2021, 7:58
8. Leilei Bao, Jongho Park, Gwenaël Bonfante, Beomjoon Kim: Recent advances in porous microneedles: materials, fabrication, and transdermal applications, Drug Delivery and Translational Research, 2021, 12(2), pp.395–414, DOI:10.1007/s13346-021-01045-x
9. Kai Takeuchi, Nobuyuki Takama, Kirti Sharma, Oliver Paul, Patrick Ruther, Tadatomo Suga, Beomjoon Kim: Microfluidic chip connected to porous microneedle array for continuous ISF sampling, Drug Delivery and Translational Research, 2021, Vol. 12, pp.435–443
10. Natalie P. Holmes, Sylvain Chambon, Alexandre Holmes, Xiaoxue Xu, Kazuhiko Hirakawa, Elise Deniau, Christine Lartigau-Dagron and Antoine Bousquet: Organic semiconductor colloids: From the knowledge acquired in photovoltaics to the generation of solar hydrogen fuel, Current Opinion in Colloid & Interface Science, 2021, 56:101511
11. Xiangyu Zhu, Marc Bescond, Toshiki Onoue, Gerald Bastard, Francesca Carosella, Robson Ferreira, Naomi Nagai, and Kazuhiko Hirakawa: Electron Transport in Double-Barrier Semiconductor Heterostructures for Thermionic Cooling, Physical Review Applied, 2021, 16, 064017-1~11
12. Marc Bescond, Guillaume Dangoisse, Xiangyu Zhu, Chloé Salhani and Kazuhiko Hirakawa: Comprehensive Analysis of Electron Evaporative Cooling in Double-Barrier Semiconductor Heterostructures, Physical Review Applied, 2022, 17, 014001

2022

13. Tachikawa, J. Ordonez-Miranda, Y. Wu, L. Jalabert, R. Anufriev, S. Volz and M. Nomura: In-plane surface phonon-polariton thermal conduction in dielectric multilayer systems, Applied Physics Letters, 2022, 121, 202202, pp.1-5, doi: 10.1063/5.0117081
14. Sebastian Volz, Masahiro Nomura and Jose Ordonez-Miranda: Resonant Polariton Thermal Transport Along a Vacuum Gap, Physical Review Applied, 2022, 18, L051003, pp.1-5
15. Jose Ordonez‑Miranda, Maelie Coral, Masahiro Nomura, Sebastian Volz: Resonant Thermal Transport Driven by Surface Phonon‑Polaritons in a Cylindrical Cavity, International Journal of Thermophysics, 2023, 44:73, pp.1-9

2023~

16. Roman Anufriev, Daisuke Ohori, Yunhui Wu, Ryoto Yanagisawa, Laurent Jalabert, Seiji Samukawa, Masahiro Nomura: Impact of nanopillars on phonon dispersion and thermal conductivity of silicon membranes, Nanoscale, 2023, Vol.15, pp2248-2253
17. Jose Ordonez-Miranda, Yuriy A. Kosevich, Bong Jae Lee, Masahiro Nomura, Sebastian Volz: Plasmon Thermal Conductance and Thermal Conductivity of Metallic Nanofilms, Physical Review Applied, 2023, Vol.19, Iss.4, 044046
18. Jose Ordonez-Miranda, Laurent Jalabert, Yunhui Wu, Sebastian Volz, Masahiro Nomura: Analytical integration of the heater and sensor 3ω signals of anisotropic bulk materials and thin films, Journal of Applied Physics, 2023, Vol.133, Iss.20, 205104, doi:10.1063/5.0151725
19. Jose Ordonez-Miranda, Yuriy A. Kosevich, Masahiro Nomura, Sebastian Volz: Long-range, short-wavelength, and ultrafast heat conduction driven by three plasmon modes supported by graphene, Physical Review B, 2023, Vol.108, Iss.16, L161404
20. Saeko Tachikawa, Jose Ordonez-Miranda, Laurent Jalabert, Yunhui Wu, Roman Anufriev, Yangyu Guo, Byunggi Kim, Hiroyuki Fujita, Sebastian Volz, Masahiro Nomura, Enhanced Far-Field Thermal Radiation through a Polaritonic Waveguide, Physical Review Letters, 2024, Vol.132, Iss.18, 186904
21. Jose Ordonez-Miranda, Roman Anufriev, Masahiro Nomura, Sebastian Volz: Dimensional crossover in thermal radiation: From three- to two-dimensional heat transfer between metallic membranes, Physical Review Applied, 2024, Vol.22, L031006