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ORCIDTakeshi Hayakawa
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2020 – today
- 2025
[c31]Masato Higuchi, Takeshi Hayakawa:
Evaluation of a Dielectric Elastomer Actuator Made of an Organogel Fabricated by 3D Printing. SII 2025: 54-57- 2024
- [c30]Akito Watanabe, Yoshiyuki Yokoyama, Takeshi Hayakawa:
Evaluation of Permeability of Thermoresponsive Microgel Valves for Single-Cell Analysis Devices. CBS 2024: 1-4 - [c29]Xueping Yu, Takeshi Hayakawa:
Investigation of influence factors of embedded droplet printing for generation of cancer cell spheroids with controllable size. CBS 2024: 13-16 - 2023
- [c28]Kanji Kaneko, Mamiko Tsugane, Yosuke Hasegawa, Takeshi Hayakawa, Hiroaki Suzuki:
Experimental and Numerical Investigation of Particle Capture for Agglutination-Based NP detection Using the Vibration-Induced Flow. MHS 2023: 1-4 - [c27]Hiroyasu Kobayashi, Yuha Koike, Takeshi Hayakawa
:
High-speed cell rotation based on a vibration-induced flow designed by evaluations of vertical flow around microstructures. SII 2023: 1-4 - [c26]Yuta Tezuka, Asahi Tsujino, Takeshi Hayakawa:
Fabrication of a Spherical-Shape Dielectric Elastomer Actuator Made of an Organogel. SII 2023: 1-4 - [c25]Asahi Tsujino, Takeshi Hayakawa:
Analysis of Dynamic Characteristics of a Balloon-Type Dielectric Elastomer Actuator Pre-Stretched by Water Pressure. SII 2023: 1-4 - 2022
- [c24]Natsumi Hirata, Takeshi Hayakawa:
Acoustofluidic manipulation system with an open microfluidic chip. MHS 2022: 1 - [c23]Kyoka Nakano, Hiroki Wada, Yoshiyuki Yokoyama, Takeshi Hayakawa:
Lift-off Process of On-chip Micro-Gel Actuator for Cell Manipulations. MHS 2022: 1 - [c22]Hinako Sato, Yoshiyuki Yokoyama, Takeshi Hayakawa:
Driving of flagellated micro-gel robot by using light-scanning system. MHS 2022: 1 - [c21]Kanji Kaneko, Mamiko Tsugane, Taku Sato, Takeshi Hayakawa, Yosuke Hasegawa, Hiroaki Suzuki:
Detection of nanoparticles in a minute sample using the vibration induced flow. NEMS 2022: 151-156 - 2021
- [c20]Shunnosuke Kodera, Tomoki Watanabe, Yoshiyuki Yokoyama, Takeshi Hayakawa:
Laser Scanning Drive of the Peristaltic Micro-Gelrobot with Soft Rigid Hybrid Structures. SII 2021: 83-86 - 2020
- [j6]Kouhei Hattori, Takeshi Hayakawa, Akira Nakanishi, Mihoko Ishida, Hideaki Yamamoto, Ayumi Hirano-Iwata, Takashi Tanii:
Contribution of AMPA and NMDA receptors in the spontaneous firing patterns of single neurons in autaptic culture. Biosyst. 198: 104278 (2020) - [j5]Hiroki Wada, Yuha Koike, Yoshiyuki Yokoyama, Takeshi Hayakawa:
Evaluation of the Response Characteristics of On-Chip Gel Actuators for Various Single Cell Manipulations. IEEE Robotics Autom. Lett. 5(4): 5205-5212 (2020) - [c19]Takeshi Hayakawa, Yuki Arase:
Fine-Grained Error Analysis on English-to-Japanese Machine Translation in the Medical Domain. EAMT 2020: 155-164
2010 – 2019
- 2019
- [c18]Naoki Kitada, Takeshi Hayakawa:
Size Separation Method of Microparticles Based On Gravity-Aided Vibration-Induced Flow. MHS 2019: 1-2 - [c17]Natsumi Koike, Takeshi Hayakawa:
Fabrication of Transparent Soft Actuator toward Realizing Three-Dimensional Transparent Soft Actuator. MHS 2019: 1-2 - [c16]Yuha Koike, Yoshiyuki Yokoyama, Takeshi Hayakawa:
Massive-Integrated On-Chip Gel Actuators for Single Cell Manipulation. MHS 2019: 1-2 - [c15]Toshiyuki Matsui, Hiroaki Suzuki, Takeshi Hayakawa:
DESIGN AND EVALUATION OF MICROMIXIER WITH LOW DEAD VOLUME BASED ON VIBRATION-INDUCED FLOW. MHS 2019: 1-2 - 2018
- [j4]Takeshi Hayakawa, Hisataka Maruyama, Takafumi Watanabe, Fumihito Arai:
Three-Dimensional Blood Vessel Model with Temperature-Indicating Function for Evaluation of Thermal Damage during Surgery. Sensors 18(2): 345 (2018) - [c14]Naoki Kitada, Takeshi Hayakawa:
Size Separation Method of Microparticles Based on Vibration-Induced Flow. MHS 2018: 1-2 - [c13]Tomoki Watanabe, Yoshiyuki Yokoyama, Takeshi Hayakawa:
Fabrication of Micro-Gel Robot Having a Soft-Rigid Hybrid Structure. MHS 2018: 1-2 - 2017
- [c12]Takeshi Hayakawa, Fumihito Arai:
On-chip micromanipulation method based on mode switching of vibration-induced asymmetric flow. ICRA 2017: 6631-6636 - 2016
- [c11]Yusuke Kasai, Shinya Sakuma, Takeshi Hayakawa, Fumihito Arai:
High-speed on-chip local flow control by synchronized actuation of piezo-driven dual membrane pumps. MHS 2016: 1-2 - [c10]Yusei Someya, Seiji Omata, Takeshi Hayakawa, Mamoru Mitsuishi, Naohiko Sugita, Kanako Harada, Yasuo Noda, Takashi Ueta, Kiyoto Totsuka, Fumiyuki Araki, Hajime Aihara, Fumihito Arai:
Training system using Bionic-eye for internal limiting membrane peeling. MHS 2016: 1-3 - [c9]Takafumi Watanabe, Hisataka Maruyama, Takeshi Hayakawa, Fumihito Arai:
3D blood vessel model with temperature Indicator for evaluating thermal damage during surgery. MHS 2016: 1-3 - 2015
- [j3]Kou Nakahara, Shinya Sakuma, Takeshi Hayakawa, Fumihito Arai:
On-Chip Transportation and Measurement of Mechanical Characteristics of Oocytes in an Open Environment. Micromachines 6(5): 648-659 (2015) - [c8]Takeshi Hayakawa, Shinya Sakuma, Fumihito Arai:
On-chip cell transportation based on vibration-induced local flow in open chip environment. IROS 2015: 1409-1414 - [c7]Maki Kikukawa, Takeshi Hayakawa, Hisataka Maruyama, Fumihito Arai:
Cell adhesion control of optically-driven microtool using thermo-sensitive gel and laser heating. MHS 2015: 1-2 - [c6]Hisataka Maruyama, Takafumi Watanabe, Takeshi Hayakawa, Tomohisa Tanaka, Taisuke Masuda, Fumihito Arai:
Functional vessel model having temperature indicator for surgical simulator. MHS 2015: 1-3 - [c5]Kou Nakahara, Shinya Sakuma, Takeshi Hayakawa, Fumihito Arai:
Mechanical characterization of oocyte using an opened microchannel environment. MHS 2015: 1-3 - 2014
- [j2]Takeshi Hayakawa, Shinya Sakuma, Takeshi Fukuhara, Yoshiyuki Yokoyama, Fumihito Arai:
A Single Cell Extraction Chip Using Vibration-Induced Whirling Flow and a Thermo-Responsive Gel Pattern. Micromachines 5(3): 681-696 (2014) - [j1]Takeshi Hayakawa, Shota Fukada, Fumihito Arai:
Fabrication of an On-Chip Nanorobot Integrating Functional Nanomaterials for Single-Cell Punctures. IEEE Trans. Robotics 30(1): 59-67 (2014) - [c4]Takeshi Hayakawa, Shinya Sakuma, Fumihito Arai:
On-chip cell manipulation by vibration-induced whirling flow. MHS 2014: 1 - 2013
- [c3]Takeshi Hayakawa, Fumihito Arai:
Fabrication and manipulation of 3D hybrid nanorobot for single cell puncture. MHS 2013: 1-2 - 2012
- [c2]Takeshi Hayakawa, Hisataka Maruyama, Fumihito Arai:
High thermal conductive nano pillars for temperature distribution measurement of a single cell. MHS 2012: 488-490
2000 – 2009
- 2008
- [c1]Hayato Omori, Takeshi Hayakawa, Taro Nakamura:
Locomotion and turning patterns of a peristaltic crawling earthworm robot composed of flexible units. IROS 2008: 1630-1635
Coauthor Index
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