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ORCIDKazuo Nakazato
Person information
- affiliation: Nagoya University, Japan
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2010 – 2019
- 2019
[j15]Kiichi Niitsu
, Taiki Nakanishi, Shunya Murakami, Maya Matsunaga, Atsuki Kobayashi, Karim Nissar Mohammad, Jun Ito, Naoya Ozawa, Tetsunari Hase, Hiromasa Tanaka, Mitsuo Sato, Hiroki Kondo, Kenji Ishikawa, Hidefumi Odaka, Yoshinori Hasegawa, Masaru Hori, Kazuo Nakazato:
A 65-nm CMOS Fully Integrated Analysis Platform Using an On-Chip Vector Network Analyzer and a Transmission-Line-Based Detection Window for Analyzing Circulating Tumor Cell and Exosome. IEEE Trans. Biomed. Circuits Syst. 13(2): 470-479 (2019)- [c27]Kiichi Niitsu, Taichi Sakabe, Mariko Miyachi, Yoshinori Yamanoi, Hiroshi Nishihara, Tatsuya Tomo, Kazuo Nakazato:
2D optical imaging using photosystem I photosensor platform with 32x32 CMOS biosensor array. ASP-DAC 2019: 7-8 - [c26]Kiichi Niitsu, Yuuki Yamaji, Atsuki Kobayashi, Kazuo Nakazato:
A low-voltage CMOS electrophoresis IC using electroless gold plating for small-form-factor biomolecule manipulation. ASP-DAC 2019: 11-12 - 2018
- [j14]Kiichi Niitsu, Atsuki Kobayashi, Yuya Nishio, Kenya Hayashi, Kei Ikeda, Takashi Ando, Yudai Ogawa, Hiroyuki Kai, Matsuhiko Nishizawa, Kazuo Nakazato:
A Self-Powered Supply-Sensing Biosensor Platform Using Bio Fuel Cell and Low-Voltage, Low-Cost CMOS Supply-Controlled Ring Oscillator With Inductive-Coupling Transmitter for Healthcare IoT. IEEE Trans. Circuits Syst. I Regul. Pap. 65-I(9): 2784-2796 (2018) - [c25]Atsuki Kobayashi, Yuya Nishio, Kenya Hayashi, Kazuo Nakazato, Kiichi Niitsu:
A 350-mV, under-200-ppm allan deviation floor gate-leakage-based timer using an amplifier-less replica-bias switching technique in 55-nm DDC CMOS. CICC 2018: 1-4 - [c24]Kiichi Niitsu, Taichi Sakabe, Mariko Miyachi, Yoshinori Yamanoi, Hiroshi Nishihara, Tatsuya Tomo, Kazuo Nakazato:
Demonstration of 2D Optical Imaging Using Photosystem I Photosensor Platform with 3232 CMOS Biosensor Array. NEWCAS 2018: 104-108 - 2017
- [j13]Yuuki Yamaji, Kazuo Nakazato, Kiichi Niitsu:
Sub-1-V CMOS-Based Electrophoresis Using Electroless Gold Plating for Small-Form-Factor Biomolecule Manipulation. IEICE Trans. Electron. 100-C(6): 592-596 (2017) - [j12]Kei Ikeda, Atsuki Kobayashi, Kazuo Nakazato, Kiichi Niitsu:
Design and Analysis of Scalability in Current-Mode Analog-to-Time Converter for an Energy-Efficient and High-Resolution CMOS Biosensor Array. IEICE Trans. Electron. 100-C(6): 597-601 (2017) - [j11]Kohei Gamo, Kazuo Nakazato, Kiichi Niitsu:
A Current-Integration-Based CMOS Amperometric Sensor with 1024 × 1024 Bacteria-Sized Microelectrode Array for High-Sensitivity Bacteria Counting. IEICE Trans. Electron. 100-C(6): 602-606 (2017) - [j10]Atsuki Kobayashi, Kei Ikeda, Yudai Ogawa, Hiroyuki Kai, Matsuhiko Nishizawa, Kazuo Nakazato, Kiichi Niitsu:
Design and Experimental Verification of a 0.19 V 53 μW 65 nm CMOS Integrated Supply-Sensing Sensor With a Supply-Insensitive Temperature Sensor and an Inductive-Coupling Transmitter for a Self-Powered Bio-sensing System Using a Biofuel Cell. IEEE Trans. Biomed. Circuits Syst. 11(6): 1313-1323 (2017) - [c23]Kei Ikeda, Atsuki Kobayashi, Kazuo Nakazato, Kiichi Niitsu:
A scalable time-domain biosensor array using logarithmic cyclic time-attenuation-based TDC for high-resolution and large-scale bio-imaging. ASP-DAC 2017: 11-12 - [c22]Kohei Gamo, Kazuo Nakazato, Kiichi Niitsu:
A current-integration-based CMOS amperometric sensor with 1.2 μm × 2.05 μm electroless-plated microelectrode array for high-sensitivity bacteria counting. ASP-DAC 2017: 19-20 - [c21]Atsuki Kobayashi, Kei Ikeda, Yudai Ogawa, Matsuhiko Nishizawa, Kazuo Nakazato, Kiichi Niitsu:
Design of an energy-autonomous bio-sensing system using a biofuel cell and 0.19V 53μW integrated supply-sensing sensor with a supply-insensitive temperature sensor and inductive-coupling transmitter. ASP-DAC 2017: 25-26 - [c20]Taiki Nakanishi, Maya Matsunaga, Atsuki Kobayashi, Kazuo Nakazato, Kiichi Niitsu:
A fully-integrated circulating tumor cell analyzer using an on-chip vector network analyzer and a transmission-line-based detection window in 65-nm CMOS. BioCAS 2017: 1-4 - [c19]Takeshi Shimizu, Masaki Tanaka, Kazuo Nakazato:
Live demonstration: BCT-II - A hand-held, stand-alone, multimodal bio-sensing system. BioCAS 2017: 1 - [c18]Eizo Ushijima, Satoshi Fujimoto, Kiichi Niitsu, Kazuo Nakazato:
Application of magnetic arrangement of microbeads for CMOS biosensor array sensitivity. BioCAS 2017: 1-4 - [c17]Maya Matsunaga, Taiki Nakanishi, Atsuki Kobayashi, Kazuo Nakazato, Kiichi Niitsu:
Three-dimensional millimeter-wave frequency-shift-based CMOS biosensor using vertically stacked LC oscillators. NORCAS 2017: 1-6 - 2016
- [j9]Kiichi Niitsu, Tsuyoshi Kuno, Masayuki Takihi, Kazuo Nakazato:
Well-Shaped Microelectrode Array Structure for High-Density CMOS Amperometric Electrochemical Sensor Array. IEICE Trans. Electron. 99-C(6): 663-666 (2016) - [c16]Kiichi Niitsu, Atsuki Kobayashi, Yudai Ogawa, Matsuhiko Nishizawa, Kazuo Nakazato:
Design of an energy-autonomous, disposable, supply-sensing biosensor using bio fuel cell and 0.23-V 0.25-µm zero-Vth all-digital CMOS supply-controlled ring oscillator with inductive transmitter. ASP-DAC 2016: 23-24 - [c15]Kei Ikeda, Atsuki Kobayashi, Kazuo Nakazato, Kiichi Niitsu:
Live demonstration: Current-mode analog-to-time converter for a large scale CMOS biosensor array. BioCAS 2016: 131 - [c14]Kohei Gamo, Kazuo Nakazato, Kiichi Niitsu:
Live demonstration: Noise-immune current-integration-based CMOS amperometric sensor platform with 1.2 μm × 2.05μm electroless-plated microelectrode array for robust bacteria counting. BioCAS 2016: 132 - [c13]Atsuki Kobayashi, Kei Ikeda, Yudai Ogawa, Matsuhiko Nishizawa, Kazuo Nakazato, Kiichi Niitsu:
An energy-autonomous bio-sensing system using a biofuel cell and 0.19V 53μW 65nm-CMOS integrated supply-sensing sensor with a supply-insensitive temperature sensor and inductive-coupling transmitter. BioCAS 2016: 148-151 - [c12]Kei Ikeda, Atsuki Kobayashi, Kazuo Nakazato, Kiichi Niitsu:
A current-mode analog-to-time converter with short-pulse output capability using local intra-cell activation for high-speed time-domain biosensor array. NORCAS 2016: 1-6 - 2015
- [j8]Kiichi Niitsu, Shoko Ota, Kohei Gamo, Hiroki Kondo, Masaru Hori, Kazuo Nakazato:
Development of Microelectrode Arrays Using Electroless Plating for CMOS-Based Direct Counting of Bacterial and HeLa Cells. IEEE Trans. Biomed. Circuits Syst. 9(5): 607-619 (2015) - [c11]Kohei Gamo, Kiichi Niitsu, Kazuo Nakazato:
Noise-immune current-integration-based CMOS amperometric sensor platform with 1.2 μm × 2.05 μm electroless-plated microelectrode array for robust bacteria counting. BioCAS 2015: 1-4 - [c10]Kiichi Niitsu, Atsuki Kobayashi, Yudai Ogawa, Matsuhiko Nishizawa, Kazuo Nakazato:
An energy-autonomous, disposable, big-data-based supply-sensing biosensor using bio fuel cell and 0.23-V 0.25-μm Zero-Vth all-digital CMOS supply-controlled ring oscillator with inductive transmitter. BioCAS 2015: 1-4 - 2014
- [j7]Yoshiro Riho, Kazuo Nakazato:
A new extension method of retention time for memory cell on dynamic random access memory. Integr. 47(3): 329-338 (2014) - [j6]Yoshiro Riho, Kazuo Nakazato:
Partial Access Mode: New Method for Reducing Power Consumption of Dynamic Random Access Memory. IEEE Trans. Very Large Scale Integr. Syst. 22(7): 1461-1469 (2014) - [c9]Shoko Ota, Kiichi Niitsu, Hiroki Kondo, Masaru Hori, Kazuo Nakazato:
Live demonstration: A CMOS sensor platform with 1.2 µm × 2.05 µm electroless-plated 1024 × 1024 microelectrode array for high-sensitivity rapid direct bacteria counting. BioCAS 2014: 185 - [c8]Hayato Komori, Kiichi Niitsu, Junko Tanaka, Yu Ishige, Masao Kamahori, Kazuo Nakazato:
Live demonstration: An extended-gate CMOS sensor array with enzyme-immobilized microbeads for redox-potential glucose detection. BioCAS 2014: 191 - [c7]Shoko Ota, Kiichi Niitsu, Hiroki Kondo, Masaru Hori, Kazuo Nakazato:
A CMOS sensor platform with 1.2 µm × 2.05 µm electroless-plated 1024 × 1024 microelectrode array for high-sensitivity rapid direct bacteria counting. BioCAS 2014: 460-463 - [c6]Hayato Komori, Kiichi Niitsu, Junko Tanaka, Yu Ishige, Masao Kamahori, Kazuo Nakazato:
An extended-gate CMOS sensor array with enzyme-immobilized microbeads for redox-potential glucose detection. BioCAS 2014: 464-467 - [c5]Yoshiro Riho, Kazuo Nakazato:
A new DRAM architecture and its control method for the system power consumption. ACM Great Lakes Symposium on VLSI 2014: 187-192 - [c4]Masayuki Takihi, Kiichi Niitsu, Kazuo Nakazato:
Charge-conserved analog-to-time converter for a large-scale CMOS biosensor array. ISCAS 2014: 33-36 - 2013
- [j5]Tatsuhiro Numata, Shigeyasu Uno, Kazuo Nakazato:
Circuit simulation model for ultimately-scaled ballistic nanowire MOSFETs. IEICE Electron. Express 10(1): 20120906 (2013) - [c3]Yoshiro Riho, Kazuo Nakazato:
A new extension method of retention time for memory cell on dynamic random access memory. ACM Great Lakes Symposium on VLSI 2013: 149-154 - 2012
- [c2]Boram Kim, Kazuo Nakazato:
Dual data pulse width modulator for wireless Simultaneous Measurement of Redox Potential and Temperature using a Single RFID Chip. ICECS 2012: 368-371 - [c1]Kazuo Nakazato:
BioCMOS LSIs for portable gene-based diagnostic inspection system. ISCAS 2012: 2287-2290 - 2010
- [j4]Shigeyasu Uno, Junichi Hattori, Kazuo Nakazato, Nobuya Mori:
Form factor increase and its physical origins in electron-modulated acoustic phonon interaction in a free-standing semiconductor plate. Math. Comput. Model. 51(7-8): 863-872 (2010) - [j3]Junichi Hattori, Shigeyasu Uno, Nobuya Mori, Kazuo Nakazato:
Universality in electron-modulated-acoustic-phonon interactions in a free-standing semiconductor nanowire. Math. Comput. Model. 51(7-8): 880-887 (2010)
2000 – 2009
- 2009
- [j2]Kazuo Nakazato:
An Integrated ISFET Sensor Array. Sensors 9(11): 8831-8851 (2009) - 2008
- [j1]Kazuo Nakazato, Mitsuo Ohura, Shigeyasu Uno:
CMOS Cascode Source-Drain Follower for Monolithically Integrated Biosensor Array. IEICE Trans. Electron. 91-C(9): 1505-1515 (2008)
Coauthor Index
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