Journal & Conference Publications

 

2022

1.     K. Chen, X. Tang, B. Jia, C. Chao, J. Hou, L. Dong, Y. Wei, T. Xiao, K. Goda, and L. Guo, “Graphene oxide bulk material reinforced by heterophase platelets with multiscale interface crosslinking”, Nature Materials 21, 1121 (2022)

2.     M. Herbig, A. Isozaki, D. Di Carlo, J. Guck, N. Nitta, H. Shintaku, A. Wu, I. Nikaido, S. Kamikawaji, E. Suyama, R. Damoiseaux, and K. Goda, “Best practices for reporting throughput in biomedical research”, Nature Methods 19, 633 (2022)

3.     K. Hiramatsu, T. Tajima, and K. Goda, “Ultrafast, dual-band coherent Raman spectroscopy without ultrashort pulses”, ACS Photonics doi.org/10.1021/acsphotonics.2c00768 (2022)

4.     L. Liu, S. Noguchi, T. Xiao, S. Karhadkar, K. Hiramatsu, H. Segawa, T. Itoh, J. Qu, K. Takei, and K. Goda, “Highly scalable, wearable surface-enhanced Raman spectroscopy”, Advanced Optical Materials doi.org/10.1002/adom.202200054 (2022)

5.     M. Lindley, J. Gala de Pablo, W. Peterson, A. Isozaki, K. Hiramatsu, K. Goda, “High-throughput Raman-activated cell sorting in the fingerprint region”, Advanced Materials Technologies doi.org/10.1002/admt.202101567 (2022)

6.     W. Peterson, J. Gala de Pablo, M. Lindley, K. Hiramatsu, and K. Goda, “Ultrafast impulsive Raman spectroscopy across the THz-fingerprint region”, Advanced Photonics 4, 016003 (2022)

7.     K. Huang, H. Matsumura, Y. Zhao, M. Herbig, D. Yuan, Y. Mineharu, J. Harmon, J. Findinier, M. Yamagishi, S. Ohnuki, N. Nitta, A. Grossman, Y. Ohya, H. Mikami, A. Isozaki, and K. Goda, “Deep imaging flow cytometry”, Lab on a Chip 22, 876 (2022)

8.     Y. Deng, J. A. Duque, C. Su, Y. Zhou, M. Nishikawa, T. Xiao, Y. Yatomi, H. W. Hou, and K. Goda, “Understanding stenosis-induced platelet aggregation on a chip by high-speed optical imaging”, Sensors and Actuators B: Chemical 356, 131318 (2022)

9.     Y. Zhao, A. Isozaki, M. Herbig, M. Hayashi, K. Hiramatsu, S. Yamazaki, N. Kondo, S. Ohnuki, Y. Ohya, N. Nitta, and K. Goda, “Intelligent sort-timing prediction for image-activated cell sorting”, Cytometry Part A doi.org/10.1002/cyto.a.24664 (2022)

10.  Y. Zhou, M. Nishikawa, H. Kanno, R. Yang, Y. Ibayashi, T. Xiao, W. Peterson, N. Nitta, S. Miyata, Y. Kanthi, G. K. Rohde, K. Moriya, Y. Yatomi, and K. Goda, “Long-term effects of Pfizer-BioNTech COVID-19 vaccinations on platelets”, Cytometry Part A doi.org/10.1002/cyto.a.24677 (2022)

11.  J. Harmon, J. Findinier, N. T. Ishii, M. Herbig, A. Isozaki, A. Grossman, and K. Goda, “Intelligent image-activated cell sorting by mitochondrial relocation”, Cytometry Part A doi.org/10.1002/cyto.a.24661 (2022)

12.  P. M. Pancorbo, H. Zhang, X. Yu, T. Xiao, and K. Goda, “Metal-free SERS: where we are now, where we are heading”, Europhysics Letters 136, 34001 (2022)

13.  D. Wang, X. Yuang, Y. Weng, S. Wei, K. Goda, S. Liu, and C. Lei, “Ultrafast imaging for uncovering laser-material interaction dynamics”, International Journal of Mechanical System Dynamics doi.org/10.1002/msd2.12024 (2022)

14.  Y. Zhou, H. Kanno, M. Nishikawa, T. Xiao, K. Moriya, Y. Yatomi, and K. Goda, “Analysis of platelet aggregation by optofluidic imaging”, Journal of the Imaging Society of Japan (2022) in press

15.  H. Kanno, M. Nishikawa, Y. Zhou, T. Xiao, T. Suzuki, Y. Ibayashi, J. Harmon, S. Takizawa, K. Hiramatsu, N. Nitta, R. Kameyama, W. Peterson, J. Takiguchi, M. Shifat-E-Rabbi, Y. Zhuang, X. Yin, A. H. M. Rubaiyat, Y. Deng, H. Zhang, S. Miyata, G. K. Rohde, W. Iwasaki, Y. Yatomi, and K. Goda, “Analyzing circulating platelet aggregates in patients with COVID-19 by massive image-based single-cell profiling”, 化学とマイクロ・ナノシステム学会誌 21, 1 (2022)

16.  K. Goda, “計画的セレンディピティが医学・創薬を革新する!”, 医学のあゆみ 282, 23252 (2022)

17.  K. Hiramatsu and K. Goda, “先端光技術で藻類バイオスクリーニング”, 遺伝 76, 450 (2022)

18.  K. Goda and K. Hiramatsu, “High-speed biophotonics with a dual-comb source”, レーザー学会学術講演会第42回年次大会, Osaka, Japan (2022)

19.  Y. Deng, J. A. Duque, C. Su, Y. Zhou, M. Nishikawa, T. Xiao, Y. Yatomi, H. W. Hou, and K. Goda, “Studying vascular stenosis by high-throughput optical microscopy on a chip”, SPIE Photonics West, San Francisco, USA (2022)

20.  W. Peterson, M. Lindley, J. Gala de Pablo, K. Hiramatsu, and K. Goda, “THz-fingerprint coherent Raman spectroscopy at over 20,000 spectra/sec”, SPIE Photonics West, San Francisco, USA (2022)

21.  T. Xiao, N. Chen, Z. Luo, Y. Kitahama, K. Hiramatsu, N. Kishimoto, T. Itoh, Z. Cheng, and K. Goda, “Porous carbon nanowires for plasmon-free SERS”, SPIE Photonics West, San Francisco, USA (2022)

22.  T. Xiao, Z. Luo, K. Hiramatsu, A. Isozaki, T. Itoh, Z. Cheng, M. Nomura, S. Iwamoto, and K. Goda, “Chiral-field-enhanced Raman optical activity by a silicon nanodisk array”, SPIE Photonics West, San Francisco, USA (2022)

23.  K. Goda, “Raman image-activated cell sorting and beyond”, SPIE Photonics West, San Francisco, USA (2021)

24.  K. Goda, “従来SERSからの脱却:金属フリーSERSとウェアラブルSERS”, 18回プラズモニクスシンポジウム, Osaka, Japan (2022)

25.  A. Isozaki and K. Goda, “画像と深層学習で広がるフローサイトメトリーの応用”, 日本サイトメトリー学会, Tokyo, Japan (2022)

26.  M. Herbig, J. Harmon, J. Findinier, N. Ishii, A. Isozaki, A. R. Grossman, and K. Goda, “High-throughput image-activated cell soring by mitochondrial relocation”, CYTO, Philadelphia, USA (2022)

27.  M. Herbig, A. Isozaki, D. Di Carlo, J. Guck, N. Nitta, R. Damoiseaux, S. Kamikawaji, E. Suyama, H. Shintaku, A. R. Wu, I. Nikaido, and K. Goda, “A standardized metric for throughput for cytometry”, CYTO, Philadelphia, USA (2022)

28.  M. Herbig, K. Huang, H. Matsumura, Y. Zhao, D. Yuan, Y. Mineharu, J. Harmon, J. Findinier, M. Yamagishi, S. Ohnuki, N. Nitta, A. R. Grossman, Y. Ohya, H. Mikami, A. Isozaki, and K. Goda, “Resolution-enhanced imaging flow cytometry by deep learning”, CYTO, Philadelphia, USA (2022)

29.  Y. Deng, J. A. Deque, C. Su, Y. Zhou, M. Nishikawa, T. Xiao, Y. Yatomi, H. W. Hou, and K. Goda, “Uncovering the pathogenesis and treatment of atherosclerosis by high-throughput microscopy”, CYTO, Philadelphia, USA (2022)

30.  H. Matsumura, L. Shen, A. Isozaki, H. Mikami, D. Yuan, M. Herbig, Y. Kondo, T. Mori, Y. Kusumoto, M. Nishikawa, Y. Yatomi, S. Matsusaka, and K. Goda, “Detection and characterization of circulating tumor cell clusters by optomechanical imaging flow cytometry”, CYTO, Philadelphia, USA (2022)

31.  M. Lindley, J. Gala de Pablo, J. W. Peterson, A. Isozaki, K. Hiramatsu, and K. Goda, “Broadband fingerprint-region Raman-activated cell sorting at 50 cells per second”, CYTO, Philadelphia, USA (2022)

32.  R. Nishiyama, K. Hiramatsu, S. Kawamura, K. Dodo, K. Furuya, J. Gala de Pablo, S. Takizawa, W. Min, M. Sodeoka, and K. Goda, “Multiplex flow cytometry with Raman tags”, CYTO, Philadelphia, USA (2022)

33.  Y. Zhou, M. Nishikawa, H. Kanno, T. Xiao, Y. Yatomi, and K. Goda, “Uncovering the pathogenesis of microvascular thrombosis in COVID-19 via high-throughput microscopy on a chip”, CYTO, Philadelphia, USA (2022)

34.  K. Goda, “Ultrafast imaging in flow”, SPIE Photonics Europe, Strasbourg, France (2022)

35.  K. Hiramatsu and K. Goda, “Ultrabroadband time-domain Raman spectroscopy using synchronized mode-locked lasers”, SPIE Photonics Europe, Strasbourg, France (2022)

36.  T. Kobayashi, M. Xu, J. Harmon, R. Shakhmatov, A. Isozaki, and K. Goda, “高速イメージングフローサイトメトリーによるユーグレナ細胞の形態と重金属の除去効率の関係性解明”, 化学とマイクロ・ナノシステム学会, Tokyo, Japan (2022)

37.  Y. Zhao, A. Isozaki, M. Herbig, M. Hayashi, K. Hiramatsu, S. Yamazaki, N. Kondo, S. Ohnuki, Y. Ohya, N. Nitta, and K. Goda, “Machine learning-based sort-timing prediction for image-activated cell sorting”, 化学とマイクロ・ナノシステム学会, Tokyo, Japan (2022)

38.  J. Harmon, F. Findinier, N. Ishii, M. Herbig, A. Isozaki, A. R. Grossman, and K. Goda, “Intelligent image-activated cell sorting based on complex intracellular morphology”, 化学とマイクロ・ナノシステム学会, Tokyo, Japan (2022)

39.  J. Dong, T. Xiao, and K. Goda, “光共振器の真空状態を介した振動強結合による光合成エネルギー移動プロセスの制御”, 量子生命科学会第4回大会, Kobe, Japan (2022)

40.  Y. Kitahama, L. Liu, P. M. Pancorbo, T. Xiao, S. Noguchi, M. Marumi, J. Gala de Pablo, S. Karhadkar, K. Hiramatsu, H. Segawa, T. Itoh, J. Qu, K. Takei, and K. Goda, “ウェアラブル量子センサーの実現に向けた金ナノメッシュによる表面増強ラマン散乱”, 量子生命科学会第4回大会, Kobe, Japan (2022)

41.  M. Nishikawa, H. Kanno, Y. Zhou, T. Xiao, N. Nitta, Y. Yatomi, and K. Goda, “COVID-19における血小板凝集塊の大規模イメージング解析”, 日本血栓止血学会学術集会, Sendai, Japan (2022)

42.  Y. Zhou, Y. Deng, J. A. Duque, C. Su, M. Nishikawa, T. Xiao, Y. Yatomi, H. W. Hou, and K. Goda, “オンチップ血管狭窄と高速イメージングを用いた血小板凝集の統計解析”, 日本血栓止血学会学術集会, Sendai, Japan (2022)

43.  Y. Zhou, Y. Nobori, M. Nishikawa, T. Xiao, M. Anraku, Y. Yatomi, and K. Goda, “アゴニストの種類による血小板凝集塊の分類:深層学習を用いた解析”, 日本血栓止血学会学術集会, Sendai, Japan (2022)

44.  Y. Nobori, M. Anraku, Y. Zhou, T. Xiao, K. Goda, M. Ono, and J. Nakajima, “人工臓器回路内血栓の早期発見に向けた循環血小板凝集塊の有用性の検討”, 日本血栓止血学会学術集会, Sendai, Japan (2022)

45.  T. Tamura, P. McCann, K. Hiramatsu, and K. Goda, “蛍光エンコーディングによる高感度時間領域ラマン分光,” 分子化学討論会, Tokyo, Japan (2022)

46.  Y. Zhou, M. Nishikawa, H. Kanno, R. Yang, T. Xiao, Y. Yatomi, and K. Goda, “mRNA COVID-19ワクチン接種の血小板への長期的影響”, 23回日本検査血液学会学術集会, Tokyo, Japan (2022)

47.  M. Nishikawa, H. Kanno, Y. Zhou, R. Yang, K. Ono, T. Xiao, N. Nitta, Y. Yatomi, and K. Goda, “播種性血管内凝固症候群における循環血小板凝集塊の解析”, 23回日本検査血液学会学術集会, Tokyo, Japan (2022)

48.  H. Kanno, C. Zhang, M. Herbig, Y. Zhou, M. Nishikawa, R. Yang, Y. Ibayashi, T. Xiao, Y. Yatomi, and K. Goda, “血小板凝集塊の大規模画像解析による血栓症とCOVID-19関連血栓症のアルゴリズム分類”, 23回日本検査血液学会学術集会, Tokyo, Japan (2022)

49.  R. Shakhmatov, R. Taira, M. Nogawa, M. Herbig, S. Miyata, T. Xiao, and K. Goda, “高速流体イメージングと機械学習を用いた血小板製剤中の細菌の検出”, 23回日本検査血液学会学術集会, Tokyo, Japan (2022)

50.  P. McCann, K. Hiramatsu, and K. Goda, “Fluorescence-encoded time-domain coherent Raman spectroscopy”, International Conference on Raman Spectroscopy, Long Beach, USA (2022)

51.  R. Nishiyama, K. Hiramatsu, K. Dodo, S. Kawamura, W. Min, M. Sodeoka, and K. Goda, “Super-multiplex flow cytometry with cyanine-based Raman tags”, International Conference on Raman Spectroscopy, Long Beach, USA (2022)

52.  K. Hiramatsu, M. Lindley, K. Yamada, K. Suzuki, and K. Goda, “Label-free characterization of rare-cell populations by high-throughput Raman flow cytometry”, International Conference on Raman Spectroscopy, Long Beach, USA (2022)

53.  A. Matsumoto, C. Zhang, A. Isozaki, K. Goda, Y. Toyoshima, and Y. Iino, “Investigating how worms integrate sensory and motor information in salt klinotaxis,” CeNeuro, Vienna, Austria (2022

54.  T. Xiao, Z. Luo, K. Hiramatsu, A. Isozaki, T. Itoh, Z. Cheng, M. Nomura, S. Iwamoto, and K. Goda, “On-chip chiral-field-enhanced Raman optical activity for biosensing”, CLEO Pacific Rims, Sapporo, Japan (2022)

55.  M. Marumi, K. Hiramatsu, L. Liu, P. M. Pancorbo, T. Xiao, S. Noguchi, J. Gala de Pablo, S. Karhadkar, K. Hiramatsu, H. Segawa, Y. Kitahama, T. Itoh, J. Qu, K. Takei, and K. Goda, “Gold nanomesh for wearable SERS”, International Conference on Raman Spectroscopy, Long Beach, USA (2022)

56.  T. Xiao, K. Hiramatsu, N. Chen, Z. Luo, Y. Kitahama, N. Kishimoto, T. Itoh, Z. Cheng, and K. Goda, “Porous carbon nanowires for metal-free SERS”, International Conference on Raman Spectroscopy, Long Beach, USA (2022)

57.  S. Takizawa, K. Hiramatsu, S. Ono, and K. Goda, “High-speed time-domain coherent Raman spectral imaging with compressed sensing”, International Conference on Raman Spectroscopy, Long Beach, USA (2022)

 

2021

1.     M. Nishikawa, H. Kanno, Y. Zhou, T. Xiao, T. Suzuki, Y. Ibayashi, J. Harmon, S. Takizawa, K. Hiramatsu, N. Nitta, R. Kameyama, W. Peterson, J. Takiguchi, M. Shifat-E-Rabbi, Y. Zhuang, X. Yin, A. H. M. Rubaiyat, Y. Deng, H. Zhang, S. Miyata, G. K. Rohde, W. Iwasaki, Y. Yatomi, and K. Goda, “Massive image-based single-cell profiling reveals high levels of circulating platelet aggregates in patients with COVID-19”, Nature Communications 12, 7135 (2021)

2.     H. Koide, A. Okishima, Y. Hoshino, Y. Kamon, K. Yoshimatsu, K. Saito, I. Yamauchi, S. Ariizumi, Y. Zhou, T. Xiao, K. Goda, N. Oku, T. Asai, and K. J. Shea, “Synthetic hydrogel nanoparticles for sepsis therapy”, Nature Communications 12, 5552 (2021)

3.     T. Xiao, Z. Cheng, Z. Luo, A. Isozaki, K. Hiramatsu, T. Itoh, M. Nomura, S. Iwamoto, and K. Goda, “All-dielectric chiral-field-enhanced Raman optical activity”, Nature Communications 12, 3062 (2021)

4.     J. Gala de Pablo, M. Lindley, K. Hiramatsu, and K. Goda, “High-throughput Raman flow cytometry and beyond”, Accounts of Chemical Research 54, 2132 (2021)

5.     P. Cheng, X. Tian, W. Tang, J. Cheng, J. Bao, H. Wang, S. Zheng, Y. Wang, X. Wei, T. Chen, H. Feng, T. Xue, K. Goda, and H. He, “Direct control of store-operated calcium channels by ultrafast laser”, Cell Research 31, 758 (2021)

6.     Y. Zhou, A. Isozaki, A. Yasumoto, T. Xiao, Y. Yatomi, C. Lei, and K. Goda, “Intelligent platelet morphometry”, Trends in Biotechnology 39, 978 (2021)

7.     K. C. M. Lee, J. Guck, K. Goda, and K. K. Tsia, “Deep biophysical cytometry: prospects and challenges”, Trends in Biotechnology 39, 1249 (2021)

8.     R. Kameyama, S. Takizawa, K. Hiramatsu, and K. Goda, “Dual-comb coherent Raman spectroscopy with near 100% duty cycle”, ACS Photonics 8, 975 (2021)

9.     M. Xu, D. Yuan, S. Yan, C. Lei, K. Hiramatsu, J. Harmon, Y. Zhou, M. H. Loo, T. Hasunuma, A. Isozaki, and K. Goda, “Morphological indicator of Euglena gracilis with a high heavy metal removal efficiency”, Environmental Science and Technology 55, 7880 (2021)

10.  P. C. McCann, K. Hiramatsu, and K. Goda, “Highly sensitive low-frequency time-domain Raman spectroscopy via fluorescence-encoding”, Journal of Physical Chemistry Letters 12, 7859 (2021)

11.  Y. Nakagawa, S. Ohnuki, N. Kondo, K. Itto, F. Ghanegolmohammadi, A. Isozaki, Y. Ohya, and K. Goda, “Are droplets really suitable for single-cell analysis? A case study on yeast in droplets”, Lab on a Chip 21, 3793 (2021)

12.  R. Bekdash, J. R. Quejada, S. Ueno, F. Kawano, K. Morikawa, U. Mahesh, R. Avula, E. Wan, S. L. Lee, K. Nakanishi, A. Chalan, T. Lee, R. Liu, S. Homma, S. O. Marx, K. Goda, and M. Yazawa, “GEM-IL: a highly responsive fluorescent lactate indicator”, Cell Reports Methods 1, 100092 (2021)

13.  M. H. Loo, Y. Nakagawa, A. Isozaki, and K. Goda, “High-throughput sorting of nanoliter droplets enabled by a sequentially addressable dielectrophoretic array”, Electrophoresis 43, 477 (2021)

14.  M. Lindley, J. Gala de Pablo, R. Kinegawa, K. Hiramatsu, and K. Goda, “Highly sensitive Fourier-transform coherent anti-Stokes Raman scattering spectroscopy via genetic algorithm pulse shaping”, Optics Letters 46, 4320 (2021)

15.  A. Isozaki, D. Huang, Y. Nakagawa, and K. Goda, “Dual sequentially addressable dielectrophoretic array for high-throughput, scalable, multiplexed droplet sorting”, Microfluidics and Nanofluidics 25, 32 (2021)

16.  M. Li, H. Liu, S. Zhuang, and K. Goda, “Droplet flow cytometry for single-cell analysis”, RSC Advances 11, 20944 (2021)

17.  J. P. Houston, K. Goda, and A. Filby, “CYTO Virtual”, Cytometry Part A 99, 127 (2021)

18.  K. Goda, “科学の成長モデルの変化と今後の展望”, 光学 50, 216 (2021)

19.  A. Isozaki, N. Nitta, T. Sugimura, and K. Goda, “画像活性セルソーター:画像情報に基づく生きた細胞の高速分取法”, 実験医学増刊 39, 198 (2021)

20.  Y. Zhou, H. Kanno, T. Xiao, R. Shakhmatov, Y. Ibayashi, M. Nishikawa, Y. Yatomi, and K. Goda, “COVID-19の診断補助に向けたタイムストレッチ・イメージング”, レーザー研究 49, 228 (2021)

21.  K. Hiramatsu and K. Goda, “バイオイメージング極秘ファイル:展望”, Optronics 12 (2021)

22.  K. Goda, T. Itoh, and T. Xiao, “多孔性炭素ナノワイヤを用いた金属フリーの表面増強ラマン分光法”, 光技術動向調査報告書 (2021)

23.  K. Tsia and K. Goda, “High-speed biomedical imaging and spectroscopy VI”, SPIE Proceedings 11654 (2021)

24.  P. McCann, K. Hiramatsu, and K. Goda, “Super-sensitive Raman spectroscopy through time-domain fluorescence-encoding”, Pacifichem, Hawaii, USA (2021)

25.  J. Harmon, J. Findinier, A. Isozaki, A. Grossman, and K. Goda, “Deep learning based classification of Chlamydomonas reinhardtii displaying mitochondrial repositioning”, Pacifichem, Hawaii, USA (2021)

26.  K. Hiramatsu, M. Lindley, J. Gala de Pablo, A. Isozaki, and K. Goda, “High-throughput vibrational flow cytometry and cell sorting in the fingerprint region”, Pacifichem, Hawaii, USA (2021)

27.  J. Gala de Pablo, M. Lindley, K. Hiramatsu, A. Isozaki, and K. Goda, “Label-free single-cell metabolic phenotyping by coherent vibrational flow cytometry”, Pacifichem, Hawaii, USA (2021)

28.  H. Matsumura, L. T.-W. Shen, H. Mikami, A. Isozaki, D. Yuan, T. Miura, Y. Kusumoto, M. Nishikawa, A. Yasumoto, T. Yamada, F. Ueda, H. Bando, H. Hara, Y. Yatomi, S. Matsusaka, and K. Goda, “High-throughput on-chip imaging of diverse cancer cells in blood”, Pacifichem, Hawaii, USA (2021)

29.  W. Peterson, M. Lindley, J. Gala de Pablo, K. Hiramatsu, and K. Goda, “Sensitive low-frequency coherent Raman spectroscopy at 24,000 spectra/sec by Sagnac interferometry”, Pacifichem, Hawaii, USA (2021)

30.  Y. Nakagawa, S. Ohnuki, N. Kondo, A. Isozaki, Y. Ohya, and K. Goda, “微小液滴によるSaccharomyces cerevisiaeの培養と高速分取”, 酵母遺伝学フォーラム第54回研究報告会, Okazaki, Japan (2021)

31.  M. Lindley, J. Gala de Pablo, R. Kinegawa, K. Hiramatsu, and K. Goda, “Genetic algorithm pulse shaping for sensitivity enhancement in Fourier-transform coherent anti-Stokes Raman scattering spectroscopy”, 46回レーザ顕微鏡研究会&シンポジウム, Virtual, Japan (2021)

32.  Y. Nobori, M. Anraku, Y. Zhou, T. Xiao, K. Goda, S. Kinoshita, H. Kimura, Y. Ono, and J. Nakajima, “左室補助人工心臓装着症例における循環微小血栓検出の有用性の検討”, 59回日本人工臓器学会総会, Tokyo, Japan (2021)

33.  S. Noguchi, T. Inoue, X. Tang, N. Hashimoto, N. Shinoda, T. Xiao, N. Chen, M. Atobe, and K. Goda, “生体量子計測に向けたカーボンSERS基盤の開発”, 量子生命科学会第3回大会, Tokyo, Japan (2021)

34.  S. Karhadkar, T. Xiao, and K. Goda, “全誘電体スーパーセルへのオンチップ振動強結合”, 量子生命科学会第3回大会, Tokyo, Japan (2021)

35.  J. Dong, T. Xiao, and K. Goda, “多重波動共鳴による光合成エネルギー伝達の操作”, 量子生命科学会第3回大会, Tokyo, Japan (2021)

36.  M. Hayashi, N. T. Ishii, J. Harmon, T. Araki, S. Ohnuki, N. Kondo, A. Isozaki, Y. Ohya, and K. Goda, “Image-activated sorting of genetically perturbed yeast towards image-based pooled screens”, MicroTAS, Palm Springs, USA (2021)

37.  Y. Nakagawa, S. Ohnuki, N. Kondo, A. Isozaki, Y. Ohya, and K. Goda, “Reassessing microdroplets as a platform for single-cell analysis”, MicroTAS, Palm Springs, USA (2021)

38.  N. T. Ishii, T. Wakamiya, T. Araki, M. Hayashi, H. Matsumura, K. Kita, Y. Okamoto, M. Yanagida, A. Isozaki, and K. Goda, “High-throughput intelligent image-activated sorting of antigen-localizing T cells”, MicroTAS, Palm Springs, USA (2021)

39.  J. Gala de Pablo, M. Lindley, A. Isozaki, K. Hiramatsu, W. Peterson, K. Ishii, A. Tomoko, and K. Goda, “High-throughput Raman flow cytometry for directed evolution”, SciX, Rhode Island, USA (2021)

40.  K. Hiramatsu and K. Goda, “Raman spectroscopy and imaging of single cells in flow”, SciX, Rhode Island, USA (2021)

41.  Y. Zhou, A. Yasumoto, M. Nishikawa, Y. Nobori, T. Xiao, M. Anraku, Y. Yatomi, and K. Goda, “Real-time monitoring of blood clots in extracorporeal life support by intelligent platelet aggregate characterizer”, SPIE Photonics West, Virtual, USA (2021)

42.  M. Xu, J. Harmon, T. Hasunuma, A. Isozaki, and K. Goda, “AI on a chip for identifying microalgal cells with high heavy metal removal efficiency”, Transducers, Virtual (2021)

43.  Y. Nakagawa, S. Ohunuki, N. Kondo, A. Isozaki, Y. Ohya, and K. Goda, “Reevaluating the cell conditions in droplets: the effect of droplet size on cell morphology”, 化学とマイクロ・ナノシステム学会, Virtual, Japan (2021)

44.  H. Matsumura, L. T.-W. S., H. Mikami, A. Isozaki, D. Yuan, T. Miura, K. Kusumoto, M. Nishikawa, A. Yasumoto, Y. Yatomi, S. Matsusaka, and K. Goda, “高速蛍光イメージングフローサイトメトリーによるがん細胞の検出”, 化学とマイクロ・ナノシステム学会, Virtual, Japan (2021)

45.  K. Huang, A. Isozaki, H. Matsumura, D. Yuan, Y. Mineharu, J. Harmon, J. Findinier, M. Yamagishi, N. Nitta, A. Grossman, H. Mikami, and K. Goda, “Deep-learning-based image restoration for imaging flow cytometry”, 化学とマイクロ・ナノシステム学会, Virtual, Japan (2021)

46.  J. W. Peterson, K. Hiramatsu, and K. Goda, “High-speed low-frequency vibrational spectroscopy using a Sagnac interferometer”, 68回応用物理学会春季学術講演会, Online, Japan (2021)

47.  R. Kameyama, S. Takizawa, K. Hiramatsu, and K. Goda, “High-speed coherent Raman spectroscopy with a quasi-dual-comb source”, 68回応用物理学会春季学術講演会, Online, Japan (2021)

48.  R. Kameyama, S. Takizawa, K. Hiramatsu, and K. Goda, “Quasi-dual-comb source opens new avenues for rapid spectroscopy”, 10th Advanced Lasers and Photon Sources, Online, Japan (2021)

49.  P. McCann, K. Hiramatsu, and K. Goda, “Fluorescence-encoded time-domain coherent Raman spectroscopy through single-photon counting”, SPIE Photonics West, Virtual, USA (2021)

50.  R. Kameyama, S. Takizawa, K. Hiramatsu, and K. Goda, “Fast, sensitive dual-comb CARS spectroscopy with a quasi-dual-comb laser”, SPIE Photonics West, Virtual, USA (2021)

51.  R. Kinegawa, J. Gala de Pablo, Y. Wang, K. Hiramatsu, and K. Goda, “Four-wave mixing and second-harmonic generation imaging flow cytometry”, 82回応用物理学会春季学術講演会, Online, Japan (2021)

52.  M. Matsumoto, Y. Toyoshima, C. Zhang, A. Isozaki, K. Goda, and Y. Iino, “線虫の塩走性における感覚運動統合と行動制御の神経機構の解明”, 日本分子生物学会, Yokohama, Japan (2021)

53.  M. Lindley, J. Gala de Pablo, A. Isozaki, K. Hiramatsu, and K. Goda, “High-throughput Raman-activated on-chip cell sorting”, International Symposium on Micro-NanoMechatronics and Human Science, Virtual, Tokyo (2021)

54.  P. C. McCann, K. Hiramatsu, and K. Goda, “Fluorescence-encoded time-domain coherent Raman spectroscopy”, 日本分光学会年次講演会, Online, Japan (2021)

55.  S. Takizawa, K. Hiramatsu, and K. Goda, “Compressed Fourier-transform spectral imaging: A simulation study”, 日本分光学会年次講演会, Online, Japan (2021)

56.  W. Peterson, J. Gala de Pablo, M. Lindley, K. Hiramatsu, and K. Goda, “Ultra-rapid impulsive Raman spectroscopy of the low-frequency and fingerprint regions by synchronous detection of probe phase delay and frequency shift”, 日本分光学会年次講演会, Online, Japan (2021)

57.  K. Hiramatsu, N. Chen, T. Xiao, Z. Luo, Y. Kitahama, N. Kishimoto, T. Itoh, Z. Cheng, and K. Goda, “Porous carbon nanowires for plasmon-free SERS”, 日本分光学会年次講演会, Online, Japan (2021)

58.  K. Hiramatsu, T. Xiao, Z. Luo, A. Isozaki, T. Itoh, Z. Cheng, M. Nomura, S. Iwamoto, and K. Goda, “Chiral-field-enhanced Raman optical activity by a silicon nanodisk array”, 日本分光学会年次講演会, Online, Japan (2021)

59.  Y. Nakagawa, M. H. Loo, A. Isozaki, and K. Goda, “An electrode array and slanted microchannel: strategies for enhancing throughputs of large-droplet sorting”, 化学とマイクロ・ナノシステム学会第44回研究会, Virtual, Japan (2021)

60.  K. Huang, H. Matsumura, Y. Zhao, M. Herbig, D. Yuan, Y. Mineharu, J. Harmon, M. Yamagishi, S. Ohnuki, N. Nitta, Y. Ohya, H. Mikami, A. Isozaki, and K. Goda, “Deep-learning-based image restoration for imaging flow cytometry and its applications”, 化学とマイクロ・ナノシステム学会第44回研究会, Virtual, Japan (2021)

61.  H. Matsumura, T.-W. Shen, H. Mikami, A. Isozaki, D. Yuan, Y. Kusumoto, M. Nishikawa, T. Yamada, A. Ueda, H. Bando, H. Hara, Y. Yatomi, S. Matsusaka, and K. Goda, “蛍光イメージングフローサイトメトリーによる血中循環腫瘍細胞の検出”, 化学とマイクロ・ナノシステム学会第44回研究会, Virtual, Japan (2021)

 

2020

1.     N. Chen, T. Xiao, Z. Luo, Y. Kitahama, K. Hiramatsu, N. Kishimoto, T. Ito, Z. Cheng, and K. Goda, “Porous carbon nanowire array for surface-enhanced Raman spectroscopy”, Nature Communications 11, 4772 (2020)

2.     N. Nitta, T. Iino, A. Isozaki, M. Yamagishi, Y. Kitahama, S. Sakuma, Y. Suzuki, H. Tezuka, M. Oikawa, F. Arai, T. Asai, D. Deng, H. Fukuzawa, M. Hase, T. Hasunuma, T. Hayakawa, K. Hiraki, K. Hiramatsu, Y. Hoshino, M. Inaba, Y. Inoue, T. Ito, M. Kajikawa, H. Karakawa, Y. Kasai, Y. Kato, H. Kobayashi, C. Lei, S. Matsusaka, H. Mikami, A. Nakagawa, K. Numata, T. Ota, T. Sekiya, K. Shiba, Y. Shirasaki, N. Suzuki, S. Tanaka, S. Ueno, H. Watarai, T. Yamano, M. Yazawa, Y. Yonamine, D. Di Carlo, Y. Hosokawa, S. Uemura, T. Sugimura, Y. Ozeki, and K. Goda, “Raman image-activated cell sorting”, Nature Communications 11, 3452 (2020)

3.     H. Mikami, M. Kawaguchi, C.-J. Huang, H. Matsumura, T. Sugimura, K. Huang, C. Lei, S. Ueno, T. Miura, T. Ito, K. Nagasawa, T. Maeno, H. Watarai, M. Yamagishi, S. Uemura, S. Ohnuki, Y. Ohya, H. Kurokawa, S. Matsusaka, C.-W. Sun, Y. Ozeki, and K. Goda, “Virtual-freezing fluorescence imaging flow cytometry”, Nature Communications 11, 1162 (2020)

4.     A. Isozaki, Y. Shibata, N. Tanaka, D. L. Setyaningrum, Y. Nakagawa, M. H. Loo, J. Park, Y. Shirasaki, D. Huang, C. Riche, H. Tsoi, T. Ota, H. Miwa, Y. Kanda, T. Ito, K. Yamada, O. Iwata, K. Suzuki, Y. Kato, T. Hasunuma, S. Matsusaka, M. Yamagishi, M. Yazawa, S. Uemura, K. Nagasawa, H. Watarai, D. Di Carlo, and K. Goda, “Sequentially addressable dielectrophoretic array for high-throughput sorting of large-volume biological compartments”, Science Advances 6, eaba6712 (2020)

5.     Y. Zhou, A. Yasumoto, C. Lei, C.-J. Huang, H. Kobayashi, Y. Wu, S. Yan, C.-W. Sun, Y. Yatomi, and K. Goda, “Intelligent classification of platelet aggregates by agonist type”, eLife 9, e52938 (2020)

6.     A. Isozaki, J. Harmon, Y. Zhou, S. Li, Y. Nakagawa, M. Hayashi, H. Mikami, C. Lei, and K. Goda, “AI on a chip”, Lab on a Chip 20, 3074 (2020)

7.     A. Isozaki, H. Mikami, H. Tezuka, H. Matsumura, K. Huang, M. Akamine, K. Hiramatsu, T. Iino, T. Ito, H. Karakawa, Y. Kasai, Y. Li, Y. Nakagawa, S. Ohnuki, T. Ota, Y. Qian, S. Sakuma, T. Sekiya, Y. Shirasaki, N. Suzuki, E. Tayyabi, T. Wakamiya, M. Xu, M. Yamagishi, H. Yan, Q. Yu, S. Yan, D. Yuan, W. Zhang, Y. Zhao, F. Arai, R. E. Campbell, C. Danelon, D. Di Carlo, K. Hiraki, Y. Hoshino, Y. Hosokawa, M. Inaba, A. Nakagawa, Y. Ohya, M. Oikawa, S. Uemura, Y. Ozeki, T. Sugimura, N. Nitta, and K. Goda, “Intelligent image-activated cell sorting 2.0”, Lab on a Chip 20, 2263 (2020)

8.     H. Yan, Y. Wu, Y. Zhou, M. Xu, P. Paie, C. Lei, S. Yan, and K. Goda, “Virtual optofluidic time-stretch quantitative phase imaging”, APL Photonics 5, 046103 (2020)

9.     K. Goda, B. Jalali, C. Lei G. Situ, and P. Westbrook, “AI boosts photonics and vice versa”, APL Photonics 5, 070401 (2020)

10.  K. Goda, G. Popescu, K. Tsia, D. Psaltis, “Computational optical imaging goes viral”, APL Photonics 5, 030401 (2020)

11.  K. Hiramatsu, K. Yamada, M. Lindley, K. Suzuki, and K. Goda, “Large-scale label-free single-cell analysis of paramylon in Euglena gracilis by high-throughput broadband Raman flow cytometry”, Biomedical Optics Express 11, 1752 (2020)

12.  S. Takizawa, K. Hiramatsu, and K. Goda, “Compressed time-domain coherent Raman spectroscopy with real-time random sampling”, Vibrational Spectroscopy 107, 103042 (2020)

13.  H. Kanno, H. Mikami, and K. Goda, “High-speed single-pixel imaging by frequency-time-division multiplexing”, Optics Letters 45, 2339 (2020)

14.  Y. Weng, G. Wu, L. Mei, Q. Wang, K. Goda, S. Liu, and C. Lei, “Temporally interleaved optical time-stretch imaging”, Optics Letters 45, 2387 (2020)

15.  Y. Wu, Y. Zhou, C.-J. Huang, H. Kobayashi, S. Yan, Y. Ozeki, Y. Wu, C.-W. Sun, A. Yasumoto, Y. Yatomi, C. Lei, and K. Goda, “Intelligent frequency-shifted optofluidic time-stretch quantitative phase imaging”, Optics Express 28, 519 (2020)

16.  T. Saiki, T. Hosobata, Y. Kono, M. Takeda, A. Ishijima, M. Tamamitsu, Y. Kitagawa, K. Goda, S. Morita, S. Ozaki, K. Motohara, Y. Yamagata, K. Nakagawa, and I. Sakuma, “Sequentially timed all-optical mapping photography boosted by a branched 4f system with a slicing mirror”, Optics Express 28, 31914 (2020)

17.  Y. Weng, L. Mei, G. Wu, S. Chen, B. Zhan, K. Goda, S. Liu, and C. Lei, “Analysis of signal detection configurations in optical time-stretch imaging”, Optics Express 28, 29272 (2020)

18.  Y. Yonamine, K. Hiramatsu, T. Ideguchi, T. Ito, T. Fujiwara, Y. Miura, K. Goda, and Y. Hoshino, “Spatiotemporal monitoring of intracellular metabolic dynamics by resonance Raman microscopy with stable isotope labeling”, RSC Advances 10, 16679 (2020)

19.  J. Harmon, H. Mikami, H. Kanno, T. Ito, and K. Goda, “Accurate classification of microalgae by intelligent frequency-division-multiplexed fluorescence imaging flow cytometry”, OSA Continuum 3, 430 (2020)

20.  K. Goda, “Quantum light and quantum life: understanding quantum-biological phenomena by quantum technology”, Optronics 8, 54 (2020)

21.  A. Nakagawa, N. Nitta, T. Sugimura, A. Isozaki, Y. Ozeki, and K. Goda, “インテリジェント画像活性細胞選抜法 医療・生命科学分野への展開”, 医学のあゆみ 273, 20524 (2020)

22.  K. Tsia and K. Goda, “High-speed biomedical imaging and spectroscopy V”, SPIE Proceedings 11250 (2020)

23.  N. Nitta, Y. Suzuki, K. Goda, and Y. Ozeki, “Multicolor Raman imaging flow cytometry”, CYTO Virtual (2020)

24.  A. Isozaki, H. Mikami, H. Tezuka, H. Matsumura, K. Huang, Y. Ozeki, T. Sugimura, N. Nitta, and K. Goda, “iIACS2.0: intelligent image-activated cell sorting upgraded”, CYTO Virtual (2020)

25.  A. Isozaki, Y. Nakagawa, M. H. Loo, D. Di Carlo, and K. Goda, “Sequentially addressable dielectrophoretic array for high-throughput droplet sorting”, CYTO Virtual (2020)

26.  Y. Zhou, A. Yasumoto, C. Lei, C.-J. Huang, H. Kobayashi, Y. Wu, S. Yan, C.-W. Sun, Y. Yatomi, and K. Goda, “Intelligent platelet biology: characterizing platelets by deep learning”, CYTO Virtual (2020)

27.  K. Goda “Vibrational flow cytometry and beyond”, CYTO Virtual (2020)

28.  M. Xu, D. Yuan, S. Yan, C. Lei, K. Hiramatsu, J. Harmon, Y. Zhou, M. H. Loo, T. Hasunuma, A. Isozaki, and K. Goda, “A cellular morphological indicator toward directed evolution of microalgae for highly efficient wastewater treatment”, 化学とマイクロ・ナノシステム学会, Virtual, Japan (2020)

29.  H. Matsumura, A. Isozaki, Y. Zhao, K. Huang, T. Wakamiya, D. Yuan, H. Mikami, S. Ohnuki, S. Uemura, Y. Ohya, and K. Goda, “出芽酵母の大規模な遺伝子解析のための高スループット細胞形態分取法”, 化学とマイクロ・ナノシステム学会, Virtual, Japan (2020)

30.  D. Yuan, J. Gala de Pablo, M. Lindley, M. H. Loo, M. Hayashi, Y. Zhao, K. Hiramatsu, A. Isozaki, and K. Goda, “Viscoelastic-fluid-based single-particle analyzer with Fourier-transform coherent anti-Stokes Raman scattering spectroscopy”, 化学とマイクロ・ナノシステム学会, Virtual, Japan (2020)

31.  Y. Nakagawa, S. Ohnuki, A. Isozaki, N. Kondo, Y. Ohya, and K. Goda, “Exploring the advantage of large droplets for single-cell analysis”, 化学とマイクロ・ナノシステム学会, Virtual, Japan (2020)

32.  H. Kanno, H. Mikami, and K. Goda, “High-throughput FLIM flow cytometry”, CYTO Virtual (2020)

33.  M. H. Loo, Y. Nakagawa, A. Isozaki, and K. Goda, “High-throughput sorting of nanoliter droplets using an electrode array with a slanted microchannel”, MicroTAS Virtual (2020)

34.  Y. Zhou, A. Yasumoto, M. Nishikawa, Y. Nobori, Y. Wang, M. Anraku, Y. Yatomi, and K. Goda, “Intelligent on-chip analysis of thrombosis in ECMO with a goat model”, MicroTAS Virtual (2020)

35.  J. Gala, M. Lindley, K. Hiramatsu, A. Isozaki, and K. Goda, “Vibrational flow cytometry on a chip: a label-free tool for metabolic phenotyping”, MicroTAS Virtual (2020)

36.  R. Kameyama, K. Hiramatsu, and K. Goda, “繰り返し周波数変調による高速コヒーレントラマン分光法”, 分子科学会, Virtual, Japan (2020)

37.  S. Noguchi, T. Xiao, and K. Goda, “バンドエンジニアリングによる光合成過程中の振動を利用した電荷移動の制御”, 量子生命科学会第2回大会, Virtual, Japan (2020)

38.  T. Xiao and K. Goda, “キラルな生体分子における振動状態の縮退の観察”, 量子生命科学会第2回大会, Virtual, Japan (2020)

39.  K. Goda, Y. Ozeki, K. Hiramatsu, and Y. Suzuki, “High-throughput vibrational flow cytometry and beyond”, SPIE Photonics West BIOS, San Francisco, USA (2020)

40.  H. Kanno, A. Tamang, H. Mikami, K. Goda, and S. D. Evans, “Cell membrane poration by hydrodynamic stretching of live cells”, SPIE Photonics West BIOS, San Francisco, USA (2020)

41.  H. Kanno, H. Mikami, and K. Goda, “Ultrafast fluorescence lifetime imaging microscopy by frequency-division-multiplexing”, SPIE Photonics West BIOS, San Francisco, USA (2020)

42.  W. Peterson, K. Hiramatsu, and K. Goda, “Highly sensitive low-frequency Raman spectroscopy enabled by Sagnac-enhanced impulsive stimulated Raman scattering”, SPIE Photonics West BIOS, San Francisco, USA (2020)

43.  K. Hiramatsu and K. Goda, “High-throughput vibrational flow cytometry”, SPIE Photonics West BIOS, San Francisco, USA (2020)

44.  M. Lindley, K. Hiramatsu, F. Shibata, T. Takeshita, S. Kawano, and K. Goda, “High-throughput multimodal Raman-fluorescence flow cytometry”, SPIE Photonics West BIOS, San Francisco, USA (2020)

45.  Y. Zhou, A. Yasumoto, C. Lei, C.-J. Huang, H. Kobayashi, Y. Wu, S. Yan, C.-W. Sun, Y. Yatomi, and K. Goda, “Classification of platelet aggregates by intelligent imaging flow cytometry”, SPIE Photonics West BIOS, San Francisco, USA (2020)

46.  H. Kobayashi, C. Lei, C.-J. Huang, A. Yasumoto, M. Jona, W. Li, Y. Yalikun, B. Guo, C.-W. Sun, Y. Tanaka, M. Yamada, Y. Yatomi, and K. Goda, “Simple, rapid, and cost-effective drug-susceptibility testing of leukemia by intelligent whole-blood imaging flow cytometry”, SPIE Photonics West BIOS, San Francisco, USA (2020)

47.  K. Goda, “AI cell sorting”, SPIE Photonics West BIOS, San Francisco, USA (2020)

 

2019

1.     A. Isozaki, H. Mikami, K. Hiramatsu, S. Sakuma, Y. Kasai, T. Iino, T. Yamano, A. Yasumoto, Y. Oguchi, N. Suzuki, Y. Shirasaki, T. Endo, T. Ito, K. Hiraki, M. Yamada, S. Matsusaka, T. Hayakawa, H. Fukuzawa, Y. Yatomi, F. Arai, D. Di Carlo, A. Nakagawa, Y. Hoshino, Y. Hosokawa, S. Uemura, T. Sugimura, Y. Ozeki, N. Nitta, and K. Goda, “A practical guide to intelligent image-activated cell sorting”, Nature Protocols 14, 2370 (2019)

2.     K. Hiramatsu, T. Ideguchi, Y. Yonamine, S. Lee, Y. Luo, K. Hashimoto, T. Ito, M. Hase, J. Park, Y. Kasai, S. Sakuma, T. Hayakawa, F. Arai, Y. Hoshino, and K. Goda, “High-throughput label-free molecular fingerprinting flow cytometry”, Science Advances 5, eaau0241 (2019)

3.     Y. Suzuki, K. Kobayashi, Y. Wakisaka, D. Deng, Y. Fujiwaki, H. Liu, S. Tanaka, C.-J. Huang, C. Lei, S. Lee, A. Isozaki, Y. Kasai, T. Hayakawa, S. Sakuma, F. Arai, K. Koizumi, H. Tezuka, M. Inaba, K. Hiraki, T. Ito, M. Hase, S. Matsusaka, K. Shiba, K. Suga, M. Nishikawa, M. Jona, Y. Yatomi, Y. Yaxiaer, Y. Tanaka, T. Sugimura, N. Nitta, K. Goda, and Y. Ozeki, “Label-free chemical imaging flow cytometry by high-speed multicolor stimulated Raman scattering”, PNAS 116, 15842 (2019)

4.     M. Lindley, K. Hiramatsu, H. Nomoto, F. Shibata, T. Takeshita, S. Kawano, and K. Goda, “Ultrafast simultaneous Raman-fluorescence spectroscopy”, Analytical Chemistry 91, 15563 (2019)

5.     A. Cossarizza et al, “Guidelines for the use of flow cytometry and cell sorting in immunological studies (second edition)”, European Journal of Immunology 49, 1457 (2019)

6.     H. Kobayashi, C. Lei, Y. Wu, C.-J. Huang, A. Yasumoto, M. Jona, W. Li, Y. Yaxiaer, Y. Jiang, B. Guo, C.-W. Sun, Y. Tanaka, M. Yamada, Y. Yatomi, and K. Goda, “Intelligent whole-blood imaging flow cytometry for simple, rapid, cost-effective drug-susceptibility testing of leukemia”, Lab on a Chip 19, 2688 (2019)

7.     T. Iino, S. W. Lee, K. Okano, H. Hagihara, T. Yamakawa, H. Z. Yi, T. Maeno, Y. Kasai, T. Hayakawa, S. Sakuma, F. Arai, K. Goda, and Y. Hosokawa, “High-speed microparticle isolation unlimited by Poisson statistics”, Lab on a Chip 19, 2669 (2019)

8.     K. Goda, “Biophotonics and beyond”, APL Photonics 4, 050401 (2019)

9.     H. Kanno, H. Mikami, Y. Kaya, Y. Ozeki, and K. Goda, “Simple, stable, compact implementation of frequency-division-multiplexed microscopy by inline interferometry“, Optics Letters 44, 467 (2019)

10.  W. Peterson, K. Hiramatsu, and K. Goda, “Sagnac-enhanced impulsive stimulated Raman scattering for highly sensitive low-frequency Raman spectroscopy”, Optics Letters 44, 5282 (2019)

11.  Y. Yalikun, N. Ota, B. Guo, T. Tang, Y. Zhou, C. Lei, H. Kobayashi, Y. Hosokawa, M. Li, H. E. Munoz, D. Di Carlo, K. Goda, and Y. Tanaka, “Effect of flow-induced microfluidic chip deformation on imaging flow cytometry”, Cytometry Part A 97, 909 (2019)

12.  F. Zhang, C. Lei, C.-J. Huang, H. Kobayashi, C.-W. Sun, and K. Goda, “Intelligent image de-blurring for imaging flow cytometry”, Cytometry Part A 95, 549 (2019)

13.  K. Goda, N. Nitta, and A. Filby, “In flow cytometry, image is everything”, Cytometry Part A 95, 475 (2019)

14.  N. Ota, Y. Yalikun, T. Suzuki, S. Lee, Y. Hosokawa, K. Goda, and Y. Tanaka, “Enhancement in acoustic focusing of micro and nanoparticles by thinning a microfluidic device”, Royal Society Open Science 6, 181776 (2019)

15.  D. Di Carlo, F. Arai, K. Goda, T. Huang, Y.-H. Lo, N. Nitta, Y. Ozeki, K. Tsia, S. Uemura, and K. Wong, “Comment on ghost cytometry”, Science 364, eaav1429 (2019)

16.  R. Kinegawa, K. Hiramatsu, K. Hashimoto, V. R. Badarla, T. Ideguchi, and K. Goda, “High-speed broadband Fourier-transform coherent anti-Stokes Raman scattering spectral microscopy”, Journal of Raman Spectroscopy 50, 1141 (2019)

17.  K. Goda, “Publicationの危機、解決へリーダーシップを”, Nature Digest 16, 20 (2019)

18.  K. Hiramatsu and K. Goda, “高速ラマン分光法を利用した細胞個性を無標識・大規模計測”, Bioscience & Industry 77, 308 (2019)

19.  K. Goda, “細胞検索エンジンが拓く新世界”, 応用物理 88, 522 (2019)

20.  D. Wu, H. Kobayashi, C. Ding, C. Lei, K. Goda, and M. Ghassemi, “Modeling the biological pathology continuum with HSIC-regularized Wasserstein auto-encoders”, 32nd Conference on Neural Information Processing Systems (2019)

21.  W. Zhao, C. Lei, H. Huang, K. Goda, and H. Chen, “A comparison of image recognition algorithms for cell phenotyping in optofluidic time-stretch microscopy”, SPIE Photonics Asia, Beijing, China, doi.org/10.1117/12.2537782 (2019)

22.  A. Isozaki, H. Mikami, K. Hiramatsu, and K. Goda, “高速蛍光イメージング・ラマン分光法と生物学・医学への展開”, オプトロニクス 9 (2019)

23.  K. Tsia and K. Goda, “High-speed biomedical imaging and spectroscopy IV”, SPIE Proceedings 10889 (2021)

24.  A. Isozaki, Y. Nakagawa, M. H. Loo, Y. Shibata, N. Tanaka, D. L. Setyaningrum, J.-W. Park, Y. Shirasaki, H. Mikami, S. Uemura, D. Di Carlo, and K. Goda, “電極アレイを用いた高速液滴分取”, 化学とマイクロ・ナノシステム学会, 18, 33 (2019)

25.  A. Isozaki, N. Nitta, T. Sugimura, H. Mikami, S. Sakuma, Y. Kasai, F. Arai, D. Di Carlo, Y. Hosokawa, S. Uemura, Y. Ozeki, and K. Goda, “インテリジェント画像活性細胞選抜法とその応用”, 化学とマイクロ・ナノシステム学会, Kanazawa, Japan (2019)

26.  K. Hiramatsu and K. Goda, “High-throughput Raman spectroscopic flow cytometry”, ANZNMF Symposium, Wollongong, Australia (2019)

27.  K. Goda, “Intelligent image-activated cell sorting”, ANZNMF Symposium, Wollongong, Australia (2019)

28.  Y. Ozeki, Y. Suzuki, and K. Goda, “Label-free multicolor imaging flow cytometry with stimulated Raman scattering”, 80回応用物理学会秋季学術講演会, Sapporo, Japan (2019)

29.  K. Hiramatsu, M. Lindley K. Yamada, K. Suzuki, and K. Goda, “Large-scale label-free single-cell analysis by vibrational flow cytometry”, 80回応用物理学会秋季学術講演会, Sapporo, Japan (2019)

30.  S. Takizawa, K. Hiramatsu, and K. Goda, “Time-domain coherent Raman spectroscopy with compressive sensing”, 80回応用物理学会秋季学術講演会, Sapporo, Japan (2019)

31.  A. Isozaki, N. Nitta, T. Sugimura, H. Mikami, S. Sakuma, Y. Kasai, F. Arai, D. Di Carlo, Y. Hosokawa, S. Uemura, Y. Ozeki, and K. Goda, “AI細胞選抜法”, 37回日本ロボット学会 学術講演会, Tokyo, Japan (2019)

32.  T. Iino, K. Okano, S. Lee, T. Yamakawa, H. Hagihara, H. Zhou-Yi, T. Maeno, Y. Kasai, S. Sakuma, T. Hayakawa, F. Arai, Y. Ozeki, K. Goda, and Y. Hosokawa, “High-speed sorting of microparticles using femtosecond laser pulses”, 80回応用物理学会秋季学術講演会, Sapporo, Japan (2019)

33.  M. Lindley, K. Hiramatsu, F. Shibata, T. Takeshita, S. Kawano, and K. Goda, “Simultaneous Raman-fluorescence flow cytometry”, 80回応用物理学会秋季学術講演会, Sapporo, Japan (2019)

34.  A. Isozaki, Y. Nakagawa, M. H. Loo, Y. Shibata, N. Tanaka, D. L. Setyaningrum, J. W. Park, Y. Shirasaki, H. Mikami, S. Uemura, D. Di Carlo, and K. Goda, “High-throughput droplet sorting with an electrode array”,  化学とマイクロ・ナノシステム学会, Hamamatsu, Japan (2019)

35.  Y. Ozeki, N. Nitta, T. Sugimura, A. Isozaki, H. Mikami, D. Di Carlo, Y. Hosokawa, S. Uemura, and K. Goda, “Intelligent image-activated cell sorting and beyond”, CLEO, San Jose, USA (2019)

36.  A. Yasumoto, N. Nitta, T. Sugimura, S. Uemura, Y. Ozeki, K. Goda, and Y. Yatomi, “High-throughput sorting of platelet aggregates by intelligent image-activated cell sorting”, Congress of the International Society on Thrombosis and Haemostasis, Melbourne, Australia (2019)

37.  T. Maeno, T. Uzawa, I. Kono, K. Okano, T. Iino, K. Fukita, Y. Oshikawa, T. Ogawa, O. Iwata, T. Ito, K. Suzuki, K. Goda, and Y. Hosokawa “Femtosecond laser photoporation of fluorogenic peptide aptamers for highly sensitive imaging of polysaccharides in Euglena gracilis”, The 8th International Congress on Laser Advanced Materials Processing, Hiroshima, Japan (2019)

38.  K. Goda, Y. Ozeki, N. Nitta, T. Sugimura, A. Isozaki, H. Mikami, D. Di Carlo, Y. Hosokawa, and S. Uemura, “AI cell sorting”, The 8th Advanced Lasers and Photon Sources (ALPS2019), Yokohama, Japan (2019)

39.  S. Yan, H. Yan, C. Lei, and K. Goda, “Single-step separation and identification of tumor cells in whole blood by time-stretch microscopy with a microfluidic cell sorter”, ANZNMF Symposium, Wollongong, Australia (2019)

40.  Y. Ozeki, H. Mikami, N. Nitta, T. Sugimura, A. Isozaki, D. Di Carlo, Y. Hosokawa, S. Uemura, and K. Goda, “インテリジェント画像活性細胞選抜法:基本原理と応用展開”, 66回応用物理学会春季学術講演会, Tokyo, Japan (2019)

41.  H. Kanno, H. Mikami, and K. Goda, “Ultrafast fluorescence lifetime imaging microscopy by frequency-division multiplexing”, 66回応用物理学会春季学術講演会, Tokyo, Japan (2019)

42.  J. W. Peterson, K. Hiramatsu, and K. Goda, “Time-domain Raman spectroscopy using a Sagnac interferometer”, 66回応用物理学会春季学術講演会, Tokyo, Japan (2019)

43.  H. Mikami, M. Kawaguchi, Y. Ozeki, and K. Goda, “Highly sensitive flow cytometry by virtual-freezing fluorescence imaging”, 66回応用物理学会春季学術講演会, Tokyo, Japan (2019)

44.  K. Hiramatsu, T. Ideguchi, Y. Yonamine, S. Lee, Y. Luo, K. Hashimoto, T. Ito, M. Hase, J. Park, Y. Kasai, S. Sakuma, T. Hayakawa, F. Arai, Y. Hoshino, and K. Goda, “High-throughput broadband Raman flow cytometry”, 日本化学会第99春季年会, Kobe, Japan (2019)

45.  H. Hiramatsu, N. Nitta, T. Sugimura, A. Isozaki, H. Mikami, D. Di Carlo, Y. Hosokawa, S. Uemura, Y. Ozeki, and K. Goda, “Intelligent image-activated cell sorting: principles and applications”, 日本化学会第99春季年会, Kobe, Japan (2019)

46.  Y. Hashimoto, T. Miura, H. Mikami, Y. Ozeki, and K. Goda, “High-speed, high-sensitivity imaging flow cytometry with a scanned line-focus excitation beam”, 日本化学会第99春季年会, Kobe, Japan (2019)

47.  K. Huang, R. Zhang, H. Mikami, Y. Ozeki, and K. Goda, “High-speed fluorescence imaging flow cytometry with oblique light-sheet excitation”, 日本化学会第99春季年会, Kobe, Japan (2019)

48.  Y. Nakagawa, M. H. Loo, D. L. Setyaningrum, K. Nagasawa, H. Watarai, A. Isozaki, and K. Goda, “High-throughput droplet sorting enhanced by an electrode array and its applications”, 日本化学会第99春季年会, Kobe, Japan (2019)

49.  M. H. Loo, Y. Nakagawa, A. Isozaki, and K. Goda, “An electrode-array-based high-throughput nano-liter-droplet sorter assisted by a slanted microchannel”, 日本化学会第99春季年会, Kobe, Japan (2019)

50.  H. Mikami, M. Kawaguchi, C.-J. Huang, C. Lei, S. Ueno, T. Miura, T. Ito, K. Nagasawa, T. Maeno, H. Watarai, C.-W. Sun, Y. Ozeki, and K. Goda, “Fluorescence imaging flow cytometry with ultrahigh sensitivity enabled by virtual motion freezing”, SPIE Photonics West BIOS, San Francisco, USA (2019)

51.  T. Wu, C.-J. Huang, C. Lei, C.-W. Sun, Y. Ozeki, and K. Goda, “Frequency-shifted optofluidic time-stretch quantitative phase imaging”, SPIE Photonics West BIOS, San Francisco, USA (2019)

52.  M. Lindley, H. Nomoto, K. Hiramatsu, and K. Goda, “High-speed simultaneous CARS and fluorescence spectroscopies”, SPIE Photonics West BIOS, San Francisco, USA (2019)

53.  K. Hiramatsu, T. Ideguchi, Y. Yonamine, S. Lee, Y. Luo, K. Hashimoto, T. Ito, M. Hase, J.-W. Park, Y. Kasai, S. Sakuma, T. Hayakawa, F. Arai, Y. Hoshino, and K. Goda, “High-throughput broadband CARS flow cytometry at >2,000 cells/s”, SPIE Photonics West BIOS, San Francisco, USA (2019)

54.  N. Nitta, T. Sugimura, Y. Hosokawa, S. Uemura, Y. Ozeki, and K. Goda, “High-throughput image-activated cell sorting with intelligence”, SPIE Photonics West BIOS, San Francisco, USA (2019)

55.  N. Nitta, T. Sugimura, Y. Hosokawa, S. Uemura, Y. Ozeki, and K. Goda, “Intelligent image-activated cell sorting: principles and applications”, SPIE Photonics West BIOS, San Francisco, USA (2019)

56.  Z. Cheng, T. Xiao, W. Zhou, C. Chang, S. Y. Set, M. Takenaka, H. K. Tsang, and K. Goda, “Mid-infrared high-Q germanium resonators”, SPIE Photonics West BIOS, San Francisco, USA (2019)

57.  H. Mikami, H. Kanno, Y. Kaya, Y. Ozeki, and K. Goda, “Ultrafast laser-scanning fluorescence microscopy with a compact inline implementation”, SPIE Photonics West BIOS, San Francisco, USA (2019)

58.  A. Tamang, F. J. Armistead, A. J. Harvie, S. Meredith, J. P. de Gala, H. Kanno, H. Mikami, L. J. C. Jeuken, K. Goda, S. D. Evans, and K. Critchley, “Cell membrane poration by hydrodynamic stretching of live cells”, SPIE Photonics West BIOS, San Francisco, USA (2019)

59.  A. Zhang, M. H. Loo, Y. Nakagawa, A. Isozaki, and K. Goda, “Low-loss droplet picking for high-throughput rare-cell sorting”, 化学とマイクロ・ナノシステム学会, Hamamatsu, Japan (2019)

60.  Y. Nakagawa, M. H. Loo, S. Ohnuki, Y. Ohya, A. Isozaki, and K. Goda, “A droplet microfluidic platform for separation of cells with low proliferative activity”, 化学とマイクロ・ナノシステム学会, Hamamatsu, Japan (2019)

61.  A. Isozaki, D. Huang, and K. Goda, “電極アレイを用いた多分岐高速液滴分取”, 化学とマイクロ・ナノシステム学会, Hamamatsu, Japan (2019)

62.  K. Hiramatsu and K. Goda, “Vibrational flow cytometry for large-scale label-free single-cell analysis”, International Symposium on Micro-NanoMechatronics and Human Science, Nagoya, Japan (2019)

63.  W. Peterson, K. Hiramatsu, and K. Goda, “Highly sensitive low-frequency Raman spectroscopy enabled by Sagnac-enhanced impulsive stimulated Raman scattering”, Student Conference on Light, Osaka, Japan (2019)

64.  M. Lindley, K. Hiramatsu, F. Shibata, T. Takeshita, S. Kawano, and K. Goda, “Single-laser fluorescence-Raman flow cytometry”, Biomedical Raman Imaging Conference, Osaka, Japan (2019)

65.  K. Hiramatsu and K. Goda, “High-throughput broadband vibrational flow cytometry”, Biomedical Raman Imaging Conference, Osaka, Japan (2019)

66.  S. Takizawa, K. Hiramatsu, and K. Goda, “Compressed time-domain Raman spectroscopy toward video-rate molecular imaging”, Biomedical Raman Imaging Conference, Osaka, Japan (2019)

67.  K. Hiramatsu and K. Goda, “高スループット振動分光フローサイトメトリー”, レーザー学会学術講演会第40回年次大会, Sendai, Japan (2019)

68.  K. Hiramatsu and K. Goda, “高速ラマン分光法による大規模1細胞解析”, 17回医用分光学研究会, Yokohama, Japan (2019)

69.  K. Hiramatsu and K. Goda, “多元的分光計測による大規模1細胞解析”, 分光学会生細胞部会, Tokyo, Japan (2019)

70.  K. Goda, “Intelligent image-activated cell sorting and beyond”, Annual Meeting, Optics & Photonics Japan, Osaka, Japan (2019)

71.  K. Goda, “Intelligent image-activated cell sorting and beyond”, MicroTAS, Basel, Switzerland (2019)

 

2018

1.     N. Nitta, T. Sugimura, A. Isozaki, H. Mikami, K. Hiraki, S. Sakuma, T. Iino, F. Arai, T. Endo, Y. Fujiwaki, H. Fukuzawa, M. Hase, T. Hayakawa, K. Hiramatsu, Y. Hoshino, M. Inaba, T. Ito, H. Karakawa, Y. Kasai, K. Koizumi, S. Lee, C. Lei, M. Li, T. Maeno, S. Matsusaka, D. Murakami, A. Nakagawa, Y. Oguchi, M. Oikawa, T. Ota, K. Shiba, H. Shintaku, Y. Shirasaki, K. Suga, Y. Suzuki, N. Suzuki, Y. Tanaka, H. Tezuka, C. Toyokawa, Y. Yalikun, M. Yamada, M. Yamagishi, T. Yamano, A. Yasumoto, Y. Yatomi, M. Yazawa, D. Di Carlo, Y. Hosokawa, S. Uemura, Y. Ozeki, and K. Goda, “Intelligent image-activated cell sorting“, Cell 175, 266 (2018)

2.     C. Lei, H. Kobayashi, D. Wu, M. Li, A. Isozaki, A. Yasumoto, H. Mikami, T. Ito, N. Nitta, T. Sugimura, M. Yamada, Y. Yatomi, D. Di Carlo, Y. Ozeki, and K. Goda, “High-throughput imaging flow cytometry by optofluidic time-stretch microscopy“, Nature Protocols 13, 1603 (2018)

3.     H. Mikami, J. Harmon, H. Kobayashi, S. Hamad, Y. Wang, O. Iwata, K. Suzuki, T. Ito, Y. Aisaka, N. Kutsuna, K. Nagasawa, H. Watarai, Y. Ozeki, and K. Goda, “Ultrafast confocal fluorescence microscopy beyond the fluorescence lifetime limit“, Optica 5, 117 (2018)

4.     M. Li, M. van Zee, C. T. Riche, B. Tofig, S. Gallaher, S. Merchant, R. Damoiseaux, K. Goda, and D. Di Carlo, “A gelatin microdroplet platform for high-throughput sorting of hyperproducing single-cell-derived microalgal clones“, Small 14, 1803315 (2018)

5.     H. Mikami, C. Lei, Y. Ozeki, and K. Goda, “High-speed imaging meets single-cell analysis“, Chem 4, 1 (2018)

6.     H. E. Munoz, M. Li, C. T. Riche, N. Nitta, E. Diebold, J. Lin, K. Owsley, M. Bahr, K. Goda, and D. Di Carlo, “Single-cell analysis of morphological and metabolic heterogeneity in Euglena gracilis by fluorescence imaging flow cytometry“, Analytical Chemistry 90, 11280 (2018)

7.     M. Li, M. van Zee, K. Goda, and D. Di Carlo, “Size-based sorting of hydrogel droplets using inertial microfluidics“, Lab on a Chip 18, 2575 (2018)

8.     T. Xiao, Z. Bao, Z. Cheng, and K. Goda, “Giant optical activity in an all-dielectric spiral nanoflower“, Small 14, 1800485 (2018)

9.     T.-H. Xiao, Z. Zhao, W. Zhou, M. Takenaka, H. K. Tsang, Z. Cheng, and K. Goda, “Mid-infrared high-Q germanium nanocavity“, Photonics Research 43, 2885 (2018)

10.  T. Miura, H. Mikami, A. Isozaki, T. Ito, Y. Ozeki, and K. Goda, “On-chip light-sheet fluorescence imaging flow cytometry at a high flow speed of 1 m/s“, Biomedical Optics Express 9, 3424 (2018)

11.  C. Lei and K. Goda, “The complete optical oscilloscope“, Nature Photonics 12, 190 (2018)

12.  T. Ideguchi, T. Nakamura, S. Takizawa, M. Tamamitsu, S. Lee, K. Hiramatsu, V. R. Badarla, J. Park, Y. Kasai, T. Hayakawa, S. Sakuma, F. Arai, and K. Goda, “Microfluidic single-particle chemical analyzer with dual-comb coherent Raman spectroscopy“, Optics Letters 43, 4057 (2018)

13.  T. Xiao, Z. Zhao, W. Zhou, C. Chang, S. Y. Set, M. Takenaka, H. K. Tsang, Z. Cheng, and K. Goda, “Mid-infrared high-Q germanium microring resonator“, Optics Letters 43, 2885 (2018)

14.  C. Lei, N. Nitta, Y. Ozeki, and K. Goda, “Optofluidic time-stretch imaging: recent advances“, Optical Review 25, 464 (2018)

15.  T. Maeno, T. Uzawa, I. Kono, K. Okano, T. Iino, K. Fukita, O. Iwata, K. Suzuki, T. Ito, K. Goda, and Y. Hosokawa, “Targeted delivery of fluorogenic peptide aptamers into live microalgae by femtosecond laser photoporation at single-cell resolution“, Scientific Reports 8, 8271 (2018)

16.  K. Goda, A. Zumbusch, Z. Huang, and Y. Ozeki, “Guest editorial: Special topic on coherent Raman spectroscopy and imaging“, APL Photonics 3, 090401 (2018)

17.  Y. Ozeki and K. Goda, “Opening a new world by unconventional bioimaging“, Optronics 37, 62 (2018)

18.  C. Lei, H. Kobayashi, Y. Ozeki, and K. Goda, “Optical time-stretch imaging for biofuel production, medical diagnostics, and drug discovery“, Optronics 37, 74 (2018)

19.  H. Mikami, Y. Ozeki, and K. Goda, “Ultrafast confocal fluorescence microscopy using telecommunication technology“, Optronics 37, 94 (2018)

20.  T. Xiao, Z. Cheng, and K. Goda, “高性能ナノデバイスを実現する螺旋状ナノフラワー“, 化学 74, 45 (2018)

21.  K. Goda and N. Nitta, “スーパースター細胞を超高速に発見する“, 理学部ニュース 11, 6 (2018)

22.  K. Tsia and K. Goda, “High-speed biomedical imaging and spectroscopy III: toward big data instrumentation and management”, SPIE Proceedings 10505 (2018)

23.  H. Mikami, T. Miura, Y. Ozeki, and K. Goda, “High-throughput fluorescence imaging flow cytometry with light-sheet excitation and machine learning”, SPIE Photonics West BIOS, San Francisco, USA (2018)

24.  C. Lei, H. Kobayashi, Y. Jiang, Y. Wu, B. Guo, A. Yasumoto, T. Ito, Y. Yatomi, Y. Ozeki, and K. Goda, “Machine-learning-assisted optofluidic time-stretch microscopy for drug discovery and medical diagnostics”, SPIE Photonics West BIOS, San Francisco, USA (2018)

25.  H. Mikami, J. Harmon, Y. Ozeki, and K. Goda, “Accurate classification of microalgal cells by frequency-division-multiplexed confocal imaging flow cytometry”, SPIE Photonics West BIOS, San Francisco, USA (2018)

26.  Y. Suzuki, K. Kobayashi, D. Deng, Y. Wakisaka, K. Goda, and Y. Ozeki, “Multicolor stimulated Raman imaging of live microalgal cells using fast wavelength-switched laser pulses”, SPIE Photonics West BIOS, San Francisco, USA (2018)

27.  Y. Suzuki, K. Goda, and Y. Ozeki, “High-speed multicolor SRS imaging”, SPIE Photonics West BIOS, San Francisco, USA (2018)

28.  K. Hiramatsu, R. Kinegawa, K. Hashimoto, V. R. Badarla, T. Ideguchi, and K. Goda, “High-speed broadband Fourier-transform CARS spectroscopy”, SPIE Photonics West BIOS, San Francisco, USA (2018)

29.  K. Hiramatsu, Y.  Luo, T. Ideguchi, and K. Goda, “Heterodyne-detected rapid-scan Fourier-transform CARS spectroscopy”, SPIE Photonics West BIOS, San Francisco, USA (2018)

30.  K. Goda, “Large-scale single-cell analysis with extreme imaging”, SPIE Photonics West BIOS, Hot Topics, San Francisco, USA (2018)

31.  C. Lei, H. Kobayashi, Y. Ozeki, and K. Goda, “Optofluidic time-stretch microscopy with an extreme throughput of 1 million cells/s”, SPIE Photonics Europe, Strasbourg, France (2018)

32.  C. Lei, H. Kobayashi, Y. Ozeki, and K. Goda, “Extreme-throughput imaging flow cytometry at 1,000,000 cells per second”, CYTO, Prague, Czech Republic (2018)

33.  N. Nitta, A. Yasumoto, H. Mikami, A. Isozaki, T. Sugimura, T. Iino, H. Karakawa, Y. Ozeki, Y. Yatomi, and K. Goda, “Accurate quantification of platelet aggregates by imaging flow cytometry with machine learning”, CYTO, Prague, Czech Republic (2018)

34.  M. Li, M. van Zee, C. T. Riche, B. Tofig, R. Damoiseaux, K. Goda, and D. Di Carlo, “High-throughput screening and sorting of hyperproductive single microalgal cells using gelatin microgels”, CYTO, Prague, Czech Republic (2018)

35.  H. Mikami, J. Harmon, T. Ito, Y. Ozeki, and K. Goda, “Fluorescence imaging flow cytometry without an image sensor: breaking the throughput barrier by telecommunication technology”, CYTO, Prague, Czech Republic (2018)

36.  T. Yamano, T. Toyokawa, S. Matsuoka, N. Nitta, T. Sugimura, A. Isozaki, T. Iino, T. Ito, K. Goda, and H. Fukuzawa, “High-throughput screening of algal mutant cells based on CO2-dependent protein relocation by intelligent image-activated cell sorting”, 60回日本植物生理学会年会, Nagoya, Japan (2018)

37.  T. Yamano, T. Toyokawa, N. Nitta, T. Sugimura, A. Isozaki, T. Iino, T. Ito, K. Goda, and H. Fukuzawa, “細胞検索エンジンによるタンパク質局在異常を指標とした藻類細胞の高速ミュータントスクリーニング”, 生体運動研究合同班会議, Fukuoka, Japan (2018)

38.  H. Mikami, Y. Ozeki, and K. Goda, “Fluorescence-lifetime-surpassed ultrafast confocal fluorescence microscopy”, 65回応用物理学会春季学術講演会, Tokyo, Japan (2018)

39.  H. Kanno, H. Mikami, Y. Ozeki, and K. Goda, “Compact, highly stable implementation of ultrafast confocal microscopy by in-line interferometry”, 65回応用物理学会春季学術講演会, Tokyo, Japan (2018)

40.  C. Lei, H. Kobayashi, Y. Ozeki, and K. Goda, “Detection of cellular drug responses by optofluidic time-stretch microscopy with an extreme throughput of 1 million cells/s”, 日本化学会第98春季年会, Funabashi, Japan (2018)

41.  K. Hiramatsu, Y. Luo, T. Ideguchi, and K. Goda, “ヘテロダイン検出高速走査FT-CARS分光法”, 日本化学会第98春季年会, Funabashi, Japan (2018)

42.  Z. Cheng, T. Xiao, Z. Zhao, W. Zhou, M. Takenaka, H. K. Tsang, and K. Goda, “Mid-infrared germanium-suspended-membrane photonic integrated circuits for low-cost and portable molecular fingerprinting”, 日本化学会第98春季年会, Funabashi, Japan (2018)

43.  T. Miura, H. Mikami, Y. Ozeki, and K. Goda, “ミラー埋め込み型マイクロ流路と機械学習を用いた高スループットイメージングフローサイトメトリー”, 日本化学会第98春季年会, Funabashi, Japan (2018)

44.  Y. Hashimoto, T. Miura, H. Mikami, Y. Ozeki, and K. Goda, “走査型ラインフォーカス励起ビームによる高感度蛍光イメージングフローサイトメトリー”, 日本化学会第98春季年会, Funabashi, Japan (2018)

45.  T. Xiao, Z. Cheng, and K. Goda, “A giant chiroptical effect enabled by a dielectric spiral nanoflower”, 79回応用物理学会秋季学術講演会, Nagoya, Japan (2018)

46.  Y. Zhou, A. Yasumoto, C. Lei, and K. Goda, “Analysis of platelet anti-coagulation by optofluidic time-stretch microscopy”, 79回応用物理学会秋季学術講演会, Nagoya, Japan (2018)

47.  Y. Wu, C. Lei, Y. Ozeki, and K. Goda, “Time-stretch quantitative phase imaging for cancer detection”, 79回応用物理学会秋季学術講演会, Nagoya, Japan (2018)

48.  M. Lindley, H. Nomoto, K. Hiramatsu, and K. Goda, “High-speed simultaneous Raman-fluorescence spectrometer”, 79回応用物理学会秋季学術講演会, Nagoya, Japan (2018)

49.  Z. Cheng, T. Xiao, Z. Zhao, W. Zhou, C. Yao, S. Y. Set, M. Takenaka, H. K. Tsang, and K. Goda, “Mid-infrared high-Q germanium photonic crystal cavity”, 79回応用物理学会秋季学術講演会, Nagoya, Japan (2018)

50.  H. Kobayashi, C. Lei, Y. Ozeki, and K. Goda, “無標識明視野画像による全血中のがん細胞薬剤応答評価”, 79回応用物理学会秋季学術講演会, Nagoya, Japan (2018)

51.  H. Kanno, J. Harmon, H. Mikami, T. Ito, Y. Ozeki, and K. Goda, “周波数分割多重イメージングフローサイトメトリーによる微細藻類の高精度分類”, 79回応用物理学会秋季学術講演会, Nagoya, Japan (2018)

52.  T. Maeno, M. Uzawa, I. Kono, K. Okano, T. Iino, K. Suita, Y. Oikawa, T. Ogawa, S. Iwata, T. Ito, K. Suzuki, K. Goda, and Y. Hosokawa, “蛍光アプタマーのフェムト秒レーザー細胞分子導入によるユーグレナ細胞内の多糖成分の高感度イメージング”, 79回応用物理学会秋季学術講演会, Nagoya, Japan (2018)

53.  S. Takizawa, T. Nakamura, T. Ideguchi, M. Tamamitsu, S. Lee, K. Hiramatsu, R. Venkata, J. Park, H. Kasai, K. Hayakawa, S. Sakuma, F. Arai, and K. Goda, “デュアルコムコヒーレントラマン分光によるマイクロ流体1粒子分析”, 79回応用物理学会秋季学術講演会, Nagoya, Japan (2018)

 

2017

1.     C. V. Hoang, K. Hayashi, Y. Ito, G. Naoki, S. Xi, Z. Cheng, K. Ueno, K. Goda, and H. Misawa, “Interplay of hot electrons from localized and propagating plasmons“, Nature Communications 8, 771 (2017)

2.     Y. Jiang, C. Lei, A. Yasumoto, T. Ito, B. Guo, H. Kobayashi, Y. Ozeki, Y. Yatomi, and K. Goda, “Label-free detection of aggregated platelets in blood by machine-learning-aided optofluidic time-stretch microscopy“, Lab on a Chip 17, 2426 (2017)

3.     H. Kobayashi, C. Lei, A. Mao, Y. Jiang, Y. Wu, B. Guo, Y. Ozeki, and K. Goda, “Label-free detection of cellular drug responses by high-throughput bright-field imaging and machine learning“, Scientific Reports 7, 12454 (2017)

4.     M. Li, H. E. Munoz, K. Goda, and D. Di Carlo, “Shape-based separation of microalga Euglena gracilis using inertial microfluidics“, Scientific Reports 7, 10802 (2017)

5.     B. Guo, C. Lei, T. Ito, Y. Yaxiaer, H. Kobayashi, Y. Jiang, Y. Tanaka, Y. Ozeki, and K. Goda, “High-throughput label-free single-cell microalgal lipid screening by machine-learning-equipped optofluidic time-stretch quantitative phase microscopy“, Cytometry Part A 91, 494 (2017)

6.     K. Hiramatsu, Y. Luo, T. Ideguchi, and K. Goda, “Rapid-scan Fourier-transform coherent anti-Stokes Raman scattering spectroscopy with heterodyne detection“, Optics Letters 42, 4335 (2017)

7.     T.-H. Xiao, Z. Zhao, W. Zhou, M. Takenaka, H. K. Tsang, Z. Cheng, and K. Goda, “Mid-infrared germanium photonic crystal cavity“, Optics Letters 42, 2882 (2017)

8.     J. Kang, Z. Cheng, W. Zhou, T.-H. Xiao, K.-L. Gopalakrisna, M. Takenaka, H. K. Tsang, and K. Goda, “A focusing subwavelength grating coupler for mid-infrared suspended membrane Ge waveguides“, Optics Letters 42, 2094 (2017)

9.     Y. Yonamine, Y. Suzuki, T. Ito, Y. Miura, K. Goda, Y. Ozeki, and Y. Hoshino, “Monitoring photosynthetic activity in live microalgal cells by Raman spectroscopy with deuterium oxide as a tracking probe“, ChemBioChem 18, 2063 (2017)

10.  T.-H. Xiao, Z. Cheng, and K. Goda, “Graphene-on-silicon hybrid plasmonic-photonic integrated circuits“, Nanotechnology 28, 245201 (2017)

11.  B. Guo, C. Lei, Y. Wu, H. Kobayashi, T. Ito, A. Yasumoto, Y. Yaxiaer, S. W. Lee, A. Isozaki, M. Li, Y. Jiang, A. Yasumoto, D. Di Carlo, Y. Tanaka, Y. Yatomi, Y. Ozeki, and K. Goda, “Optofluidic time-stretch quantitative phase microscopy“, Methods 136, 116 (2017)

12.  C. Lei, Y. Wu, A. C. Sankaranarayanan, S. Chang, B. Guo, N. Sasaki, H. Kobayashi, C. Sun, Y. Ozeki, and K. Goda, “GHz optical time-stretch microscopy by compressive sensing“, IEEE Photonics Journal 9, 3900308 (2017)

13.  C. Lei, Y. Ozeki, and K. Goda, “Large-scale label-free single-cell analysis by optofluidic time-stretch microscopy and artificial intelligence“, Japanese Journal of Optics 46, 282 (2017)

14.  Y. Ozeki, Y. Suzuki, Y. Wakisaka, and K. Goda, “Single-cell metabolite analysis of Euglena gracilis with stimulated Raman scattering”, Japanese Journal of Optics 46, 247 (2017)

15.  T. Ideguchi and K. Goda, “Broadband coherent Raman spectroscopy running at 24,000 spectra per second”, Japanese Journal of Optics 46, 228 (2017)

16.  Y. Ozeki, Y. Suzuki, Y. Wakisaka, and K. Goda, “誘導ラマン散乱顕微法による生きた微細藻類の1細胞代謝物解析“, Optical Alliance 28, 11 (2017)

17.  Y. Ozeki and K. Goda, “微細藻類の高速・無標識・一細胞代謝物イメージング“, Bioscience & Industry 75, 204 (2017)

18.  K. Hiramatsu, T. Ideguchi, and K. Goda, “高速無標識バイオイメージングに向けたFourier-transform CARS“, Optical Alliance 28, 48 (2017)

19.  O. Iwata, K. Yamada, T. Ito, K. Suzuki, Y. Ozeki, and K. Goda, “スーパー微細藻類バイオ燃料の創出に向けた基盤技術“, 生物物理 57, 235 (2017)

20.  Y. Ozeki, T. Ideguchi, and K. Goda, “高速ラマン計測による生命科学へのアプローチ“, 電気学会誌 137, 768 (2017)

21.  K. Goda, “2030年のサイエンスと革命前夜”, 理学部ニュース 5, 3 (2017)

22.  M. Tamamitsu, Y. Sakaki, T. Nakamura, G. K. Podagatlapalli, T. Ideguchi, and K. Goda, “Ultrafast broadband Fourier-transform CARS spectroscopy operating at 50,000 spectra/second“, Proceedings of SPIE doi:10.1117/12.2249726 (2017)

23.  B. Guo, C. Lei, T. Ito, Y. Ozeki, and K. Goda, “High-throughput label-free screening of Euglena gracilis with optofluidic time-stretch quantitative phase microscopy“, Proceedings of SPIE doi:10.1117/12.2251157 (2017)

24.  Y. Suzuki, Y. Wakisaka, O. Iwata, A. Nakashima, T. Ito, M. Hirose, R. Domon, M. Sugawara, N. Tsumura, H. Watarai, T. Shimobaba, K. Suzuki, K. Goda, and Y. Ozeki, “High-speed stimulated Raman scattering microscopy for studying the metabolic diversity of motile Euglena gracilis“, Proceedings of SPIE doi:10.1117/12.2250455 (2017)

25.  H. Mikami, J. Harmon, Y. Ozeki, and K. Goda, “High-speed bioimaging with frequency-division-multiplexed fluorescence confocal microscopy“, Proceedings of SPIE doi:10.1117/12.2272924 (2017)Y. Suzuki, K. Kobayashi, D. Deng, Y. Wakisaka, K. Goda, and Y. Ozeki, “Multicolor stimulated Raman scattering microscopy by rapid wavelength switching of laser pulses”, The 24th Congress of the International Commission for Optics, Tokyo, Japan (2017)

26.  Z. Cheng, J. Wang, Z. Chen, T. Xiao, H. K. Tsang, C. Shu, J.-B. Xu, and K. Goda, “Graphene-on-silicon slot waveguides and applications”, Progress in Electromagnetics Research Symposium (PIERS), St. Petersburg, Russia (2017)

27.  Y. Suzuki, Y. Wakisaka, T. Ito, D. Deng, K. Goda, and Y. Ozeki, “Chemical imaging of live microalgal cells by multicolor stimulated Raman scattering microscopy”, 日本分光学会国際シンポジウム「ラマン分光のバイオ応用展開」, Tokyo (2017)

28.  Y. Suzuki, K. Goda, and Y. Ozeki, “誘導ラマン散乱による生きた微細藻類の無標識1細胞解析”, 日本植物学会第81回大会, Chiba, Japan (2017)

29.  R. Kinegawa, K. Hiramatsu, T. Ideguchi, and K. Goda, “高速フーリエ変換CARS顕微鏡”, 78回応用物理学会秋季学術講演会, Fukuoka, Japan (2017)

30.  C. Lei, H. Mikami, Y. Suzuki, Y. Ozeki, and K. Goda, “エクストリームイメージング:基本原理と生命計測応用”, 78回応用物理学会秋季学術講演会, Fukuoka, Japan (2017)

31.  H. Mikami, J. Harmon, Y. Ozeki, and K. Goda, “High-speed three-dimensional fluorescence imaging with frequency-division-multiplexed confocal microscopy”, SPIE Photonics West BIOS, San Francisco (2017)

32.  K. Kobayashi, Y. Suzuki, D. Deng, Y. Wakisaka, K. Goda, and Y. Ozeki, “High-speed multicolor stimulated Raman scattering microscopy enabled by rapid wavelength switching”, SPIE Photonics West BIOS, San Francisco (2017)

33.  Y. Jiang, C. Lei, A. Yasumoto, T. Ito, B. Guo, H. Kobayashi, Y. Ozeki, Y. Yatomi, and K. Goda, “High-throughput label-free platelet aggregate detection with optofluidic time-stretch microscopy”, SPIE Photonics West BIOS, San Francisco (2017)

34.  H. Kobayashi, C. Lei, A. Mao, Y. Jiang, B. Guo, Y. Ozeki, and K. Goda, “Label-free image-based detection of drug resistance with optofluidic time-stretch microscopy”, SPIE Photonics West BIOS, San Francisco (2017)

35.  B. Guo, C. Lei, T. Ito, Y. Jiang, Y. Ozeki, and K. Goda, “Optofluidic time-stretch quantitative phase microscopy for high-throughput label-free single-cell screening”, SPIE Photonics West BIOS, San Francisco (2017)

36.  A. Yasumoto, Y. Jiang, C. Lei, Y. Aisaka, T. Ito, B. Guo, H. Kobayashi, N. Nitta, N. Kutsuna, Y. Ozeki, A. Nakagawa, K. Goda, and Y. Yatomi, “非標識リアルタイムイメージング装置を用いた血小板凝集塊の検出法の確立”, 39回日本血栓止血学会学術集会 (2017)

37.  Z. Cheng, T. Xiao, and K. Goda, “Design of a graphene-based waveguide-integrated photonic gas sensor”, 日本化学会第97春季年会 (2017)

38.  J. Harmon, H. Mikami, Y. Ozeki, and K. Goda, “High-throughput fluorescence imaging flow cytometry with an enhanced image resolution”, 日本化学会第97春季年会 (2017)

39.  T. Miura, H. Mikami, Y. Ozeki, and K. Goda, “Light-sheet fluorescence imaging flow cytometry with a mirror-embedded microfluidic device”, 日本化学会第97春季年会 (2017)

40.  Y. Liu, Z. Li, S. Moroianu, H. Mikami, Y. Ozeki, and K. Goda, “Imaging flow cytometry with sensitivity-optimized coded-excitation fluorescence microscopy”, 日本化学会第97春季年会 (2017)

41.  B. Guo, C. Lei, T. Ito, Y. Yaxiaer, H. Kobayashi, Y. Jiang, Y. Tanaka, Y. Ozeki, and K. Goda, “Optofluidic time-stretch quantitative phase microscopy of Euglena gracilis”, 日本化学会第97春季年会 (2017)

42.  Y. Jiang, C. Lei, A. Yasumoto, Y. Ozeki, Y. Yatomi, and K. Goda, “Label-free investigation of agonist-activated platelet aggregation with optofluidic time-stretch microscopy”, 日本化学会第97春季年会 (2017)

43.  D. L. Setyaningrum, J. Park, T. Uzawa, Y. Ito, A. Isozaki, and K. Goda, “Droplet microfluidic platform for cell-free expression of green fluorescent protein”, 日本化学会第97春季年会 (2017)

44.  Y. Luo, K. Hashimoto, M. Takahashi, M. Tamamitsu, Y. Sakaki, T. Nakamura, G. K. Podagatlapalli, T. Ideguchi, and K. Goda, “Rapid-scan Fourier-transform coherent anti-Stoked Raman scattering spectroscopy”, 日本化学会第97春季年会 (2017)

45.  Y. Yonamine, Y. Suzuki, T. Ito, M. Hasunuma, K. Wang, Y. Aisaka, Y. Miura, K. Goda, Y. Ozeki, and Y. Hoshino, “安定同位体標識を用いたラマン分光法による藻類の代謝追跡”, 66回高分子学会年次大会, Chiba, Japan (2017)

46.  K. Kobayashi, Y. Suzuki, D. Deng, Y. Wakisaka, K. Goda, and Y. Ozeki, “高速誘導ラマン散乱顕微鏡のための超高速波長切り替え可能なレーザー光源”, 64回応用物理学会春季学術講演会, Yokohama, Japan (2017)

47.  Y. Suzuki, K. Kobayashi, D. Deng, T. Ito, Y. Wakisaka, S. Lee, K. Goda, and Y. Ozeki, “高速誘導ラマンフローサイトメトリーによるユーグレナ解析”, 64回応用物理学会春季学術講演会, Yokohama, Japan (2017)

48.  K. Kobayashi, Y. Suzuki, D. Deng, Y. Wakisaka, K. Goda, and Y. Ozeki, “マルチカラー誘導ラマン散乱顕微鏡のための超高速波長切り替えレーザー光源の改良”, 64回応用物理学会春季学術講演会, Yokohama, Japan (2017)

49.  K. Goda, “Ultrafast imaging for single-cell analysis”, CLEO-PR, OECC & PGC, Singapore (2017)

50.  C. Lei, B. Guo, Y. Jiang, Y. Wu, H. Kobayashi, T. Ito, A. Yasumoto, Y. Yatomi, Y. Ozeki, and K. Goda, “High-throughput, label-free, multivariate cell analysis with optofluidic time-stretch microscopy”, CLEO-PR, OECC & PGC, Singapore (2017)

51.  Y. Yonamine, Y. Suzuki, T. Ito, T. Hasunuma, K. Wang, Y. Aisaka, Y. Miura, K. Goda, Y. Ozeki, and Y. Hoshino, “安定同位体標識を用いたラマンイメージング法による代謝追跡”, 27回バイオ・高分子シンポジウム (2017)

52.  Y. Yonamine, Y. Suzuki, T. Ito, K. Wang, Y. Aisaka, Y. Miura, K. Goda, Y. Ozeki, and Y. Hoshino, “安定同位体標識を用いたラマンイメージングによる藻類の代謝追跡”, 66回高分子討論会, Matsuyama, Japan (2017)

53.  Y. Yonamine, K. Hiramatsu, T. Ito, T. Ideguchi, Y. Miura, K. Goda, and Y. Hoshino, “安定同位体標識を用いた共鳴ラマン分光法による藻類の代謝追跡”, 66回高分子討論会, Matsuyama, Japan (2017)

54.  K. Hiramatsu, Y. Luo, T. Ideguchi, and K. Goda, “Heterodyne-detected rapid-scan Fourier-transform CARS spectroscopy”, SPIE Photonics West BIOS, San Francisco, USA (2018)

55.  Y. Suzuki, K. Goda, and Y. Ozeki, “High-speed multicolor SRS imaging”, SPIE Photonics West BIOS, San Francisco, USA (2018)

56.  Y. Ozeki, Y. Suzuki, Y. Wakisaka, K. Kobayashi, D. Deng, and K. Goda, “High-speed stimulated Raman microscopy for label-free metabolite imaging of microalgae”, Optics & Photonics Japan, Tokyo, Japan (2017)

 

2016

1.     Y. Wakisaka, Y. Suzuki, O. Iwata, A. Nakashima, T. Ito, M. Hirose, R. Domon, M. Sugawara, N. Tsumura, H. Watarai, T. Shimobaba, K. Suzuki, K. Goda, and Y. Ozeki, “Probing the metabolic heterogeneity of live Euglena gracilis with stimulated Raman scattering microscopy“, Nature Microbiology 1, 16124 (2016)

2.     T. Ideguchi, T. Nakamura, Y. Kobayashi, and K. Goda, “Kerr-lens mode-locked bidirectional dual-comb ring laser for broadband dual-comb spectroscopy“, Optica 3, 748 (2016)

3.     K. Hashimoto, M. Takahashi, T. Ideguchi, and K. Goda, “Broadband coherent Raman spectroscopy running at 24,000 spectra per second“, Scientific Reports 6, 21036 (2016)

4.     K. Yamada, H. Suzuki, T. Takeuchi, Y. Kazama, S. Mitra, T. Abe, K. Goda, K. Suzuki, and O. Iwata, “Efficient selective breeding of live oil-rich Euglena gracilis with fluorescence-activated cell sorting“, Scientific Reports 6, 26327 (2016)

5.     C. Lei, B. Guo, Z. Cheng, and K. Goda, “Optical time-stretch imaging: principles and applications“, Applied Physics Reviews 3, 011102 (2016)

6.     C. Lei, T. Ito, M. Ugawa, T. Nozawa, O. Iwata, M. Maki, G. Okada, H. Kobayashi, X. Sun, P. Tiamsak, N. Tsumura, K. Suzuki, D. Di Carlo, Y. Ozeki, and K. Goda, “High-throughput label-free image cytometry and image-based classification of live Euglena gracilis“, Biomedical Optics Express 7, 2703 (2016)

7.     M. Li, H. E. Munoz, A. Schmidt, B. Guo, C. Lei, K. Goda, and D. Di Carlo, “Inertial focusing of ellipsoid Euglena gracilis cells in a stepped microchannel“, Lab on a Chip 16, 4458 (2016)

8.     M. Tamamitsu, Y. Sakaki, T. Nakamura, G. K. Podagatlapalli, T. Ideguchi, and K. Goda, “Ultrafast broadband Fourier-transform CARS spectroscopy at 50,000 spectra/second enabled by a scanning Fourier-domain delay line“, Vibrational Spectroscopy 91, 163 (2016)

9.     B. Guo, C. Lei, T. Ito, Y. Jiang, Y. Ozeki, and K. Goda, “High-throughput accurate single-cell screening of Euglena gracilis with fluorescence-assisted optofluidic time-stretch microscopy“, PLoS ONE 11, e0166214 (2016)

10.  J.-W. Park, S. H. Kim, T. Ito, T. Fujii, S. Y. Kim, T. Laurell, S. W. Lee, and K. Goda, “Acoustofluidic harvesting of microalgae on a single chip“, Biomicrofluidics 10, 034119 (2016)

11.  A. Phatak, Z. Cheng, C. Qin, and K. Goda, “Design of electro-optic modulators based on graphene-on-silicon slot waveguides“, Optics Letters 41, 2501 (2016)

12.  Z. Cheng and K. Goda, “Design of waveguide-integrated graphene devices for photonic gas sensing“, Nanotechnology 27, 505206 (2016)

13.  H. Mikami, L. Gao, and K. Goda, “Ultrafast optical imaging technology: principles and applications of emerging methods“, Nanophotonics 5, 98 (2016)

14.  Z. Cheng, C. Qin, F. Wang, H. He, and K. Goda, “Progress on mid-IR graphene photonics and biochemical applications“, Frontiers of Optoelectronics 9, 1 (2016)

15.  C. Lei, Z. Cheng, and K. Goda, “Cancer detection with high-throughput image cytometry”, Medical Imaging Technology 34, 68 (2016)

16.  H. Mikami, C. Lei, Y. Suzuki, Y. Ozeki, and K. Goda, “超高速イメージングで生命科学“, O plus E 38, 922 (2016)

17.  K. Hashimoto, T. Ideguchi, and K. Goda, “高速の化学分析が可能に!高速広帯域コヒーレントラマン分光の実現”, 化学 71, 68 (2016)

18.  A. Yazaki, K. Goda, and B. Jalali, “超高速表面検査を実現する分散融合型暗視野レーザスキャナ”, 画像ラボ 27, 1 (2016)

19.  H. Mikami and K. Goda, “異分野融合がセレンディピティを引き起こす”, 理学部ニュース 5, 8 (2016)

20.  M. Oikawa, D. Hiyama, R. Hirayama, S. Hasegawa, Y. Endo, T. Sugie, N. Tsumura, M. Kuroshima, M. Maki, G. Okada, C. Lei, Y. Ozeki, K. Goda, and T. Shimobaba, “A computational approach to real-time image processing for serial time-encoded amplified microscopy”, SPIE Photonics West BIOS, San Francisco (2016)

21.  Y. Wakisaka, Y. Suzuki, K. Tokunaga, M. Hirose, R. Domon, R. Akaho, M. Kuroshima, N. Tsumura, T. Shimobaba, O. Iwata, K. Suzuki, A. Nakashima, K. Goda, and Y. Ozeki, “Label-free chemical imaging of live Euglena gracilis by high-speed stimulated Raman scattering spectral microscopy”, SPIE Photonics West BIOS, San Francisco (2016)

22.  H. Mikami, H. Kobayashi, Y. Wang, S. Hamad, Y. Ozeki, and K. Goda, “Enhanced speed in fluorescence imaging using beat frequency multiplexing”, SPIE Photonics West BIOS, San Francisco (2016)

23.  C. Lei, M. Ugawa, T. Nozawa, T. Ideguchi, D. Di Carlo, S. Ota, Y. Ozeki, and K. Goda, “High-throughput time-stretch microscopy with morphological and chemical specificity”, SPIE Photonics West BIOS, San Francisco (2016)

24.  S. Morita, M. Tamamitsu, Y. Kitagawa, K. Nakagawa, Y. Yamagata, R. Horisaki, Y. Oishi, K. Motohara, and K. Goda, “Fabrication process of slicing mirror for hyperspectral imaging and its performance evaluation”, euspen’s 16th International Conference & Exhibition, Nottingham (2016)

25.  C. Lei, T. Ito, D. Di Carlo, Y. Ozeki, and K. Goda, “High-throughput single-cell image analysis of live Euglena gracilis for efficient biofuel production”, CLEO, San Jose (2016)

26.  H. Mikami, H. Kobayashi, S. Hamad, Y. Ozeki, and K. Goda, “Ultrafast confocal fluorescence microscopy by frequency-division-multiplexed multi-line focusing”, CLEO, San Jose (2016)

27.  T. Ideguchi, K. Hashimoto, M. Takahashi, and K. Goda, “High-throughput broadband Fourier-transform CARS”, CLEO, San Jose (2016)

28.  T. Ideguchi, T. Nakamura, Y. Kobayashi, and K. Goda, “Bidirectional Kerr-lens mode-locked dual-comb ring laser”, CLEO, San Jose (2016)

29.  J. W. Park, S. Kim, T. Ito, S. Kim, T. Fujii, T. Laurell, S. W. Lee, and K. Goda, “Efficient enrichment of microalgae based on acoustophoretic microfluidics”, World Congress on Biosensors, Stockholm (2016)

30.  M. Li, H. E. Munoz, J. Lin, K. Owsley, K. Goda, E. Diebold, and K. Goda, “Inertial focusing and imaging flow cytometry of Euglena gracilis for biodiesel applications”, CYTO, Seattle (2016)

31.  M. Li, H. E. Munoz, J. Lin, K. Owsley, E. Diebold, K. Goda, and D. Di Carlo, “Analysis of microalgal lipid production using high-throughput fluorescence imaging flow cytometry”, MicroTAS, Dublin (2016)

32.  K. Goda, 「フォノンをリアルタイム可視化するフェムト秒動画撮像法」, 63回応用物理学会春季学術講演会, 東京工業大学 (2016)

33.  K. Hashimoto, M. Takahashi, T. Ideguchi, and K. Goda, 「超高速広帯域フーリエ変換CARS分光」, 63回応用物理学会春季学術講演会, 東京工業大学 (2016)

34.  T. Nakamura, T. Ideguchi, Y. Kobayashi, and K. Goda, 「双方向発振デュアルコムリングレーザー」, 63回応用物理学会春季学術講演会, 東京工業大学 (2016)

35.  Y. Sakaki, M. Tamamitsu, T. Nakamura, G. K. Podagatlapalli, T. Ideguchi, and K. Goda, 「位相操作型干渉計を用いた超高速フーリエ変換コヒーレントラマン分光」, 63回応用物理学会春季学術講演会, 東京工業大学 (2016)

36.  H. Mikami, H. Kobayashi, H. Syed, Y. Wang, Y. Ozeki, and K. Goda, 「周波数分割多重化された蛍光共焦点顕微鏡法の高速化」, 63回応用物理学会春季学術講演会, 東京工業大学 (2016)

37.  L. Cheng, M. Ugawa, T. Nozawa, D. Di Carlo, Y. Ozeki, and K. Goda, “High-throughput optofluidic microparticle analyzer based on time-stretch imaging”, 63回応用物理学会春季学術講演会, 東京工業大学 (2016)

38.  H. Hagiwara, K. Yamakawa, T. Iino, N. Tanaka, Y. Shibata, T. Nozawa, A. Isozaki, D. Di Carlo, K. Goda, and Y. Hosokawa, 「フェムト秒レーザー誘起衝撃力を用いたマイクロチップ中での単一細胞の高速操作」, 63回応用物理学会春季学術講演会, 東京工業大学 (2016)

39.  K. Yamakawa, H. Hagiwara, T. Iino, N. Tanaka, Y. Shibata, T. Nozawa, A. Isozaki, D. Di Carlo, K. Goda, and Y. Hosokawa, 「フェムト秒レーザー誘起衝撃力を用いたマイクロチップ中での微小物体の高速ソーティング」, 63回応用物理学会春季学術講演会, 東京工業大学 (2016)

40.  C. Lei, B. Guo, T. Ito, Y. Ozeki, and K. Goda, “High-speed optofluidic time-stretch microscopy for high-throughput label-free cell classification”, ICHSIP, Osaka (2016)

41.  B. Guo, C. Lei, T. Ito, Y. Jiang, Y. Ozeki, and K. Goda, “High-throughput optofluidic profiling of Euglena gracilis with morphological and chemical specificity”, SPIE Photonics Asia, Beijing (2016)

42.  C. Lei, T. Ito, D. Di Carlo, Y. Ozeki, and K. Goda, “High-throughput optofluidic microalgal cell analyzer with single-cell resolution for biofuel production”, SPIE Photonics Asia, Beijing (2016)

43.  C. Lei, A. Mao, H. Kobayashi, Y. Jiang, B. Guo, and K. Goda, “Morphology-based cancer detection with optofluidic time-stretch microscopy”, SPIE Photonics Asia, Beijing (2016)

44.  Y. Suzuki, Y. Wakisaka, O. Iwata, A. Nakashima, K. Suzuki, T. Ito, M. Hirose, R. Domon, M. Sugawara, N. Tsumura, H. Watarai, T. Shimobaba, K. Goda, and O. Yasuyuki, “High-speed stimulated Raman scattering microscopy for single-cell analysis of metabolites in live Euglena gracilis”, 77回応用物理学会秋季学術講演会, 新潟 (2016)

45.  H. Mikami, J. Harmon, H. Kobayashi, Y. Ozeki, and K. Goda, “Speed enhancement in frequency-division-multiplexed confocal microscopy by multi-line focusing”, 77回応用物理学会秋季学術講演会, 新潟 (2016)

46.  H. Kobayashi, Y. Suzuki, D. Ding, Y. Wakisaka, K. Goda, and Y. Ozeki, 「パルスの波長切り替えによる高速マルチカラー誘導ラマン散乱顕微法」, 77回応用物理学会秋季学術講演会, 新潟 (2016)

47.  H Mikami, J. Harmon, H. Kobayashi, Y. Ozeki, and K. Goda, “High-throughput fluorescence imaging flow cytometry with multi-line frequency-division-multiplexed confocal microscopy”, 31st International Congress on High-Speed Imaging and Photonics, Osaka, Japan (2016)

48.  C. Lei, B. Guo, T. Ito, Y. Ozeki, and K. Goda, “High-speed optofluidic time-stretch microscopy for high-throughput label-free cell classification”, 31st International Congress on High-Speed Imaging and Photonics, Osaka, Japan (2016)

49.  T. Nakamura, T. Ideguchi, Y. Kobayashi, and K. Goda, “双方向発振デュアルコムリングレーザー”, 23回レーザー夏の学校, Atami, Japan (2016)

50.  K. Kobayashi, Y. Suzuki, D. Deng, Y. Wakisaka, K. Goda, and Y. Ozeki, “高速マルチカラー誘導ラマン散乱顕微鏡のための超高速波長切り替えレーザー光源”, Optics & Photonics Japan, Tokyo, Japan (2016)

51.  Y. Suzuki, Y. Wakisaka, O. Iwata, A. Nakashima, K. Suzuki, T. Ito, M. Hirose, R. Domon, M. Sugawara, N. Tsumura, T. Shimobaba, K. Goda, and Y. Ozeki, “誘導ラマン散乱顕微鏡による生きたユーグレナの代謝物イメージングと統計解析”, Optics & Photonics Japan, Tokyo, Japan (2016)

52.  H. Mikami, J. Harmon, Y. Ozeki, and K. Goda, “周波数多重化された共焦点顕微鏡による超高速蛍光イメージング”, レーザー学会学術講演会, Tokushima, Japan (2016)

53.  R. Nagamura, A. Isozaki, and K. Goda, “マイクロ流路による高粘度油滴生成”, 化学とマイクロ・ナノシステム学会, Chiba, Japan (2016)

54.  A. Isozaki, N. Tanaka, and K. Goda, “液滴安定化マイクロ流路を用いた高速液滴生成デバイス”, 化学とマイクロ・ナノシステム学会, Chiba, Japan (2016)

55.  H. L. Tsoi, A. Isozaki, and K. Goda, “表面弾性波を用いたマイクロ流路内微小粒子の操作”, 化学とマイクロ・ナノシステム学会, Chiba, Japan (2016)

56.  N. Tanaka, Y. Shibata, A. Isozaki, and K. Goda, “A coalescence-free microdroplet generator enabled by surfactant coating with fluidic walls”, Microfluidics, European Molecular Biology Laboratory Conference, Munchen, Germany (2016)

57.  N. Tanaka, A. Isozaki, and K. Goda, “High-throughput generation of coalescence-free droplets with a secondary surfactant-assisted oil injection”, 27th International Symposium on Micro-Nano Mechatronics and Human Science, Nagoya, Japan (2016)

58.  H. L. Tsoi, A. Isozaki, and K. Goda, “Particle/cell manipulation and sorting with surface acoustic waves in a microfluidic device”, 27th International Symposium on Micro-Nano Mechatronics and Human Science, Nagoya, Japan (2016)

59.  Y. Ozeki, Y. Suzuki, Y. Wakisaka, and K. Goda, “誘導ラマン散乱による生きたユーグレナの1細胞代謝物解析”, ユーグレナ研究会第32回研究集会, Tokyo, Japan (2016)

60.  Y. Yonamine, Y. Suzuki, T. Ito, M. Hasunuma, Y. Miura, K. Goda, Y. Ozeki, and Y. Hoshino, “安定同位体プローブを用いたラマン分光法による藻類の代謝追跡”, 65回高分子討論会, Yokohama, Japan (2016)

 

2015

1.     H. He, K. Nakagawa, Y. Wang, Y. Hosokawa, and K. Goda, “Mechanism for microtsunami-induced intercellular mechanosignalling“, Nature Photonics 9, 623 (2015)

2.     T. Ishida, T. Sato, T. Ishikawa, M. Oguma, N. Itamura, K. Goda, N. Sasaki, and H. Fujita, “Time-lapse nanoscopy of friction in the non-Amontons and non-Coulomb regime“, Nano Letters 15, 1476 (2015)

3.     M. Ugawa, C. Lei, T. Nozawa, T. Ideguchi, D. Di Carlo, S. Ota, Y. Ozeki, and K. Goda, “High-throughput optofluidic particle profiling with morphological and chemical specificity“, Optics Letters 40, 4803 (2015)

4.     M. Tamamitsu, K. Nakagawa, R. Horisaki, A. Iwasaki, Y. Oishi, A. Tsukamoto, F. Kannari, I. Sakuma, and K. Goda, “Design for sequentially timed all-optical mapping photography with optimum temporal performance“, Optics Letters 40, 633 (2015)

5.     T. Suzuki, F. Isa, L. Fujii, K. Hirosawa, K. Nakagawa, K. Goda, I. Sakuma, and F. Kannari, “Sequentially timed all-optical mapping photography (STAMP) utilizing spectral filtering“, Optics Express 23, 30512 (2015)

6.     M. Tamamitsu, Y. Kitagawa, K. Nakagawa, R. Horisaki, Y. Oishi, S. Morita, Y. Yamagata, K. Motohara, and K. Goda, “Spectrum slicer for snapshot spectral imaging“, Optical Engineering 54, 123115 (2015)

7.     K. Nakagawa, F. Kannari, I. Sakuma, and K. Goda, “Photography on the femtosecond scale“, Imaging & Microscopy 4, 44 (2015)

8.     M. Ugawa, T. Ideguchi, and K. Goda, “Ultrafast spectroscopy and its applications enabled by time-domain Fourier optics“, Review of Laser Engineering 43, 193 (2015)

9.     K. Nakagawa and K. Goda, “Sequentially timed all-optical mapping photography for capturing picosecond-to-femtosecond dynamics”, Journal of Japan Laser Processing Society 22, 225 (2015)

10.  K. Nakagawa, “STAMP (Sequentially timed all-optical mapping photography) for observation of ultrafast non-repetitive phenomena”, Review of Laser Engineering 43, 198 (2015)

11.  K. Nakagawa and K. Goda, “超高速光学撮像法が拓くフロンティア“, 応用物理 84, 409 (2015)

12.  K. Nakagawa, H. Kobayashi, G. Yu, Y. Wakisaka, T. Nozawa, and K. Goda, “高速・高分解能ブレインイメージングに向けた技術革新”, Brain Science Review, クバプロ (2015)

13.  A. Yazaki, K. Goda, and B. Jalali, “超高速表面検査を実現する分散融合型暗視野レーザスキャナー”, 映像情報メディア学会誌 69, 574 (2015)

14.  K. Nakagawa and K. Goda, “1兆分の1秒以下の世界を捉える連写撮影法”, 画像ラボ 26, 13 (2015)

15.  K. Goda, “Extreme imaging and beyond”, Frontiers in Optics, OSA Technical Digest, LM2H.1 (2015)

16.  K. Nakagawa, A. Iwasaki, Y. Oishi, R. Horisaki, A. Tsukamoto, A. Nakamura, K. Hirosawa, H. Liao, T. Ushida, K. Goda, F. Kannari, and I. Sakuma, “Motion picture femtophotography with sequentially timed all-optical mapping photography”, CLEO, San Jose (2015)

17.  K. Goda, “Ultrafast optical imaging based on spatiotemporal dispersion”, Proceedings of 56th Meeting on Lightwave Sensing Technology, Tokyo (2015)

18.  H. Mikami and K. Goda, “超高速光イメージング技術の最新動向”, 38回日本分子生物学会, Kobe, Japan (2015)

19.  K. Hashimoto, H. Mizuno, K. Nakagawa, R. Horisaki, A. Iwasaki, F. Kannari, I. Sakuma, and K. Goda, “Multispectral imaging with a periscope array”, 26回先端光量子科学アライアンスセミナー・先端光科学におけるフーリエ光学応用シンポジウム (2015)

20.  M. Ugawa, T. Ideguchi, and K. Goda, “Ultrafast spectroscopy and imaging enabled by dispersive Fourier transformation”, 26回先端光量子科学アライアンスセミナー・先端光科学におけるフーリエ光学応用シンポジウム (2015)

21.  K. Goda, “先端光技術によるセレンディピティの計画的創出”, 光エレクトロニクス研究会第130委員会, 東京理科大学 (2015)

22.  Y. Kitagawa, S. Morita, Y. Yamagata, S. Ozaki, M. Tamamitsu, K. Nakagawa, K. Goda, and K. Motohara, “超精密切削加工による天文用イメージスライスミラー”, 40回光学シンポジウム, 東京大学 (2015)

23.  C. Lei, M. Ugawa, T. Nozawa, T. Ito, O. Iwata, K. Suzuki, D. Di Carlo, Y. Ozeki, and K. Goda, “High-throughput optofluidic microparticle analyzer based on time-stretch imaging”, East Lake Forum, China (2015)

24.  H. Hagihara, T. Yamakawa, T. Iino, A. Isozaki, T. Nozawa, Y. Shibata, N. Tanaka, D. Di Carlo, K. Goda, and Y. Hosokawa, “Fast manipulation of single cells in microfluidic channel utilizing femtosecond laser-induced impulsive force 1: Laser energy and focus position dependency estimated by micro polymer particles”, Annual Meeting of the Physical Society of the Republic of China, Kaoshing, Taiwan (2015)

25.  T. Maeno, T. Yamakawa, T. Iino, O. Iwata, K. Suzuki, A. Isozaki, T. Nozawa, Y. Shibata, N. Tanaka, D. Di Carlo, K. Goda, and Y. Hosokawa, “Fast manipulation of single cells in microfluidic channel utilizing femtosecond laser-induced impulsive force 2: Physical and biological behavior of Euglena gracilis”, Annual Meeting of the Physical Society of the Republic of China, Kaoshing, Taiwan (2015)

26.  Y. Shibata, A. Isozaki, and K. Goda, “誘電永動を用いたドロプレット分取における電極配置に関する検討”, 化学とマイクロ・ナノシステム学会, Kitakyushu, Japan (2015)

27.  H. Hagihara, T. Yamakawa, T. Iino, N. Tanaka, Y. Shibata, T. Nozawa, A. Isozaki, D. Di Carlo, K. Goda, and Y. Hosokawa, “Estimation of single cell manipulation ability of femtosecond laser-induced impulsive force toward development of high-speed single cell sorting in microchip”, 3rd NCTU-NAIST Joint Workshop on Laser Bio/Nano Science, Hsinchu, Taiwan (2016)

28.  T. Maeno, T. Yamakawa, T. Iino, O. Iwata, K. Suzuki, N. Tanaka, Y. Shibata, T. Nozawa, A. Isozaki, D. Di Carlo, K. Goda, and Y. Hosokawa, “Estimation of manipulation ability of Euglena in microfluidic channels utilizing femtosecond laser-induced impulsive force”, 3rd NCTU-NAIST Joint Workshop on Laser Bio/Nano Science, Hsinchu, Taiwan (2016)

 

2014

1.     K. Nakagawa, A. Iwasaki, Y. Oishi, R. Horisaki, A. Tsukamoto, A. Nakamura, K. Hirosawa, H. Liao, T. Ushida, K. Goda, F. Kannari, and I. Sakuma, “Sequentially timed all-optical mapping photography“, Nature Photonics 8, 695 (2014)

2.     K. Hashimoto, H. Mizuno, K. Nakagawa, R. Horisaki, A. Iwasaki, F. Kannari, I. Sakuma, and K. Goda, “High-speed multispectral videography with a periscope array in a spectral shaper“, Optics Letters 39, 6942 (2014)

3.     A. Yazaki, C. Kim, J. Chan, A. Mahjoubfar, K. Goda, M. Watanabe, and B. Jalali, “Ultrafast dark-field surface inspection with hybrid-dispersion laser scanning“, Applied Physics Letters 104, 251106 (2014)

4.     M. Ugawa, H. Kobayashi, and K. Goda, “Ultrafast optical imaging for freezing fast dynamics”, Japanese Journal of Optics 3, 124 (2014)

5.     K. Nakagawa, I. Sakuma, F. Kannari, and K. Goda, “Motion picture femtophotography”, Optics & Photonics News 59, December (2014)

6.     M. Takahashi, Y. Sakaki, T. Ideguchi, and K. Goda, 「分散フーリエ分光法・デュアルコム分光法を用いた新規な超高速分光測定」, 分光研究 63, 5, 210 (2014)

7.     M. Ugawa, T. Ideguchi, and K. Goda, 「迅速・非侵襲に血中がん細胞を発見するカメラ」, PET Journal 28, 28 (2014)

8.     K. Nakagawa and K. Goda, 1兆分の1秒以下の世界を捉える連写カメラ」, セラミックス 49, 12 (2014)

9.     A. Nakagawa, K. Ohtani, K. Goda, R. Armonda, and E. Tominaga, 「爆風による外傷性脳損傷 (blast-induced traumatic brain injury), Annual Review 神経, 192 (2014)

10.  B. Jalali, M. Li, K. Goda, and M. H. Asghari, “Real-time photonic measurements, data management, and processing”, Proceedings of SPIE 9279 (2014)

11.  M. Ugawa, B. Jalali, and K. Goda, “Dispersive Fourier transformation for spectroscopy and imaging of non-repetitive dynamics”, 日本分光学会年次講演会 (2014)

 

2013

1.     K. Goda and B. Jalali, “Dispersive Fourier transformation for fast continuous single-shot measurements“, Nature Photonics 7, 102 (2013)

2.     H. Chen, C. Wang, A. Yazaki, C. Kim, K. Goda, and B. Jalali, “Ultrafast web inspection with hybrid dispersion laser scanner“, Applied Optics 52, 4072 (2013)

3.     A. Mahjoubfar, K. Goda, G. Betts, and B. Jalali, “Optically amplified detection for biomedical sensing and imaging“, Journal of Optical Society of America A 30, 2124 (2013)

4.     M. Takahashi and K. Goda, 「超高速光イメージング技術を用いた低コストがん診断法」, 映像情報インダストリアル, 5月号 (2013)

5.     T. Hattori, Y. Shimoda, H. Ishii, Y. Saito, T. Nakao, M. Watanabe, Y. Yoshitake, and K. Goda, 「欠陥検査のための空間-時間列変換を用いた超高速撮像技術」, 74回応用物理学会秋季学術講演会,京都 (2013)

6.     K. Goda, D. Di Carlo, and B. Jalali, “Ultrafast automated image cytometry for cancer detection”, 35th Annual International Conference of the IEEE Engineering in Medicine and Biology Society, Osaka, Japan (2013)

7.     K. Goda, G. Yu, Y. Wakisaka, and H. Kobayashi, “High-throughput image cytometry for rare cell detection”, JSAP Autumn Meeting, Kyoto, Japan (2013)

8.     K. Goda, B. Jalali, K. Hashimoto, S. Ueno, and S. Yamada, “Dispersive Fourier transformation and application to cancer detection”, Frontiers in Optics, Orlando, FL (2013)

9.     B. Jalali, E. D. Diebold, A. Mahjoubfar, B. W. Buckley, and K. Goda, “Ultrahigh throughput single cell imaging”, Frontiers in Optics, Orlando, FL (2013)

10.  A. Fard, C. Wang, O. Malik, G. Fu, A. Quach, K. Goda, and B. Jalali, “Near-100 MHz optical coherence tomography at 800 nm”, Symposium on Optical Coherence Tomography for Non-Destructive Testing, Linz, Austria (2013)

11.  A. Mahjoubfar, K. Goda, C. Wang, A. Fard, J. Adam, D. R. Gossett, A. Ayazi, E. Sollier, O. Malik, E. Chen, Y. Liu, R. Brown, N. Sarkhosh, D. Di Carlo, and B. Jalali, “3D ultrafast laser scanner”, SPIE Photonics West, San Francisco, CA (2013)

12.  H. Chen, K. Goda, C. Wang, and B. Jalali, “Ultrafast surface inspection using hybrid dispersion laser scanner”, CLEO Applications and Technology, San Jose, CA (2013)

13.  A. Ayazi, K. Goda, C. K. Lonappan, J. Adam, J. Sadasivam, D. R. Gossett, E. Sollier, A. Fard, S. C. Hur, C. Murray, C. Wang, N. Brackbill, D. Di Carlo, and B. Jalali, “Real-time image processor for detection of rare cells and particles in flow at 37 million line scans per second”, SPIE Photonics West, San Francisco, CA (2013)

 

2012

1.     K. Goda, A. Ayazi, D. R. Gossett, J. Sadasivam, C. K. Lonappan, E. Sollier, A. Fard, S. C. Hur, J. Adam, C. Murray, C. Wang, N. Brackbill, D. Di Carlo, and B. Jalali, “High-throughput single-microparticle imaging flow analyzer“, PNAS (2012)

2.     K. Goda, A. Mahjoubfar, C. Wang, A. Fard, J. Adam, D. R. Gossett, A. Ayazi, O. Malik, E. Chen, D. Di Carlo, and B. Jalali, “Hybrid dispersion laser scanner“, Scientific Reports 2, 445 (2012)

3.     D. R. Gossett, H. T. K. Tse, J. Dudani, K. Goda, T. Woods, S. Graves, and D. Di Carlo, “Inertial manipulation and transfer of microparticles across laminar fluid streams“, Small 8, 2757 (2012)

4.     K. Goda, A. Fard, O. Malik, G. Fu, A. Quach, and B. Jalali, “High-throughput optical coherence tomography at 800 nm“, Optics Express 20, 19612 (2012)

5.     D. R. Gossett, H. T. K. Tse, K. Goda, O. Adeyiga, T. A. Woods, S. W. Graves, O. O. Yang, and D. Di Carlo, “Leukocyte mechanophenotyping by deformability cytometry”, mTAS Conference, Okinawa, Japan (2012)

6.     C. Wang, K. Goda, M. Ibsen, and B. Jalali, “Dispersive Fourier transformation in the 800 nm spectral range”, Conference on Lasers and Electro Optics (CLEO), Baltimore, MD (2012)

7.     Z. Tan, C. Wang, K. Goda, O. Malik, and B. Jalali, “All-optical passive periodic sawtooth filter and its application to fast interrogation of fiber Bragg grating sensor array”, Optical Fiber Communication Conference and Exposition (OFC), Los Angeles, CA (2012)

 

2011

1.     S. H. Kim, K. Goda, A. Fard, and B. Jalali, “An optical time-domain analog pattern correlator for high-speed image recognition”, Optics Letters 36, 220 (2011)

2.     A. Fard, A. Mahjoubfar, K. Goda, D. R. Gossett, D. Di Carlo, and B. Jalali, “Nomarski serial time-encoded amplified microscopy for high-speed contrast-enhanced imaging of transparent media”, Biomedical Optics Express 2, 3387 (2011)

3.     A. Mahjoubfar, K. Goda, A. Ayazi, A. Fard, S. H. Kim, and B. Jalali, “High-speed nanometer-resolved imaging vibrometer and velocimeter”, Applied Physics Letters 98, 101107 (2011)

4.     Z. Tan, C. Wang, K. Goda, and B. Jalali, “Jammed-array wideband sawtooth filter”, Optics Express 19, 24563 (2011)

5.     K. Goda, D. R. Gossett, A. Ayazi, E. Sollier, C. S. Hur, A. Fard, D. Di Carlo, and B. Jalali, “Development of high-throughput imaging flow cytometry for real-time cancer diagnostics and therapy”, Era of Hope Conference, Orlando, FL (2011)

6.     B. Jalali, K. Goda, A. Fard, and S. H. Kim, “From analog-to-digital conversion to blood screening: evolution of photonic time stretch”, Conference on Lasers and Electro Optics (CLEO), Baltimore, MD (2011)

7.     K. Goda, A. Mahjoubfar, A. Ayazi, A. Fard, S. H. Kim, and B. Jalali, “High-speed nanometer-resolved multi-dimensional imaging-based laser vibrometry”, Conference on Lasers and Electro Optics (CLEO), Baltimore, MD (2011)

8.     A. Fard, A. Mahjoubfar, K. Goda, and B. Jalali, “Nomarski serial-time encoded amplified microscopy for high-throughput imaging of transparent media”, Conference on Lasers and Electro Optics (CLEO), Baltimore, MD (2011)

 

2010

1.     K. Goda and B. Jalali, “Noise figure of amplified dispersive Fourier transformation”, Physical Review A 82, 033827 (2010)

2.     B. Jalali, D. R. Solli, K. Goda, K. Tsia, and C. Ropers, “Real-time measurements, rare events, and photon economics”, European Journal of Physics Special Topics 185, 145 (2010)

3.     B. Jalali, K. Goda, P. Soon-Shiong, and K. K. Tsia, “Time-stretch imaging and its applications to high-throughput microscopy and microsurgery”, IEEE Photonics Society Newsletter 24, 11 (2010)

4.     B. Jalali, P. Soon-Shiong, and K. Goda, “Breaking speed and sensitivity limits”, Optik & Photonik 2, 32 (2010)

5.     K. K. Tsia, K. Goda, D. Capewell, and B. Jalali, “Performance of serial time-encoded amplified microscope”, Optics Express 18, 10016 (2010)

6.     The LIGO Scientific Collaboration and the VIRGO Collaboration, “Searches for gravitational waves from known pulsars with Science Run 5 LIGO data”, The Astrophysical Journal 713, 671 (2010)

7.     The LIGO Scientific Collaboration and the VIRGO Collaboration, “Search for gravitational-wave bursts associated with gamma-ray bursts using data from LIGO Science Run 5 and VIRGO Science Run 1”, The Astrophysical Journal 715, 1438 (2010)

8.     K. Goda and B. Jalali, “Serial time-encoded amplified microscopy (STEAM) for high-throughput detection of rare cells”, IEEE Photonics Society Winter Topicals, Majorca, Spain (2010)

9.     A. Nakagawa, T. Arafune, M. Fujimura, K. Ohtani, H. Yamamoto, T. Matsunaga, T. Washio, A. Tsukamoto, T. Nakano, M. Nakai, M. Yamada, C. Sato, K. Goda, Y. Ogawa, S. Miyazaki, M. Sun, T. Kumabe, Y. Haga, T. Ushida, K. Takayama, S. Nishino, M. Niinomi, I. Sakuma, and T. Tominaga, “Bench top animal model for blast-induced traumatic brain injury using microexplosives: difference of pathology by the presence of the skull”, Seventh International Conference on Flow Dynamics, Sendai, Japan (2010)

10.  B. Jalali, K. Goda, and K. K. Tsia, “High-throughput imaging technology for real-time cancer diagnostics and therapy”, SPIE Optics & Photonics, San Diego, CA (2010)

11.  K. Goda, A. Motafakker-Fard, and B. Jalali, “Dispersive Fourier-transform spectral interferometry for ultrafast real-time axial profiling of multi-layer objects”, SPIE Photonics West, San Francisco, CA (2010)

12.  K. K. Tsia, K. Goda, and B. Jalali, “Performance of serial-time encoded amplified microscopy”, Conference on Lasers and Electro Optics (CLEO), San Jose, CA (2010)

13.  A. Mahjoubfar, K. Goda, and B. Jalali, “Raman amplification at 800 nm in single-mode fiber for biological sensing and imaging”, Conference on Lasers and Electro Optics (CLEO), San Jose, CA (2010)

 

2009

1.     K. Goda, K. K. Tsia, and B. Jalali, “Serial time-encoded amplified imaging for real-time observation of fast dynamic phenomena“, Nature 458, 1145 (2009)

2.     The LIGO Scientific Collaboration and the VIRGO Collaboration, “An upper limit on the stochastic gravitational-wave background of cosmological origin“, Nature 460, 990 (2009)

3.     K. Goda, D. R. Solli, K. K. Tsia, and B. Jalali, “Theory of amplified dispersive Fourier transformation“, Physical Review A 80, 043821 (2009)

4.     K. Goda, A. Mahjoubfar, and B. Jalali, “Demonstration of Raman gain at 800 nm in single-mode fiber and its potential application to biological sensing and imaging”, Applied Physics Letters 95, 251101 (2009)

5.     K. K. Tsia, K. Goda, D. Capewell, and B. Jalali, “Simultaneous mechanical-scan-free confocal microscopy and laser microsurgery”, Optics Letters 34, 2099 (2009)

6.     K. Goda, 「光情報処理を用いた超高速イメージング法」, OptoNews 3, 7 (2009)

7.     The LIGO Scientific Collaboration, “All-sky LIGO search for periodic gravitational waves in the early fifth-science-run data”, Physical Review Letters 102, 111102 (2009)

8.     The LIGO Scientific Collaboration, “LIGO: the laser interferometer gravitational-wave observatory”, Reports on Progress in Physics 72, 076901 (2009)

9.     The LIGO Scientific Collaboration, “Einstein@Home search for periodic gravitational waves in LIGO S4 data”, Physical Review D 79, 022001 (2009)

10.  The LIGO Scientific Collaboration, “Einstein@Home search for periodic gravitational waves in early S5 LIGO data”, Physical Review D 80, 042003 (2009)

11.  The LIGO Scientific Collaboration, “Search for gravitational waves from low mass binary coalescences in the first year of LIGO’s S5 data”, Physical Review D 79, 122001 (2009)

12.  The LIGO Scientific Collaboration, “Search for gravitational waves from low mass compact binary coalescence in 186 days of LIGO’s fifth science run”, Physical Review D 80, 047101 (2009)

13.  The LIGO Scientific Collaboration, “Search for gravitational wave ringdowns from perturbed black holes in LIGO S4 data”, Physical Review D 80, 062001 (2009)

14.  The LIGO Scientific Collaboration, “First LIGO search for gravitational wave bursts from cosmic (super)strings”, Physical Review D 80, 062002 (2009)

15.  The LIGO Scientific Collaboration, “Search for high frequency gravitational-wave bursts in the first calendar year of LIGO’s fifth science run”, Physical Review D 80, 102002 (2009)

16.  The LIGO Scientific Collaboration, “Search for gravitational-wave bursts in the first year of the fifth LIGO science run”, Physical Review D 80, 102001 (2009)

17.  The LIGO Scientific Collaboration, “Stacked search for gravitational waves from the 2006 SGR 1900+14 storm”, Astrophysical Journal Letters 701, L68 (2009)

18.  The LIGO Scientific Collaboration, “Observation of a kilogram-scale oscillator near its quantum ground state”, New Journal of Physics 11, 073032 (2009)

19.  K. Goda and B. Jalali, “Serial time-encoded amplified imaging – the world’s fastest imaging system”, International Imaging Industry Association Annual Meeting, Monterey, CA (2009)

20.  K. K. Tsia, K. Goda, and B. Jalali, “Mechanical-scan-free laser microsurgery with simultaneous spectrally-encoded confocal microscopy”, Novel Techniques in Microscopy (NTM), Vancouver, Canada (2009)

21.  K. Goda, K. K. Tsia, and B. Jalali, “Serial time-encoded amplified microscopy (STEAM)”, Conference on Lasers and Electro Optics (CLEO), Baltimore, MD (2009)

22.  K. Goda, A. Fard, and B. Jalali, “Phase-contrast serial time-encoded amplified microscopy”, European Conference on Lasers and Electro Optics (CLEO) and European Quantum Electronics Conference, Munich, Germany (2009)

 

2008

1.     K. Goda, O. Miyakawa, E. E. Mikhailov, S. Saraf, R. Adhikari, K. McKenzie, R. Ward, S. Vass, A. J. Weinstein, and N. Mavalvala, “A quantum-enhanced prototype gravitational-wave detector“, Nature Physics 4, 472 (2008)

2.     K. Goda, K. K. Tsia, and B. Jalali, “Amplified dispersive Fourier-transform imaging for ultrafast displacement sensing and barcode reading”, Applied Physics Letters 93, 131109 (2008)

3.     K. Goda, D. R. Solli, and B. Jalali, “Real-time optical reflectometry enabled by amplified dispersive Fourier transformation”, Applied Physics Letters 93, 031106 (2008)

4.     K. Goda, E. E. Mikhailov, O. Miyakawa, S. Saraf, S. Vass, A. J. Weinstein, and N. Mavalvala, “Generation of a stable low-frequency squeezed vacuum field with periodically-poled KTiOPO4 at 1064 nm”, Optics Letters 33, 92 (2008)

5.     The LIGO Scientific Collaboration, “Search for gravitational-wave bursts from soft gamma repeaters”, Physical Review Letters 101, 211102 (2008)

6.     The LIGO Scientific Collaboration, “Search for S3 LIGO data for gravitational wave signals from spinning black hole and neutron star binary inspirals”, Physical Review D 78, 042002 (2008)

7.     The LIGO Scientific Collaboration, “Search for gravitational waves from binary inspirals in S3 and S4 LIGO data”, Physical Review D 77, 062002 (2008)

8.     The LIGO Scientific Collaboration, “Search for gravitational waves associated with 39 gamma-ray bursts using data from the second, third, and fourth LIGO runs”, Physical Review D 77, 062004 (2008)

9.     The LIGO Scientific Collaboration, “First cross-correlation analysis of interferometric and resonant-bar gravitational-wave data for stochastic backgrounds”, Physical Review D 77, 022001 (2008)

10.  The LIGO Scientific Collaboration, “Implications for the origin of GRB 070201 from LIGO observations”, The Astrophysical Journal 681, 1419 (2008)

11.  The LIGO Scientific Collaboration, “Beating the spin-down limit on gravitational wave emission from the Crab Pulsar” Astrophysical Journal Letters 683, L45 (2008)

12.  The LIGO Scientific Collaboration, “A joint search for gravitational wave bursts with AURIGA and LIGO”, Classical and Quantum Gravity 25, 095004 (2008)

13.  The LIGO Scientific Collaboration, “First joint search for gravitational-wave bursts in LIGO and GEO 600 data”, Classical and Quantum Gravity 25, 245008 (2008)

14.  K. Goda, K. K. Tsia, and B. Jalali, “Amplified dispersive Fourier-transform imaging for ultrafast displacement sensing and barcode reading”, IEEE Photonics Society Annual Meeting, Newport, CA (2008)

 

2007

1.     K. Somiya, K. Goda, Y. Chen, and E. E. Mikhailov, “Utility investigation of artificial time delay in displacement-noise-free interferometers”, Physical Review D 76, 022002 (2007)

2.     The LIGO Scientific Collaboration, “Searches for periodic gravitational waves from unknown isolated sources and Scorpius X-1: results from the second LIGO science run”, Physical Review D 76, 082001 (2007)

3.     The LIGO Scientific Collaboration, “Search for gravitational wave radiation associated with the pulsating tail of the SGR 1806-20 hyperflare of 27 December 2004 using LIGO”, Physical Review D 76, 062003 (2007)

4.     The LIGO Scientific Collaboration, “Upper limits on gravitational wave emission from 78 radio pulsars”, Physical Review D 76, 042001 (2007)

5.     The LIGO Scientific Collaboration, “Upper limit map of a background of gravitational waves”, Physical Review D 76, 082003 (2007)

6.     The LIGO Scientific Collaboration, “First cross-correlation analysis of interferometric and resonant-bar gravitational-wave data for stochastic backgrounds”, Physical Review D 76, 022001 (2007)

7.     The LIGO Scientific Collaboration, “Search for gravitational-wave bursts in LIGO data from the fourth science run”, Classical and Quantum Gravity 24, 5343 (2007)

8.     The LIGO Scientific Collaboration, “Searching for a stochastic background of gravitational waves with LIGO”, The Astrophysical Journal 659, 918 (2007)

9.     K. Goda, E. E. Mikhailov, and N. Mavalvala, “Experimental demonstration of a squeezing-enhanced laser-interferometric gravitational-wave detector”, LIGO Scientific Collaboration / VIRGO March Meeting, Livingston, LA (2007)

10.  S. Saraf, K. Goda, N. Mavalvala, E. Mikhailov, and O. Miyakawa, “Generation of a squeezed vacuum field with PPKTP at 1064 nm for gravitational wave interferometers”, Advanced Solid State Photonics, Vancouver, Canada (2007)

 

2006

1.     G. Popescu, T. Ikeda, K. Goda, C. A. Best, M. Laposata, S. Manley, R. R. Dasari, K. Badizadegan, and M. Feld, “Optical measurement of cell membrane tension”, Physical Review Letters 97, 218101 (2006)

2.     Y. Chen, A. Pai, K. Somiya, S. Kawamura, S. Sato, K. Kokeyama, R. L. Ward, K. Goda, and E. E. Mikhailov, “Interferometers for displacement-noise-free gravitational-wave detection”, Physical Review Letters 97, 151103 (2006)

3.     E. E. Mikhailov, K. Goda, and N. Mavalvala, “Noninvasive measurements of cavity parameters by use of squeezed vacuum”, Physical Review A 74, 033817 (2006)

4.     E. E. Mikhailov, K. Goda, T. Corbitt, and N. Mavalvala, “Frequency-dependent squeeze-amplitude attenuation and squeeze-angle rotation by electromagnetically induced transparency for gravitational-wave interferometers”, Physical Review A 73, 053810 (2006)

5.     The LIGO Scientific Collaboration, “Joint LIGO and TAMA300 search for gravitational waves from inspiralling neutron star binaries”, Physical Review D 73, 102002 (2006)

6.     The LIGO Scientific Collaboration, “Search for gravitational waves from binary black hole inspirals in LIGO data”, Physical Review D 72, 062001 (2006)

7.     The LIGO Scientific Collaboration, “Search for gravitational-wave bursts in LIGO’s third science run”, Classical and Quantum Gravity 23, S29 (2006)

8.     G. Popescu, T. Ikeda, C. A. Best, K. Goda, K. Badizadegan, R. R. Dasari, and M. S. Feld, “Observation of apparent membrane tension in red blood cells using actively stabilized Hilbert phase microscopy”, Biomedical Topical Meeting, Fort Lauderdale, FL (2006)

 

2005

1.     K. McKenzie, E. E. Mikhailov, K. Goda, P. K. Lam, N. Grosse, M. B. Gray, N. Mavalvala, and D. E. McClelland, “Quantum noise locking”, Journal of Optics B: Quantum and Semiclassical Optics 7, S421 (2005)

2.     K. Goda, K. McKenzie, E. E. Mikhailov, P. K. Lam, D. E. McClelland, and N. Mavalvala, “Photothermal fluctuations as a fundamental limit to low-frequency squeezing in a degenerate optical parametric oscillator”, Physical Review A 72, 043819 (2005)

3.     The LIGO Scientific Collaboration, “Upper limits on a stochastic background of gravitational waves”, Physical Review Letters 95, 221101 (2005)

4.     The LIGO Scientific Collaboration, “Limits on gravitational-wave emission from selected pulsars using LIGO data”, Physical Review Letters 94, 181103 (2005)

5.     The LIGO Scientific Collaboration, “Search for gravitational waves associated with the gamma ray burst GRB030329 using the LIGO detectors”, Physical Review D 72, 042002 (2005)

6.     The LIGO Scientific Collaboration, “Upper limits on gravitational wave bursts in LIGO’s second science run”, Physical Review D 72, 062001 (2005)

7.     The LIGO Scientific Collaboration, “Upper limits from the LIGO and TAMA detectors on the rate of gravitational-wave bursts”, Physical Review D 72, 122004 (2005)

8.     The LIGO Scientific Collaboration, “Search for gravitational waves from galactic and extra-galactic binary neutron stars”, Physical Review D 72, 082001 (2005)

9.     The LIGO Scientific Collaboration, “Search for gravitational waves from primordial black hole binary coalescences in the galactic halo”, Physical Review D 72, 082002 (2005)

10.  The LIGO Scientific Collaboration, “First all-sky upper limits from LIGO on the strength of periodic gravitational waves using the Hough transform”, Physical Review D 72, 102004 (2005)

11.  K. Goda and N. Mavalvala, “Development of a stable low-frequency squeezed vacuum source for gravitational wave interferometers”, SPIE Fluctuations and Noise, Austin, TX (2005)

 

2004

1.     K. Goda, D. Ottaway, B. Connelly, R. Adhikari, N. Mavalvala, and A. Gretarsson, “Frequency resolving spatiotemporal wavefront sensor”, Optics Letters 29, 1452 (2004)

2.     The LIGO Scientific Collaboration, “First upper limits from LIGO on gravitational wave bursts”, Physical Review D 69, 102001 (2004)

3.     The LIGO Scientific Collaboration, “Analysis of LIGO data for gravitational waves from binary neutron stars”, Physical Review D 69, 122001 (2004)

4.     The LIGO Scientific Collaboration, “Setting upper limits on the strength of periodic gravitational waves from PSR J1939+2134 using the first science data from the GEO 600 and LIGO detectors”, Physical Review D 69, 082004 (2004)

5.     The LIGO Scientific Collaboration, “Analysis of first LIGO science data for stochastic gravitational waves”, Physical Review D 69, 122004 (2004)

6.     The LIGO Scientific Collaboration, “Detector description and performance for the first coincidence observations between LIGO and GEO”, Nuclear Instruments and Methods in Physics Research Section A 517, 154 (2004)