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Y. Matsumoto, Y. Asao, Y. Asao, A. Yoshikawa, H. Sekiguchi, M. Takada, M. Furu, S. Saito, M. Kataoka, Hideaki Abe, T. Yagi, K. Togashi, Masakazu Toi (2018)
Label-free photoacoustic imaging of human palmar vessels: a structural morphological analysisScientific Reports, 8
Chulhong Kim, C. Favazza, Lihong Wang (2010)
In vivo photoacoustic tomography of chemicals: high-resolution functional and molecular optical imaging at new depths.Chemical reviews, 110 5
Masakazu Toi, Y. Asao, Y. Matsumoto, H. Sekiguchi, A. Yoshikawa, M. Takada, M. Kataoka, Takaaki Endo, N. Kawaguchi‐Sakita, M. Kawashima, E. Fakhrejahani, S. Kanao, Iku Yamaga, Y. Nakayama, M. Tokiwa, M. Torii, T. Yagi, T. Sakurai, K. Togashi, T. Shiina (2017)
Visualization of tumor-related blood vessels in human breast by photoacoustic imaging system with a hemispherical detector arrayScientific Reports, 7
B. Pogue, S. Davis, F. Leblond, Michael Mastanduno, H. Dehghani, K. Paulsen (2011)
Implicit and explicit prior information in near-infrared spectral imaging: accuracy, quantification and diagnostic valuePhilosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 369
Minghua Xu, Lihong Wang (2005)
Universal back-projection algorithm for photoacoustic computed tomography, 5697
TW Sederberg (1986)
Free-form deformation of solid geometric modelsProc SIGGRAPH’86, 20
A. Makris, T. Powles, S. Kakolyris, M. Dowsett, S. Ashley, A. Harris (1999)
Reduction in angiogenesis after neoadjuvant chemoendocrine therapy in patients with operable breast carcinomaCancer, 85
J. Xia, A. Danielli, Yan Liu, Lidai Wang, K. Maslov, Lihong Wang (2013)
Calibration-free quantification of absolute oxygen saturation based on the dynamics of photoacoustic signals.Optics letters, 38 15
Hao Zhang, K. Maslov, G. Stoica, Lihong Wang (2006)
Functional photoacoustic microscopy for high-resolution and noninvasive in vivo imagingNature Biotechnology, 24
Home page of the ImPACT program
I. Wygant, X. Zhuang, D. Yeh, O. Oralkan, A. Ergun, M. Karaman, B. Khuri-Yakub (2008)
Integration of 2D CMUT arrays with front-end electronics for volumetric ultrasound imagingIEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control, 55
Xueding Wang, Xueyi Xie, G. Ku, Lihong Wang, G. Stoica (2006)
Noninvasive imaging of hemoglobin concentration and oxygenation in the rat brain using high-resolution photoacoustic tomography.Journal of biomedical optics, 11 2
K. Fukutani, Y. Someda, Masakazu Taku, Y. Asao, S. Kobayashi, T. Yagi, M. Yamakawa, T. Shiina, T. Sugie, M. Toi (2011)
Characterization of photoacoustic tomography system with dual illumination, 7899
R. Kruger, C. Kuzmiak, R. Lam, D. Reinecke, S. Rio, Doreen Steed (2013)
Dedicated 3D photoacoustic breast imaging.Medical physics, 40 11
G. Quarto, L. Spinelli, A. Pifferi, A. Torricelli, R. Cubeddu, F. Abbate, Nicola Balestreri, S. Menna, E. Cassano, P. Taroni (2014)
Estimate of tissue composition in malignant and benign breast lesions by time-domain optical mammography.Biomedical optics express, 5 10
M. Milani, A. Harris (2008)
Targeting tumour hypoxia in breast cancer.European journal of cancer, 44 18
T. Shiina (2016)
Innovative photoacoustic imaging technology to support vascular health science2016 Conference on Lasers and Electro-Optics (CLEO)
E. Fakhrejahani, M. Torii, Toshiyuki Kitai, S. Kanao, Y. Asao, Yohei Hashizume, Y. Mikami, Iku Yamaga, M. Kataoka, T. Sugie, M. Takada, H. Haga, K. Togashi, T. Shiina, M. Toi (2015)
Clinical Report on the First Prototype of a Photoacoustic Tomography System with Dual Illumination for Breast Cancer ImagingPLoS ONE, 10
Toshiyuki Kitai, M. Torii, T. Sugie, S. Kanao, Y. Mikami, T. Shiina, M. Toi (2014)
Photoacoustic mammography: initial clinical resultsBreast Cancer, 21
Jing Meng, Lihong Wang, L. Ying, D. Liang, Liang Song (2012)
Compressed-sensing photoacoustic computed tomography in vivo with partially known supportOptics Express, 20
Jeesu Kim, Sara Park, Y. Jung, Sun-yeob Chang, Jin-Yeol Park, Yumiao Zhang, J. Lovell, Chulhong Kim (2016)
Programmable Real-time Clinical Photoacoustic and Ultrasound Imaging SystemScientific Reports, 6
T. Sederberg, S. Parry (1986)
Free-form deformation of solid geometric modelsProceedings of the 13th annual conference on Computer graphics and interactive techniques
P. Viacava, A. Naccarato, G. Bocci, G. Fanelli, P. Aretini, A. Lonobile, G. Evangelista, G. Montruccoli, G. Bevilacqua (2004)
Angiogenesis and VEGF expression in pre‐invasive lesions of the human breastThe Journal of Pathology, 204
Y. Asao, Yohei Hashizume, T. Suita, Ken-ichi Nagae, K. Fukutani, Yoshiaki Sudo, Toshikazu Matsushita, S. Kobayashi, M. Tokiwa, Iku Yamaga, E. Fakhrejahani, M. Torii, M. Kawashima, M. Takada, S. Kanao, M. Kataoka, T. Shiina, M. Toi (2016)
Photoacoustic mammography capable of simultaneously acquiring photoacoustic and ultrasound imagesJournal of Biomedical Optics, 21
To practically apply photoacoustic (PA) imaging technology in medicine, we have developed prototypes of a photoacoustic mammography (PAM) device to acquire images for diagnosing breast cancer in the Kyoto University/Canon joint research project (CK project supported by MEXT, Japan). First, the basic ability of the PAM system to visualize the network of blood vessels and the Hb saturation index was evaluated using a prototype of PAM that has a flat scanning detector and is capable of simultaneously acquiring photoacoustic (PA) and ultrasound images. Next, another prototype of a PAM device with hemispherical sensors was developed to improve the visibility of the 3D structure of vessels by reducing the limited view effect. In clinical examination of breast cancer cases, the PAM system allowed 3D visualization of fine vessel networks with a spatial resolution of a half-millimeter and enabled us to determine the features of tumor-related vascular structures in human breast cancer. In addition, the oxygen saturation status of Hb was visualized using two different wavelengths, enabling more precise characterization of the tumor microenvironment. Results of clinical evaluation using our developed prototype of a PAM device confirmed that PA imaging technology has the potential to promote early detection of breast cancer, and realization of its practical use is expected in the near future.
Biomedical Engineering Letters – Springer Journals
Published: May 7, 2018
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