Abstract
Optical techniques are one of the most useful methods for elucidating how the brain works. In particular, by using a potential-sensitive dye [1] or a calcium probe, potential changes in cell membrane or Ca2+ ion concentration associated with neural activities can be converted to fluorescence intensity. Visualizing neural activity by combining these and microscopic techniques is widely used in recent neurosciences.
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References
Blasdel GG, Salama G (1986) Nature 321:579–585
Nakai J, Ohkura M, Imoto K (2001) Nat Biotechnol 19:137–141
Dombeck DA, Graziano MS, Tank DW (2009) J Neurosci 29:13751–13760
Ferezou I, Bolea S, Petersen CCH (2006) Neuron 50:617–629. Sawinski J, Wallace DJ, Greenberg DS, Grossmann S, Denk W, Kerr JN (2009) Proc Natl Acad Sci USA 106:19557–19562
Ghosh KK, Burns LD, Cocker ED, Nimmerjahn A, Ziv Y, El Gamal A, Schnitzer MJ (2011) Nat Methods 8:871–878
UCLA miniscope project. https://miniscope.org
Ohta J, Higuchi A, Tagawa A, Sasagawa K, Tokuda T, Hatanaka Y, Ishikawa Y Shiosaka S (2008) An implantable CMOS image sensor for monitoring deep brain activities of a freely moving mouse. In: 2008 IEEE biomedical circuits and systems conference. IEEE, pp 269–272
Ohta J, Tokuda T, Sasagawa K, Noda T (2009) Sensors 9, 9073–9093
Ohta J, Ohta Y, Takehara H, Noda T, Sasagawa K, Tokuda T, Haruta M, Kobayashi T, Akay YM, Akay M (2017) Proc IEEE 105:158–166
Takehara H, Katsuragi Y, Ohta Y, Motoyama M, Takehara H, Noda T, Sasagawa K, Tokuda T, Ohta J (2016) Appl Phys Express 9:047001
Kobayashi T, Motoyama M, Masuda H, Ohta Y, Haruta M, Noda T, Sasagawa K, Tokuda T, Tamura H, Ishikawa Y, Shiosaka S, Ohta J (2012) Biosens Bioelectron 38:321–330
Haruta M, Sunaga Y, Yamaguchi T, Takehara H, Noda T, Sasagawa K, Tokuda T, Ohta J (2015) Jpn J Appl Phys 54:04DL10. Sunaga Y, Yamaura H, Haruta M, Yamaguchi T, Motoyama M, Ohta Y, Takehara H, Noda T, Sasagawa K, Tokuda T, Yoshimura Y (2016) Implantable imaging device for brain functional imaging system using flavoprotein fluorescence. Jpn J Appl Phys 55(3S2):03DF02
Wong WS, Sands T, Cheung NW, Kneissl M, Bour DP, Mei P, Romano LT, Johnson NM (1999) Appl Phys Lett 75:1360–1362
Sasagawa K, Haruta M, Fujimoto K, Ohta Y, Noda T, Tokuda T, Ohta J (2017) The 13th IEEE BioCAS (BioCAS2017)
Sasagawa K, Yamaguchi T, Haruta M, Sunaga Y, Ohta Y, Takehara H, Takehara H, Noda T, Tokuda T, Ohta J (2016) Ext. Abstr. Solid state devices and materials, H-4-05
Sasagawa K, Kimura A, Haruta M, Noda T, Tokuda T, Ohta J (2018) Biomed Opt Express 9:4329–4344
Sasagawa K, Ohta Y, Kawahara M, Haruta M, Noda T, Tokuda T, Ohta J (2019) AIP Adv 9:035108
Hee WS, Sasagawa K, Kameyama A, Kimura A, Haruta M, Tokuda T, Ohta J (2019) Lens-free dual-color fluorescent CMOS image sensor for Förster resonance energy transfer imaging. Sens Mater 31(8):2579–2594
Sasagawa K, Ohta Y, Haruta M, Noda T, Tokuda T, Ohta J (2018) IEEE BioCAS 2018. Cleveland, OH, USA
Rustami E, Sasagawa K, Ohta Y, Haruta M, Noda T, Tokuda T, Ohta J (2019) A thin composite emission filter and fiber coupled laser excitation for implantable fluorescence imager application. In: 2019 IEEE international symposium on circuits and systems (ISCAS)Â A2L-I-2, Sapporo, Japan
Rustami E, Sasagawa K, Sugie K, Ohta Y, Haruta M, Noda T, Tokuda T, Ohta J, Needle-type image sensor with band-pass composite emission filter and parallel fiber-coupled laser excitation. IEEE Trans Circ Syst I (to be published)
Wang A, Molnar A (2012) A light-field image sensor in 180 nm CMOS. J Solid-State Circ 47(1):257–271. https://doi.org/10.1109/JSSC.2011.2164669
Adams JK, Boominathan V, Avants BW, Vercosa DG, Ye F, Baraniuk RG, Robinson JT, Veeraraghavan A (2017) Sci Adv 3:e1701548
Sugie K, Sasagawa K, Guinto MC, Haruta M, Tokuda T, Ohta J (2019) Electron Lett 55(13):729–731
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Sasagawa, K., Haruta, M., Ohta, Y., Takehara, H., Tokuda, T., Ohta, J. (2020). Implantable CMOS Fluorescent Imaging Devices. In: Tsytsarev, V., Yamamoto, V., Zhong, N. (eds) Functional Brain Mapping: Methods and Aims. Brain Informatics and Health. Springer, Singapore. https://doi.org/10.1007/978-981-15-6883-1_6
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