Fluorescence lifetime imaging of calcium flux in neurons in response to pulsed infrared light

Alex J. Walsh; Anna Sedelnikova; Gleb P. Tolstykh; Bennett L. Ibey; Hope T. Beier

doi:10.1117/12.2249522

Fluorescence lifetime imaging of calcium flux in neurons in response to pulsed infrared light

Alex J. Walsh, Anna Sedelnikova, Gleb P. Tolstykh, Bennett L. Ibey, Hope T. Beier

Department of Cellular & Integrative Physiology

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

5 Scopus citations

Abstract

Pulsed infrared light can excite action potentials in neurons; yet, the fundamental mechanism underlying this phenomenon is unknown. Previous work has observed a rise in intracellular calcium concentration following infrared exposure, but the source of the calcium and mechanism of release is unknown. Here, we used fluorescence lifetime imaging of Oregon Green BAPTA-1 to study intracellular calcium dynamics in primary rat hippocampal neurons in response to infrared light exposure. The fluorescence lifetime of Oregon Green BAPTA-1 is longer when bound to calcium, and allows robust measurement of intracellular free calcium concentrations. First, a fluorescence lifetime calcium calibration curve for Oregon Green BAPTA-1 was determined in solutions. The normalized amplitude of the short and long lifetimes was calibrated to calcium concentration. Then, neurons were incubated in Oregon Green BAPTA-1 and exposed to pulses of infrared light (0-1 J/cm2; 0-5 ms; 1869 nm). Fluorescence lifetime images were acquired prior to, during, and after the infrared exposure. Fluorescence lifetime images, 64x64 pixels, were acquired at 12 or 24 ms for frame rates of 83 and 42 Hz, respectively. Accurate α₁ approximations were achieved in images with low photon counts by computing an α₁ index value from the relative probability of the observed decay events. Results show infrared light exposure increases intracellular calcium in neurons. Altogether, this study demonstrates accurate fluorescence lifetime component analysis from low-photon count data for improved imaging speed.

Original language	English (US)
Title of host publication	Multiphoton Microscopy in the Biomedical Sciences XVII
Editors	Karsten Konig, Peter T. C. So, Ammasi Periasamy, Xiaoliang S. Xie
Publisher	SPIE
ISBN (Electronic)	9781510605794
DOIs	https://doi.org/10.1117/12.2249522
State	Published - 2017
Event	Multiphoton Microscopy in the Biomedical Sciences XVII - San Francisco, United States Duration: Jan 29 2017 → Jan 31 2017

Publication series

Name	Progress in Biomedical Optics and Imaging - Proceedings of SPIE
Volume	10069
ISSN (Print)	1605-7422

Other

Other	Multiphoton Microscopy in the Biomedical Sciences XVII
Country/Territory	United States
City	San Francisco
Period	1/29/17 → 1/31/17

Keywords

Oregon Green BAPTA-1
fluorescence lifetime imaging
infrared neural stimulation
time-correlated single photon counting

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Atomic and Molecular Physics, and Optics
Biomaterials
Radiology Nuclear Medicine and imaging

Access to Document

10.1117/12.2249522

Cite this

Walsh, A. J., Sedelnikova, A., Tolstykh, G. P., Ibey, B. L., & Beier, H. T. (2017). Fluorescence lifetime imaging of calcium flux in neurons in response to pulsed infrared light. In K. Konig, P. T. C. So, A. Periasamy, & X. S. Xie (Eds.), Multiphoton Microscopy in the Biomedical Sciences XVII [100691B] (Progress in Biomedical Optics and Imaging - Proceedings of SPIE; Vol. 10069). SPIE. https://doi.org/10.1117/12.2249522

Fluorescence lifetime imaging of calcium flux in neurons in response to pulsed infrared light. / Walsh, Alex J.; Sedelnikova, Anna; Tolstykh, Gleb P. et al.
Multiphoton Microscopy in the Biomedical Sciences XVII. ed. / Karsten Konig; Peter T. C. So; Ammasi Periasamy; Xiaoliang S. Xie. SPIE, 2017. 100691B (Progress in Biomedical Optics and Imaging - Proceedings of SPIE; Vol. 10069).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Walsh, AJ, Sedelnikova, A, Tolstykh, GP, Ibey, BL & Beier, HT 2017, Fluorescence lifetime imaging of calcium flux in neurons in response to pulsed infrared light. in K Konig, PTC So, A Periasamy & XS Xie (eds), Multiphoton Microscopy in the Biomedical Sciences XVII., 100691B, Progress in Biomedical Optics and Imaging - Proceedings of SPIE, vol. 10069, SPIE, Multiphoton Microscopy in the Biomedical Sciences XVII, San Francisco, United States, 1/29/17. https://doi.org/10.1117/12.2249522

Walsh, Alex J. ; Sedelnikova, Anna ; Tolstykh, Gleb P. et al. / Fluorescence lifetime imaging of calcium flux in neurons in response to pulsed infrared light. Multiphoton Microscopy in the Biomedical Sciences XVII. editor / Karsten Konig ; Peter T. C. So ; Ammasi Periasamy ; Xiaoliang S. Xie. SPIE, 2017. (Progress in Biomedical Optics and Imaging - Proceedings of SPIE).

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title = "Fluorescence lifetime imaging of calcium flux in neurons in response to pulsed infrared light",

abstract = "Pulsed infrared light can excite action potentials in neurons; yet, the fundamental mechanism underlying this phenomenon is unknown. Previous work has observed a rise in intracellular calcium concentration following infrared exposure, but the source of the calcium and mechanism of release is unknown. Here, we used fluorescence lifetime imaging of Oregon Green BAPTA-1 to study intracellular calcium dynamics in primary rat hippocampal neurons in response to infrared light exposure. The fluorescence lifetime of Oregon Green BAPTA-1 is longer when bound to calcium, and allows robust measurement of intracellular free calcium concentrations. First, a fluorescence lifetime calcium calibration curve for Oregon Green BAPTA-1 was determined in solutions. The normalized amplitude of the short and long lifetimes was calibrated to calcium concentration. Then, neurons were incubated in Oregon Green BAPTA-1 and exposed to pulses of infrared light (0-1 J/cm2; 0-5 ms; 1869 nm). Fluorescence lifetime images were acquired prior to, during, and after the infrared exposure. Fluorescence lifetime images, 64x64 pixels, were acquired at 12 or 24 ms for frame rates of 83 and 42 Hz, respectively. Accurate α1 approximations were achieved in images with low photon counts by computing an α1 index value from the relative probability of the observed decay events. Results show infrared light exposure increases intracellular calcium in neurons. Altogether, this study demonstrates accurate fluorescence lifetime component analysis from low-photon count data for improved imaging speed.",

keywords = "Oregon Green BAPTA-1, fluorescence lifetime imaging, infrared neural stimulation, time-correlated single photon counting",

author = "Walsh, {Alex J.} and Anna Sedelnikova and Tolstykh, {Gleb P.} and Ibey, {Bennett L.} and Beier, {Hope T.}",

note = "Funding Information: National Research Council Research Associateship Program (AW), AFOSR LRIR #14RH02COR and #15RHCOR204. Publisher Copyright: {\textcopyright} 2017 SPIE.; Multiphoton Microscopy in the Biomedical Sciences XVII ; Conference date: 29-01-2017 Through 31-01-2017",

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AU - Walsh, Alex J.

AU - Sedelnikova, Anna

AU - Tolstykh, Gleb P.

AU - Ibey, Bennett L.

AU - Beier, Hope T.

PY - 2017

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N2 - Pulsed infrared light can excite action potentials in neurons; yet, the fundamental mechanism underlying this phenomenon is unknown. Previous work has observed a rise in intracellular calcium concentration following infrared exposure, but the source of the calcium and mechanism of release is unknown. Here, we used fluorescence lifetime imaging of Oregon Green BAPTA-1 to study intracellular calcium dynamics in primary rat hippocampal neurons in response to infrared light exposure. The fluorescence lifetime of Oregon Green BAPTA-1 is longer when bound to calcium, and allows robust measurement of intracellular free calcium concentrations. First, a fluorescence lifetime calcium calibration curve for Oregon Green BAPTA-1 was determined in solutions. The normalized amplitude of the short and long lifetimes was calibrated to calcium concentration. Then, neurons were incubated in Oregon Green BAPTA-1 and exposed to pulses of infrared light (0-1 J/cm2; 0-5 ms; 1869 nm). Fluorescence lifetime images were acquired prior to, during, and after the infrared exposure. Fluorescence lifetime images, 64x64 pixels, were acquired at 12 or 24 ms for frame rates of 83 and 42 Hz, respectively. Accurate α1 approximations were achieved in images with low photon counts by computing an α1 index value from the relative probability of the observed decay events. Results show infrared light exposure increases intracellular calcium in neurons. Altogether, this study demonstrates accurate fluorescence lifetime component analysis from low-photon count data for improved imaging speed.

AB - Pulsed infrared light can excite action potentials in neurons; yet, the fundamental mechanism underlying this phenomenon is unknown. Previous work has observed a rise in intracellular calcium concentration following infrared exposure, but the source of the calcium and mechanism of release is unknown. Here, we used fluorescence lifetime imaging of Oregon Green BAPTA-1 to study intracellular calcium dynamics in primary rat hippocampal neurons in response to infrared light exposure. The fluorescence lifetime of Oregon Green BAPTA-1 is longer when bound to calcium, and allows robust measurement of intracellular free calcium concentrations. First, a fluorescence lifetime calcium calibration curve for Oregon Green BAPTA-1 was determined in solutions. The normalized amplitude of the short and long lifetimes was calibrated to calcium concentration. Then, neurons were incubated in Oregon Green BAPTA-1 and exposed to pulses of infrared light (0-1 J/cm2; 0-5 ms; 1869 nm). Fluorescence lifetime images were acquired prior to, during, and after the infrared exposure. Fluorescence lifetime images, 64x64 pixels, were acquired at 12 or 24 ms for frame rates of 83 and 42 Hz, respectively. Accurate α1 approximations were achieved in images with low photon counts by computing an α1 index value from the relative probability of the observed decay events. Results show infrared light exposure increases intracellular calcium in neurons. Altogether, this study demonstrates accurate fluorescence lifetime component analysis from low-photon count data for improved imaging speed.

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KW - fluorescence lifetime imaging

KW - infrared neural stimulation

KW - time-correlated single photon counting

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ER -

Fluorescence lifetime imaging of calcium flux in neurons in response to pulsed infrared light

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