Model-convolution approach to modeling fluorescent protein dynamics

B. L. Sprague; M. K. Gardner; C. G. Pearson; P. S. Maddox; K. Bloom; E. D. Salmon; D. J. Odde

Model-convolution approach to modeling fluorescent protein dynamics

B. L. Sprague, M. K. Gardner, C. G. Pearson, P. S. Maddox, K. Bloom, E. D. Salmon, D. J. Odde

Research output: Contribution to journal › Conference article › peer-review

Abstract

Fluorescence microscopy is a popular technique for visualizing protein dynamics in living cells. However, the precise distribution of fluorophores underlying the observed fluorescence is not always obvious, even after deconvolution, particularly when features on a scale of 250 nm or less are of interest In contrast, quantitative models of protein dynamics predict an actual fluorophore distribution. "Model-Convolution" is a method that bridges this gap by convolving model-predicted fluorophore location data with the point spread function of the microscope system so that simulated images can be generated and directly compared to experimental images. This article offers a practical guide to model-convolution.

Original language	English (US)
Pages (from-to)	1821-1825
Number of pages	5
Journal	Conference Record - Asilomar Conference on Signals, Systems and Computers
Volume	2
State	Published - 2004
Event	Conference Record of the Thirty-Eighth Asilomar Conference on Signals, Systems and Computers - Pacific Grove, CA, United States Duration: Nov 7 2004 → Nov 10 2004

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AU - Sprague, B. L.

AU - Gardner, M. K.

AU - Pearson, C. G.

AU - Maddox, P. S.

AU - Bloom, K.

AU - Salmon, E. D.

AU - Odde, D. J.

PY - 2004

Y1 - 2004

N2 - Fluorescence microscopy is a popular technique for visualizing protein dynamics in living cells. However, the precise distribution of fluorophores underlying the observed fluorescence is not always obvious, even after deconvolution, particularly when features on a scale of 250 nm or less are of interest In contrast, quantitative models of protein dynamics predict an actual fluorophore distribution. "Model-Convolution" is a method that bridges this gap by convolving model-predicted fluorophore location data with the point spread function of the microscope system so that simulated images can be generated and directly compared to experimental images. This article offers a practical guide to model-convolution.

AB - Fluorescence microscopy is a popular technique for visualizing protein dynamics in living cells. However, the precise distribution of fluorophores underlying the observed fluorescence is not always obvious, even after deconvolution, particularly when features on a scale of 250 nm or less are of interest In contrast, quantitative models of protein dynamics predict an actual fluorophore distribution. "Model-Convolution" is a method that bridges this gap by convolving model-predicted fluorophore location data with the point spread function of the microscope system so that simulated images can be generated and directly compared to experimental images. This article offers a practical guide to model-convolution.

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JO - Conference Record - Asilomar Conference on Signals, Systems and Computers

JF - Conference Record - Asilomar Conference on Signals, Systems and Computers

T2 - Conference Record of the Thirty-Eighth Asilomar Conference on Signals, Systems and Computers

Y2 - 7 November 2004 through 10 November 2004

ER -

Model-convolution approach to modeling fluorescent protein dynamics

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