聚焦光束通过多个生物细胞的三维计算

2009 DoD High Performance Computing Modernization Program Users Group Conference Pub Date : 2009-02-12 DOI:10.1117/12.809433

M. Starosta, A. Dunn, R. Thomas

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引用次数: 33

摘要

采用大规模并行时域有限差分法计算了聚焦光束在多个异质生物细胞中的散射。为了提高计算精度和计算效率，仿真中采用了完全匹配的层边界条件和仅散射场方法。入射场采用聚焦高斯光束的五阶近似。采用参数化方法研究了核折射率、细胞器体积密度、细胞形状和细胞膜等不同细胞精细结构对光束点扩散函数的影响。研究发现，细胞内散射体数量的增加对双光子PSF的影响不大，而双光子激发信号的强度则与组织内散射体的密度和光束聚焦深度有关。

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Three-Dimensional Computation of Focused Beam Propagation through Multiple Biological Cells

A massively parallel finite difference time domain method was used to compute scattering of a focused optical beam by multiple heterogeneous biological cells. A perfectly matched layer boundary condition and the scattered-field-only method were utilized in the simulation to increase accuracy and computational efficiency. A fifth-order approximation to the focused Gaussian beam was used for the incident field. A parametric study was performed to determine scattering effects of varying cellular fine structure, such as nuclear refractive index, organelle volume density, cellular shape and the cell membrane on the point spread function (PSF) of the beam. It was found that two-photon PSF is largely unaffected by increasing numbers of scatterers within cells, while two-photon excitation signal strength is dependent on both beam focal depth and the density of scatterers in tissue.

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2009 DoD High Performance Computing Modernization Program Users Group Conference

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