Add to ORKGWe present a coupled forward-adjoint Monte Carlo (cFAMC) method to determine the spatially resolved sensitivity distributions produced by optical interrogation of three-dimensional (3-D) tissue volumes. We develop a general computational framework that computes the spatial and angular distributions of the forward-adjoint light fields to provide accurate computations in mesoscopic tissue volumes. We provide full computational details of the cFAMC method and provide results for low- and high-scattering tissues probed using a single pair of optical fibers. We examine the effects of source-detector separation and orientation on the sensitivity distributions and consider how the degree of angular discretization used in the 3-D tissue model impac...
International audienceMonte Carlo (MC) based simulations of photon transport in living tissues have ...
International audienceLight propagation in turbid media is driven by the equation of radiative trans...
We describe the development of a rapid, noncontact imaging method, modulated imaging (MI), for quant...
We present a coupled forward-adjoint Monte Carlo (cFAMC) method to determine the spatially resolved ...
We introduce a novel Monte Carlo method for the analysis of optical probe design that couples a forw...
An extension of the Monte Carlo method in diffuse optics was developed. Diffuse optical technology m...
In the recent years, optical imaging has attracted increasing attention in the field of clinical dia...
The use of perturbation and differential Monte Carlo (pMC/dMC) methods in conjunction with nonlinear...
Details of the interaction of photons with tissue phantoms are elucidated using Monte Carlo simulati...
A radiative transport method based on efficient coupled forward-adjoint Monte Carlo simulations is u...
We present a Monte Carlo (MC) method to determine depth-dependent probability distributions of photo...
Local and superficial optical characterization of biological tissues can be achieved by measuring th...
Monte Carlo (MC) based simulations of photon transport in living tissues have become the "gold stand...
The focal field distribution of tightly focused laser beams in turbid media is sensitive to optical ...
Local and superficial optical property characterization of biological tissues can be performed by me...
International audienceMonte Carlo (MC) based simulations of photon transport in living tissues have ...
International audienceLight propagation in turbid media is driven by the equation of radiative trans...
We describe the development of a rapid, noncontact imaging method, modulated imaging (MI), for quant...
We present a coupled forward-adjoint Monte Carlo (cFAMC) method to determine the spatially resolved ...
We introduce a novel Monte Carlo method for the analysis of optical probe design that couples a forw...
An extension of the Monte Carlo method in diffuse optics was developed. Diffuse optical technology m...
In the recent years, optical imaging has attracted increasing attention in the field of clinical dia...
The use of perturbation and differential Monte Carlo (pMC/dMC) methods in conjunction with nonlinear...
Details of the interaction of photons with tissue phantoms are elucidated using Monte Carlo simulati...
A radiative transport method based on efficient coupled forward-adjoint Monte Carlo simulations is u...
We present a Monte Carlo (MC) method to determine depth-dependent probability distributions of photo...
Local and superficial optical characterization of biological tissues can be achieved by measuring th...
Monte Carlo (MC) based simulations of photon transport in living tissues have become the "gold stand...
The focal field distribution of tightly focused laser beams in turbid media is sensitive to optical ...
Local and superficial optical property characterization of biological tissues can be performed by me...
International audienceMonte Carlo (MC) based simulations of photon transport in living tissues have ...
International audienceLight propagation in turbid media is driven by the equation of radiative trans...
We describe the development of a rapid, noncontact imaging method, modulated imaging (MI), for quant...