Accelerated Monte Carlo models to simulate fluorescence spectra from layered tissues.

Two efficient Monte Carlo models are described, facilitating predictions of complete time-resolved fluorescence spectra from a light-scattering and light-absorbing medium. These are compared with a third, conventional fluorescence Monte Carlo model in terms of accuracy, signal-to-noise statistics, and simulation time. The improved computation efficiency is achieved by means of a convolution technique, justified by the symmetry of the problem. Furthermore, the reciprocity principle for photon paths, employed in one of the accelerated models, is shown to simplify the computations of the distribution of the emitted fluorescence drastically. A so-called white Monte Carlo approach is finally suggested for efficient simulations of one excitation wavelength combined with a wide range of emission wavelengths. The fluorescence is simulated in a purely scattering medium, and the absorption properties are instead taken into account analytically afterward. This approach is applicable to the conventional model as well as to the two accelerated models. Essentially the same absolute values for the fluorescence integrated over the emitting surface and time are obtained for the three models within the accuracy of the simulations. The time-resolved and spatially resolved fluorescence exhibits a slight overestimation at short delay times close to the source corresponding to approximately two grid elements for the accelerated models, as a result of the discretization and the convolution. The improved efficiency is most prominent for the reverse-emission accelerated model, for which the simulation time can be reduced by up to two orders of magnitude.

[1]  S Andersson-Engels,et al.  Real-time method for fitting time-resolved reflectance and transmittance measurements with a monte carlo model. , 1998, Applied optics.

[2]  Antonio Pifferi,et al.  Accelerated Monte Carlo models to simulate fluorescence of layered tissue , 2000, European Conference on Biomedical Optics.

[3]  James G. Fujimoto,et al.  Advances in Optical Imaging and Photon Migration , 1996 .

[4]  B. Wilson,et al.  In Vivo Fluorescence Spectroscopy and Imaging for Oncological Applications , 1998, Photochemistry and photobiology.

[5]  R Nossal,et al.  Effects of multiple-passage probabilities on fluorescent signals from biological media. , 1997, Applied optics.

[6]  M. Schweiger,et al.  Photon-measurement density functions. Part 2: Finite-element-method calculations. , 1995, Applied optics.

[7]  B. Wilson,et al.  Forward-adjoint fluorescence model: Monte Carlo integration and experimental validation. , 1997, Applied optics.

[8]  J. Mourant,et al.  Monitoring photosensitizer concentration by use of a fiber-optic probe with a small source-detector separation. , 2000, Applied optics.

[9]  S. Jacques,et al.  Light distributions in artery tissue: Monte Carlo simulations for finite‐diameter laser beams , 1989, Lasers in surgery and medicine.

[10]  H. Sterenborg,et al.  Quantification of the hematoporphyrin derivative by fluorescence measurementusing dual-wavelength excitation anddual-wavelength detection. , 1993, Applied optics.

[11]  Sune Svanberg,et al.  Optical monitoring of volcanic sulphur dioxide emissions - comparison between four different remote-sensing spectroscopic techniques , 2002 .

[12]  M S Patterson,et al.  Determination of the optical properties of turbid media from a single Monte Carlo simulation , 1996, Physics in medicine and biology.

[13]  R. Rava,et al.  Analytical model for extracting intrinsic fluorescence in turbid media. , 1993, Applied optics.

[14]  L Wang,et al.  MCML--Monte Carlo modeling of light transport in multi-layered tissues. , 1995, Computer methods and programs in biomedicine.

[15]  Michael S. Feld,et al.  A model for extraction of diagnostic information from laser induced fluorescence spectra of human artery wall , 1989 .

[16]  Brian W. Pogue,et al.  Mathematical model for time-resolved and frequency-domain fluorescence spectroscopy in biological tissues. , 1994, Applied optics.

[17]  M S Patterson,et al.  Imaging of fluorescent yield and lifetime from multiply scattered light reemitted from random media. , 1997, Applied optics.

[18]  Y. Yazdi,et al.  Combined ultrasound and fluorescence spectroscopy for physico-chemical imaging of atherosclerosis , 1995, IEEE Transactions on Biomedical Engineering.

[19]  Britton Chance,et al.  Fast and noninvasive fluorescence imaging of biological tissues in vivo using a flying-spot scanner , 2001, IEEE Transactions on Biomedical Engineering.

[20]  G. C. Pomraning,et al.  Linear Transport Theory , 1967 .

[21]  R. Weissleder,et al.  In vivo imaging of tumors with protease-activated near-infrared fluorescent probes , 1999, Nature Biotechnology.

[22]  B. Hooper Optical-thermal response of laser-irradiated tissue , 1996 .

[23]  H R Gordon Equivalence of the point and beam spread functions of scattering media: a formal demonstration. , 1994, Applied optics.

[24]  Norman S. Nishioka,et al.  Light propagation in tissue during fluorescence spectroscopy with single-fiber probes , 2001 .

[25]  S. Avrillier,et al.  Influence of the emission-reception geometry in laser-induced fluorescence spectra from turbid media. , 1998, Applied optics.

[26]  Ashleyj . Welch,et al.  Optical-Thermal Response of Laser-Irradiated Tissue , 1995 .

[27]  B. Wilson,et al.  Absorption spectroscopy in tissue-simulating materials: a theoretical and experimental study of photon paths. , 1995, Applied optics.

[28]  J. Mourant,et al.  Ultraviolet and visible spectroscopies for tissue diagnostics: fluorescence spectroscopy and elastic-scattering spectroscopy. , 1997, Physics in medicine and biology.

[29]  R. Berg Laser-Based Cancer Diagnostics and Therapy - Tissue Optics considerations. , 1995 .

[30]  J. Still,et al.  Diagnosis of burn depth using laser-induced indocyanine green fluorescence: a preliminary clinical trial. , 2001, Burns : journal of the International Society for Burn Injuries.

[31]  M Motamedi,et al.  Evaluation of spectral correction techniques for fluorescence measurements on pigmented lesions in vivo. , 1996, Journal of photochemistry and photobiology. B, Biology.

[32]  J Wu,et al.  Intrinsic fluorescence spectroscopy in turbid media: disentangling effects of scattering and absorption. , 2001, Applied optics.

[33]  C. Gardner,et al.  Monte Carlo simulation of light transport in tissue: unscattered absorption events. , 1994, Applied optics.

[34]  S L Jacques,et al.  Fluorescence spectroscopy of tissue: recovery of intrinsic fluorescence from measured fluorescence. , 1996, Applied optics.

[35]  Craig Gardner,et al.  Propagation of fluorescent light , 1997, Lasers in surgery and medicine.