Time-resolved detection of small objects in turbid media by diffusive light: simulation versus experiment

A method is presented to simulate the light propagation in turbid media. Based on a numerical algorithm to solve the time-dependent diffusion equation, the method takes into account spatial variations of the reduced scattering and absorption factors of the medium due to the presence of objects as well as random fluctuations of these factors. The simulation results for tissuelike phantoms are compared to experimental data and excellent agreement is found. The technique is employed to explore the possibility of locating millimeter-sized objects, immersed in turbid media, from time- resolved measurements of the transmitted or reflected (near- infrared) light. A method is proposed to enhance the imaging power of the time-resolved technique. Using the data- processing technique we find that it is possible to detect 1 mm-diameter objects, independent of their location within the sample and under unfavorable conditions. Experimental data of a time-resolved reflection experiment on a 1 mm diameter tube filled with blood and embedded in an intralipid solution are presented. The results show that, using the data processing technique, it is possible to detect the tube to a depth of 15 mm from the illuminated surface in a 70 mm thick sample. Simulation data are in excellent agreement with these experimental results.

[1]  D. Watmough Diaphanography: mechanism responsible for the images. , 1982, Acta radiologica. Oncology.

[2]  Hans De Raedt,et al.  Applications of the generalized Trotter formula , 1983 .

[3]  D. Delpy,et al.  Time-resolved optical imaging of a solid tissue-equivalent phantom. , 1995, Applied optics.

[4]  A E Profio,et al.  Spectral transmittance and contrast in breast diaphanography. , 1985, Medical physics.

[5]  E Gratton,et al.  Propagation of photon-density waves in strongly scattering media containing an absorbing semi-infinite plane bounded by a straight edge. , 1993, Journal of the Optical Society of America. A, Optics and image science.

[6]  D. Boas,et al.  Experimental images of heterogeneous turbid media by frequency-domain diffusing-photon tomography. , 1995, Optics letters.

[7]  A. Lagendijk,et al.  Location of objects in multiple-scattering media , 1993 .

[8]  Hans De Raedt,et al.  Product formula algorithms for solving the time dependent Schrödinger equation , 1987 .

[9]  Kristel Michielsen,et al.  Algorithm to solve the time-dependent Schro¨dinger equation for a charged particle in an inhomogeneous magnetic field: application to the Aharonov-Bohm effect , 1994 .

[10]  M S Patterson,et al.  Optical properties of normal and diseased human breast tissues in the visible and near infrared. , 1990, Physics in medicine and biology.

[11]  L. O. Svaasand,et al.  Properties of photon density waves in multiple-scattering media. , 1993, Applied optics.

[12]  H Key,et al.  Optical attenuation characteristics of breast tissues at visible and near-infrared wavelengths. , 1991, Physics in medicine and biology.

[13]  W. Zinth,et al.  Time-gated transillumination of biological tissues and tissuelike phantoms. , 1994, Applied optics.

[14]  R Marchesini,et al.  Extinction and absorption coefficients and scattering phase functions of human tissues in vitro. , 1989, Applied optics.

[15]  Kristel Michielsen,et al.  Time-gated transillumination and reflection by biological tissues and tissuelike phantoms: simulation versus experiment , 1997 .

[16]  K. Symanzik Proof and Refinements of an Inequality of Feynman , 1965 .

[17]  J M Schmitt,et al.  Interference of diffusive light waves. , 1992, Journal of the Optical Society of America. A, Optics and image science.

[18]  B Chance,et al.  Quantitative Measurement of Optical Parameters in the Breast Using Time-Resolved Spectroscopy: Phantom and Preliminary In Vivo Results , 1994, Investigative radiology.