Image reconstruction in optical tomography
Open Access
- 29 June 1997
- journal article
- research article
- Published by The Royal Society in Philosophical Transactions Of The Royal Society B-Biological Sciences
- Vol. 352 (1354), 717-726
- https://doi.org/10.1098/rstb.1997.0054
Abstract
Optical tomography is a new medical imaging modality that is at the threshold of realization. A large amount of clinical work has shown the very real benefits that such a method could provide. At the same time a considerable effort has been put into theoretical studies of its probable success. At present there exist gaps between these two realms. In this paper we review some general approaches to inverse problems to set the context for optical tomography, defining both the terms forward problem and inverse problem. An essential requirement is to treat the problem in a nonlinear fashion, by using an iterative method. This in turn requires a convenient method of evaluating the forward problem, and its derivatives and variance. Photon transport models are described and methods for obtaining analytical and numerical solutions for the most commonly used ones are reviewed. The inverse problem is approached by classical gradient–based solution methods. In order to develop practical implementations of these methods, we discuss the important topic of photon measurement density functions, which represent the derivative of the forward problem. We show some results that represent the most complex and realistic simulations of optical tomography yet developed. We suggest, in particular, that both time–resolved, and intensity–modulated systems can reconstruct variations in both optical absorption and scattering, but that unmodulated, non–time–resolved systems are prone to severe artefact. We believe that optical tomography reconstruction methods can now be reliably applied to a wide variety of real clinical data. The expected resolution of the method is poor, meaning that it is unlikely that the type of high–resolution images seen in computed tomography or medical resonance imaging can ever be obtained. Nevertheless we strongly expect the functional nature of these images to have a high degree of clinical significance.Keywords
This publication has 37 references indexed in Scilit:
- Initial assessment of a simple system for frequency domain diffuse optical tomographyPhysics in Medicine & Biology, 1995
- Direct calculation of the moments of the distribution of photon time of flight in tissue with a finite-element methodApplied Optics, 1995
- Experimental images of heterogeneous turbid media by frequency-domain diffusing-photon tomographyOptics Letters, 1995
- Localization of absorbers in scattering media by use of frequency-domain measurements of time-dependent photon migrationApplied Optics, 1994
- Application of the finite-element method for the forward and inverse models in optical tomographyJournal of Mathematical Imaging and Vision, 1993
- Photon hitting densityApplied Optics, 1993
- The theoretical basis for the determination of optical pathlengths in tissue: temporal and frequency analysisPhysics in Medicine & Biology, 1992
- The propagation of optical radiation in tissue I. Models of radiation transport and their applicationLasers in Medical Science, 1991
- Time resolved reflectance and transmittance for the noninvasive measurement of tissue optical propertiesApplied Optics, 1989
- The theory of the back-scattering of light by bloodJournal of Physics D: Applied Physics, 1978