Association between Rectal Optical Signatures and Colonic Neoplasia: Potential Applications for Screening

Roy, Hemant K.; Turzhitsky, Vladimir; Kim, Young; Goldberg, Michael J.; Watson, Patrice; Rogers, Jeremy D.; Gomes, Andrew; Kromine, Alexey; Brand, Randall E.; Jameel, Mohammed; Bogovejic, Andrej; Pradhan, Prabhakar; Backman, Vadim

doi:10.1158/0008-5472.can-08-4780

Cited by 61 publications

(79 citation statements)

References 45 publications

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“…These parameters have been found to have diagnostic value for the detection of colon, pancreatic, and skin cancer. 20,[47][48][49] In this section, we will discuss the dependence of these parameters on the optical properties l * s , g, and m. Several inverse models for the calculation of these optical properties are presented in Sec. 5.…”

Section: Dependence Of Lebs Peak Properties On the Optical Propertiesmentioning

confidence: 99%

“…LEBS spectroscopy has previously been shown to have promise for the detection of several types of epithelial cancers. 14,19,20 These studies have shown that LEBS parameters such as the peak width, enhancement factor, and spectral dependence have diagnostic potential for cancer detection. The aim of this work is to relate the measured LEBS parameters (width, enhancement factor, and spectral dependence) to the optical properties of the scattering media.…”

Section: Introductionmentioning

confidence: 99%

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Measurement of optical scattering properties with low-coherence enhanced backscattering spectroscopy

Turzhitsky¹,

Radosevich²,

Rogers³

et al. 2011

J. Biomed. Opt.

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Abstract. Low-coherence enhanced backscattering (LEBS) is a depth selective technique that allows noninvasive characterization of turbid media such as biological tissue. LEBS provides a spectral measurement of the tissue reflectance distribution as a function of distance between incident and reflected ray pairs through the use of partial spatial coherence broadband illumination. We present LEBS as a new depth-selective technique to measure optical properties of tissue in situ. Because LEBS enables measurements of reflectance due to initial scattering events, LEBS is sensitive to the shape of the phase function in addition to the reduced scattering coefficient (μ * s ). We introduce a simulation of LEBS that implements a two parameter phase function based on the Whittle-Matérn refractive index correlation function model. We show that the LEBS enhancement factor (E) primarily depends on μ * s , the normalized spectral dependence of E (S n ) depends on one of the two parameters of the phase function that also defines the functional type of the refractive index correlation function (m), and the LEBS peak width depends on both the anisotropy factor (g) and m. Three inverse models for calculating these optical properties are described and the calculations are validated with an experimental measurement from a tissue phantom. C 2011 Society of Photo-Optical Instrumentation Engineers (SPIE).

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Section: Dependence Of Lebs Peak Properties On the Optical Propertiesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Measurement of optical scattering properties with low-coherence enhanced backscattering spectroscopy

Turzhitsky¹,

Radosevich²,

Rogers³

et al. 2011

J. Biomed. Opt.

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“…These strategies include light scattering spectroscopy, 4,5 angle-resolved low coherence interferometry, 6,7 Raman spectroscopy, 8,9 diffuse optical spectroscopy, 10 partial wave spectroscopic (PWS) microscopy, 11,12 low-coherence enhanced backscattering, 12,13 quantitative phase microscopy, [14][15][16] and noninterferometric quantitative phase microscopy (NIQPM). 17 Cellular level observations of cancerous cells enabled by these technologies include an increase in subcellular constituent size, 4,5,7,13,14,17,18 changes in density, 7,14,17,18 alterations of the organization of this density to a more inhomogeneous state, 12,14,18 alterations in cellular metabolism, 10 and changes in biochemical composition 8 including higher concentrations of nuclear acids. 9 To date, label-free optical studies undertaking a detailed analysis of cellular physical properties in the context of cancer have been focused on measuring single parameters to establish one-dimensional biophysical signatures of cellular and/or tissue alterations due to cancer.…”

Section: Introductionmentioning

confidence: 99%

Network signatures of nuclear and cytoplasmic density alterations in a model of pre and postmetastatic colorectal cancer

et al. 2014

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Abstract. Cells contributing to the pathogenesis of cancer possess cytoplasmic and nuclear structural alterations that accompany their aberrant genetic, epigenetic, and molecular perturbations. Although it is known that architectural changes in primary and metastatic tumor cells can be quantified through variations in cellular density at the nanometer and micrometer spatial scales, the interdependent relationships among nuclear and cytoplasmic density as a function of tumorigenic potential has not been thoroughly investigated. We present a combined optical approach utilizing quantitative phase microscopy and partial wave spectroscopic microscopy to perform parallel structural characterizations of cellular architecture. Using the isogenic SW480 and SW620 cell lines as a model of pre and postmetastatic transition in colorectal cancer, we demonstrate that nuclear and cytoplasmic nanoscale disorder, micron-scale dry mass content, mean dry mass density, and shape metrics of the dry mass density histogram are uniquely correlated within and across different cellular compartments for a given cell type. The correlations of these physical parameters can be interpreted as networks whose nodal importance and level of connection independence differ according to disease stage. This work demonstrates how optically derived biophysical parameters are linked within and across different cellular compartments during the architectural orchestration of the metastatic phenotype.

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“…17,18 Combining these sensitivities with the ability to selectively interrogate different layers of tissue through implementation of a partial spatial coherence source, CBS has become a promising technique for the characterization and detection of colorectal and pancreatic cancers. 19,20 In order to accurately characterize a tissue sample using CBS, it is necessary to understand the dependencies of the peak shape on tissue structural composition. While various analytical formalisms have been developed to describe the CBS peak shape for different sample properties, each of these calculations rely on simplifying assumptions (e.g., scalar approximation 21 or double scattering 22 ) which cannot fully describe the complex sensitivities of the CBS peak.…”

Section: Introductionmentioning

confidence: 99%

Open source software for electric field Monte Carlo simulation of coherent backscattering in biological media containing birefringence

Radosevich¹,

Rogers²,

Capoglu³

et al. 2012

J. Biomed. Opt

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Abstract.We present an open source electric field tracking Monte Carlo program to model backscattering in biological media containing birefringence, with computation of the coherent backscattering phenomenon as an example. These simulations enable the modeling of tissue scattering as a statistically homogeneous continuous random media under the Whittle-Matérn model, which includes the Henyey-Greenstein phase function as a special case, or as a composition of discrete spherical scatterers under Mie theory. The calculation of the amplitude scattering matrix for the above two cases as well as the implementation of birefringence using the Jones N-matrix formalism is presented. For ease of operator use and data processing, our simulation incorporates a graphical user interface written in MATLAB to interact with the underlying C code. Additionally, an increase in computational speed is achieved through implementation of message passing interface and the semi-analytical approach. Finally, we provide demonstrations of the results of our simulation for purely scattering media and scattering media containing linear birefringence.

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Association between Rectal Optical Signatures and Colonic Neoplasia: Potential Applications for Screening

Cited by 61 publications

References 45 publications

Measurement of optical scattering properties with low-coherence enhanced backscattering spectroscopy

Measurement of optical scattering properties with low-coherence enhanced backscattering spectroscopy

Network signatures of nuclear and cytoplasmic density alterations in a model of pre and postmetastatic colorectal cancer

Open source software for electric field Monte Carlo simulation of coherent backscattering in biological media containing birefringence

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