Near-infrared Spectral Tomography Integrated with Digital Breast Tomosynthesis: Effects of Tissue Scattering on Optical Data Acquisition Design

Overview

Journal Med Phys

Specialty Biophysics

Date 2012 Jul 27

PMID 22830789

Citations 6

Authors

Kelly Michaelsen

Venkat Krishnaswamy

Brian W Pogue

Steven P Poplack

Keith D Paulsen

Affiliations

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Abstract

Purpose: Design optimization and phantom validation of an integrated digital breast tomosynthesis (DBT) and near-infrared spectral tomography (NIRST) system targeting improvement in sensitivity and specificity of breast cancer detection is presented. Factors affecting instrumentation design include minimization of cost, complexity, and examination time while maintaining high fidelity NIRST measurements with sufficient information to recover accurate optical property maps.

Methods: Reconstructed DBT slices from eight patients with abnormal mammograms provided anatomical information for the NIRST simulations. A limited frequency domain (FD) and extensive continuous wave (CW) NIRST system was modeled. The FD components provided tissue scattering estimations used in the reconstruction of the CW data. Scattering estimates were perturbed to study the effects on hemoglobin recovery. Breast mimicking agar phantoms with inclusions were imaged using the combined DBT∕NIRST system for comparison with simulation results.

Results: Patient simulations derived from DBT images show successful reconstruction of both normal and malignant lesions in the breast. They also demonstrate the importance of accurately quantifying tissue scattering. Specifically, 20% errors in optical scattering resulted in 22.6% or 35.1% error in quantification of total hemoglobin concentrations, depending on whether scattering was over- or underestimated, respectively. Limited frequency-domain optical signal sampling provided two regions scattering estimates (for fat and fibroglandular tissues) that led to hemoglobin concentrations that reduced the error in the tumor region by 31% relative to when a single estimate of optical scattering was used throughout the breast volume of interest. Acquiring frequency-domain data with six wavelengths instead of three did not significantly improve the hemoglobin concentration estimates. Simulation results were confirmed through experiments in two-region breast mimicking gelatin phantoms.

Conclusions: Accurate characterization of scattering is necessary for quantification of hemoglobin. Based on this study, a system design is described to optimally combine breast tomosynthesis with NIRST.

Citing Articles

Performance assessment of MRI guided continuous wave near-infrared spectral tomography for breast imaging.

Feng J, Jiang S, Pogue B, Paulsen K Biomed Opt Express. 2022; 12(12):7657-7672.

PMID: 35003858 PMC: 8713687. DOI: 10.1364/BOE.444131.

Digital Breast Tomosynthesis guided Near Infrared Spectroscopy: Volumetric estimates of fibroglandular fraction and breast density from tomosynthesis reconstructions.

Vedantham S, Shi L, Michaelsen K, Krishnaswamy V, Pogue B, Poplack S Biomed Phys Eng Express. 2016; 1(4).

PMID: 26941961 PMC: 4771071. DOI: 10.1088/2057-1976/1/4/045202.

Anthropomorphic breast phantoms with physiological water, lipid, and hemoglobin content for near-infrared spectral tomography.

Michaelsen K, Krishnaswamy V, Shenoy A, Jordan E, Pogue B, Paulsen K J Biomed Opt. 2014; 19(2):026012.

PMID: 24549438 PMC: 3925848. DOI: 10.1117/1.JBO.19.2.026012.

Integration of microwave tomography with magnetic resonance for improved breast imaging.

Meaney P, Golnabi A, Epstein N, Geimer S, Fanning M, Weaver J Med Phys. 2013; 40(10):103101.

PMID: 24089930 PMC: 3785540. DOI: 10.1118/1.4820361.

A digital x-ray tomosynthesis coupled near infrared spectral tomography system for dual-modality breast imaging.

Krishnaswamy V, Michaelsen K, Pogue B, Poplack S, Shaw I, Defrietas K Opt Express. 2012; 20(17):19125-36.

PMID: 23038553 PMC: 3601817. DOI: 10.1364/OE.20.019125.

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