Mammography is the most common technology used to characterize breast abnormalities in the diagnostic setting. Although mammography is a valuable screening and diagnostic technique, it has some significant limitations. Mammography has variable sensitivity: it is less sensitive in detecting breast cancer in women with radiographically dense breasts. Screening mammography has a low positive predictive value. There is also considerable variability in the radiologic interpretation of mammograms. Hence, there is considerable rationale to pursue alternative imaging methods for breast cancer detection. The principal hypothesis of Project IV is that frequency domain modulation methods for near infrared (NIR) optical spectroscopy of tissue coupled with model-based image formation from tomographically-measured optical data provides a functional imaging methodology with clinical relevance to the detection and diagnosis of breast cancer. This imaging method uses fundamentally new approaches for finite element based computed tomography reconstruction, along with new techniques for diffuse optical spectroscopy projection measurement through tissue.
The specific aims i nclude (1) constructing a parallelized 48-unit detector array for fast near- infrared (NIR) data acquisition (2) developing a new mechanical interface for clinical NIR breast scanning providing adequate optical fiber-tissue coupling and suitable precision translation for multi-slice image acquisition, (3) developing a compact diode-laser-driven spectroscopic imaging system covering the optical wavelengths between 600 and 850 nm which is sufficient to quantitatively image absorption coefficients in vivo and evaluate its functional imaging capabilities in terms of hemoglobin concentration image absorption coefficients in vivo and evaluate its functional imaging capabilities in terms of hemoglobin concentration, oxygen saturation, water and lipid concentrations, (4) advancing, in conjunction with the Computational Core, model-based image reconstruction technology for NIR absorption by investigation multi-component objection functions, adaptive spatial regularization, adaptive dual meshing, three-dimensional methods, parallel processing and multi-spectral modulation strategies for increasing property sensitivity, and (5) evaluating, in conjunction with the Clinical Core, the clinical potential of NIR breast imaging in a trial involving patients with normal and abnormal mammograms, with the goal of defining the available contrast for optical imaging and the pathobiologic basis for this contrast. While there is still no absolute proof that optical imaging will enhance the diagnosis or management of breast disease, much of the preliminary data indicates there is a difference in tissue composition (due to hemoglobin volume, much of the preliminary data indicates that there is a difference in tissue composition (due to hemoglobin volume, oxygenation, water content, calcification, etc.) which can be discriminated through the use of near-infrared spectroscopy; hence, the technique holds promise of exploiting new contrast mechanisms for breast cancer detection, which offers the possibility of adding new functional information to diagnostic decision-making.

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Program Projects (P01)
Project #
5P01CA080139-03
Application #
6493959
Study Section
Subcommittee G - Education (NCI)
Project Start
2001-08-28
Project End
2002-07-31
Budget Start
1998-10-01
Budget End
1999-09-30
Support Year
3
Fiscal Year
2001
Total Cost
$168,689
Indirect Cost
Name
Dartmouth College
Department
Type
DUNS #
041027822
City
Hanover
State
NH
Country
United States
Zip Code
03755
Halter, Ryan J; Hartov, Alex; Poplack, Steven P et al. (2015) Real-time electrical impedance variations in women with and without breast cancer. IEEE Trans Med Imaging 34:38-48
Epstein, N R; Meaney, P M; Paulsen, K D (2014) 3D parallel-detection microwave tomography for clinical breast imaging. Rev Sci Instrum 85:124704
Jiang, Shudong; Pogue, Brian W; Kaufman, Peter A et al. (2014) Predicting breast tumor response to neoadjuvant chemotherapy with diffuse optical spectroscopic tomography prior to treatment. Clin Cancer Res 20:6006-15
Meaney, Paul M; Kaufman, Peter A; Muffly, Lori S et al. (2013) Microwave imaging for neoadjuvant chemotherapy monitoring: initial clinical experience. Breast Cancer Res 15:R35
Laughney, Ashley M; Krishnaswamy, Venkataramanan; Rice, Tyler B et al. (2013) System analysis of spatial frequency domain imaging for quantitative mapping of surgically resected breast tissues. J Biomed Opt 18:036012
Krishnaswamy, Venkataramanan; Laughney, Ashley M; Wells, Wendy A et al. (2013) Scanning in situ spectroscopy platform for imaging surgical breast tissue specimens. Opt Express 21:2185-94
Jiang, Shudong; Pogue, Brian W; Michaelsen, Kelly E et al. (2013) Pilot study assessment of dynamic vascular changes in breast cancer with near-infrared tomography from prospectively targeted manipulations of inspired end-tidal partial pressure of oxygen and carbon dioxide. J Biomed Opt 18:76011
Laughney, Ashley M; Krishnaswamy, Venkataramanan; Rizzo, Elizabeth J et al. (2013) Spectral discrimination of breast pathologies in situ using spatial frequency domain imaging. Breast Cancer Res 15:R61
Grzegorczyk, Tomasz M; Meaney, Paul M; Kaufman, Peter A et al. (2012) Fast 3-d tomographic microwave imaging for breast cancer detection. IEEE Trans Med Imaging 31:1584-92
Pallone, Matthew J; Meaney, Paul M; Paulsen, Keith D (2012) Surface scanning through a cylindrical tank of coupling fluid for clinical microwave breast imaging exams. Med Phys 39:3102-11

Showing the most recent 10 out of 129 publications