Today's medical imaging methods have insufficient specificity for reliable differentiation between benign and malignant breast lesions in patients. Pathologic evaluation is currently the only way to obtain a definitive diagnosis. This research will use a novel method of magnetic resonance imaging (MRI), Sweep Imaging with Fourier Transform (SWIFT), at very high magnetic field (4 Tesla) to distinguish malignant from benign breast lesions. Specificity will be gained from improved temporal resolution and contrast kinetic parameter extraction measured non-invasively with proton (1H) MRI. In addition to high temporal resolution and immunity to T2* effects at even the highest contrast agent concentrations, SWIFT offers several other improvements. The 3D radial sampling scheme is motion-correctable with simple k-space based processing. Due to the smooth rotating gradient trajectory, SWIFT is immune to gradient group delay, gradient ramp based errors, and produces orders of magnitude fewer eddy currents than other rapid radial sequences. Another extremely desirable effect of the smooth gradient is that SWIFT is extremely quiet, leading to an improved patient experience and fewer failures to scan. Breast lesions will be visualized by dynamic contrast-enhanced three-dimensional MRI and simultaneously processed into high-temporal resolution / low-spatial resolution, high-spatial resolution / low temporal-resolution, or mixed image series. Since data from a single scan can be formatted into variable spatial and temporal resolutions, the total imaging time can be reduced compared with standard MRI scanning methods. SWIFT MRI measurements will be correlated with biopsy results to determine whether this MRI sequence accurately identifies and characterizes malignant lesions in breast patients. This research will reveal whether the SWIFT sequence bears new capabilities in medical imaging for breast cancer diagnosis.
The proposed research is aimed at improving the accuracy of detection and determination of extent of disease in women suspected of having breast cancer. It should also help reduce cases where a woman is told she has breast cancer in error.
| Nissi, Mikko J; Lehto, Lauri J; Corum, Curtis A et al. (2015) Measurement of T1 relaxation time of osteochondral specimens using VFA-SWIFT. Magn Reson Med 74:175-184 |
| Kobayashi, Naoharu; Idiyatullin, Djaudat; Corum, Curt et al. (2015) SWIFT MRI enhances detection of breast cancer metastasis to the lung. Magn Reson Med 73:1812-9 |
| Corum, Curtis A; Benson, John C; Idiyatullin, Djaudat et al. (2015) High-spatial- and high-temporal-resolution dynamic contrast-enhanced MR breast imaging with sweep imaging with Fourier transformation: a pilot study. Radiology 274:540-7 |
| Lehto, Lauri Juhani; Garwood, Michael; Gröhn, Olli et al. (2015) Phase imaging in brain using SWIFT. J Magn Reson 252:20-8 |
| Corum, Curtis A; Idiyatullin, Djaudat; Snyder, Carl J et al. (2015) Gap cycling for SWIFT. Magn Reson Med 73:677-82 |
| Snyder, Angela L S; Corum, Curtis A; Moeller, Steen et al. (2014) MRI by steering resonance through space. Magn Reson Med 72:49-58 |
| Idiyatullin, Djaudat; Corum, Curtis A; Nixdorf, Donald R et al. (2014) Intraoral approach for imaging teeth using the transverse B1 field components of an occlusally oriented loop coil. Magn Reson Med 72:160-5 |
| Zhang, Jinjin; Chamberlain, Ryan; Etheridge, Michael et al. (2014) Quantifying iron-oxide nanoparticles at high concentration based on longitudinal relaxation using a three-dimensional SWIFT Look-Locker sequence. Magn Reson Med 71:1982-8 |
| Luhach, Ihor; Idiyatullin, Djaudat; Lynch, Conor C et al. (2014) Rapid ex vivo imaging of PAIII prostate to bone tumor with SWIFT-MRI. Magn Reson Med 72:858-63 |
| Wang, Luning; Corum, Curtis A; Idiyatullin, Djaudat et al. (2013) T? estimation for aqueous iron oxide nanoparticle suspensions using a variable flip angle SWIFT sequence. Magn Reson Med 70:341-7 |
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