High frame‐rate simultaneous bilateral breast DCE‐MRI

Dougherty, Lawrence; Isaac, Gamaliel; Rosen, Mark; Nunes, Linda White; Moate, Peter J.; Boston, Raymond C.; Schnall, Mitchell D.; Song, Hee Kwon

doi:10.1002/mrm.21114

Cited by 33 publications

(27 citation statements)

References 27 publications

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“…20 Because of their mutual importance, consistent efforts have been aimed at accomplishing both high temporal and spatial resolution DCE-MRI. [21][22][23][24][25][26][27] A recently developed mathematical theory of signal processing and data acquisition, compressed sensing ͑CS͒ theory, [28][29][30][31] provides a novel way to accomplish this goal. The breakthrough in the CS theory is its ability to allow images to be faithfully recovered from what appear to be highly incomplete data sets, where one of the central tenets of signal processing and data acquisition, the Nyquist sampling theory, has been violated.…”

Section: Introductionmentioning

confidence: 99%

Feasibility of high temporal resolution breast DCE‐MRI using compressed sensing theory

et al. 2010

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Purpose:To investigate the feasibility of high temporal resolution breast DCE-MRI using compressed sensing theory. Methods: Two experiments were designed to investigate the feasibility of using reference image based compressed sensing ͑RICS͒ technique in DCE-MRI of the breast. The first experiment examined the capability of RICS to faithfully reconstruct uptake curves using undersampled data sets extracted from fully sampled clinical breast DCE-MRI data. An average approach and an approach using motion estimation and motion compensation ͑ME/MC͒ were implemented to obtain reference images and to evaluate their efficacy in reducing motion related effects. The second experiment, an in vitro phantom study, tested the feasibility of RICS for improving temporal resolution without degrading the spatial resolution. Results: For the uptake-curve reconstruction experiment, there was a high correlation between uptake curves reconstructed from fully sampled data by Fourier transform and from undersampled data by RICS, indicating high similarity between them. The mean Pearson correlation coefficients for RICS with the ME/MC approach and RICS with the average approach were 0.977Ϯ 0.023 and 0.953Ϯ 0.031, respectively. The comparisons of final reconstruction results between RICS with the average approach and RICS with the ME/MC approach suggested that the latter was superior to the former in reducing motion related effects. For the in vitro experiment, compared to the fully sampled method, RICS improved the temporal resolution by an acceleration factor of 10 without degrading the spatial resolution. Conclusions: The preliminary study demonstrates the feasibility of RICS for faithfully reconstructing uptake curves and improving temporal resolution of breast DCE-MRI without degrading the spatial resolution.

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Section: Introductionmentioning

confidence: 99%

Feasibility of high temporal resolution breast DCE‐MRI using compressed sensing theory

et al. 2010

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“…In particular, without ISPM the actual physical separation between superimposed slices is a (from medial regions) or 2 a (from lateral regions) but with ISPM the separation is constant (1.5 a ). SENSE reconstruction with a factor of 2 unwraps each pair of two superimposed slices whether ISPM is applied or not [22], but the geometry factors ( g -factors) over the slabs vary due to change of coil sensitivity differences. Changing g -factors by relocating aliasing artifacts is also used in the “controlled aliasing in parallel imaging results in higher acceleration” (CAIPIRINHA) method [23].…”

Section: Methodsmentioning

confidence: 99%

Independent slab‐phase modulation combined with parallel imaging in bilateral breast MRI

Han

Beatty

Daniel

et al. 2009

Magnetic Resonance in Med

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Independent slab-phase modulation allows three-dimensional imaging of multiple volumes without encoding the space between volumes, thus reducing scan time. Parallel imaging further accelerates data acquisition by exploiting coil sensitivity differences between volumes. This work compared bilateral breast image quality from self-calibrated parallel imaging reconstruction methods such as modified sensitivity encoding, generalized autocalibrating partially parallel acquisitions and autocalibrated reconstruction for Cartesian sampling (ARC) for data with and without slab-phase modulation. A study showed an improvement of image quality by incorporating slab-phase modulation. Geometry factors measured from phantom images were more homogenous and lower on average when slab-phase modulation was used for both mSENSE and GRAPPA reconstructions. The resulting improved signal-tonoise ratio (SNR) was validated for in vivo images as well using ARC instead of GRAPPA, illustrating average SNR efficiency increases in mSENSE by 5% and ARC by 8% based on region of interest analysis. Furthermore, aliasing artifacts from mSENSE reconstruction were reduced when slab-phase modulation was used. Overall, slab-phase modulation with parallel imaging improved image quality and efficiency for 3D While breast cancer is the second leading cause of death due to cancer among American women (1), early diagnosis and treatment can reduce mortality rates (2). Currently, the most common breast cancer screening method is X-ray mammography, which has limited ability to detect tumors in young women who have more dense breasts than postmenopausal women (3). Several studies show that MRI has much higher sensitivity for detecting cancer, especially in high-risk patients (4,5). Recently, breast MRI has been recommended by the American Cancer Society for women at 20-25% or greater lifetime risk of breast cancer (6). The ability of MRI to detect breast cancer is dependent on high-quality images, particularly with high signal-to-noise ratio (SNR) and spatial resolution. In addition, for dynamic contrast-enhanced breast imaging (7,8) resolution is also helpful for accurate characterization of contrast kinetics.Bilateral breast imaging can be more cost-effective than unilateral breast imaging and helps to detect contralateral tumors (9). Normally, bilateral breast MRI is conducted by exciting and imaging the two separated breasts together, using a volume-selective excitation. The region between the two breasts might provide useful information for diagnosis; however, when high temporal resolution is needed, not imaging that region can be beneficial as it usually occupies 20-30% of total volume. In addition, not exciting that region provides better shims over the two breasts and reduces cardiac motion artifacts. A dual-band spectralspatial excitation pulse (10,11) excites the two separate breast slabs simultaneously but independently with their own center frequencies and linear shims and thus provides robust fat suppression over each slab (12). It also allows ind...

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“…Numerous methods exist for the implementation of each of the above steps: T1 and M 0 maps can be acquired with several techniques; [3][4][5][6] different mathematical models can be used to analyze the dynamic data; [7][8][9][10][11][12][13][14] and finally, various pulse sequences differing in sampling strategies and acquisition parameters have been developed to sample the signal in k-space. [15][16][17][18] The vast majority of preclinical sampling strategies used for DCE-MRI acquire a limited number of relatively thick slices. Volume averaging and limited coverage make it difficult to characterize the heterogeneity in the tumor microenvironment.…”

Section: Introductionmentioning

confidence: 99%

“…The work is an extension of previous efforts employing projection imaging with keyhole sampling. 17,[19][20][21] Keyhole sampling, initially defined for rectilinear MRI, 22 refers to a post-acquisition filtering technique in which the center of k-space is updated more frequently than the periphery with the purpose of increasing temporal resolution. Projection imaging, when implemented as a 3D sequence, provides inherently volumetric measurements, has reduced sensitivity to motion and flow artifacts, and allows for shorter echo times as compared to traditional Cartesian methods.…”

Section: Introductionmentioning

confidence: 99%

A comparison of radial keyhole strategies for high spatial and temporal resolution 4D contrast-enhanced MRI in small animal tumor models

et al. 2013

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Purpose: Dynamic contrast-enhanced (DCE) MRI has been widely used as a quantitative imaging method for monitoring tumor response to therapy. The simultaneous challenges of increasing temporal and spatial resolution in a setting where the signal from the much smaller voxel is weaker have made this MR technique difficult to implement in small-animal imaging. Existing protocols employed in preclinical DCE-MRI acquire a limited number of slices resulting in potentially lost information in the third dimension. This study describes and compares a family of four-dimensional (3D spatial + time), projection acquisition, radial keyhole-sampling strategies that support high spatial and temporal resolution. Methods: The 4D method is based on a RF-spoiled, steady-state, gradient-recalled sequence with minimal echo time. An interleaved 3D radial trajectory with a quasi-uniform distribution of points in k-space was used for sampling temporally resolved datasets. These volumes were reconstructed with three different k-space filters encompassing a range of possible radial keyhole strategies. The effect of k-space filtering on spatial and temporal resolution was studied in a 5 mM CuSO 4 phantom consisting of a meshgrid with 350-μm spacing and in 12 tumors from three cell lines (HT-29, LoVo, MX-1) and a primary mouse sarcoma model (three tumors/group). The time-to-peak signal intensity was used to assess the effect of the reconstruction filters on temporal resolution. As a measure of heterogeneity in the third dimension, the authors analyzed the spatial distribution of the rate of transport (K trans ) of the contrast agent across the endothelium barrier for several different types of tumors. Results: Four-dimensional radial keyhole imaging does not degrade the system spatial resolution. Phantom studies indicate there is a maximum 40% decrease in signal-to-noise ratio as compared to a fully sampled dataset. T1 measurements obtained with the interleaved radial technique do not differ significantly from those made with a conventional Cartesian spin-echo sequence. A bin-by-bin comparison of the distribution of the time-to-peak parameter shows that 4D radial keyhole reconstruction does not cause significant temporal blurring when a temporal resolution of 9.9 s is used for the subsamples of the keyhole data. In vivo studies reveal substantial tumor heterogeneity in the third spatial dimension that may be missed with lower resolution imaging protocols. Conclusions: Volumetric keyhole imaging with projection acquisition provides a means to increase spatiotemporal resolution and coverage over that provided by existing 2D Cartesian protocols. Furthermore, there is no difference in temporal resolution between the higher spatial resolution keyhole reconstruction and the undersampled projection data. The technique allows one to measure complex heterogeneity of kinetic parameters with isotropic, microscopic spatial resolution.

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High frame‐rate simultaneous bilateral breast DCE‐MRI

Cited by 33 publications

References 27 publications

Feasibility of high temporal resolution breast DCE‐MRI using compressed sensing theory

Feasibility of high temporal resolution breast DCE‐MRI using compressed sensing theory

Independent slab‐phase modulation combined with parallel imaging in bilateral breast MRI

A comparison of radial keyhole strategies for high spatial and temporal resolution 4D contrast-enhanced MRI in small animal tumor models

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