Phase-contrast magnetic resonance imaging (PC-MRI) is a noninvasive technique capable of quantifying hemodynamics in the heart and great vessels. Because spin moving through a spatially varying magnetic field accumulates phase compared to static spin, velocity information in PC-MRI is encoded into the phase of the complex-valued image. This information is then retrieved by measuring the phase differences between images collected under different values of the velocity-encoding gradients. Cardiovascular applications of PC-MRI include quantification of cardiac function, evaluation of stenosis, assessment of congenital heart disease, and evaluation of aortic atherosclerosis.
Clinical application of PC-MRI to 4D flow imaging and to real-time through-plane velocity imaging has been precluded by long scan times and low acquisition efficiency. Several methodological improvements have been proposed to reduce acquisition time of flow imaging via PC-MRI: parallel MRI (pMRI), fast sampling strategies, and iterative image recovery inspired by compressive sensing (CS) concepts. For 2D PC-MRI, Kim et al. proposed k-t SPARSE-SENSE and reported a six-fold acceleration for liver imaging with electrocardiogram triggering; k-t SPARSE-SENSE combines randomized Cartesian sampling, pMRI, and sparsity of temporal principal components analysis (PCA). More recently, Giese et al. individually processed principal components from multiple spatial compartments in the image series to capture the spatially varying dynamic behavior. Kwak et al. recovered five-fold accelerated 2D PC-MRI by enforcing total variation (TV) minimization of both encoded and compensated images as well as exploiting the sparsity of the complex difference image. Most 2D PC-MRI reconstruction methods can be extended for 4D flow where even higher acceleration is possible due to additional redundancy. Knobloch et al. proposed a method that utilizes both temporal PCA and the complex difference of velocity-encoded and velocity-compensated images to report an eight-fold acceleration for 4D flow. Despite these proposed processing methods, the challenge remains to achieve 4D flow imaging in clinically relevant acquisition times.
The present disclosure is directed to a novel technique for accelerated Phase-contrast magnetic resonance imaging (PC-MRI). The technique is based on Bayesian inference yet admits fast computation via an approximate message passing algorithm. The Bayesian formulation allows modeling and exploitation of the statistical relationships across space, time, and encodings in order to achieve reproducible estimation of flow from highly undersampled data.
Several characteristics are disclosed in accordance with the present disclosure. First, data are jointly processed across all coils, frames, and encodings. Second, overcomplete (non-decimated) wavelets are employed for transform-based compression jointly across both space and time. Third, an optimized sampling strategy provides a distinct variable density sampling pattern for each encoding; the sampling also facilitates estimation of coil sensitivity maps. Fourth, a mixture density model is employed to capture the strong redundancy between the background and velocity-encoded images; the approach captures not only the similarity in magnitudes between background and velocity-encoded images but also the phase similarity in velocity-free regions. From the mixture density, the algorithm implicitly learns a probabilistic segmentation of image frames into velocity-containing and velocity-free regions. Fifth, approximate message passing provides a fast computational framework to enable minimum mean squared error (MMSE) estimation while jointly processing the large corpus of spatiotemporal data. Sixth, an expectation-maximization procedure within the empirical Bayes framework provides automatic parameter tuning. Together, these characteristics yield a principled estimation approach that enables accelerated PC-MRI.
To describe the above, herein the term “ReVEAL” is used, which means “Reconstructing Velocity Encoded MRI with Approximate Message passing aLgorithms.” For time-resolved, planar imaging with one velocity encoded direction (through-plane), it is demonstrated that prospectively undersampled acquisition achieving an acceleration factor of 10 using both phantom and in vivo data. The techniques of the present disclosure will yield higher acceleration with the increased number of correlated encodings present in 4D flow imaging.
Thus, in accordance with present disclosure, there is described a method of image acquisition and reconstruction in a magnetic resonance imaging (MRI) apparatus. The method includes acquiring undersampled phase-contrast magnetic resonance imaging (PC-MRI) data using Variable density incoherent spatiotemporal acquisition (VISTA) sampling; modeling the PC-MRI data in accordance with statistical relationships across space, time and encodings; performing an image reconstruction from modeled PC-MRI data; and displaying reconstructed images.
In accordance with additional aspects of the disclosure, a magnetic resonance imaging (MRI) system is described. The system includes an MRI machine that acquires undersampled phase-contrast magnetic resonance imaging (PC-MRI) data using Variable density incoherent spatiotemporal acquisition (VISTA) sampling generates MRI image data. The system also includes a computing device that receives the PC-MRI data and models the PC-MRI data in accordance with statistical relationships across space, time and encodings, the computing device further performing an image reconstruction from modeled PC-MRI data. A display that receives and displays reconstructed images.
Other systems, methods, features and/or advantages will be or may become apparent to one with skill in the art upon examination of the following drawings and detailed description. It is intended that all such additional systems, methods, features and/or advantages be included within this description and be protected by the accompanying claims.
The components in the drawings are not necessarily to scale relative to each other. Like reference numerals designate corresponding parts throughout the several views.
Theory
Parallel MRI Signal Model
The received signal model for 2D dynamic MRI with multiple receiver coils will now be described. The measured data yit from the ith coil at time index, or frame, t can be represented by the relationship:
y
i
t
=D
t
FShd i
t
x
t+φit (1)
where Dt is a k-space sample selection operator at time t, F is the 2D Fourier operator, and Sit is a diagonal matrix which represents the ith coil sensitivity map. Here, xt∈CN is a vectorization of the two-dimensional image to be recovered, yit∈CM is the subsampled Fourier measurements, and φit∈CN is additive noise. Relationship (1) can be rewritten in block notation for C coils as follows:
The 2D signal model given in (2) can be viewed as a single time instance in a dynamic image sequence. The signal model for the dynamic sequence of P frames is given by
where At represents the measurement matrix at time t with possibly time-dependent downsampling and coil sensitivities Dt and Sit, respectively. Relationship (3) can be written as y=Ax+φ.
For the k-space sampling pattern described by Dt, i=1, . . . , P variable density incoherent sampling patterns can be used. The design results in sampling patterns that differ across frames as well as across the velocity encodings. The sampling design optimizes a constrained energy potential to produce a pseudo-random pattern that promotes incoherence of the operator A, limits eddy currents, and provides a fully sampled k-space when time-averaged across all frames. The last of these constraints facilitates estimation of coil sensitivities without calibration data.
A representative VISTA sampling pattern for PC-MRI is shown in
Bayesian Representation of Data Dependencies
In phase-contrast imaging, velocity is encoded into the phase of the complex-valued MR images. Due to off-resonance effects and magnetic field inhomogeneities, the MR images have phase, referred to here as background phase, which does not contain velocity information. To compensate for background phase, two measurements are made. The first, denoted by yb, is the velocity-compensated measurement. The corresponding image xb=mejθ
x
v
=me
j(θ
+θ
)
=x
b
e
jθ
. (4)
The signals xb and xv are measured under the model in (3), which may be denoted as:
y
b
=A
b
x
b+φb (5)
y
v
=A
v
x
v+φv, (6)
where φb and φv are additive measurement noise. The measurement matrices, Ab and Av, may differ, thereby allowing for different sampling patterns for each of the two measurements.
To capture the physical behavior suggested in (3), xb, xv, and θv may be modeled as random variables. The phase difference θv, explicitly appears in the model as a parameter to be inferred from the noisy data. In addition, a “hidden” Bernoulli random variable may be introduced, denoted as v, to indicate the inferred locations in xv that contain non-zero velocity. By application of Bayes' theorem and the chain rule for conditional probability densities, the posterior distribution on these unknown variables, given the observed noisy measurements, can be written as the following relationship:
In relationship (7), ∝ denotes proportionality; the double subscripts ybm and xbn denote the mth measurement sample and nth image pixel, respectively, for the background encoding. Further, N and M denote the total number of pixels and measurements, respectively. Three independence assumptions are invoked. The model in (7) assumes that θv and xb are independent, i.e. p(θv|xb)=p(θv). Likewise, it is assumed that v is independent of both θv and xb, i.e. p(v|xb, θv)=p(v). A third independence assumption, p(θv|v)=p(θv) is chosen for convenience, similar to indicator variable modeling. These independence assumptions are used herein to bypass potential regularizing structure in favor of modeling and computational simplicity; more prominent signal structure is exploited in the remaining factors discussed below.
A mixture density to capture the redundancy between a velocity-encoded pixel, xvn, and the corresponding velocity-compensated (background) pixel, xbn may be adopted in view of relationship (4). The conditional distribution is given by the following:
p(xvn|xbn,θvn,vn)=(1−vn)CN(xvn;xbn,σ2)+vnCN(xvn;xbnejθ
The notation CN(x; μ,σ2) denotes a circularly symmetric complex-valued Gaussian density on x with mean μ and variance σ2. The distribution is conditioned on the hidden indicator variable, vn, which serves as probabilistic segmentation of the image into velocity-containing and velocity-free regions, with vn=1 denoting velocity at pixel n. The first term of (8), (1−vn)CN(xvn;xbn,σ2), represents the relationship between xv and xb for zero-velocity regions. This term models xvn as a Gaussian perturbed version of xbn. The variance, σ2, serves to model physical departures of noiseless images from the idealized assumption in relationship (4). In contrast, the effects of measurement noise are modeled by the likelihood function given below.
The non-Gaussian conditional distribution of xvn given xbn and vn=1 (i.e., velocity-containing pixels) is depicted in
where I0(x) denotes a zeroth-ordered Bessel function of the first kind.
Additional modeling choices remain in (7). First, it is assumed that the k-space measurements yb and yv are corrupted by additive, circularly symmetric complex Gaussian noise. This yields the likelihood models:
p(ybn|xb)=CN(ybn;[Abxb]n,ω2) (10)
p(ybn|xv)=CN(yvn;[Avxv]n,ω2), (11)
where ω2 is the noise variance, and the mean, [Ax]n, is the nth element of the matrix vector product Ax. Second, for the prior on the phase, p(θvn), the non-informative prior of equal probability on the interval [0,2π) may be adopted. Third, a hidden variable v∈{0,1}N may be defined as a Bernoulli indicator with p(vn=1)=γ. Thus, γ is the prior probability that any pixel contains non-zero velocity, and 1−γ is the prior probability that a pixel contains no velocity.
Finally, the prior p(xb) may be addressed. It may be observed that a three-dimensional non-decimated wavelet transform, Ψ, applied to xb and xv across both space and time results in few non-negligible coefficients. Rather than postulate a prior density to model this behavior, augmenting the likelihood may be selected. To this end, {tilde over (M)}-by-N matrices Ãb and Ãv are formed, appending Ψ as additional rows to the matrices Ab and Av. Then, a zero-mean Laplace likelihood for p([Ψxb]m|xb) and p([Ψxv]m|xv) may be adopted. The Laplace density for a complex-valued random variable x and scaling parameter λ is:
The Laplace prior in Eq. (12) can be related to the l1 norm by the maximum a posteriori (MAP) estimate. The MAP solution maximizes the posterior distribution. To see the relation, observe that the maximum of the log posterior under Gaussian likelihood and Laplace prior given as:
However, the MMSE estimate may be approximated, given by the mean of the posterior distribution, via sum-product message passing. The cost function for MMSE minimization, within an approximate message passing algorithm, is described by the Bethe Free Energy.
Approximate Message Passing
On the dense, loopy portion of the graph, the message passing computation can be greatly simplified by adopting generalized approximate message passing (GAMP), which invokes the central limit theorem and Taylor series approximations to dramatically reduce computational complexity. A GAMP toolbox maybe used for message passing on this portion of the graph. Message evaluation implements a first order computation involving the matrix A, the conjugate transpose, AH, and the wavelet transforms Ψ and ΨH; therefore, fast transforms or parallel hardware for the implementation of A, AH, Ψ, and ΨH enable computation in seconds, not hours.
Methods
Flow Phantom Data Acquisition
For experimental validation, a CardioFlow 5000 MR flow pump (Shelley Medical Imaging Technologies, Toronto, Ontario, Canada) was used. This programmable pump generates periodic, reproducible flow profiles and is capable of generating a volumetric flow rate of 300 ml/s. The phantom included a water bottle and flexible pipe. The pipe was bent into a u-shape such that two sections of the pipe were aligned in parallel beneath the bottle. The imaging plane was perpendicular to the parallel pipe sections such that in-flow and return-flow to the pump were measured simultaneously. For flow quantification, the two cross-sections of the pipe in each image sequence were treated as separate measurements. The volume passing through each cross section should be the same, but their velocity-time profile may differ.
The CardioFlow 5000 MR comes with two pre-programmed physiological waveforms; one waveform that mimics the femoral flow and the other that mimics the carotid flow. To generate additional waveforms, these two waveforms were modified by changing the vertical scaling, horizontal scaling, and duty cycle. In total, twelve different waveforms were generated for n=24 unique measurements per acceleration factor. Data were collected on a 1.5 T scanner (Avanto, Siemens Healthcare, Erlangen, Germany) with a 32-channel coil array. The prospectively downsampled data were collected using VISTA for seven different acceleration rates, i.e., R=1, 2, 4, 5, 8, 10 and 16.
All data were collected using a gradient-echo pulse sequence, with TE=2.94 ms, TR=4.92 ms, and VENC=150 cm/s. The datasets were collected using prospectively triggered segmented acquisition, with pseudo-EKG trigger signal generated by the flow pump. The segment size (k-space lines/segment) was set at 4, resulting in a temporal resolution of 39.4 ms that was fixed across all datasets. The matrix size and field of view were 160×160 and 300×300 mm2, respectively. The acquisition time was 40/R pseudo-heartbeats.
In Vivo Cardiac Data Acquisition
With reference to
The data were collected using a gradient-echo pulse sequence, with TE=3.21 ms, TR=5.63 ms for retrospectively downsampled data and TE=3.10 ms and TR=5.17 ms for prospectively sampled data. Each in vivo dataset was collected in a single breath-hold using segmented acquisition with prospective EKG triggering. For the retrospectively downsampled data, the VENC was set at 180 cm/s and the segment size was set at 3, resulting in a temporal resolution of 33.8 ms and acquisition time of 36 heartbeats. For the prospectively sampled data, the VENC was set at 150 cm/s and the segment size was set at 4, resulting in a temporal resolution of 41.3 ms and acquisition time of 40/R heartbeats. The matrix size and field of view were 192×108 and 360×248 mm2, respectively, for retrospectively downsampled data and 160×160 and 300×300 mm2, respectively, for prospectively downsampled data.
Image Reconstruction
The ReVEAL reconstruction was computed off-line using customized Matlab software (Mathworks, Natick, Mass.) running on Red Hat Enterprise Linux with an Intel Core i7-2600 at 3.4 GHz CPU and 8 GB of RAM. Coil sensitivity maps were self-calibrated by averaging undersampled k-space data over all time frames and applying the adaptive array combination method (406). Maxwell correction was applied to all the datasets by incorporating the correction map into the data model given by relationship (8).
The noise variance, ω2, was automatically estimated from the periphery of k-space for each acquisition, after SVD-based compression from 32 (phantom) or 18 (in vivo) coils to 12 virtual coils. The prior probability of flow, γ, at each pixel and frame is learned directly from the data using an expectation-maximization procedure. The parameter σ2 characterizes the variability between encodings, and was set to ω2/√{square root over (C)}. The relative values of λ across the 8 wavelet sub-bands were λ0×{0.01,1,1,2,1.2,2.4,2.4,3.6}. These relative values were determined by application of an automated procedure to a separate in vivo data set and were held fixed across all acceleration rates and for both phantom and in vivo data. The single algorithm parameter requiring ad hoc tuning was λ0, which sets a global scaling of the wavelet regularization. Herein, λ0=0.7 may be employed for all in vivo data and λ0=4 for the flow phantom data. Daubechies db1 wavelets were used in the spatial dimensions and db3 wavelets in the temporal dimension.
ReVEAL is compared with k-t SPARSE-SENSE as well as ReVEAL with the mixture density omitted, termed “ReVEAL no mixture.” Although the ReVEAL no mixture reconstruction relies on over-complete spatio-temporal wavelets, a squared-error penalty for data fidelity, optimized VISTA sampling patterns, and message passing computation, it does not assume any relationship between encodings. Comparison between ReVEAL and ReVEAL no mixture is intended to highlight the benefit from the regularizing effect of the proposed statistical model between encodings in relationship (8). A code to implement k-t SPARSE-SENSE was provided by Daniel Kim, Li Feng, and Hassan Haji-Valizadeh. Reconstruction times for the prospectively downsampled in vivo dataset at R=10 were approximately 6.5 minutes, 3.5 minutes, and 7 minutes, for ReVEAL, ReVEAL no mixture, and k-t SPARSE-SENSE, respectively.
Data Analysis
Peak velocity (PV) and stroke volume (SV) were used as quantitative measures of fidelity. The PV is defined as the maximum velocity across all pixels and frames within a region of interest (ROI). The SV is defined as the volume of blood or fluid passing through an ROI for one heartbeat or pump cycle. ROls were identified for each image series by manually segmenting the pipes or blood vessels from the magnitude images. To capture the motion of the aorta during the heartbeat, each ROI was manually shifted from frame-to-frame. The size of the ROI was held constant across different acceleration rates and frames to limit variation in PV and SV due to ROI selection.
For phantom imaging and retrospectively downsampled in vivo data, the reconstructions corresponding to R=1 (fully sampled) data were used as reference. For the prospectively accelerated in vivo data, data reconstructed at R=1.74 with GRAPPA were used as reference. Bland-Altman plots—one for each acceleration rate—were used to display PV and SV. To quantify variations due to physiological changes, an additional Bland-Altman plot was created comparing the two R=1.74 GRAPPA reconstructions.
The retrospectively downsampled in vivo dataset, collected from a single volunteer, does not mimic the real-life acquisition process but is included because it does not suffer from physiological variations present in the prospectively sampled datasets. In the retrospectively accelerated case, the reference is know precisely, thus guaranteeing the same velocity-time profile for each acceleration. A Bland-Altman plot was not constructed for the retrospectively downsampled in vivo data due to the small sample size. However, normalized mean squared error (NMSE) and the structural similarity index (SSIM) for the velocity map were calculated for each acceleration rate. NMSE is defined as:
where xref is the noisy reference from fully sampled data and {circumflex over (x)}R the reconstructed image from acceleration rate R. xref and {circumflex over (x)}R were formed from the compensated image magnitude and velocity encoded phase, i.e., |xbejθ
Results
Retrospectively Accelerated In Vivo Data
The retrospectively downsampled image sequences were reconstructed using ReVEAL, ReVEAL no mixture, and k-t SPARSE-SENSEs; results are shown in
The PV and SV were calculated inside the ascending aorta and plotted versus acceleration rate R. Results from R=1 were calculated using the adaptive array combination method and are given as a reference. As shown in
As evident in rows c and d of
To examine the modeling choice in Eq. (8), histograms were constructed from fully sampled data, as shown in
Prospectively Accelerated Phantom Data
The phantom data were reconstructed using ReVEAL, ReVEAL no mixture, and k-t SPARSE-SENSE; the fully sampled data, reconstructed with the adaptive array combination array combination method, were used as reference. The resulting Bland-Altman analyses and Pearson correlation coefficients are tabulated in Table 1.
−0.11
0.95
0.99
−0.11
0.47
0.99
0.44
0.87
0.99
0.99
0.99
0.99
0.79
0.99
0.99
0.99
0.99
0.99
0.99
0.99
0.99
2.61
0.99
2.72
0.99
−0.52
2.60
0.99
−0.13
0.99
0.99
0.99
0.99
0.99
0.87
0.99
−0.08
2.39
0.96
0.99
0.99
−0.62
3.83
0.99
−2.10
6.30
0.97
3.48
0.99
The corresponding Bland-Altman plots are provided in
The variability of ReVEAL is low up to R=10, increasing only moderately compared to R=2. The fidelity of reconstruction is therefore preserved to an acceleration factor R=10. Fidelity of PV and SV is, however, lost at R=16as seen in the negative bias and increased variance. In comparison, ReVEAL no mixture compares favorably to ReVEAL at low acceleration rates but degrades significantly beyond R=5, and k-t SPARSESENSE exhibits large variances. Also, the Pearson correlation coefficients for ReVEAL are consistently higher than those of ReVEAL no mixture and k-t SPARSESENSE.
Prospectively Accelerated In Vivo Data
The prospectively sampled in vivo data were reconstructed using ReVEAL, ReVEAL no mixture, and k-t SPARSE-SENSE. The GRAPPA reconstructions at R=1.74, were used as reference. The resulting Bland—Altman analyses and Pearson correlation coefficients are tabulated in Table 2.
0.98
−0.97
4.92
0.97
−2.78
0.98
−2.90
8.51
0.98
2.05
3.76
0.98
4.48
0.97
−0.54
10.98
0.81
11.31
4.32
10.15
0.04
0.85
12.55
0.83
0.81
3.89
0.82
−2.08
3.95
0.96
−13.01
10.17
0.85
11.74
0.82
10.07
0.82
2.12
8.01
The corresponding Bland-Altman plots are provided in
As evident from Table 2, the variability of ReVEAL, for R≦10, compares favorably to both ReVEAL at R=2 and GRAPPA at R=1.74. As was the case for phantom imaging, fidelity of PV and SV is lost at R=16 as reflected in the relatively large bias and variance. In comparison, the performances of ReVEAL no mixture and k-t SPARSESENSE degrade rapidly beyond R=5. For R=10, representative velocity-time profiles for mean and peak velocities are shown in
Discussion
The proposed ReVEAL approach for PC-MRI yields an empirical Bayes reconstruction with fast message passing computation that jointly processes the entire data set across space, time, coils, and encodings. Estimation of stroke volume and peak velocity using prospective in vivo acquisition at R=10 showed variance and Pearson correlation coefficient similar to R=1.74 GRAPPA (n=10); the accelerated measurement comprised four heart-beats in a single breath-hold, segmented acquisition. The posterior means computed by the algorithm provide MMSE estimates of image magnitude and velocity-encoded phase, and posterior variances provide, if desired and with no additional computation, confidence labels for the estimated quantities produced by the nonlinear reconstruction. Further, these posterior probabilities enable automated tuning of algorithm parameters via expectation-maximization, demonstrated here for selection of the prior probability of flow parameter, γ. The wavelet regularization in ReVEAL provides spatio-temporal regularization, while k-t SPARSE-SENSE, for example, captures only temporal regularization. Further, the signal structure present between encodings is exploited in ReVEAL using a non-Gaussian mixture density, which significantly reduced both bias and variance in SV and PV for R>5. The mixture density implicitly results in an automated segmentation of pixels via the posterior probability of the velocity indicator variable, v; the action of this velocity indicator, v, is particularly visible, for example, at the brachial arteries seen in
The proposed Bayesian data model includes the independence assumption, p(θv|v)=p(θv). This choice to impose no additional statistical dependence is adopted for computational convenience; that is, potential regularization gain from additional physically-motivated structure is conservatively bypassed in favor of computational simplicity. Yet, additional structure across space, time and encodings may indeed be incorporated in the Bayesian model presented here and is a topic of continuing investigation. Examples include Markov random fields and Markov trees. The Bayesian approach of ReVEAL enables both a flexible modeling framework and a fast computational engine for exploiting signal structure not readily captured in traditional regularized inversion methods.
The ReVEAL approach, as presented here, required one user-defined parameter, λ0, that scaled the wavelet regularization; and, the ratios of regularization parameters for the eight wavelet subbands were set using a separate in vivo scan not otherwise included in the study. The automated expectation-maximization procedure used here for selection of the prior probability of flow, γ, could be employed for fully-automated tuning of all parameters.
The acceleration provided by ReVEAL may be traded for improved spatial or temporal resolution. For example, enhanced temporal resolution can allow flow imaging for pediatric and stress imaging applications where higher heart rates are encountered or for vessels, e.g. carotid or femoral arteries, with rapidly changing velocity-time profiles. Alternatively, the acceleration may enable real-time, free-breathing acquisition for 2D PC-MRI. Acceleration beyond the R=10 demonstrated here for through-plane flow imaging can be achieved in 4D flow imaging due to the added redundancy from the two additional encodings and one additional spatial dimension. The computational complexity of the approximate message passing algorithm scales only linearly in the number of encodings, receive coils, frames, and number of k-space samples per coil; therefore, ReVEAL is expected to remain computationally tractable for larger image series and for 4D flow imaging.
Example MRI Data Processing System
With reference to
Computing device 1602 may be a computer of any form factor. Different and additional components may be incorporated into computing device 1602. Components of MRI data processing system 1600 may be positioned in a single location, a single facility, and/or may be remote from one another. As a result, computing device 1602 may also include a communication interface, which provides an interface for receiving and transmitting data between devices using various protocols, transmission technologies, and media as known to those skilled in the art. The communication interface may support communication using various transmission media that may be wired or wireless.
Display 1604 presents information to a user of computing device 1602 as known to those skilled in the art. For example, display 1604 may be a thin film transistor display, a light emitting diode display, a liquid crystal display, or any of a variety of different displays known to those skilled in the art now or in the future.
Input interface 1606 provides an interface for receiving information from the user for entry into computing device 1602 as known to those skilled in the art. Input interface 1606 may use various input technologies including, but not limited to, a keyboard, a pen and touch screen, a mouse, a track ball, a touch screen, a keypad, one or more buttons, etc. to allow the user to enter information into computing device 1602 or to make selections presented in a user interface displayed on display 1604. Input interface 1606 may provide both an input and an output interface. For example, a touch screen both allows user input and presents output to the user.
Memory 1608 is an electronic holding place or storage for information so that the information can be accessed by processor 1610 as known to those skilled in the art. Computing device 1602 may have one or more memories that use the same or a different memory technology. Memory technologies include, but are not limited to, any type of RAM, any type of ROM, any type of flash memory, etc. Computing device 1602 also may have one or more drives that support the loading of a memory media such as a compact disk or digital video disk.
Processor 1610 executes instructions as known to those skilled in the art. The instructions may be carried out by a special purpose computer, logic circuits, or hardware circuits. Thus, processor 1610 may be implemented in hardware, firmware, software, or any combination of these methods. The term “execution” is the process of running an application or the carrying out of the operation called for by an instruction. The instructions may be written using one or more programming language, scripting language, assembly language, etc. Processor 1610 executes an instruction, meaning that it performs the operations called for by that instruction. Processor 1610 operably couples with display 1604, with input interface 1606, with memory 1608, and with the communication interface to receive, to send, and to process information. Processor 1610 may retrieve a set of instructions from a permanent memory device and copy the instructions in an executable form to a temporary memory device that is generally some form of RAM. Computing device 1602 may include a plurality of processors that use the same or a different processing technology.
Image data processing application 1612 performs operations associated with performing parallel image reconstruction of undersampled image data in k-space. Some or all of the operations subsequently described may be embodied in image data processing application 1612. The operations may be implemented using hardware, firmware, software, or any combination of these methods. With reference to the exemplary embodiment of
MRI machine 1601 and computing device 1602 may be integrated into a single system such as an MRI machine. MRI machine 1601 and computing device 1602 may be connected directly. For example, MRI machine 1601 may connect to computing device 1602 using a cable for transmitting information between MRI machine 1601 and computing device 1602. MRI machine 1601 may connect to computing device 1602 using a network. MRI images may be stored electronically and accessed using computing device 1602. MRI machine 1601 and computing device 1602 may not be connected. Instead, the MRI data acquired using MRI machine 1601 may be manually provided to computing device 1602. For example, the MRI data may be stored on electronic media such as a CD or a DVD. After receiving the MRI data, computing device 1602 may initiate processing of the set of images that comprise an MRI study.
Thus, the present disclosure presented ReVEAL as a novel technique for recovery of accelerated PC-MRI data; the approach includes Bayesian modeling of PC-MRI data, a VISTA sampling strategy, and fast message passing computation. Quantitative results were presented for in vivo and flow phantom data for 2D through plane flow measurements; further, ReVEAL is extensible to applications such as 4D flow, real-time 2D flow, and DENSE.
This application claims priority to U.S. Provisional Patent Application No. 62/164,521, filed May 20, 2015, entitled “A BAYESIAN MODEL FOR HIGHLY ACCELERATED PHASE-CONTRAST MRI,” which is incorporated herein by reference in its entirety.
Number | Date | Country | |
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62164521 | May 2015 | US |