Your search keyword '"Sodickson DK"' showing total 178 results

151. Inherently self-calibrating non-Cartesian parallel imaging.

Author

Yeh EN, Stuber M, McKenzie CA, Botnar RM, Leiner T, Ohliger MA, Grant AK, Willig-Onwuachi JD, and Sodickson DK

Subjects

Artificial Intelligence, Calibration, Coronary Vessels anatomy & histology, Equipment Failure Analysis methods, Feasibility Studies, Humans, Information Storage and Retrieval methods, Magnetic Resonance Angiography standards, Reproducibility of Results, Sensitivity and Specificity, Algorithms, Artifacts, Image Enhancement methods, Image Interpretation, Computer-Assisted methods, Imaging, Three-Dimensional methods, Magnetic Resonance Angiography instrumentation, Magnetic Resonance Angiography methods

Abstract

The use of self-calibrating techniques in parallel magnetic resonance imaging eliminates the need for coil sensitivity calibration scans and avoids potential mismatches between calibration scans and subsequent accelerated acquisitions (e.g., as a result of patient motion). Most examples of self-calibrating Cartesian parallel imaging techniques have required the use of modified k-space trajectories that are densely sampled at the center and more sparsely sampled in the periphery. However, spiral and radial trajectories offer inherent self-calibrating characteristics because of their densely sampled center. At no additional cost in acquisition time and with no modification in scanning protocols, in vivo coil sensitivity maps may be extracted from the densely sampled central region of k-space. This work demonstrates the feasibility of self-calibrated spiral and radial parallel imaging using a previously described iterative non-Cartesian sensitivity encoding algorithm.

Published

2005

152. Parallel magnetic resonance imaging with adaptive radius in k-space (PARS): constrained image reconstruction using k-space locality in radiofrequency coil encoded data.

Author

Yeh EN, McKenzie CA, Ohliger MA, and Sodickson DK

Subjects

Algorithms, Humans, Models, Statistical, Phantoms, Imaging, Software, Image Processing, Computer-Assisted methods, Magnetic Resonance Imaging methods

Abstract

A parallel image reconstruction algorithm is presented that exploits the k-space locality in radiofrequency (RF) coil encoded data. In RF coil encoding, information relevant to reconstructing an omitted datum rapidly diminishes as a function of k-space separation between the omitted datum and the acquired signal data. The proposed method, parallel magnetic resonance imaging with adaptive radius in k-space (PARS), harnesses this physical property of RF coil encoding via a sliding-kernel approach. Unlike generalized parallel imaging approaches that might typically involve inverting a prohibitively large matrix for arbitrary sampling trajectories, the PARS sliding-kernel approach creates manageable and distributable independent matrices to be inverted, achieving both computational efficiency and numerical stability. An empirical method designed to measure total error power is described, and the total error power of PARS reconstructions is studied over a range of k-space radii and accelerations, revealing "minimal-error" conditions at comparatively modest k-space radii. PARS reconstructions of undersampled in vivo Cartesian and non-Cartesian data sets are shown and are compared selectively with traditional SENSE reconstructions. Various characteristics of the PARS k-space locality constraint (such as the tradeoff between signal-to-noise ratio and artifact power and the relationship with iterative parallel conjugate gradient approaches or nonparallel gridding approaches) are discussed.

Published

2005

153. Rapid volumetric MRI using parallel imaging with order-of-magnitude accelerations and a 32-element RF coil array: feasibility and implications.

Author

Sodickson DK, Hardy CJ, Zhu Y, Giaquinto RO, Gross P, Kenwood G, Niendorf T, Lejay H, McKenzie CA, Ohliger MA, Grant AK, and Rofsky NM

Subjects

Adult, Computer Simulation, Contrast Media, Equipment Design, Humans, Imaging, Three-Dimensional, Time Factors, Image Enhancement instrumentation, Magnetic Resonance Imaging instrumentation

Abstract

Rationale and Objectives: Many clinical applications of Magnetic Resonance Imaging are constrained by basic limits on imaging speed. Parallel MRI relaxes these limits by using the sensitivity patterns of arrays of radiofrequency receiver coils to encode spatial information in a manner complementary to traditional encoding with magnetic field gradients. Until now, parallel MRI has been used to achieve modest improvements in imaging speed; order-of-magnitude improvements have been elusive given fundamental losses in signal-to-noise ratio. The goal of this work was to demonstrate that, with appropriate hardware and careful SNR management, rapid volumetric imaging at high accelerations is in fact feasible., Materials and Methods: Contrast-enhanced MRI with an axial 3D spoiled gradient echo imaging sequence was performed in healthy adult subjects using a 32-element RF coil array and a prototype 32-channel MR imaging system. Large imaging volumes were prescribed, in place of traditional limited slabs targeted only to suspect regions., Results: As much as 16-fold net accelerations of imaging were achieved repeatably using this approach. The use of large 3D volumes allowed comprehensive anatomical coverage at clinically useful spatial and/or temporal resolution. The need for careful, time-consuming, and subject-specific scan prescription was also eliminated., Conclusion: The highly parallel imaging approach presented here allows previously inaccessible volumetric coverage for time-sensitive MRI examinations such as contrast-enhanced MRA, and simultaneously provides a substantially simplified imaging paradigm. The resulting capability for rapid volumetric imaging promises to combine the strengths of MRI with some of the advantages of alternative imaging modalities such as multidetector CT.

Published

2005

154. Highly parallel volumetric imaging with a 32-element RF coil array.

Author

Zhu Y, Hardy CJ, Sodickson DK, Giaquinto RO, Dumoulin CL, Kenwood G, Niendorf T, Lejay H, McKenzie CA, Ohliger MA, and Rofsky NM

Subjects

Equipment Design, Humans, Radio Waves, Image Enhancement instrumentation, Magnetic Resonance Imaging instrumentation

Abstract

The improvement of MRI speed with parallel acquisition is ultimately an SNR-limited process. To offset acquisition- and reconstruction-related SNR losses, practical parallel imaging at high accelerations should include the use of a many-element array with a high intrinsic signal-to-noise ratio (SNR) and spatial-encoding capability, and an advantageous imaging paradigm. We present a 32-element receive-coil array and a volumetric paradigm that address the SNR challenge at high accelerations by maximally exploiting multidimensional acceleration in conjunction with noise averaging. Geometric details beyond an initial design concept for the array were determined with the guidance of simulations. Imaging with the support of 32-channel data acquisition systems produced in vivo results with up to 16-fold acceleration, including images from rapid abdominal and MRA studies.

Published

2004

155. Effects of inductive coupling on parallel MR image reconstructions.

Author

Ohliger MA, Ledden P, McKenzie CA, and Sodickson DK

Subjects

Phantoms, Imaging, Image Processing, Computer-Assisted instrumentation, Image Processing, Computer-Assisted methods, Magnetic Resonance Imaging instrumentation

Abstract

Theoretical arguments and experimental results are presented that characterize the impact of inductive coupling on the performance of parallel MRI reconstructions. A simple model of MR signal and noise reception suggests that the intrinsic amount of spatial information available from a given coil array is unchanged in the presence of inductive coupling, as long as the sample remains the dominant source of noise for the coupled array. Any loss of distinctness in the measured coil sensitivities is compensated by information stored in the measured noise correlations. Adjustments to the theory are described to account for preamplifier noise contributions. Results are presented from an experimental system in which preamplifier input impedances are systematically adjusted in order to vary the level of coupling between array elements. Parallel image reconstructions using an array with four different levels of coupling and an acceleration factor up to six show average SNR changes of -7.6% to +7.5%. The modest changes in overall SNR are accompanied by similarly small changes in g-factor. These initial results suggest that moderate amounts of inductive coupling should not have a prohibitive effect on the use of a given coil array for parallel MRI., (Copyright 2004 Wiley-Liss, Inc.)

Published

2004

156. Shortening MR image acquisition time for volumetric interpolated breath-hold examination with a recently developed parallel imaging reconstruction technique: clinical feasibility.

Author

McKenzie CA, Lim D, Ransil BJ, Morrin M, Pedrosa I, Yeh EN, Sodickson DK, and Rofsky NM

Subjects

Adult, Aged, Analysis of Variance, Artifacts, Female, Humans, Liver pathology, Male, Mathematical Computing, Middle Aged, Reproducibility of Results, Time Factors, Image Interpretation, Computer-Assisted methods, Liver Diseases diagnosis, Liver Neoplasms diagnosis, Magnetic Resonance Imaging methods

Abstract

A recently developed parallel magnetic resonance (MR) imaging technique, parallel imaging with an augmented radius in k space, was used to accelerate the volumetric interpolated breath-hold examination (VIBE) performed in 20 patients referred for clinical liver imaging. Nonaccelerated MR images were also acquired in these patients. A five-point scale was used to score the quality of the images. The acceleration resulted in reduced image quality: The nonaccelerated images had a significantly higher (P <.05) mean score--3.8 +/- 0.3 (SD), indicating good quality--than the accelerated images--3.0 +/- 0.3, indicating acceptable quality. However, for three patients who could not hold their breath for the duration necessary for nonaccelerated imaging, less severe breathing artifacts on the accelerated images resulted in improved quality compared with the quality of the nonaccelerated images. Parallel MR imaging-accelerated VIBE may be beneficial for patients who have difficulty sustaining a breath hold for the duration necessary to perform nonaccelerated imaging., (Copyright RSNA, 2003)

Published

2004

157. Lumped-element planar strip array (LPSA) for parallel MRI.

Author

Lee RF, Hardy CJ, Sodickson DK, and Bottomley PA

Subjects

Equipment Design, Humans, Leg anatomy & histology, Mathematics, Models, Theoretical, Phantoms, Imaging, Magnetic Resonance Imaging instrumentation

Abstract

The recently introduced planar strip array (PSA) can significantly reduce scan times in parallel MRI by enabling the utilization of a large number of RF strip detectors that are inherently decoupled, and are tuned by adjusting the strip length to integer multiples of a quarter-wavelength (lambda/4) in the presence of a ground plane and dielectric substrate. In addition, the more explicit spatial information embedded in the phase of the signals from the strip array is advantageous (compared to loop arrays) for limiting aliasing artifacts in parallel MRI. However, losses in the detector as its natural resonance frequency approaches the Larmor frequency (where the wavelength is long at 1.5 T) may limit the signal-to-noise ratio (SNR) of the PSA. Moreover, the PSA's inherent lambda/4 structure severely limits our ability to adjust detector geometry to optimize the performance for a specific organ system, as is done with loop coils. In this study we replaced the dielectric substrate with discrete capacitors, which resulted in both SNR improvement and a tunable lumped-element PSA (LPSA) whose dimensions can be optimized within broad constraints, for a given region of interest (ROI) and MRI frequency. A detailed theoretical analysis of the LPSA is presented, including its equivalent circuit, electromagnetic fields, SNR, and g-factor maps for parallel MRI. Two different decoupling schemes for the LPSA are described. A four-element LPSA prototype was built to test the theory with quantitative measurements on images obtained with parallel and conventional acquisition schemes., (Copyright 2003 Wiley-Liss, Inc.)

Published

2004

158. Ultimate intrinsic signal-to-noise ratio for parallel MRI: electromagnetic field considerations.

Author

Ohliger MA, Grant AK, and Sodickson DK

Subjects

Algorithms, Humans, Liver anatomy & histology, Magnetic Resonance Imaging instrumentation, Signal Processing, Computer-Assisted, Electromagnetic Fields, Image Processing, Computer-Assisted methods, Magnetic Resonance Imaging methods

Abstract

A method is described for establishing an upper bound on the spatial encoding capabilities of coil arrays in parallel MRI. Ultimate intrinsic signal-to-noise ratio (SNR), independent of any particular conductor arrangement, is calculated by expressing arbitrary coil sensitivities in terms of a complete set of basis functions that satisfy Maxwell's equations within the sample and performing parallel imaging reconstructions using these basis functions. The dependence of the ultimate intrinsic SNR on a variety of experimental conditions is explored and a physically intuitive explanation for the observed behavior is provided based on a comparison between the electromagnetic wavelength and the distance between aliasing points. Imaging at high field strength, with correspondingly short wavelength, is shown to offer advantages for parallel imaging beyond those already expected due to the larger available spin polarization. One-dimensional undersampling of k-space yields a steep drop in attainable SNR for more than a 5-fold reduction of scan time, while 2D undersampling permits access to much higher degrees of acceleration. Increased tissue conductivity decreases baseline SNR, but improves parallel imaging performance. A procedure is also provided for generating the optimal coil sensitivity pattern for a given acceleration, which will serve as a useful guide for future coil designs., (Copyright 2003 Wiley-Liss, Inc.)

Published

2003

159. Rapid MR imaging by sensitivity profile indexing and deconvolution reconstruction (SPID).

Author

Azhari H, Sodickson DK, and Edelman RR

Subjects

Brain anatomy & histology, Heart anatomy & histology, Humans, Mathematics, Phantoms, Imaging, Sensitivity and Specificity, Image Processing, Computer-Assisted, Magnetic Resonance Imaging methods

Abstract

A new parallel MR imaging technique, which uses localized information from the elements of a multi-coil array to accelerate imaging, is described. The technique offers an alternative reconstruction approach to currently available techniques (e.g., SMASH and SENSE). Following a partial k-space data acquisition, image reconstruction in this approach proceeds in two steps: first, fitting the measured coil sensitivities to a set of partially localized target functions, a blurred intermediate image of the studied object is produced. Blurring is obtained in a systematic manner, forming images of the studied object convolved with a known convolution kernel. Full spatial resolution is then recovered by deconvolution of the blurred images with the known kernel function. The technique offers flexibility in the arrangement of the acquired signal data k-lines, and a mechanism for controlling reconstruction quality through the convolution the deconvolution procedure. The technique was validated in phantom and in vivo imaging experiments demonstrating high time reduction factors.

Published

2003

160. State of the art in adrenal imaging.

Author

Blake MA, Jhaveri KS, Sweeney AT, Sodickson DK, Arellano RS, Harisinghani MG, Boland GW, and Mueller PR

Subjects

Adrenal Gland Neoplasms pathology, Adrenal Gland Neoplasms secondary, Algorithms, Biopsy, Needle, Humans, Magnetic Resonance Imaging, Models, Structural, Phlebography, Adrenal Gland Neoplasms diagnosis, Tomography, Emission-Computed methods, Tomography, X-Ray Computed methods

Abstract

The purposes of this article were to outline the current state of adrenal imaging, to highlight new developments, and to review the current radiologic advances that provide improved functional and structural information about adrenal disorders.

Published

2002

161. Self-calibrating parallel imaging with automatic coil sensitivity extraction.

Author

McKenzie CA, Yeh EN, Ohliger MA, Price MD, and Sodickson DK

Subjects

Adult, Calibration, Humans, Image Processing, Computer-Assisted, Sensitivity and Specificity, Abdomen anatomy & histology, Heart anatomy & histology, Magnetic Resonance Imaging methods

Abstract

Calibration of the spatial sensitivity functions of coil arrays is a crucial element in parallel magnetic resonance imaging (PMRI). The most common approach has been to measure coil sensitivities directly using one or more low-resolution images acquired before or after accelerated data acquisition. However, since it is difficult to ensure that the patient and coil array will be in exactly the same positions during both calibration scans and accelerated imaging, this approach can introduce sensitivity miscalibration errors into PMRI reconstructions. This work shows that it is possible to extract sensitivity calibration images directly from a fully sampled central region of a variable-density k-space acquisition. These images have all the features of traditional PMRI sensitivity calibrations and therefore may be used for any PMRI reconstruction technique without modification. Because these calibration data are acquired simultaneously with the data to be reconstructed, errors due to sensitivity miscalibration are eliminated. In vivo implementations of self-calibrating parallel imaging using a flexible coil array are demonstrated in abdominal imaging and in real-time cardiac imaging studies., (Copyright 2002 Wiley-Liss, Inc.)

Published

2002

162. Recent advances in image reconstruction, coil sensitivity calibration, and coil array design for SMASH and generalized parallel MRI.

Author

Sodickson DK, McKenzie CA, Ohliger MA, Yeh EN, and Price MD

Subjects

Calibration, Electricity, Equipment Design, Humans, Image Processing, Computer-Assisted trends, Magnetic Resonance Imaging trends, Models, Statistical, Software, Image Processing, Computer-Assisted instrumentation, Image Processing, Computer-Assisted methods, Magnetic Resonance Imaging instrumentation, Magnetic Resonance Imaging methods

Abstract

Parallel magnetic resonance imaging (MRI) techniques use spatial information from arrays of radiofrequency (RF) detector coils to accelerate imaging. A number of parallel MRI techniques have been described in recent years, and numerous clinical applications are currently being explored. The advent of practical parallel imaging presents various challenges for image reconstruction and RF system design. Recent advances in tailored SiMultaneous Acquisition of Spatial Harmonics (SMASH) image reconstructions are summarized. These advances enable robust SMASH imaging in arbitrary image planes with a wide range of coil array geometries. A generalized formalism is described which may be used to understand the relations between SMASH and SENSE, to derive typical implementations of each as special cases, and to form hybrid techniques combining some of the advantages of both. Accurate knowledge of coil sensitivities is crucial for parallel MRI, and errors in calibration represent one of the most common and the most pernicious sources of error in parallel image reconstructions. As one example, motion of the patient and/or the coil array between the sensitivity reference scan and the accelerated acquisition can lead to calibration errors and reconstruction artifacts. Self-calibrating parallel MRI approaches that address this problem by eliminating the need for external sensitivity references are reviewed. The ultimate achievable signal-to-noise ratio (SNR) for parallel MRI studies is closely tied to the geometry and sensitivity patterns of the coil arrays used for spatial encoding. Several parallel imaging array designs that depart from the traditional model of overlapped adjacent loop elements are described.

Published

2002

163. Improved spatial harmonic selection for SMASH image reconstructions.

Author

McKenzie CA, Yeh EN, and Sodickson DK

Subjects

Humans, Image Processing, Computer-Assisted, Mathematics, Phantoms, Imaging, Magnetic Resonance Imaging methods

Abstract

The fitting of coil sensitivity functions to spatial harmonics is central to image reconstructions using the simultaneous acquisition of spatial harmonics (SMASH) technique. It has previously been shown that the selection of the set of spatial harmonics used in a SMASH reconstruction can have a noticeable effect on the quality of the reconstructed image. However, a mechanism for automatic selection of the best set of harmonics in any particular situation has not been provided. In this work, a modification to the SMASH reconstruction procedure is introduced that allows the use of a weighted average of all possible harmonics in a reconstruction. The new reconstruction procedure is shown to allow automatic selection of the spatial harmonics and substantially improve SNR for both phantom and in vivo images., (Copyright 2001 Wiley-Liss, Inc.)

Published

2001

164. Coil-by-coil image reconstruction with SMASH.

Author

McKenzie CA, Ohliger MA, Yeh EN, Price MD, and Sodickson DK

Subjects

Abdomen anatomy & histology, Adult, Equipment Design, Humans, Phantoms, Imaging, Reference Values, Sensitivity and Specificity, Image Enhancement instrumentation, Image Processing, Computer-Assisted instrumentation, Magnetic Resonance Imaging instrumentation

Abstract

The SiMultaneous Acquisition of Spatial Harmonics (SMASH) technique uses linear combinations of undersampled datasets from the component coils of an RF coil array to reconstruct fully sampled composite datasets in reduced imaging times. In previously reported implementations, SMASH reconstructions were designed to reproduce the images that would otherwise be obtained by simple sums of fully gradient encoded component coil images. This strategy has left SMASH images vulnerable to phase cancellation artifacts when the sensitivities of RF coil array elements are not suitably phase-aligned. In fully gradient encoded imaging schemes these artifacts can be eliminated using a variety of methods for combining the individual coil images, including matched filter combinations as well as sum of squares combinations. Until now, these reconstruction schemes have been unavailable to SMASH reconstructions as SMASH produced a final composite image directly from the raw component coil k-space datasets. This article demonstrates a modification to SMASH that allows reconstruction of a full set of accelerated individual component coil images by fitting component coil sensitivity functions to a complete set of spatial harmonics tailored for each coil in the array. Standard component coil combinations applied to the individual reconstructed images produce final composite images free of phase cancellation artifacts., (Copyright 2001 Wiley-Liss, Inc.)

Published

2001

165. A generalized approach to parallel magnetic resonance imaging.

Author

Sodickson DK and McKenzie CA

Subjects

Algorithms, Calibration, Models, Statistical, Models, Theoretical, Phantoms, Imaging, Image Processing, Computer-Assisted, Magnetic Resonance Imaging instrumentation, Magnetic Resonance Imaging methods

Abstract

Parallel magnetic resonance (MR) imaging uses spatial encoding from multiple radiofrequency detector coils to supplement the encoding supplied by magnetic field gradients, and thereby to accelerate MR image acquisitions beyond previous limits. A generalized formulation for parallel MR imaging is derived, demonstrating the relationship between existing techniques such as SMASH and SENSE, and suggesting new algorithms with improved performance. Hybrid approaches combining features of both SMASH-like and SENSE-like image reconstructions are constructed, and numerical conditioning techniques are described which can improve the practical robustness of parallel image reconstructions. Incorporation of numerical conditioning directly into parallel reconstructions using the generalized approach also removes a cumbersome and potentially error-prone sensitivity calibration step involving division of two distinct in vivo reference images. Hybrid approaches in combination with numerical conditioning are shown to extend the range of accelerations over which high-quality parallel images may be obtained.

Published

2001

166. Superiority of prone position in free-breathing 3D coronary MRA in patients with coronary disease.

Author

Stuber M, Danias PG, Botnar RM, Sodickson DK, Kissinger KV, and Manning WJ

Subjects

Adult, Aged, Artifacts, Feasibility Studies, Female, Humans, Male, Middle Aged, Sensitivity and Specificity, Coronary Disease diagnosis, Image Enhancement, Image Processing, Computer-Assisted, Imaging, Three-Dimensional, Magnetic Resonance Angiography, Prone Position

Abstract

Navigator-gated and corrected 3D coronary MR angiography (MRA) allows submillimeter image acquisition during free breathing. However, cranial diaphragmatic drift and relative phase shifts of chest-wall motion are limiting factors for image quality and scanning duration. We hypothesized that image acquisition in the prone position would minimize artifacts related to chest-wall motion and suppress diaphragmatic drift. Twelve patients with radiographically-confirmed coronary artery disease and six healthy adult volunteers were studied in both the prone and the supine position during free-breathing navigator-gated and corrected 3D coronary MRA. Image quality and the diaphragmatic positions were objectively compared. In the prone position, there was a 36% improvement in signal-to-noise ratio (SNR; 15.5 +/- 2.7 vs. 11.4 +/- 2.6; P < 0.01) and a 34% improvement in CNR (12.5 +/- 3.3 vs. 9.3 +/- 2.5, P < 0.01). The prone position also resulted in a 17% improvement in coronary vessel definition (P < 0.01). Cranial end-expiratory diaphragmatic drift occurred less frequently in the prone position (23% +/- 17% vs. 40% +/- 26% supine; P <0.05), and navigator efficiency was higher. Prone coronary MRA results in improved SNR and CNR with enhanced coronary vessel definition. Cranial end-expiratory diaphragmatic drift also was reduced, and navigator efficiency was enhanced. When feasible, prone imaging is recommended for free-breathing coronary MRA.

Published

2001

167. Contrast-enhanced 3D MR angiography with simultaneous acquisition of spatial harmonics: A pilot study.

Author

Sodickson DK, McKenzie CA, Li W, Wolff S, Manning WJ, and Edelman RR

Subjects

Adult, Aorta, Abdominal, Contrast Media, Female, Gadolinium DTPA, Humans, Image Processing, Computer-Assisted, Male, Pilot Projects, Renal Artery, Magnetic Resonance Angiography methods

Abstract

A partially parallel image acquisition technique, simultaneous acquisition of spatial harmonics, or SMASH, was used to increase the spatial and/or temporal resolution in contrast material-enhanced three-dimensional magnetic resonance angiography of the abdominal aorta and renal arteries. In eight healthy subjects, the breath-hold duration was halved at constant spatial resolution, or the spatial resolution was doubled at fixed breath-hold duration, with a 30%-55% reduction in the signal-to-noise ratio but otherwise preserved or improved image quality.

Published

2000

168. Tailored SMASH image reconstructions for robust in vivo parallel MR imaging.

Author

Sodickson DK

Subjects

Humans, Mathematics, Phantoms, Imaging, Heart anatomy & histology, Image Processing, Computer-Assisted, Magnetic Resonance Imaging methods

Abstract

The simultaneous acquisition of spatial harmonics (SMASH) imaging technique uses spatial information from an array of RF coils to substitute for omitted encoding gradient steps and thereby to accelerate MR image acquisition. Since SMASH image reconstructions rely on the accurate generation of sinusoidally varying composite sensitivity functions to emulate the spatial modulations produced by gradients, the technique was originally believed to be limited to certain image planes or coil array configurations which were particularly suited to the generation of spatial harmonics. Several key improvements to the SMASH reconstruction procedure are described, taking advantage of various degrees of freedom in the spatial harmonic fit. The use of tailored fitting procedures, in combination with a numerical conditioning approach based on new observations about noise propagation in the fit, are shown to allow high-quality SMASH image reconstructions in oblique and double-oblique image planes, both in phantoms and in high-resolution cardiac MR images. Magn Reson Med 44:243-251, 2000., (Copyright 2000 Wiley-Liss, Inc.)

Published

2000

169. A multicoil array designed for cardiac SMASH imaging.

Author

Griswold MA, Jakob PM, Edelman RR, and Sodickson DK

Subjects

Biophysical Phenomena, Biophysics, Equipment Design, Humans, Image Processing, Computer-Assisted methods, Image Processing, Computer-Assisted statistics & numerical data, Magnetic Resonance Imaging methods, Magnetic Resonance Imaging statistics & numerical data, Models, Theoretical, Radio Waves, Heart anatomy & histology, Magnetic Resonance Imaging instrumentation

Abstract

Recently, several partially parallel acquisition (PPA) techniques have been presented which use spatial information inherent in an RF coil array to reconstruct an image from a reduced set of phase encoding steps. PPAs represent a change in paradigm for the RF coil designer since the focus for arrays to be used with PPAs is to optimize the spatial encoding that is provided by the array. One of the first practical implementations of PPA imaging was demonstrated using the SMASH technique. In this study, we present our results from the construction of the first array designed specifically for cardiac SMASH imaging. Additional design criteria are presented for SMASH arrays that are not considered in conventional array design. Using these design criteria, a four-element array was constructed and then tested in SMASH imaging experiments in the heart. This array has been used in all of our initial cardiac and head SMASH studies with good results.

Published

2000

170. SMASH imaging with an eight element multiplexed RF coil array.

Author

Bankson JA, Griswold MA, Wright SM, and Sodickson DK

Subjects

Biophysical Phenomena, Biophysics, Equipment Design, Humans, Image Processing, Computer-Assisted methods, Image Processing, Computer-Assisted standards, Image Processing, Computer-Assisted statistics & numerical data, Magnetic Resonance Imaging methods, Magnetic Resonance Imaging statistics & numerical data, Quality Control, Radio Waves, Magnetic Resonance Imaging instrumentation

Abstract

SMASH (SiMultaneous Acquisition of Spatial Harmonics) is a technique which can be used to acquire multiple lines of k-space in parallel, by using spatial information from a radiofrequency coil array to perform some of the encoding normally produced by gradients. Using SMASH, imaging speed can be increased up to a maximum acceleration factor equal to the number of coil array elements. This work is a feasibility study which examines the use of SMASH with specialized coil array and data reception hardware to achieve previously unattainable accelerations. An eight element linear SMASH array was designed to operate in conjunction with a time domain multiplexing system to examine the effectiveness of SMASH imaging with as much as eightfold acceleration factors. Time domain multiplexing allowed the multiple independent array elements to be sampled through a standard single-channel receiver. SMASH-reconstructed images using this system were compared with reference images, and signal to noise ratio and reconstruction artifact power were measured as a function of acceleration factor. Results of the imaging experiments showed an almost constant SNR for SMASH acceleration factors of up to eight. Artifact power remained low within this range of acceleration factors. This study demonstrates that efficient SMASH imaging at high acceleration factors is feasible using appropriate hardware, and that time domain multiplexing is a convenient strategy to provide the multiple channels required for rapid imaging with large arrays.

Published

2000

171. Double-oblique free-breathing high resolution three-dimensional coronary magnetic resonance angiography.

Author

Stuber M, Botnar RM, Danias PG, Sodickson DK, Kissinger KV, Van Cauteren M, De Becker J, and Manning WJ

Subjects

Adult, Aged, Coronary Angiography, Coronary Disease diagnosis, Coronary Disease diagnostic imaging, Coronary Vessels pathology, Female, Humans, Male, Coronary Vessels anatomy & histology, Image Processing, Computer-Assisted, Magnetic Resonance Angiography methods

Abstract

Objectives: The goal of the present study was to develop a strategy for three-dimensional (3D) volume acquisition along the major axes of the coronary arteries., Background: For high-resolution 3D free-breathing coronary magnetic resonance angiography (MRA), coverage of the coronary artery tree may be limited due to excessive measurement times associated with large volume acquisitions. Planning the 3D volume along the major axis of the coronary vessels may help to overcome such limitations., Methods: Fifteen healthy adult volunteers and seven patients with X-ray angiographically confirmed coronary artery disease underwent free-breathing navigator-gated and corrected 3D coronary MRA. For an accurate volume targeting of the high resolution scans, a three-point planscan software tool was applied., Results: The average length of contiguously visualized left main and left anterior descending coronary artery was 81.8 +/- 13.9 mm in the healthy volunteers and 76.2 +/- 16.5 mm in the patients (p = NS). For the right coronary artery, a total length of 111.7 +/- 27.7 mm was found in the healthy volunteers and 79.3 +/- 4.6 mm in the patients (p = NS). Comparing coronary MRA and X-ray angiography, a good agreement of anatomy and pathology was found in the patients., Conclusions: Double-oblique submillimeter free-breathing coronary MRA allows depiction of extensive parts of the native coronary arteries. The results obtained in patients suggest that the method has the potential to be applied in broader prospective multicenter studies where coronary MRA is compared with X-ray angiography.

Published

1999

172. Resolution enhancement in single-shot imaging using simultaneous acquisition of spatial harmonics (SMASH).

Author

Griswold MA, Jakob PM, Chen Q, Goldfarb JW, Manning WJ, Edelman RR, and Sodickson DK

Subjects

Computer Simulation, Echo-Planar Imaging methods, Humans, Image Processing, Computer-Assisted methods, Phantoms, Imaging, Magnetic Resonance Imaging methods

Abstract

Spatial resolution in single-shot imaging is limited by signal attenuation due to relaxation of transverse magnetization. This effect can be reduced by minimizing acquisition times through the use of short interecho spacings. However, the minimum interecho spacing is constrained by limits on gradient switching rates, radiofrequency (RF) power deposition and RF pulse length. Recently, simultaneous acquisition of spatial harmonics (SMASH) has been introduced as a method to acquire magnetic resonance images at increased speeds using a reduced number of phase-encoding gradient steps by extracting spatial information contained in an RF coil array. In this study, it is shown that SMASH can be used to reduce the effects of relaxation, resulting in single-shot images with increased spatial resolution without increasing imaging time. After a brief theoretical discussion, two strategies to reduce signal attenuation and increase spatial resolution in single-shot imaging are introduced and their performance is evaluated in phantom studies. In vivo single-shot echoplanar imaging (EPI), BURST, and half-Fourier single-shot turbo spin-echo (HASTE) images are then presented demonstrating the practical implementation of these resolution enhancement strategies. Images acquired with SMASH show increased spatial resolution and improved image quality when compared with images obtained with the conventional acquisitions. The general principles presented for imaging with SMASH can also be applied to other partially parallel imaging techniques.

Published

1999

173. Signal-to-noise ratio and signal-to-noise efficiency in SMASH imaging.

Author

Sodickson DK, Griswold MA, Jakob PM, Edelman RR, and Manning WJ

Subjects

Abdomen anatomy & histology, Adult, Algorithms, Brain anatomy & histology, Computer Simulation, Forecasting, Fourier Analysis, Heart anatomy & histology, Humans, Image Enhancement methods, Image Processing, Computer-Assisted instrumentation, Magnetic Resonance Imaging instrumentation, Models, Theoretical, Oscillometry, Phantoms, Imaging, Signal Processing, Computer-Assisted, Thorax anatomy & histology, Time Factors, Artifacts, Image Processing, Computer-Assisted methods, Magnetic Resonance Imaging methods

Abstract

A general theory of signal-to-noise ratio (SNR) in simultaneous acquisition of spatial harmonics (SMASH) imaging is presented, and the predictions of the theory are verified in imaging experiments and in numerical simulations. In a SMASH image, multiple lines of k-space are generated simultaneously through combinations of magnetic resonance signals in a radiofrequency coil array. Here, effects of noise correlations between array elements as well as new correlations introduced by the SMASH reconstruction procedure are assessed. SNR and SNR efficiency in SMASH images are compared with results using traditional array combination strategies. Under optimized conditions, SMASH achieves the same average SNR efficiency as ideal pixel-by-pixel array combinations, while allowing imaging to proceed at otherwise unattainable speeds. The k-space nature of SMASH reconstructions can lead to oscillatory spatial variations in noise standard deviation, which can produce local enhancements of SNR in particular regions.

Published

1999

174. SMASH imaging.

Author

Sodickson DK, Griswold MA, and Jakob PM

Subjects

Humans, Magnetic Resonance Imaging methods

Abstract

SMASH imaging is a new MR imaging technique that can be used to multiply the speed of existing imaging sequences. It operates by using an array of radiofrequency (RF) detection coils to perform some of the spatial encoding normally accomplished with magnetic field gradients. The speed of the SMASH technique results from appropriate combinations of coil array RF signals in which multiple lines of image data are gathered simultaneously, rather than one after another. SMASH can be used in conjunction with most rapid imaging sequences, including EPI, resulting in multiplicative gains in imaging speed. This article reviews the basic principles of SMASH imaging, outlines requirements for practical implementation, and presents a variety of in vivo results, highlighting ways in which SMASH may be used to increase imaging speed and to improve image quality for clinical MR imaging applications.

Published

1999

175. Accelerated cardiac imaging using the SMASH technique.

Author

Jakob PM, Griswold MA, Edelman RR, Manning WJ, and Sodickson DK

Subjects

Feasibility Studies, Humans, Heart anatomy & histology, Image Processing, Computer-Assisted methods, Magnetic Resonance Imaging methods

Abstract

SMASH (SiMultaneous Acquisition of Spatial Harmonics) was recently introduced as a novel rapid-imaging technique. The SMASH technique uses a partially parallel acquisition strategy, using spatial information from a radiofrequency coil array to accelerate imaging. This study constitutes the first application of SMASH to cardiac magnetic resonance imaging. The increased imaging speed provided by SMASH was used to obtain images with reduced breathhold duration, enhanced spatial resolution, and increased temporal resolution in healthy volunteers. The results obtained demonstrate the feasibility and potential clinical utility of cardiac magnetic resonance imaging using the SMASH technique.

Published

1999

176. AUTO-SMASH: a self-calibrating technique for SMASH imaging. SiMultaneous Acquisition of Spatial Harmonics.

Author

Jakob PM, Griswold MA, Edelman RR, and Sodickson DK

Subjects

Adult, Calibration, Female, Heart anatomy & histology, Heart physiology, Humans, Male, Middle Aged, Image Processing, Computer-Assisted methods, Magnetic Resonance Imaging methods

Abstract

Recently a new fast magnetic resonance imaging strategy, SMASH, has been described, which is based on partially parallel imaging with radiofrequency coil arrays. In this paper, an internal sensitivity calibration technique for the SMASH imaging method using self-calibration signals is described. Coil sensitivity information required for SMASH imaging is obtained during the actual scan using correlations between undersampled SMASH signal data and additionally sampled calibration signals with appropriate offsets in k-space. The advantages of this sensitivity reference method are that no extra coil array sensitivity maps have to be acquired and that it provides coil sensitivity information in areas of highly non-uniform spin-density. This auto-calibrating approach can be easily implemented with only a small sacrifice of the overall time savings afforded by SMASH imaging. The results obtained from phantom imaging experiments and from cardiac studies in nine volunteers indicate that the self-calibrating approach is an effective method to increase the potential and the flexibility of rapid imaging with SMASH.

Published

1998

177. Simultaneous acquisition of spatial harmonics (SMASH): fast imaging with radiofrequency coil arrays.

Author

Sodickson DK and Manning WJ

Subjects

Abdomen anatomy & histology, Adult, Artifacts, Brain anatomy & histology, Fourier Analysis, Humans, Image Processing, Computer-Assisted methods, Magnetic Resonance Imaging methods, Magnetics, Male, Phantoms, Imaging, Radio Waves, Sensitivity and Specificity, Thorax anatomy & histology, Image Enhancement methods, Magnetic Resonance Imaging instrumentation

Abstract

SiMultaneous Acquisition of Spatial Harmonics (SMASH) is a new fast-imaging technique that increases MR image acquisition speed by an integer factor over existing fast-imaging methods, without significant sacrifices in spatial resolution or signal-to-noise ratio. Image acquisition time is reduced by exploiting spatial information inherent in the geometry of a surface coil array to substitute for some of the phase encoding usually produced by magnetic field gradients. This allows for partially parallel image acquisitions using many of the existing fast-imaging sequences. Unlike the data combination algorithms of prior proposals for parallel imaging, SMASH reconstruction involves a small set of MR signal combinations prior to Fourier transformation, which can be advantageous for artifact handling and practical implementation. A twofold savings in image acquisition time is demonstrated here using commercial phased array coils on two different MR-imaging systems. Larger time savings factors can be expected for appropriate coil designs.

Published

1997

178. Spin diffusion on a lattice: Classical simulations and spin coherent states.

Author

Sodickson DK and Waugh JS

Published

1995