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3. Simulation‐based optimization and experimental comparison of intracranial T2‐weighted DANTE‐SPACE vessel wall imaging at 3T and 7T.

Author

de Buck, Matthijs H. S., Hess, Aaron T., and Jezzard, Peter

Subjects
MAGNETIC resonance imaging, VOLUNTEERS, PERFECTION, VOLUNTEER service, ANGLES
Abstract

Purpose: T2‐weighted DANTE‐SPACE (Delay Alternating with Nutation for Tailored Excitation — Sampling Perfection with Application optimized Contrasts using different flip angle Evolution) sequences facilitate non‐invasive intracranial vessel wall imaging at 7T through simultaneous suppression of blood and CSF. However, the achieved vessel wall delineation depends closely on the selected sequence parameters, and little information is available about the performance of the sequence using more widely available 3T MRI. Therefore, in this paper a comprehensive DANTE‐SPACE simulation framework is used for the optimization and quantitative comparison of T2‐weighted DANTE‐SPACE at both 7T and 3T. Methods: Simulations are used to propose optimized sequence parameters at both 3T and 7T. At 7T, an additional protocol which uses a parallel transmission (pTx) shim during the DANTE preparation for improved suppression of inflowing blood is also proposed. Data at both field strengths using optimized and literature protocols are acquired and quantitatively compared in six healthy volunteers. Results: At 7T, more vessel wall signal can be retained while still achieving sufficient CSF suppression by using fewer DANTE pulses than described in previous implementations. The use of a pTx shim during DANTE at 7T provides a modest further improvement to the inner vessel wall delineation. At 3T, aggressive DANTE preparation is required to achieve CSF suppression, resulting in reduced vessel wall signal. As a result, the achievable vessel wall definition at 3T is around half that of 7T. Conclusion: Simulation‐based optimization of DANTE parameters facilitates improved T2‐weighted DANTE‐SPACE contrasts at 7T. The improved vessel definition of T2‐weighted DANTE‐SPACE at 7T makes DANTE preparation more suitable for T2‐weighted VWI at 7T than at 3T. [ABSTRACT FROM AUTHOR]

Published
2024
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4. Accelerated 3D multi‐channel B1+ mapping at 7 T for the brain and heart.

Author

Kent, James L., de Buck, Matthijs H. S., Dragonu, Iulius, Chiew, Mark, Valkovič, Ladislav, and Hess, Aaron T.

Subjects
BODY image, BRAIN mapping, SAMPLING errors, MAPS, MAGNETIC resonance imaging
Abstract

Purpose: To acquire accurate volumetric multi‐channel B1+$$ {\mathrm{B}}_1^{+} $$ maps in under 14 s whole‐brain or 23 heartbeats whole‐heart for parallel transmit (pTx) applications at 7 T. Theory and Methods: We evaluate the combination of three recently proposed techniques. The acquisition of multi‐channel transmit array B1+$$ {\mathrm{B}}_1^{+} $$ maps is accelerated using transmit low rank (TxLR) with absolute B1+$$ {\mathrm{B}}_1^{+} $$ mapping (Sandwich) acquired in a B1+$$ {\mathrm{B}}_1^{+} $$ time‐interleaved acquisition of modes (B1TIAMO) fashion. Simulations using synthetic body images derived from Sim4Life were used to test the achievable acceleration for small scan matrices of 24 × 24. Next, we evaluated the method by retrospectively undersampling a fully sampled B1+$$ {\mathrm{B}}_1^{+} $$ library of nine subjects in the brain. Finally, Cartesian undersampled phantom and in vivo images were acquired in both the brain of three subjects (8Tx/32 receive [Rx]) and the heart of another three subjects (8Tx/8Rx) at 7 T. Results: Simulation and in vivo results show that volumetric multi‐channel B1+$$ {\mathrm{B}}_1^{+} $$ maps can be acquired using acceleration factors of 4 in the body, reducing the acquisition time to within 23 heartbeats, which was previously not possible. In silico heart simulations demonstrated a RMS error to the fully sampled native resolution ground truth of 4.2° when combined in first‐order circularly polarized mode (mean flip angle 66°) at an acceleration factor of 4. The 14 s 3D B1+$$ {\mathrm{B}}_1^{+} $$ maps acquired in the brain have a RMS error of 1.9° to the fully sampled (mean flip angle 86°). Conclusion: The proposed method is demonstrated as a fast pTx calibration technique in the brain and a promising method for pTx calibration in the body. [ABSTRACT FROM AUTHOR]

Published
2024
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5. An extended phase graph‐based framework for DANTE‐SPACE simulations including physiological, temporal, and spatial variations.

Author

de Buck, Matthijs H. S., Jezzard, Peter, and Hess, Aaron T.

Subjects
SPATIAL variation, PULSATILE flow, FLOW velocity, BLOOD flow, VELOCITY
Abstract

Purpose: The delay alternating with nutation for tailored excitation (DANTE)–sampling perfection with application‐optimized contrasts (SPACE) sequence facilitates 3D intracranial vessel wall imaging with simultaneous suppression of blood and CSF. However, the achieved image contrast depends closely on the selected sequence parameters, and the clinical use of the sequence is limited in vivo by observed signal variations in the vessel wall, CSF, and blood. This paper introduces a comprehensive DANTE‐SPACE simulation framework, with the aim of providing a better understanding of the underlying contrast mechanisms and facilitating improved parameter selection and contrast optimization. Methods: An extended phase graph formalism was developed for efficient spin ensemble simulation of the DANTE‐SPACE sequence. Physiological processes such as pulsatile flow velocity variation, varying flow directions, intravoxel velocity variation, diffusion, and B1+$$ {\mathrm{B}}_1^{+} $$ effects were included in the framework to represent the mechanisms behind the achieved signal levels accurately. Results: Intravoxel velocity variation improved temporal stability and robustness against small velocity changes. Time‐varying pulsatile velocity variation affected CSF simulations, introducing periods of near‐zero velocity and partial rephasing. Inclusion of diffusion effects was found to substantially reduce the CSF signal. Blood flow trajectory variations had minor effects, but B1+$$ {\mathrm{B}}_1^{+} $$ differences along the trajectory reduced DANTE efficiency in low‐B1+$$ {\mathrm{B}}_1^{+} $$ areas. Introducing low‐velocity pulsatility of both CSF and vessel wall helped explain the in vivo observed signal heterogeneity in both tissue types. Conclusion: The presented simulation framework facilitates a more comprehensive optimization of DANTE‐SPACE sequence parameters. Furthermore, the simulation framework helps to explain observed contrasts in acquired data. [ABSTRACT FROM AUTHOR]

Published
2024
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8. Head‐and‐neck multichannel B1+ mapping and RF shimming of the carotid arteries using a 7T parallel‐transmit head coil.

Author

de Buck, Matthijs H. S., Kent, James L., Jezzard, Peter, and Hess, Aaron T.

Subjects
CAROTID artery, HEAD, DATA mapping, NECK
Abstract

Purpose: Neurovascular MRI suffers from a rapid drop in B1+ into the neck when using transmit head coils at 7 T. One solution to improving B1+ magnitude in the major feeding arteries in the neck is to use custom RF shims on parallel‐transmit head coils. However, calculating such shims requires robust multichannel B1+ maps in both the head and the neck, which is challenging due to low RF penetration into the neck, limited dynamic range of multichannel B1+ mapping techniques, and B0 sensitivity. We therefore sought a robust, large‐dynamic‐range, parallel‐transmit field mapping protocol and tested whether RF shimming can improve carotid artery B1+ magnitude in practice. Methods: A pipeline is presented that combines B1+ mapping data acquired using circularly polarized (CP) and CP2‐mode RF shims at multiple voltages. The pipeline was evaluated by comparing the predicted and measured B1+ for multiple random transmit shims, and by assessing the ability of RF shimming to increase B1+ in the carotid arteries. Results: The proposed method achieved good agreement between predicted and measured B1+ in both the head and the neck. The B1+ magnitude in the carotid arteries can be increased by 43% using tailored RF shims or by 37% using universal RF shims, while also improving the RF homogeneity compared with CP mode. Conclusion: B1+ in the neck can be increased using RF shims calculated from multichannel B1+ maps in both the head and the neck. This can be achieved using universal phase‐only RF shims, facilitating easy implementation in existing sequences. [ABSTRACT FROM AUTHOR]

Published
2024
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10. Head-and-neck multi-channel B1+ mapping and carotid arteries RF shimming using a parallel transmit head coil

Author

de Buck, Matthijs H. S., Jezzard, Peter, and Hess, Aaron T.

Subjects
FOS: Physical sciences, Medical Physics (physics.med-ph), Physics - Medical Physics
Abstract

Purpose: Neurovascular MRI suffers from a rapid drop in B1+ into the neck when using transmit head coils at 7T. One solution to improving B1+ magnitude in the major feeding arteries in the neck is to use custom RF shims on parallel transmit (pTx) head coils. However, calculating such shims requires robust multi-channel B1+ maps in both the head and the neck, which is challenging due to low RF penetration into the neck, limited dynamic range of multi-channel B1+ mapping techniques, and B0 sensitivity. We therefore sought a robust large-dynamic-range pTx field mapping protocol, and tested whether RF shimming can improve carotid artery B1+ in practice. Methods: A pipeline is presented that combines B1+ mapping data acquired using circularly polarized (CP-) and CP2-mode RF shims at multiple voltages. The pipeline was evaluated by comparing the predicted and measured B1+ for multiple random transmit shims, and by assessing the ability of RF shimming to increase the B1+ in the carotid arteries. Results: The proposed method achieved good agreement between predicted and measured B1+ in both the head and the neck. The B1+ magnitude in the carotid arteries can be increased by 42% using tailored RF shims or by 37% using universal RF shims, while also improving the RF homogeneity compared to CP mode. Conclusion: B1+ in the neck can be increased using RF shims calculated from multi-channel B1+ maps in both the head and the neck. This can be achieved using universal phase-only RF shims, facilitating easy implementation in existing sequences., 19 pages (8 pages main text) & 10 figures. To be submitted for review

Published
2022

13. Rapid 3D absolute B1+ mapping using a sandwiched train presaturated TurboFLASH sequence at 7 T for the brain and heart.

Author

Kent, James L., Dragonu, Iulius, Valkovič, Ladislav, and Hess, Aaron T.

Subjects
MONTE Carlo method
Abstract

Purpose: To shorten the acquisition time of magnetization‐prepared absolute transmit field (B1+) mapping known as presaturation TurboFLASH, or satTFL, to enable single breath‐hold whole‐heart 3D B1+ mapping. Methods: SatTFL is modified to remove the delay between the reference and prepared images (typically 5 T1), with matching transmit configurations for excitation and preparation RF pulses. The new method, called Sandwich, is evaluated as a 3D sequence, measuring whole‐brain and gated whole‐heart B1+ maps in a single breath‐hold. We evaluate the sensitivity to B1+ and T1 using numerical Bloch, extended phase graph, and Monte Carlo simulations. Phantom and in vivo images were acquired in both the brain and heart using an 8‐channel transmit 7 Tesla MRI system to support the simulations. A segmented satTFL with a short readout train was used as a reference. Results: The method significantly reduces acquisition times of 3D measurements from 360 s to 20 s, in the brain, while simultaneously reducing bias in the measured B1+ due to T1 and magnetization history. The mean coefficient of variation was reduced by 81% for T1s of 0.5–3 s compared to conventional satTFL. In vivo, the reproducibility coefficient for flip angles in the range 0–130° was 4.5° for satTFL and 4.7° for our scheme, significantly smaller than for a short TR satTFL sequence, which was 12°. The 3D sequence measured B1+ maps of the whole thorax in 26 heartbeats. Conclusion: Our adaptations enable faster B1+ mapping, with minimal T1 sensitivity and lower sensitivity to magnetization history, enabling single breath‐hold whole‐heart absolute B1+ mapping. [ABSTRACT FROM AUTHOR]

Published
2023
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14. External Hardware and Sensors, for Improved MRI.

Author

Madore, Bruno, Hess, Aaron T., van Niekerk, Adam M. J., Hoinkiss, Daniel C., Hucker, Patrick, Zaitsev, Maxim, Afacan, Onur, and Günther, Matthias

Subjects
MAGNETIC resonance imaging, DETECTORS, VENTILATION monitoring, PATIENT monitoring, MACHINE learning
Abstract

Complex engineered systems are often equipped with suites of sensors and ancillary devices that monitor their performance and maintenance needs. MRI scanners are no different in this regard. Some of the ancillary devices available to support MRI equipment, the ones of particular interest here, have the distinction of actually participating in the image acquisition process itself. Most commonly, such devices are used to monitor physiological motion or variations in the scanner's imaging fields, allowing the imaging and/or reconstruction process to adapt as imaging conditions change. "Classic" examples include electrocardiography (ECG) leads and respiratory bellows to monitor cardiac and respiratory motion, which have been standard equipment in scan rooms since the early days of MRI. Since then, many additional sensors and devices have been proposed to support MRI acquisitions. The main physical properties that they measure may be primarily "mechanical" (eg acceleration, speed, and torque), "acoustic" (sound and ultrasound), "optical" (light and infrared), or "electromagnetic" in nature. A review of these ancillary devices, as currently available in clinical and research settings, is presented here. In our opinion, these devices are not in competition with each other: as long as they provide useful and unique information, do not interfere with each other and are not prohibitively cumbersome to use, they might find their proper place in future suites of sensors. In time, MRI acquisitions will likely include a plurality of complementary signals. A little like the microbiome that provides genetic diversity to organisms, these devices can provide signal diversity to MRI acquisitions and enrich measurements. Machine‐learning (ML) algorithms are well suited at combining diverse input signals toward coherent outputs, and they could make use of all such information toward improved MRI capabilities. Evidence Level: 2 Technical Efficacy: Stage 1 [ABSTRACT FROM AUTHOR]

Published
2023
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20. Optimization of undersampling parameters for 3D intracranial compressed sensing MR angiography at 7 T.

Author

de Buck, Matthijs H. S., Jezzard, Peter, and Hess, Aaron T.

Subjects
COMPRESSED sensing, ANGIOGRAPHY, TORTUOSITY
Abstract

Purpose: 3D time‐of‐flight MRA can accurately visualize the intracranial vasculature but is limited by long acquisition times. Compressed sensing reconstruction can be used to substantially accelerate acquisitions. The quality of those reconstructions depends on the undersampling patterns used. In this work, we optimize sets of undersampling parameters for various acceleration factors of Cartesian 3D time‐of‐flight MRA. Methods: Fully sampled datasets, acquired at 7 Tesla, were retrospectively undersampled using variable‐density Poisson disk sampling with various autocalibration region sizes, polynomial orders, and acceleration factors. The accuracy of reconstructions from the different undersampled datasets was assessed using the vessel‐masked structural similarity index. Identified optimal undersampling parameters were then evaluated in additional prospectively undersampled datasets. Compressed sensing reconstruction parameters were chosen based on a preliminary reconstruction parameter optimization. Results: For all acceleration factors, using a fully sampled calibration area of 12 × 12 k‐space lines and a polynomial order of 2 resulted in the highest image quality. The importance of parameter optimization of the sampling was found to increase for higher acceleration factors. The results were consistent across resolutions and regions of interest with vessels of varying sizes and tortuosity. The number of visible small vessels increased by 7.0% and 14.2% when compared to standard parameters for acceleration factors of 7.2 and 15, respectively. Conclusion: The image quality of compressed sensing time‐of‐flight MRA can be improved by appropriate choice of undersampling parameters. The optimized sets of parameters are independent of the acceleration factor and enable a larger number of vessels to be visualized. [ABSTRACT FROM AUTHOR]

Published
2022
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32. impact of atrial fibrillation and stroke risk factors on left atrial blood flow characteristics.

Author

Spartera, Marco, Stracquadanio, Antonio, Pessoa-Amorim, Guilherme, Ende, Adam Von, Fletcher, Alison, Manley, Peter, Ferreira, Vanessa M, Hess, Aaron T, Hopewell, Jemma C, Neubauer, Stefan, Wijesurendra, Rohan S, and Casadei, Barbara

Subjects
STROKE risk factors, ATRIAL fibrillation, MAGNETIC resonance imaging, BLOOD circulation, DESCRIPTIVE statistics, ELECTROCARDIOGRAPHY, RESEARCH funding, ELECTRIC countershock
Abstract

Aims  Altered left atrial (LA) blood flow characteristics account for an increase in cardioembolic stroke risk in atrial fibrillation (AF). Here, we aimed to assess whether exposure to stroke risk factors is sufficient to alter LA blood flow even in the presence of sinus rhythm (SR). Methods and results  We investigated 95 individuals: 37 patients with persistent AF, who were studied before and after cardioversion [Group 1; median CHA2DS2-VASc = 2.0 (1.5–3.5)]; 35 individuals with no history of AF but similar stroke risk to Group 1 [Group 2; median CHA2DS2-VASc = 3.0 (2.0–4.0)]; and 23 low-risk individuals in SR [Group 3; median CHA2DS2-VASc = 0.0 (0.0–0.0)]. Cardiac function and LA flow characteristics were evaluated using cardiac magnetic resonance. Before cardioversion, Group 1 displayed impaired left ventricular (LV) and LA function, reduced LA flow velocities and vorticity, and a higher normalized vortex volume (all P  < 0.001 vs. Groups 2 and 3). After restoration of SR at ≥4-week post-cardioversion, LV systolic function and LA flow parameters improved significantly (all P  < 0.001 vs. pre-cardioversion) and were no longer different from those in Group 2. However, in the presence of SR, LA flow peak and mean velocity, and vorticity were lower in Groups 1 and 2 vs. Group 3 (all P  < 0.01), and were associated with impaired LA emptying fraction (LAEF) and LV diastolic dysfunction. Conclusion  Patients at moderate-to-high stroke risk display altered LA flow characteristics in SR in association with an LA myopathic phenotype and LV diastolic dysfunction, regardless of a history of AF. [ABSTRACT FROM AUTHOR]

Published
2022
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33. Accelerated calibrationless parallel transmit mapping using joint transmit and receive low‐rank tensor completion.

Author

Hess, Aaron T., Dragonu, Iulius, and Chiew, Mark

Subjects
BRAIN mapping, PARALLEL algorithms, ALGORITHMS, CARDIAC magnetic resonance imaging
Abstract

Purpose: To evaluate an algorithm for calibrationless parallel imaging to reconstruct undersampled parallel transmit field maps for the body and brain. Methods: Using a combination of synthetic data and in vivo measurements from brain and body, 3 different approaches to a joint transmit and receive low‐rank tensor completion algorithm are evaluated. These methods included: 1) virtual coils using the product of receive and transmit sensitivities, 2) joint‐receiver coils that enforces a low rank structure across receive coils of all transmit modes, and 3) transmit low rank that uses a low rank structure for both receive and transmit modes simultaneously. The performance of each is investigated for different noise levels and different acceleration rates on an 8‐channel parallel transmit 7 Tesla system. Results: The virtual coils method broke down with increasing noise levels or acceleration rates greater than 2, producing normalized RMS error greater than 0.1. The joint receiver coils method worked well up to acceleration factors of 4, beyond which the normalized RMS error exceeded 0.1. Transmit low rank enabled an eightfold acceleration, with most normalized RMS errors remaining below 0.1. Conclusion: This work demonstrates that undersampling factors of up to eightfold are feasible for transmit array mapping and can be reconstructed using calibrationless parallel imaging methods. [ABSTRACT FROM AUTHOR]

Published
2021
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34. Motion correction methods for MRS: experts' consensus recommendations.

Author

Andronesi, Ovidiu C., Bhattacharyya, Pallab K., Bogner, Wolfgang, Choi, In‐Young, Hess, Aaron T., Lee, Phil, Meintjes, Ernesta M., Tisdall, M. Dylan, Zaitzev, Maxim, and Kouwe, André

Subjects
GABA, CHILD patients, GLUTATHIONE, SIGNAL-to-noise ratio
Abstract

Long acquisition times due to intrinsically low signal‐to‐noise ratio and the need for highly homogeneous B0 field make MRS particularly susceptible to motion or scanner instability compared with MRI. Motion‐induced changes in both localization and shimming (ie B0 homogeneity) degrade MRS data quality. To mitigate the effects of motion three approaches can be employed: (1) subject immobilization, (2) retrospective correction, and (3) prospective real‐time correction using internal and/or external tracking methods. Prospective real‐time correction methods can simultaneously update localization and the B0 field to improve MRS data quality. While localization errors can be corrected with both internal (navigators) and external (optical camera, NMR probes) tracking methods, the B0 field correction requires internal navigator methods to measure the B0 field inside the imaged volume and the possibility to update the scanner shim hardware in real time. Internal and external tracking can rapidly update the MRS localization with submillimeter and subdegree precision, while scanner frequency and first‐order shims of scanner hardware can be updated by internal methods every sequence repetition. These approaches are most well developed for neuroimaging, for which rigid transformation is primarily applicable. Real‐time correction greatly improves the stability of MRS acquisition and quantification, as shown in clinical studies on subjects prone to motion, including children and patients with movement disorders, enabling robust measurement of metabolite signals including those with low concentrations, such as gamma‐aminobutyric acid and glutathione. Thus, motion correction is recommended for MRS users and calls for tighter integration and wider availability of such methods by MR scanner manufacturers. [ABSTRACT FROM AUTHOR]

Published
2021
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35. An investigation into the minimum number of tissue groups required for 7T in‐silico parallel transmit electromagnetic safety simulations in the human head.

Author

Buck, Matthijs H. S., Jezzard, Peter, Jeong, Hongbae, and Hess, Aaron T.

Subjects
GRAY matter (Nerve tissue), COMPACT bone, COMPUTATIONAL electromagnetics, TISSUES
Abstract

Purpose: Safety limits for the permitted specific absorption rate (SAR) place restrictions on pulse sequence design, especially at ultrahigh fields (≥ 7 tesla). Due to intersubject variability, the SAR is usually conservatively estimated based on standard human models that include an applied safety margin to ensure safe operation. One approach to reducing the restrictions is to create more accurate subject‐specific models from their segmented MR images. This study uses electromagnetic simulations to investigate the minimum number of tissue groups required to accurately determine SAR in the human head. Methods: Tissue types from a fully characterized electromagnetic human model with 47 tissue types in the head and neck region were grouped into different tissue clusters based on the conductivities, permittivities, and mass densities of the tissues. Electromagnetic simulations of the head model inside a parallel transmit head coil at 7 tesla were used to determine the minimum number of required tissue clusters to accurately determine the subject‐specific SAR. The identified tissue clusters were then evaluated using 2 additional well‐characterized electromagnetic human models. Results: A minimum of 4‐clusters‐plus‐air was found to be required for accurate SAR estimation. These tissue clusters are centered around gray matter, fat, cortical bone, and cerebrospinal fluid. For all 3 simulated models, the parallel transmit maximum 10g SAR was consistently determined to within an error of <12% relative to the full 47‐tissue model. Conclusion: A minimum of 4‐clusters‐plus‐air are required to produce accurate personalized SAR simulations of the human head when using parallel transmit at 7 tesla. [ABSTRACT FROM AUTHOR]

Published
2021
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36. Combined fMRI-MRS acquires simultaneous glutamate and BOLD-fMRI signals in the human brain

Author

Betina Ip, I., Berrington, Adam, Hess, Aaron T., Parker, Andrew J., Emir, Uzay E., and Bridge, Holly

Subjects
Adult, Male, Brain Mapping, Magnetic Resonance Spectroscopy, genetic structures, Hemodynamics, Brain, Glutamic Acid, Neurochemistry, Magnetic Resonance Imaging, behavioral disciplines and activities, Article, Functional Spectroscopy, nervous system, Humans, Female, BOLD fMRI, Visual cortex, Glutamate, psychological phenomena and processes
Abstract

Combined fMRI-MRS is a novel method to non-invasively investigate functional activation in the human brain using simultaneous acquisition of hemodynamic and neurochemical measures. The aim of the current study was to quantify neural activity using combined fMRI-MRS at 7 T. BOLD-fMRI and semi-LASER localization MRS data were acquired from the visual cortex of 13 participants during short blocks (64 s) of flickering checkerboards. We demonstrate a correlation between glutamate and BOLD-fMRI time courses (R=0.381, p=0.031). In addition, we show increases in BOLD-fMRI (1.43±0.17%) and glutamate concentrations (0.15±0.05 I.U., ~2%) during visual stimulation. In contrast, we observed no change in glutamate concentrations in resting state MRS data during sham stimulation periods. Spectral line width changes generated by the BOLD-response were corrected using line broadening. In summary, our results establish the feasibility of concurrent measurements of BOLD-fMRI and neurochemicals using a novel combined fMRI-MRS sequence. Our findings strengthen the link between glutamate and functional activity in the human brain by demonstrating a significant correlation of BOLD-fMRI and glutamate over time, and by showing ~2% glutamate increases during 64 s of visual stimulation. Our tool may become useful for studies characterizing functional dynamics between neurochemicals and hemodynamics in health and disease., Graphical abstract fx1, Highlights • Novel MRI sequence measures hemodynamics and neurochemistry in same TR. • Stimulation block duration relevant for functional experiments (64s). • BOLD-fMRI and glutamate time courses correlate during functional stimulation. • Visual stimulation increases glutamate concentrations. • Useful to study fundamental relationship between hemodynamics and neurochemistry.

Published
2017

37. Association Between Sarcomeric Variants in Hypertrophic Cardiomyopathy and Myocardial Oxygenation: Insights From a Novel Oxygen-Sensitive Cardiovascular Magnetic Resonance Approach.

Author

Raman, Betty DPhil, Tunnicliffe, Elizabeth M., Chan, Kenneth, Ariga, Rina DPhil, Hundertmark, Moritz, Ohuma, Eric O. DPhil, Sivalokanathan, Sanjay, Tan, Yi Jie Gifford BA BM BCh, Mahmod, Masliza DPhil, Hess, Aaron T., Karamitsos, Theodoros D., Selvanayagam, Joseph DPhil, Jerosch-Herold, Michael, Watkins, Hugh, Neubauer, Stefan, Raman, Betty, Ariga, Rina, Ohuma, Eric O, Tan, Yi Jie Gifford, and Mahmod, Masliza

Published
2021
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38. Navigator‐based reacquisition and estimation of motion‐corrupted data: Application to multi‐echo spin echo for carotid wall MRI.

Author

Frost, Robert, Biasiolli, Luca, Li, Linqing, Hurst, Katherine, Alkhalil, Mohammad, Choudhury, Robin P., Robson, Matthew D., Hess, Aaron T., and Jezzard, Peter

Subjects
ECHO, IMAGE reconstruction, CARDIAC imaging
Abstract

Purpose: To assess whether artifacts in multi‐slice multi‐echo spin echo neck imaging, thought to be caused by brief motion events such as swallowing, can be corrected by reacquiring corrupted central k‐space data and estimating the remainder with parallel imaging. Methods: A single phase‐encode line (ky = 0, phase‐encode direction anteroposterior) navigator echo was used to identify motion‐corrupted data and guide the online reacquisition. If motion corruption was detected in the 7 central k‐space lines, they were replaced with reacquired data. Subsequently, GRAPPA reconstruction was trained on the updated central portion of k‐space and then used to estimate the remaining motion‐corrupted k‐space data from surrounding uncorrupted data. Similar compressed sensing‐based approaches have been used previously to compensate for respiration in cardiac imaging. The g‐factor noise amplification was calculated for the parallel imaging reconstruction of data acquired with a 10‐channel neck coil. The method was assessed in scans with 9 volunteers and 12 patients. Results: The g‐factor analysis showed that GRAPPA reconstruction of 2 adjacent motion‐corrupted lines causes high noise amplification; therefore, the number of 2‐line estimations should be limited. In volunteer scans, median ghosting reduction of 24% was achieved with 2 adjacent motion‐corrupted lines correction, and image quality was improved in 2 patient scans that had motion corruption close to the center of k‐space. Conclusion: Motion‐corrupted echo‐trains can be identified with a navigator echo. Combined reacquisition and parallel imaging estimation reduced motion artifacts in multi‐slice MESE when there were brief motion events, especially when motion corruption was close to the center of k‐space. [ABSTRACT FROM AUTHOR]

Published
2020
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39. Scattering matrix imaging pulse design for real‐time respiration and cardiac motion monitoring.

Author

Jaeschke, Sven H. F., Robson, Matthew D., and Hess, Aaron T.

Subjects
S-matrix theory, FREQUENCY division multiple access, MOTION, RESPIRATION
Abstract

Purpose: The scattering matrix (S‐matrix) of a parallel transmit (pTx) coil is sensitive to physiological motion but requires additional monitoring RF pulses to be measured. In this work, we present and evaluate pTx RF pulse designs that simultaneously excite for imaging and measure the S‐matrix to generate real‐time motion signals without prolonging the image sequence. Theory and Methods: Three pTx waveforms for measuring the S‐matrix were identified and superimposed onto the imaging excitation RF pulses: (1) time division multiplexing, (2) frequency division multiplexing, and (3) code division multiplexing. These 3 methods were evaluated in healthy volunteers for scattering sensitivity and image artefacts. The S‐matrix and real‐time motion signals were calculated on the image calculation environment of the MR scanner. Prospective cardiac triggers were identified in early systole as a high rate of change of the cardiac motion signal. Monitoring accuracy was compared against electrocardiogram or the imaged diaphragm position. Results: All 3 monitoring approaches measure the S‐matrix during image excitation with quality correlated to input power. No image artefacts were observed for frequency multiplexing, and low energy artefacts were observed in the other methods. The accuracy of the achieved prospective cardiac gating was 15 ± 16 ms for breath hold and 24 ± 17 ms during free breathing. The diaphragm position prediction accuracy was 1.3 ± 0.9 mm. In all volunteers, good quality cine images were acquired for breath hold scans and dual gated CINEs were demonstrated. Conclusion: The S‐matrix can be measured during image excitation to generate real‐time cardiac and respiratory motion signals for prospective gating. No artefacts are introduced when frequency division multiplexing is used. [ABSTRACT FROM AUTHOR]

Published
2019
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40. Cardiac gating using scattering of an 8‐channel parallel transmit coil at 7T.

Author

Jaeschke, Sven H. F., Robson, Matthew D., and Hess, Aaron T.

Abstract

Purpose: To establish a cardiac signal from scattering matrix or scattering coefficient measurements made on a 7T 8‐channel parallel transmit (pTx) system, and to evaluate its use for cardiac gating. Methods: Measurements of the scattering matrix and scattering coefficients were acquired using a monitoring pulse sequence and during a standard cine acquisition, respectively. Postprocessing used an independent component analysis and gating feature identification. The effect of the phase of the excitation radiofrequency (RF) field ( B 1 + shim) on the cardiac signal was simulated for multiple B 1 + shim configurations, and cine images were reconstructed from both the scattering coefficients and electrocardiogram (ECG). Results: The cardiac motion signal was successfully identified in all subjects with a mean signal‐to‐noise ratio of 33.1 and 5.7 using the scattering matrix and scattering coefficient measurements, respectively. The dominant gating feature in the cardiac signal was a peak aligned with end‐systole that occurred on average at 311 and 391 ms after the ECG trigger, with a mean standard deviation of 13.4 and 18.1 ms relative to ECG when using the scattering matrix and scattering coefficients measurements, respectively. The scattering coefficients showed a dependence on B 1 + shim with some shim configurations not showing any cardiac signal. Cine images were successfully reconstructed using the scattering coefficients with minimal differences compared to those using ECG. Conclusion: We have shown that the scattering of a pTx RF coil can be used to estimate a cardiac signal, and that scattering matrix and coefficients can be used to cardiac gate MRI acquisitions with the scattering matrix providing a superior cardiac signal. Magn Reson Med 80:633–640, 2018. © 2017 The Authors Magnetic Resonance in Medicine published by Wiley Periodicals, Inc. on behalf of International Society for Magnetic Resonance in Medicine. This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited. [ABSTRACT FROM AUTHOR]

Published
2018
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41. Diaphragm Position Can Be Accurately Estimated From the Scattering of a Parallel Transmit RF Coil at 7 T.

Author

Hess, Aaron T., Tunnicliffe, Elizabeth M, Rodgers, Christopher T., and Robson, Matthew D.

Abstract

Purpose: To evaluate the use of radiofrequency scattering of a parallel transmit coil to track diaphragm motion. Methods: Measurements made during radiofrequency excitation on an 8-channel parallel transmit coil by the directional couplers of the radiofrequency safety monitor were combined and converted into diaphragm position. A 30-s subject-specific calibration with an MRI navigator was used to determine a diaphragm estimate from each directional-coupler measure. Seven healthy volunteers were scanned at 7 T, in which images of the diaphragm were continuously acquired and directional couplers were monitored during excitation radiofrequency pulses. The ability to detect coughing was evaluated in one subject. The method was implemented on the scanner and evaluated for diaphragm gating of a free-breathing cardiac cine. Results: Six of the seven scans were successful. In these subjects, the root mean square difference between MRI and scattering estimation of the superior–inferior diaphragm position was 1.4 ± 0.5 mm. On the scanner, the position was calculated less than 2 ms after every radiofrequency pulse. A prospectively gated (echocardiogram and respiration) high-resolution free-breathing cine showed no respiratory artifact and sharp blood-myocardium definition. Conclusions: Transmit coil scattering is sensitive to diaphragm motion and provides rapid, quantitative, and accurate monitoring of respiration. [ABSTRACT FROM AUTHOR]

Published
2018
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42. Real-time Motion and B0 correction for LASER MRSI using EPI volumetric navigators

Author

Hess, Aaron T., Andronesi, Ovidiu C., Tisdall, M. Dylan, Sorensen, A. Gregory, van der Kouwe, André J.W., and Meintjes, Ernesta M.

Subjects
Aspartic Acid, Time Factors, Rotation, Echo-Planar Imaging, Movement, Reproducibility of Results, Signal-To-Noise Ratio, Creatine, Article, Motion, Imaging, Three-Dimensional, Image Processing, Computer-Assisted, Humans, Artifacts
Abstract

A method is presented to correct the effects of motion and motion-related B(0) perturbations on spectroscopic imaging in real time through the use of a volumetric navigator. It is demonstrated that, for an axial slice, lifting the chin significantly disrupts the B(0) homogeneity in the zero-order (frequency), first-order Y (coronal) axis and second-order ZY term. This volumetric navigator is able to measure and correct in real time both head pose and zero- to first-order B(0) inhomogeneities. The volumetric navigator was validated in six volunteers who deliberately lifted and then dropped their chin during the scan. These scans show that motion correction alone is not sufficient to recover the spectral quality. By applying real-time shim adjustments, spectral quality was fully recovered to linewidths below 0.08 ppm and the signal-to-noise ratio to within acceptable limits in five of six subjects. In the sixth subject, 83% of the spectra within the volume of interest were recovered, compared with the worst case nonshim-corrected scan, where none of the voxels fell within these quality bounds. It is shown that the use of a volumetric navigator comes at no additional cost to the scan time or spectral signal-to-noise ratio.

Published
2011

43. Real-time motion and main magnetic field correction in MR spectroscopy using an EPI volumetric navigator

Author

Hess, Aaron T, Meintjies, Ernesta, and Van der Kouwe, Andre

Subjects
Human Biology
Abstract

In population groups where subjects do not lie still during Magnetic Resonance Spectroscopy (MRS) scans, real-time volume of interest (VOI), frequency, and main magnetic field (B0) shim correction may be necessary. This work demonstrates firstly that head movement causes significant B0 disruption in both single voxel spectroscopy and spectroscopic imaging.

Published
2011

44. Prospective motion correction and selective reacquisition using volumetric navigators for vessel-encoded arterial spin labeling dynamic angiography.

Author

Frost, Robert, Hess, Aaron T., Okell, Thomas W., Chappell, Michael A., Tisdall, M. Dylan, van der Kouwe, André J. W., and Jezzard, Peter

Abstract

Purpose The aim of this study was to improve robustness to motion in a vessel-encoded angiography sequence used for patient scans. The sequence is particularly sensitive to motion between imaging segments, which causes ghosting and blurring that propagates to the final angiogram. Methods Volumetric echo planar imaging (EPI) navigators acquired in 275 ms were inserted after the imaging readout in a vessel-encoded pseudo-continuous arterial spin labeling (VEPCASL) sequence. The effects of movement between segments on the images were tested with phantom experiments. Deliberate motion experiments with healthy volunteers were performed to compare prospective motion correction (PMC) with reacquisition versus no correction. Results In scans without motion, the addition of the EPI navigator to the sequence did not affect the quality of the angiograms in comparison with the original sequence. PMC and reacquisition improved the visibility of vessels in the angiograms compared with the scans without correction. The reacquisition strategy was shown to be important for complete correction of imaging artifacts. Conclusion We have demonstrated an effective method to correct motion in vessel-encoded angiography. For reacquisition of 15 segments, the technique requires approximately 30 s of additional scanning (∼25%). Magn Reson Med 76:1420-1430, 2016. © 2015 International Society for Magnetic Resonance in Medicine [ABSTRACT FROM AUTHOR]

Published
2016
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45. Large dynamic range relative.

Author

Padormo, Francesco, Hess, Aaron T., Aljabar, Paul, Malik, Shaihan J., Jezzard, Peter, Robson, Matthew D., Hajnal, Joseph V., and Koopmans, Peter J.

Abstract

Purpose Parallel transmission (PTx) requires knowledge of the [ABSTRACT FROM AUTHOR]

Published
2016
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46. Study protocol: the Whitehall II imaging sub-study.

Author

Filippini, Nicola, Zsoldos, Enikő, Haapakoski, Rita, Sexton, Claire E., Mahmood, Abda, Allan, Charlotte L., Topiwala, Anya, Valkanova, Vyara, Brunner, Eric J., Shipley, Martin J., Auerbach, Edward, Moeller, Steen, Uğurbil, Kâmil, Junqian Xu, Yacoub, Essa, Andersson, Jesper, Bijsterbosch, Janine, Clare, Stuart, Griffanti, Ludovica, and Hess, Aaron T.

Subjects
RESEARCH protocols, CIVIL service, COGNITIVE ability, AGING, BRAIN, MAGNETIC resonance imaging of the brain, LONGITUDINAL method, MEDICAL needs assessment
Abstract

Background The Whitehall II (WHII) study of British civil servants provides a unique source of longitudinal data to investigate key factors hypothesized to affect brain health and cognitive ageing. This paper introduces the multi-modal magnetic resonance imaging (MRI) protocol and cognitive assessment designed to investigate brain health in a random sample of 800 members of the WHII study. Methods/design A total of 6035 civil servants participated in the WHII Phase 11 clinical examination in 2012-2013. A random sample of these participants was included in a sub-study comprising an MRI brain scan, a detailed clinical and cognitive assessment, and collection of blood and buccal mucosal samples for the characterisation of immune function and associated measures. Data collection for this sub-study started in 2012 and will be completed by 2016. The participants, for whom social and health records have been collected since 1985, were between 60-85 years of age at the time the MRI study started. Here, we describe the pre- specified clinical and cognitive assessment protocols, the state-of-the-art MRI sequences and latest pipelines for analyses of this sub-study. Discussion The integration of cutting-edge MRI techniques, clinical and cognitive tests in combination with retrospective data on social, behavioural and biological variables during the preceding 25 years from a well-established longitudinal epidemiological study (WHII cohort) will provide a unique opportunity to examine brain structure and function in relation to age- related diseases and the modifiable and non-modifiable factors affecting resilience against and vulnerability to adverse brain changes. [ABSTRACT FROM AUTHOR]

Published
2014
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47. An In Vivo 1H Magnetic Resonance Spectroscopy Study of the Deep Cerebellar Nuclei in Children with Fetal Alcohol Spectrum Disorders.

Author

Plessis, Lindie, Jacobson, Joseph L., Jacobson, Sandra W., Hess, Aaron T., Kouwe, Andre, Avison, Malcolm J., Molteno, Christopher D., Stanton, Mark E., Stanley, Jeffrey A., Peterson, Bradley S., and Meintjes, Ernesta M.

Subjects
NUCLEAR magnetic resonance spectroscopy, BRAIN physiology, FETAL alcohol syndrome, ASPARTIC acid, CHOLINE, INTELLIGENCE tests, RESEARCH funding, MULTIPLE regression analysis, DATA analysis software, PRENATAL exposure delayed effects
Abstract

Background Prenatal alcohol exposure has been linked to impairment in cerebellar structure and function, including eyeblink conditioning. The deep cerebellar nuclei, which play a critical role in cerebellar-mediated learning, receive extensive inputs from brain stem and cerebellar cortex and provide the point of origin for most of the output fibers to other regions of the brain. We used in vivo 1H magnetic resonance spectroscopy ( MRS) to examine effects of prenatal alcohol exposure on neurochemistry in this important cerebellar region. Methods MRS data from the deep cerebellar nuclei were acquired from 37 children with heavy prenatal alcohol exposure and 17 non- or minimally exposed controls from the Cape Coloured (mixed ancestry) community in Cape Town, South Africa. Results Increased maternal alcohol consumption around time of conception was associated with lower N-Acetylaspartate ( NAA) levels in the deep nuclei ( r = −0.33, p < 0.05). Higher levels of alcohol consumption during pregnancy were related to lower levels of the choline-containing metabolites ( r = −0.37, p < 0.01), glycerophosphocholine plus phosphocholine (Cho). Alcohol consumption levels both at conception ( r = 0.35, p < 0.01) and during pregnancy ( r = 0.38, p < 0.01) were related to higher levels of glutamate plus glutamine (Glx). All these effects continued to be significant after controlling for potential confounders. Conclusions The lower NAA levels seen in relation to prenatal alcohol exposure may reflect impaired neuronal integrity in the deep cerebellar nuclei. Our finding of lower Cho points to disrupted Cho metabolism of membrane phospholipids, reflecting altered neuropil development with potentially reduced content of dendrites and synapses. The alcohol-related alterations in Glx may suggest a disruption of the glutamate-glutamine cycling involved in glutamatergic excitatory neurotransmission. [ABSTRACT FROM AUTHOR]

Published
2014
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48. Real-time motion- and B0-correction for LASER-localized spiral-accelerated 3D-MRSI of the brain at 3T.

Author

Bogner, Wolfgang, Hess, Aaron T., Gagoski, Borjan, Tisdall, M. Dylan, van der Kouwe, Andre J.W., Trattnig, Siegfried, Rosen, Bruce, and Andronesi, Ovidiu C.

Subjects
*HUMAN mechanics, *MAGNETIC resonance imaging of the brain, *BRAIN function localization, *SPECTROSCOPIC imaging, *NEUROSCIENCES, BRAIN metabolism
Abstract

Abstract: The full potential of magnetic resonance spectroscopic imaging (MRSI) is often limited by localization artifacts, motion-related artifacts, scanner instabilities, and long measurement times. Localized adiabatic selective refocusing (LASER) provides accurate B1-insensitive spatial excitation even at high magnetic fields. Spiral encoding accelerates MRSI acquisition, and thus, enables 3D-coverage without compromising spatial resolution. Real-time position- and shim/frequency-tracking using MR navigators correct motion- and scanner instability-related artifacts. Each of these three advanced MRI techniques provides superior MRSI data compared to commonly used methods. In this work, we integrated in a single pulse sequence these three promising approaches. Real-time correction of motion, shim, and frequency-drifts using volumetric dual-contrast echo planar imaging-based navigators were implemented in an MRSI sequence that uses low-power gradient modulated short-echo time LASER localization and time efficient spiral readouts, in order to provide fast and robust 3D-MRSI in the human brain at 3T. The proposed sequence was demonstrated to be insensitive to motion- and scanner drift-related degradations of MRSI data in both phantoms and volunteers. Motion and scanner drift artifacts were eliminated and excellent spectral quality was recovered in the presence of strong movement. Our results confirm the expected benefits of combining a spiral 3D-LASER-MRSI sequence with real-time correction. The new sequence provides accurate, fast, and robust 3D metabolic imaging of the human brain at 3T. This will further facilitate the use of 3D-MRSI for neuroscience and clinical applications. [Copyright &y& Elsevier]

Published
2014
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49. Aortic Dilation in Bicuspid Aortic Valve Disease.

Author

Bissell, Malenka M., Hess, Aaron T., Biasiolli, Luca, Glaze, Steffan J., Loudon, Margaret, Pitcher, Alex, Davis, Anne, Prendergast, Bernard, Markl, Michael, Barker, Alex J., Neubauer, Stefan, and Myerson, Saul G.

Abstract

Ascending aortic dilation is important in bicuspid aortic valve (BAV) disease, with increased risk of aortic dissection. We used cardiovascular MR to understand the pathophysiology better by examining the links between 3-dimensional flow abnormalities, aortic function, and aortic dilation.A total of 142 subjects underwent cardiovascular MR (mean age, 40 years; 95 with BAV, 47 healthy volunteers). Patients with BAV had predominantly abnormal right-handed helical flow in the ascending aorta, larger ascending aortas (18.3±3.3 versus 15.2±2.2 mm/m2; P<0.001), and higher rotational (helical) flow (31.7±15.8 versus 2.9±3.9 mm2/s; P<0.001), systolic flow angle (23.1°±12.5° versus 7.0°±4.6°; P<0.001), and systolic wall shear stress (0.85±0.28 versus 0.59±0.17 N/m2; P<0.001) compared with healthy volunteers. BAV with right-handed flow and right-non coronary cusp fusion (n=31) showed more severe flow abnormalities (rotational flow, 38.5±16.5 versus 27.8±12.4 mm2/s; P<0.001; systolic flow angle, 29.4°±10.9° versus 19.4°±11.4°; P<0.001; in-plane wall shear stress, 0.64±0.23 versus 0.47±0.22 N/m2; P<0.001) and larger aortas (19.5±3.4 versus 17.5±3.1 mm/m2; P<0.05) than right-left cusp fusion (n=55). Patients with BAV with normal flow patterns had similar aortic dimensions and wall shear stress to healthy volunteers and younger patients with BAV showed abnormal flow patterns but no aortic dilation, both further supporting the importance of flow pattern in the pathogenesis of aortic dilation. Aortic function measures (distensibility, aortic strain, and pulse wave velocity) were similar across all groups.Flow abnormalities may be a major contributor to aortic dilation in BAV. Fusion type affects the severity of flow abnormalities and may allow better risk prediction and selection of patients for earlier surgical intervention. [ABSTRACT FROM AUTHOR]

Published
2013
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50. Real-time motion and B0 correction for localized adiabatic selective refocusing (LASER) MRSI using echo planar imaging volumetric navigators.

Author

Hess, Aaron T., Andronesi, Ovidiu C., Dylan Tisdall, M., Gregory Sorensen, A., Kouwe, André J. W., and Meintjes, Ernesta M.

Abstract

A method is presented to correct the effects of motion and motion-related B0 perturbations on spectroscopic imaging in real time through the use of a volumetric navigator. It is demonstrated that, for an axial slice, lifting the chin significantly disrupts the B0 homogeneity in the zero-order (frequency), first-order Y (coronal) axis and second-order ZY term. This volumetric navigator is able to measure and correct in real time both head pose and zero- to first-order B0 inhomogeneities. The volumetric navigator was validated in six volunteers who deliberately lifted and then dropped their chin during the scan. These scans show that motion correction alone is not sufficient to recover the spectral quality. By applying real-time shim adjustments, spectral quality was fully recovered to linewidths below 0.08 ppm and the signal-to-noise ratio to within acceptable limits in five of six subjects. In the sixth subject, 83% of the spectra within the volume of interest were recovered, compared with the worst case nonshim-corrected scan, where none of the voxels fell within these quality bounds. It is shown that the use of a volumetric navigator comes at no additional cost to the scan time or spectral signal-to-noise ratio. Copyright © 2011 John Wiley & Sons, Ltd. [ABSTRACT FROM AUTHOR]

Published
2012
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