Your search keyword '"methods [Echo-Planar Imaging]"' showing total 12 results

1. Rapid Geometry-Corrected Echo-Planar Diffusion Imaging at Ultrahigh Field: Fusing View Angle Tilting and Point-Spread Function Mapping

Author

Yi‐Hang Tung, Myung‐Ho In, Sinyeob Ahn, and Oliver Speck

Subjects

Echo-Planar Imaging, VAT, Brain, Water, methods [Echo-Planar Imaging], UHF, distortion correction, EPI, Diffusion Magnetic Resonance Imaging, DTI, methods [Image Processing, Computer-Assisted], methods [Diffusion Magnetic Resonance Imaging], Image Processing, Computer-Assisted, Humans, Radiology, Nuclear Medicine and imaging, ddc:610, Artifacts, diagnostic imaging [Brain], PSF, Algorithms

Abstract

PURPOSE: Severe geometric distortions induced by tissue susceptibility, water-fat chemical shift, and eddy currents pose a substantial obstacle in single-shot EPI, especially for high-resolution imaging at ultrahigh field. View angle tilting (VAT)-EPI can mitigate in-plane distortion. However, the accompanied strong image blurring prevented its widespread applications. On the other hand, point-spread function mapping (PSF)-EPI can correct distortion and blurring accurately but requires prolonged scan time. We present fused VAT-PSF-EPI and possibilities for acceleration. METHODS: MR signal equations were explicitly derived to quantify image blurring in VAT-EPI and the maximum acceleration capacity in VAT-PSF-EPI. To validate the theoretical prediction, phantom measurements with varying in-plane parallel imaging factors, slice thicknesses, and RF pulses were conducted at 7 Tesla. In addition, in vivo human brain scans were acquired with T2 and diffusion weighting to assess distortion and blurring correction. RESULTS: VAT can effectively suppress distortion, and the introduced image blurring is corrected through PSF encoding. Up to fourfold acceleration (only 5 shots) in VAT-PSF-EPI was achieved compared with standard PSF-EPI without VAT. VAT-induced signal loss was mitigated by adjusting the sequence parameters and EPI resolution. In vivo T2 -weighted EPI data with 1.4 mm3 resolution demonstrate immunity to water-fat chemical shift-induced distortion. Very high-spatial resolution diffusion-weighted EPI (0.7 × 0.7 × 2.8 mm3 and 1.2 mm3 ) demonstrates the immunity to eddy current-induced distortion. CONCLUSION: VAT-PSF-EPI is a novel spin-echo EPI-based sequence for fast high-resolution diffusion imaging at ultrahigh field.

Published

2022

2. Comparison of SMS-EPI and 3D-EPI at 7T in an fMRI localizer study with matched spatiotemporal resolution and homogenized excitation profiles

Author

Le Ster, Caroline, Moreno, Antonio, Mauconduit, Franck, Gras, Vincent, Stirnberg, Ruediger, Poser, Benedikt A., Vignaud, Alexandre, Eger, Evelyn, Dehaene, Stanislas, Meyniel, Florent, Boulant, Nicolas, IFR49 - Neurospin - CEA, Commissariat à l'énergie atomique et aux énergies alternatives (CEA), Institut National de la Santé et de la Recherche Médicale (INSERM), German Research Center for Neurodegenerative Diseases - Deutsches Zentrum für Neurodegenerative Erkrankungen (DZNE), Department of Cognitive Neuroscience [Maastricht, Pays-Bas], Faculty of Psychology and Neuroscience [Maastricht, Pays-Bas], Maastricht University [Maastricht]-Maastricht University [Maastricht], Collège de France - Chaire Psychologie cognitive expérimentale, Collège de France (CdF (institution)), This work was supported by European Research Council, Proof of Concept #700812 (https://erc.europa.eu/funding/proofconcept)., Chaire Psychologie cognitive expérimentale, MRI, RS: FPN CN 5, and Bodescot, Myriam

Subjects

Central Nervous System, Male, Physiology, [SDV.IB.IMA]Life Sciences [q-bio]/Bioengineering/Imaging, Sensory Physiology, Social Sciences, Signal-To-Noise Ratio, Biochemistry, Nervous System, methods [Echo-Planar Imaging], Diagnostic Radiology, Fats, Database and Informatics Methods, methods [Brain Mapping], methods [Magnetic Resonance Imaging], Functional Magnetic Resonance Imaging, Medicine and Health Sciences, Image Processing, Computer-Assisted, Psychology, 3 T, Language, TESLA, Brain Mapping, Echo-Planar Imaging, Radiology and Imaging, Physics, Brain, [SDV.NEU.SC]Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC]/Cognitive Sciences, TEMPORAL RESOLUTION, Magnetic Resonance Imaging, Lipids, Physical Sciences, Medicine, Female, PARALLEL, Anatomy, Sequence Analysis, Research Article, Adult, Imaging Techniques, Bioinformatics, TRANSMISSION, Science, Sequence Databases, Neuroimaging, Research and Analysis Methods, Sensitivity and Specificity, Young Adult, physiology [Brain], Diagnostic Medicine, Acoustic Signals, Humans, WHOLE-BRAIN, ddc:610, 2D, Cognitive Psychology, Biology and Life Sciences, Acoustics, PHYSIOLOGICAL NOISE, RF PULSES, [SDV.IB.IMA] Life Sciences [q-bio]/Bioengineering/Imaging, Biological Databases, ROC Curve, STATE FUNCTIONAL MRI, Cognitive Science, [SDV.NEU.SC] Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC]/Cognitive Sciences, Neuroscience

Abstract

International audience; The simultaneous multi-slice EPI (SMS-EPI, a.k.a. MB-EPI) sequence has met immense popularity recently in functional neuroimaging. A still less common alternative is the use of 3D-EPI, which offers similar acceleration capabilities. The aim of this work was to compare the SMS-EPI and the 3D-EPI sequences in terms of sampling strategies for the detection of task-evoked activations at 7T using detection theory. To this end, the spatial and temporal resolutions of the sequences were matched (1.6 mm isotropic resolution, TR = 1200 ms) and their excitation profiles were homogenized by means of calibration-free parallel-transmission (Universal Pulses). We used a fast-event "localizer" paradigm of 5:20 min in order to probe sensorimotor functions (visual, auditory and motor tasks) as well as higher level functions (language comprehension, mental calculation), where results from a previous large-scale study at 3T (N = 81) served as ground-truth reference for the brain areas implicated in each cognitive function. In the current study, ten subjects were scanned while their activation maps were generated for each cognitive function with the GLM analysis. The SMS-EPI and 3D-EPI sequences were compared in terms of raw tSNR, t-score testing for the mean signal, activation strength and accuracy of the robust sensorimotor functions. To this end, the sensitivity and specificity of these contrasts were computed by comparing their activation maps to the reference brain areas obtained in the 3T study. Estimated flip angle distributions in the brain reported a normalized root mean square deviation from the target value below 10% for both sequences. The analysis of the t-score testing for the mean signal revealed temporal noise correlations, suggesting the use of this metric instead of the traditional tSNR for testing fMRI sequences. The SMS-EPI and 3D-EPI thereby yielded similar performance from a detection theory perspective.

Published

2019

3. Whole‐brain snapshot CEST imaging at 7 T using 3D‐EPI

Author

Philipp Ehses, Suzan Akbey, Rüdiger Stirnberg, Moritz Zaiss, and Tony Stöcker

Subjects

Physics, Brain Mapping, Offset (computer science), Echo-Planar Imaging, Phantoms, Imaging, Healthy subjects, Signal-To-Noise Ratio, Image Enhancement, methods [Echo-Planar Imaging], Healthy Volunteers, Scan time, methods [Brain Mapping], Nuclear magnetic resonance, Imaging, Three-Dimensional, methods [Image Processing, Computer-Assisted], Image Processing, Computer-Assisted, Snapshot (computer storage), Humans, Radiology, Nuclear Medicine and imaging, ddc:610, methods [Image Enhancement], Isotropic resolution, methods [Imaging, Three-Dimensional]

Abstract

The aim of this work is to develop a fast and robust CEST sequence in order to allow the acquisition of a whole-brain imaging volume after a single preparation block (snapshot acquisition).A 3D-CEST sequence with an optimized 3D-EPI readout module was developed, which acquires the complete k-space data following a single CEST preparation for 1 saturation offset. Whole-brain mapping of the Z-spectrum with 2 mm isotropic resolution is achieved at 68 saturation frequencies in 5 minutes (4.33 s per offset). We analyzed the B 1 distribution in order to optimize B 1 correction and to provide accurate CEST quantification across the whole brain.We obtained maps for 3 different CEST contrasts from 4 healthy subjects. Based on our B 1 distribution analysis, we conclude that 3 B 1 sampling points allow for sufficient compensation of B 1 variations across most of the brain. Two brain regions, the cerebellum and the temporal lobes, are difficult to quantify at 7 T due to very low B 1 that was achieved in these regions.The proposed sequence enables robust acquisition of 2 mm isotropic whole-brain CEST maps at 7 Tesla within a total scan time of 16 minutes.

Published

2019

4. Rapid whole-brain resting-state fMRI at 3 T: Efficiency-optimized three-dimensional EPI versus repetition time-matched simultaneous-multi-slice EPI

Author

Benedikt A. Poser, Daniel Brenner, Tony Stöcker, Monique M.B. Breteler, Willem Huijbers, Rüdiger Stirnberg, RS: FPN CN 5, MRI, and Creative Computing

Subjects

Male, Volumetric imaging, Computer science, Rest, Cognitive Neuroscience, Iterative reconstruction, computer.software_genre, methods [Echo-Planar Imaging], 030218 nuclear medicine & medical imaging, methods [Brain Mapping], Young Adult, 03 medical and health sciences, Imaging, Three-Dimensional, 0302 clinical medicine, Aliasing, Voxel, methods [Image Processing, Computer-Assisted], Image Processing, Computer-Assisted, Journal Article, Humans, ddc:610, diagnostic imaging [Brain], Image resolution, Echo-planar imaging, Brain Mapping, Communication, Resting state fMRI, Echo-Planar Imaging, business.industry, Brain, Sampling (statistics), Pattern recognition, Neurology, Repetition Time, Undersampling, Temporal resolution, Female, Artificial intelligence, business, computer, 030217 neurology & neurosurgery, methods [Imaging, Three-Dimensional]

Abstract

State-of-the-art simultaneous-multi-slice (SMS-)EPI and 3D-EPI share several properties that benefit functional MRI acquisition. Both sequences employ equivalent parallel imaging undersampling with controlled aliasing to achieve high temporal sampling rates. As a volumetric imaging sequence, 3D-EPI offers additional means of acceleration complementary to 2D-CAIPIRINHA sampling, such as fast water excitation and elliptical sampling. We performed an application-oriented comparison between a tailored, six-fold CAIPIRINHA-accelerated 3D-EPI protocol at 530 ms temporal and 2.4 mm isotropic spatial resolution and an SMS-EPI protocol with identical spatial and temporal resolution for whole-brain resting-state fMRI at 3 T. The latter required eight-fold slice acceleration to compensate for the lack of elliptical sampling and fast water excitation. Both sequences used vendor-supplied on-line image reconstruction. We acquired test/retest resting-state fMRI scans in ten volunteers, with simultaneous acquisition of cardiac and respiration data, subsequently used for optional physiological noise removal (nuisance regression). We found that the 3D-EPI protocol has significantly increased temporal signal-to-noise ratio throughout the brain as compared to the SMS-EPI protocol, especially when employing motion and nuisance regression. Both sequence types reliably identified known functional networks with stronger functional connectivity values for the 3D-EPI protocol. We conclude that the more time-efficient 3D-EPI primarily benefits from reduced parallel imaging noise due to a higher, actual k-space sampling density compared to SMS-EPI. The resultant BOLD sensitivity increase makes 3D-EPI a valuable alternative to SMS-EPI for whole-brain fMRI at 3 T, with voxel sizes well below 3 mm isotropic and sampling rates high enough to separate dominant cardiac signals from BOLD signals in the frequency domain.

Published

2017

5. Dynamic 2D self-phase-map Nyquist ghost correction for simultaneous multi-slice echo planar imaging

Author

Itthi Chatnuntawech, Renat Yakupov, Oliver Speck, Myung-Ho In, Frank Godenschweger, Yi-Hang Tung, Kawin Setsompop, and Uten Yarach

Subjects

Pipeline (computing), Phase (waves), Field of view, Signal-To-Noise Ratio, Regularization (mathematics), methods [Echo-Planar Imaging], Article, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, symbols.namesake, 0302 clinical medicine, methods [Image Processing, Computer-Assisted], Gaussian function, Image Processing, Computer-Assisted, Nyquist–Shannon sampling theorem, Humans, Radiology, Nuclear Medicine and imaging, ddc:610, Ghosting, diagnostic imaging [Brain], Physics, Echo-Planar Imaging, Phantoms, Imaging, Brain, Signal Processing, Computer-Assisted, symbols, Artifacts, Algorithm, 030217 neurology & neurosurgery, Smoothing, Algorithms

Abstract

Purpose To develop a reconstruction pipeline that intrinsically accounts for both simultaneous multislice echo planar imaging (SMS-EPI) reconstruction and dynamic slice-specific Nyquist ghosting correction in time-series data. Methods After 1D slice-group average phase correction, the separate polarity (i.e., even and odd echoes) SMS-EPI data were unaliased by slice GeneRalized Autocalibrating Partial Parallel Acquisition. Both the slice-unaliased even and odd echoes were jointly reconstructed using a model-based framework, extended for SMS-EPI reconstruction that estimates a 2D self-phase map, corrects dynamic slice-specific phase errors, and combines data from all coils and echoes to obtain the final images. Results The percentage ghost-to-signal ratios (%GSRs) and its temporal variations for MB3Ry 2 with a field of view/4 shift in a human brain obtained by the proposed dynamic 2D and standard 1D phase corrections were 1.37 ± 0.11 and 2.66 ± 0.16, respectively. Even with a large regularization parameter λ applied in the proposed reconstruction, the smoothing effect in fMRI activation maps was comparable to a very small Gaussian kernel size 1 × 1 × 1 mm3 . Conclusion The proposed reconstruction pipeline reduced slice-specific phase errors in SMS-EPI, resulting in reduction of GSR. It is applicable for functional MRI studies because the smoothing effect caused by the regularization parameter selection can be minimal in a blood-oxygen-level-dependent activation map.

Published

2017

6. Cerebellar pathology in Friedreich's ataxia: Atrophied dentate nuclei with normal iron content

Author

Mark E. Ladd, A. Beck, Dagmar Timmann, Elke R. Gizewski, Klaus Solbach, Ludger Schöls, M Minnerop, and Oliver Kraff

Subjects

Male, Pathology, Cerebellum, Medizin, methods [Echo-Planar Imaging], lcsh:RC346-429, Volumetry, pathology [Cerebellum], metabolism [Iron], pathology [Atrophy], biology, Echo-Planar Imaging, metabolism [Cerebellum], Middle Aged, medicine.anatomical_structure, Neurology, Cerebellar Nuclei, Susceptibility weighted imaging, Biomarker (medicine), lcsh:R858-859.7, Female, Dentate nuclei, medicine.symptom, Relaxometry, metabolism [Atrophy], metabolism [Cerebellar Nuclei], Adult, medicine.medical_specialty, Ataxia, Dentate iron content, Cognitive Neuroscience, Iron, lcsh:Computer applications to medicine. Medical informatics, Article, Atrophy, In vivo, pathology [Cerebellar Nuclei], diagnosis [Friedreich Ataxia], medicine, Humans, Radiology, Nuclear Medicine and imaging, ddc:610, Ultra-high-field MRI, lcsh:Neurology. Diseases of the nervous system, business.industry, Friedreich's ataxia, medicine.disease, Friedreich Ataxia, Frataxin, biology.protein, Neurology (clinical), business, metabolism [Friedreich Ataxia]

Abstract

Background In Friedreich's ataxia (FA) the genetically decreased expression of the mitochondrial protein frataxin leads to disturbance of the mitochondrial iron metabolism. Within the cerebellum the dentate nuclei (DN) are primarily affected. Histopathological studies show atrophy and accumulation of mitochondrial iron in DN. Dentate iron content has been suggested as a biomarker to measure the effects of siderophores/antioxidant treatment of FA. We assessed the iron content and the volume of DN in FA patients and controls based on ultra-high-field MRI (7 Tesla) images. Methods Fourteen FA patients (mean age 38.1 yrs) and 14 age- and gender-matched controls participated. Multi-echo gradient echo and susceptibility weighted imaging (SWI) sequences were acquired on a 7 T whole-body scanner. For comparison SWI images were acquired on a 1.5 T MR scanner. Volumes of the DN and cerebellum were assessed at 7 and 1.5 T, respectively. Parametric maps of T2 and T2* sequences were created and proton transverse relaxation rates were estimated as a measure of iron content. Results In FA, the DN and the cerebellum were significantly smaller compared to controls. However, proton transverse relaxation rates of the DN were not significantly different between both groups. Conclusions Applying in vivo MRI methods we could demonstrate significant atrophy of the DN in the presence of normal iron content. The findings suggest that relaxation rates are not reliable biomarkers in clinical trials evaluating the potential effect of FA therapy. © 2014 The Authors. Published by Elsevier Inc. OA gold

Published

2014

7. Model-based iterative reconstruction for single-shot EPI at 7T

Author

Uten, Yarach, Myung-Ho, In, Itthi, Chatnuntawech, Berkin, Bilgic, Frank, Godenschweger, Hendrik, Mattern, Alessandro, Sciarra, and Oliver, Speck

Subjects

Adult, Male, Models, Statistical, Fourier Analysis, Echo-Planar Imaging, Phantoms, Imaging, Brain, Equipment Design, Signal-To-Noise Ratio, Magnetic Resonance Imaging, Article, methods [Echo-Planar Imaging], methods [Image Processing, Computer-Assisted], Calibration, Image Processing, Computer-Assisted, Humans, Computer Simulation, Female, ddc:610, Artifacts, diagnostic imaging [Brain], Algorithms, Software, Signal Transduction

Abstract

To describe a model-based reconstruction strategy for single-shot echo planar imaging (EPI) that intrinsically accounts for k-space nonuniformity, Nyquist ghosting, and geometric distortions during rather than before or after image reconstruction.Ramp sampling and inhomogeneous B0 field-induced distortion cause the EPI samples to lie on a non-Cartesian grid, thus requiring the nonuniform fast Fourier transform. Additionally, a 2D Nyquist ghost phase correction without the need for extra navigator acquisition is included in the proposed reconstruction. Coil compression is also incorporated to reduce the computational load. The proposed method is applied to phantom and human brain MRI data.The results demonstrate that Nyquist ghosting and geometric distortions are reduced by the proposed reconstruction. The proposed 2D phase correction is superior to a conventional 1D correction. The reductions of both artifacts lead to improved temporal signal-to-noise ratio (tSNR). The virtual coil results suggest that the processing time can be reduced by up to 75%, with a mean tSNR loss of only 3.2% when using 8-virtual instead of 32-physical coils for twofold undersampled data.The proposed reconstruction improves the quality (ghosting, geometry, and tSNR) of EPI without requiring calibration data for Nyquist ghost correction. Magn Reson Med 78:2250-2264, 2017. © 2017 International Society for Magnetic Resonance in Medicine.

Published

2017

8. High-resolution distortion-free diffusion imaging using hybrid spin-warp and echo-planar PSF-encoding approach

Author

Oliver Speck, Myung-Ho In, and Oleg Posnansky

Subjects

Point spread function, Cognitive Neuroscience, Phase (waves), Neuroimaging, Multimodal Imaging, methods [Echo-Planar Imaging], 030218 nuclear medicine & medical imaging, 03 medical and health sciences, Motion, 0302 clinical medicine, Dimension (vector space), Encoding (memory), methods [Image Processing, Computer-Assisted], methods [Diffusion Magnetic Resonance Imaging], Image Processing, Computer-Assisted, Humans, Computer vision, ddc:610, Diffusion (business), Physics, Brain Mapping, Echo-Planar Imaging, business.industry, Resolution (electron density), Echo (computing), Image Enhancement, Diffusion Magnetic Resonance Imaging, Neurology, Ultra high frequency, Artificial intelligence, methods [Image Enhancement], business, Artifacts, methods [Neuroimaging], 030217 neurology & neurosurgery, Algorithms

Abstract

High-resolution diffusion-weighted imaging (DWI) has great potential to provide unique information about tissue microstructure in-vivo. Although single-shot echo-planar imaging (EPI) is a most popular tool for DWI, its application for high-resolution DWI is limited due to T2* blurring and susceptibility- and eddy-current-induced geometric distortions, especially at ultra-high field (UHF) such as 7T. In this study, we adapt a hybrid spin-warp and echo-planar encoding strategy inspired by point spread function (PSF) mapping and optimize it for high-resolution and distortion-free diffusion imaging applications. More specifically, a 2D navigator echo is added into the original sequence for shot-to-shot motion-induced phase error estimation and correction. The spatial encoding is shared between the PSF and the EPI phase encoding dimension allowing short echo trains to preserve the diffusion and navigator signals efficiently at UHF, where T2 decay is relatively fast. In addition, variable k-space spacing was applied in the PSF dimension and combined with parallel imaging in the EPI-PE dimension to further accelerate the PSF acquisition. The results demonstrate that this method can yield isotropic submillimeter resolution without T2* blurring and geometric distortions at 7T and enables a clear and detailed delineation of human brain structures in-vivo with the diffusion contrasts. In addition, results of the proposed approach for high-resolution diffusion imaging at 3T are presented.

Published

2017

9. High-resolution diffusion MRI at 7T using a three-dimensional multi-slab acquisition

Author

Wu, W, Poser, B, Douaud, G, Frost, S, In, M, Speck, O, Koopmans, P, Miller, K, MRI, and RS: FPN CN 5

Subjects

7T, Echo-Planar Imaging, Cognitive Neuroscience, Physics::Medical Physics, Brain, methods [Image Interpretation, Computer-Assisted], methods [Diffusion Tensor Imaging], methods [Echo-Planar Imaging], Article, Diffusion, Multi-slab, Diffusion Tensor Imaging, Neurology, Image Interpretation, Computer-Assisted, Humans, High resolution, ddc:610, diagnostic imaging [Brain], Tractography, 3D

Abstract

High-resolution diffusion MRI can provide the ability to resolve small brain structures, enabling investigations of detailed white matter architecture. A major challenge for in vivo high-resolution diffusion MRI is the low signal-to-noise ratio. In this work, we combine two highly compatible methods, ultra-high field and three-dimensional multi-slab acquisition to improve the SNR of high-resolution diffusion MRI. As each kz plane is encoded using a single-shot echo planar readout, scan speeds of the proposed technique are similar to the commonly used two-dimensional diffusion MRI. In-plane parallel acceleration is applied to reduce image distortions. To reduce the sensitivity of auto-calibration signal data to subject motion and respiration, several new adaptions of the fast low angle excitation echo-planar technique (FLEET) that are suitable for 3D multi-slab echo planar imaging are proposed and evaluated. A modified reconstruction scheme is proposed for auto-calibration with the most robust method, Slice-FLEET acquisition, to make it compatible with navigator correction of motion induced phase errors. Slab boundary artefacts are corrected using the nonlinear slab profile encoding method recently proposed by our group. In vivo results demonstrate that using 7T and three-dimensional multi-slab acquisition with improved auto-calibration signal acquisition and nonlinear slab boundary artefacts correction, high-quality diffusion MRI data with ~1 mm isotropic resolution can be achieved., Highlights • High-resolution (1 mm) in vivo diffusion MRI with high SNR. • 3D multi-slab acquisition at 7T for high SNR efficiency. • Motion-robust parallel imaging kernel for 3D multi-slab acquisition. • Reducing slab boundary artefacts using nonlinear slab profile encoding. • High-quality fibre tractography with excellent anatomical fidelity.

Published

2016

10. Rapid fat suppression for three-dimensional echo planar imaging with minimized specific absorption rate

Author

Stirnberg, Rüdiger, Brenner, Daniel, Stöcker, Tony, and Shah, N Jon

Subjects

diagnostic imaging [Body Water], Echo-Planar Imaging, Absorption, Radiation, Brain, Signal Processing, Computer-Assisted, methods [Image Interpretation, Computer-Assisted], Image Enhancement, Magnetic Resonance Imaging, Sensitivity and Specificity, methods [Echo-Planar Imaging], physiology [Brain], methods [Magnetic Resonance Imaging], Imaging, Three-Dimensional, Adipose Tissue, Body Water, Subtraction Technique, Image Interpretation, Computer-Assisted, diagnostic imaging [Adipose Tissue], Humans, ddc:610, methods [Image Enhancement], diagnostic imaging [Brain], Algorithms, methods [Imaging, Three-Dimensional]

Abstract

To investigate a method for rapid water excitation with minimal radiofrequency power deposition for efficient functional MRI at ultrahigh fields.The suitability of the spectral response of a single rectangular radiofrequency pulse (rect) as a replacement of conventional fat saturation in segmented three-dimensional (3D) echo planar imaging (EPI) is explored. A pulse duration formula for lipid signal nulling independent of the small-tip-angle approximation is derived and tested by means of simulations and experiments at 3 and 7 Tesla (T).Compared with conventional binomial-11 water excitation, the single rect method is more selective and less sensitive to shim imperfections. In functional MRI, a significant measurement speedup (25%) and specific absorption rate reduction (from 44% to 1% at 7T) compared with conventional fat saturation are achieved. Furthermore, magnetization transfer effects are reduced resulting in up to 25% higher brain tissue signal-to-noise ratio.The proposed method is well suited for whole-brain functional MRI, not only at ultra-high fields, as it maximizes the sensitivity per unit time and at the same time minimizes radiofrequency power deposition. It requires little implementation effort and may thus be used in other spatially nonselective imaging methods that require fat suppression at minimal specific absorption rate and time requirements. Magn Reson Med 76:1517-1523, 2016. © 2015 International Society for Magnetic Resonance in Medicine.

Published

2015

11. Prevention of motion-induced signal loss in diffusion-weighted echo-planar imaging by dynamic restoration of gradient moments

Author

Kazim, Gumus, Brian, Keating, Benedikt A, Poser, Brian, Armstrong, Linda, Chang, Julian, Maclaren, Thomas, Prieto, Oliver, Speck, Maxim, Zaitsev, and Thomas, Ernst

Subjects

Echo-Planar Imaging, Phantoms, Imaging, Reproducibility of Results, Signal Processing, Computer-Assisted, Article, methods [Echo-Planar Imaging], Healthy Volunteers, Motion, Diffusion Magnetic Resonance Imaging, Head Movements, methods [Image Processing, Computer-Assisted], methods [Diffusion Magnetic Resonance Imaging], Image Processing, Computer-Assisted, Humans, ddc:610

Abstract

PURPOSE: Head motion is a significant problem in diffusion-weighted imaging as it may cause signal attenuation due to residual dephasing during strong diffusion encoding gradients even in single-shot acquisitions. Here, we present a new real-time method to prevent motion-induced signal loss in DWI of the brain. METHODS: The method requires a fast motion tracking system (optical in the current implementation). Two alterations were made to a standard diffusion-weighted echo-planar imaging sequence: first, real-time motion correction ensures that slices are correctly aligned relative to the moving brain. Second, the tracking data are used to calculate the motion-induced gradient moment imbalance which occurs during the diffusion encoding periods, and a brief gradient blip is inserted immediately prior to the signal readout to restore the gradient moment balance. RESULTS: Phantom experiments show that the direction as well as magnitude of the gradient moment imbalance affects the characteristics of unwanted signal attenuation. In human subjects, the addition of a moment-restoring blip prevented signal loss and improved the reproducibility and reliability of diffusion tensor measures even in the presence of substantial head movements. CONCLUSION: The method presented can improve robustness for clinical routine scanning in populations that are prone to head movements, such as children and uncooperative adult patients.

Published

2014

12. Fear Processing and Social Networking in the Absence of a Functional Amygdala

Author

Benjamin Becker, Horst Urbach, Yoan Mihov, Merve Aydin, Thomas E. Schlaepfer, Dirk Scheele, Justin S. Feinstein, Harald Reich, Wolfram S. Kunz, Ana-Maria Oros-Peusquens, Wolfgang Maier, Karl Zilles, René Hurlemann, N. J. Shah, Keith M. Kendrick, and Andreas Matusch

Subjects

Reflex, Startle, Adolescent, media_common.quotation_subject, physiopathology [Amygdala], psychology [Fear], Empathy, physiopathology [Brain], Amygdala, methods [Echo-Planar Imaging], psychology [Twins, Monozygotic], Premotor cortex, methods [Brain Mapping], methods [Magnetic Resonance Imaging], Mental Processes, medicine, Humans, ddc:610, Social Behavior, Biological Psychiatry, Mirror neuron, media_common, Facial expression, Brain Mapping, medicine.diagnostic_test, Echo-Planar Imaging, Brain, Inferior parietal lobule, Recognition, Psychology, Fear, Twins, Monozygotic, physiopathology [Lipoid Proteinosis of Urbach and Wiethe], Magnetic Resonance Imaging, Facial Expression, medicine.anatomical_structure, Lipoid Proteinosis of Urbach and Wiethe, Social competence, Female, Functional magnetic resonance imaging, Psychology, Neuroscience, Cognitive psychology

Abstract

Background The human amygdala plays a crucial role in processing social signals, such as face expressions, particularly fearful ones, and facilitates responses to them in face-sensitive cortical regions. This contributes to social competence and individual amygdala size correlates with that of social networks. While rare patients with focal bilateral amygdala lesion typically show impaired recognition of fearful faces, this deficit is variable, and an intriguing possibility is that other brain regions can compensate to support fear and social signal processing. Methods To investigate the brain's functional compensation of selective bilateral amygdala damage, we performed a series of behavioral, psychophysiological, and functional magnetic resonance imaging experiments in two adult female monozygotic twins (patient 1 and patient 2) with equivalent, extensive bilateral amygdala pathology as a sequela of lipoid proteinosis due to Urbach-Wiethe disease. Results Patient 1, but not patient 2, showed preserved recognition of fearful faces, intact modulation of acoustic startle responses by fear-eliciting scenes, and a normal-sized social network. Functional magnetic resonance imaging revealed that patient 1 showed potentiated responses to fearful faces in her left premotor cortex face area and bilaterally in the inferior parietal lobule. Conclusions The premotor cortex face area and inferior parietal lobule are both implicated in the cortical mirror-neuron system, which mediates learning of observed actions and may thereby promote both imitation and empathy. Taken together, our findings suggest that despite the pre-eminent role of the amygdala in processing social information, the cortical mirror-neuron system may sometimes adaptively compensate for its pathology.