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33 results on '"Szczepankiewicz, Filip"'

1. In vivo diffusion MRI of the human heart using a 300 mT/m gradient system

Author

Afzali, Maryam, primary, Mueller, Lars, additional, Coveney, Sam, additional, Fasano, Fabrizio, additional, Evans, Christopher John, additional, Engel, Maria, additional, Szczepankiewicz, Filip, additional, Teh, Irvin, additional, Dall'Armellina, Erica, additional, Jones, Derek K., additional, and Schneider, Jürgen E., additional

Published
2024
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2. Diffusion‐weighted MR spectroscopy: Consensus, recommendations, and resources from acquisition to modeling

Author

Ligneul, Clémence, primary, Najac, Chloé, additional, Döring, André, additional, Beaulieu, Christian, additional, Branzoli, Francesca, additional, Clarke, William T., additional, Cudalbu, Cristina, additional, Genovese, Guglielmo, additional, Jbabdi, Saad, additional, Jelescu, Ileana, additional, Karampinos, Dimitrios, additional, Kreis, Roland, additional, Lundell, Henrik, additional, Marjańska, Małgorzata, additional, Möller, Harald E., additional, Mosso, Jessie, additional, Mougel, Eloïse, additional, Posse, Stefan, additional, Ruschke, Stefan, additional, Simsek, Kadir, additional, Szczepankiewicz, Filip, additional, Tal, Assaf, additional, Tax, Chantal, additional, Oeltzschner, Georg, additional, Palombo, Marco, additional, Ronen, Itamar, additional, and Valette, Julien, additional

Published
2023
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3. Human prostate MRI at ultrahigh‐performance gradient: A feasibility study

Author

Zhu, Ante, primary, Tarasek, Matthew, additional, Hua, Yihe, additional, Fiveland, Eric, additional, Maier, Stephan E., additional, Mazaheri, Yousef, additional, Fung, Maggie, additional, Westin, Carl‐Fredrik, additional, Yeo, Desmond T. B., additional, Szczepankiewicz, Filip, additional, Tempany, Clare, additional, Akin, Oguz, additional, and Foo, Thomas K. F., additional

Published
2023
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4. Cardiac q‐space trajectory imaging by motion‐compensated tensor‐valued diffusion encoding in human heart in vivo

Author

Teh, Irvin, primary, Shelley, David, additional, Boyle, Jordan H., additional, Zhou, Fenglei, additional, Poenar, Ana‐Maria, additional, Sharrack, Noor, additional, Foster, Richard J., additional, Yuldasheva, Nadira Y., additional, Parker, Geoff J. M., additional, Dall'Armellina, Erica, additional, Plein, Sven, additional, Schneider, Jürgen E., additional, and Szczepankiewicz, Filip, additional

Published
2023
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5. A preliminary choroid plexus volumetric study in individuals with psychosis

Author

Senay, Olcay, primary, Seethaler, Magdalena, additional, Makris, Nikos, additional, Yeterian, Edward, additional, Rushmore, Jarrett, additional, Cho, Kang Ik K., additional, Rizzoni, Elizabeth, additional, Heller, Carina, additional, Pasternak, Ofer, additional, Szczepankiewicz, Filip, additional, Westin, Carl‐Frederik, additional, Losak, Jan, additional, Ustohal, Libor, additional, Tomandl, Josef, additional, Vojtisek, Lubomir, additional, Kudlicka, Peter, additional, Kikinis, Zora, additional, Holt, Daphne, additional, Lewandowski, Kathryn E., additional, Lizano, Paulo, additional, Keshavan, Matcheri S., additional, Öngür, Dost, additional, Kasparek, Tomas, additional, Breier, Alan, additional, Shenton, Martha E., additional, Seitz‐Holland, Johanna, additional, and Kubicki, Marek, additional

Published
2023
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9. Motion-compensated gradient waveforms for tensor-valued diffusion encoding by constrained numerical optimization

Author

Szczepankiewicz, Filip, Sjölund, Jens, Dall'Armellina, Erica, Plein, Sven, Schneider, Jürgen E., Teh, Irvin, Westin, Carl-Fredrik, Szczepankiewicz, Filip, Sjölund, Jens, Dall'Armellina, Erica, Plein, Sven, Schneider, Jürgen E., Teh, Irvin, and Westin, Carl-Fredrik

Abstract

Purpose Diffusion-weighted MRI is sensitive to incoherent tissue motion, which may confound the measured signal and subsequent analysis. We propose a "motion-compensated" gradient waveform design for tensor-valued diffusion encoding that negates the effects bulk motion and incoherent motion in the ballistic regime. Methods Motion compensation was achieved by constraining the magnitude of gradient waveform moment vectors. The constraint was incorporated into a numerical optimization framework, along with existing constraints that account for b-tensor shape, hardware restrictions, and concomitant field gradients. We evaluated the efficacy of encoding and motion compensation in simulations, and we demonstrated the approach by linear and planar b-tensor encoding in a healthy heart in vivo. Results The optimization framework produced asymmetric motion-compensated waveforms that yielded b-tensors of arbitrary shape with improved efficiency compared with previous designs for tensor-valued encoding, and equivalent efficiency to previous designs for linear (conventional) encoding. Technical feasibility was demonstrated in the heart in vivo, showing vastly improved data quality when using motion compensation. The optimization framework is available online in open source. Conclusion Our gradient waveform design is both more flexible and efficient than previous methods, facilitating tensor-valued diffusion encoding in tissues in which motion would otherwise confound the signal. The proposed design exploits asymmetric encoding times, a single refocusing pulse or multiple refocusing pulses, and integrates compensation for concomitant gradient effects throughout the imaging volume.

Published
2021
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23. Compartmental anisotropy of filtered exchange imaging (FEXI) in human white matter: What is happening in FEXI?

Author

Shin HG, Li X, Heo HY, Knutsson L, Szczepankiewicz F, Nilsson M, and van Zijl PCM

Subjects
Humans, Anisotropy, Adult, Male, Female, Algorithms, Brain diagnostic imaging, Diffusion Magnetic Resonance Imaging methods, Reproducibility of Results, Image Processing, Computer-Assisted methods, White Matter diagnostic imaging, Diffusion Tensor Imaging methods
Abstract

Purpose: To investigate the effects of compartmental anisotropy on filtered exchange imaging (FEXI) in white matter (WM)., Theory and Methods: FEXI signals were measured using multiple combinations of diffusion filter and detection directions in five healthy volunteers. Additional filters, including a trace-weighted diffusion filter with trapezoidal gradients, a spherical b-tensor encoded diffusion filter, and a T2 filter, were tested with trace-weighted diffusion detection., Results: A large range of apparent exchange rates (AXR) and both positive and negative filter efficiencies (σ) were found depending on the mutual orientation of the filter and detection gradients relative to WM fiber orientation. The data demonstrated that the fast-diffusion compartment suppressed by diffusional filtering is not exclusively extra-cellular, but also intra-cellular. While not comprehensive, a simple two-compartment diffusion tensor model with water exchange was able to account qualitatively for the trends in positive and negative filtering efficiencies, while standard model imaging (SMI) without exchange could not. This two-compartment diffusion tensor model also demonstrated smaller AXR variances across subjects. When employing trace-weighted diffusion detection, AXR values were on the order of the R 1 (=1/T1) of water at 3T for crossing fibers, while being less than R 1 for parallel fibers., Conclusion: Orientation-dependent AXR and σ values were observed when using multi-orientation filter and detection gradients in FEXI, indicating that WM FEXI models need to account for compartmental anisotropy. When using trace-weighted detection, AXR values were on the order of or less than R 1 , complicating the interpretation of FEXI results in WM in terms of biological exchange properties. These findings may contribute toward better understanding of FEXI results in WM., (© 2024 International Society for Magnetic Resonance in Medicine.)

Published
2024
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24. Tensor-valued diffusion MRI of human acute stroke.

Author

Zhou M, Stobbe R, Szczepankiewicz F, Budde M, Buck B, Kate M, Lloret M, Fairall P, Butcher K, Shuaib A, Emery D, Nilsson M, Westin CF, and Beaulieu C

Subjects
Humans, Diffusion Tensor Imaging methods, Diffusion Magnetic Resonance Imaging methods, Anisotropy, Brain diagnostic imaging, Brain pathology, Ischemic Stroke pathology, White Matter pathology, Stroke diagnostic imaging
Abstract

Purpose: Tensor-valued diffusion encoding can disentangle orientation dispersion and subvoxel anisotropy, potentially offering insight into microstructural changes after cerebral ischemia. The purpose was to evaluate tensor-valued diffusion MRI in human acute ischemic stroke, assess potential confounders from diffusion time dependencies, and compare to Monte Carlo diffusion simulations of axon beading., Methods: Linear (LTE) and spherical (STE) b-tensor encoding with inherently different effective diffusion times were acquired in 21 acute ischemic stroke patients between 3 and 57 h post-onset at 3 T in 2.5 min. In an additional 10 patients, STE with 2 LTE yielding different effective diffusion times were acquired for comparison. Diffusional variance decomposition (DIVIDE) was used to estimate microscopic anisotropy (μFA), as well as anisotropic, isotropic, and total diffusional variance (MK A , MK I , MK T ). DIVIDE parameters, and diffusion tensor imaging (DTI)-derived mean diffusivity and fractional anisotropy (FA) were compared in lesion versus contralateral white matter. Monte Carlo diffusion simulations of various cylindrical geometries for all b-tensor protocols were used to interpret parameter measurements., Results: MD was ˜40% lower in lesions for all LTE/STE protocols. The DIVIDE parameters varied with effective diffusion time: higher μFA and MK A in lesion versus contralateral white matter for STE with longer effective diffusion time LTE, whereas the shorter effective diffusion time LTE protocol yielded lower μFA and MK A in lesions. Both protocols, regardless of diffusion time, were consistent with simulations of greater beading amplitude and intracellular volume fraction., Conclusion: DIVIDE parameters depend on diffusion time in acute stroke but consistently indicate neurite beading and larger intracellular volume fraction., (© 2023 The Authors. Magnetic Resonance in Medicine published by Wiley Periodicals LLC on behalf of International Society for Magnetic Resonance in Medicine.)

Published
2024
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25. Diffusion-weighted MR spectroscopy: Consensus, recommendations, and resources from acquisition to modeling.

Author

Ligneul C, Najac C, Döring A, Beaulieu C, Branzoli F, Clarke WT, Cudalbu C, Genovese G, Jbabdi S, Jelescu I, Karampinos D, Kreis R, Lundell H, Marjańska M, Möller HE, Mosso J, Mougel E, Posse S, Ruschke S, Simsek K, Szczepankiewicz F, Tal A, Tax C, Oeltzschner G, Palombo M, Ronen I, and Valette J

Subjects
Consensus, Magnetic Resonance Spectroscopy methods, Diffusion, Brain metabolism, Diffusion Magnetic Resonance Imaging methods
Abstract

Brain cell structure and function reflect neurodevelopment, plasticity, and aging; and changes can help flag pathological processes such as neurodegeneration and neuroinflammation. Accurate and quantitative methods to noninvasively disentangle cellular structural features are needed and are a substantial focus of brain research. Diffusion-weighted MRS (dMRS) gives access to diffusion properties of endogenous intracellular brain metabolites that are preferentially located inside specific brain cell populations. Despite its great potential, dMRS remains a challenging technique on all levels: from the data acquisition to the analysis, quantification, modeling, and interpretation of results. These challenges were the motivation behind the organization of the Lorentz Center workshop on "Best Practices & Tools for Diffusion MR Spectroscopy" held in Leiden, the Netherlands, in September 2021. During the workshop, the dMRS community established a set of recommendations to execute robust dMRS studies. This paper provides a description of the steps needed for acquiring, processing, fitting, and modeling dMRS data, and provides links to useful resources., (© 2023 The Authors. Magnetic Resonance in Medicine published by Wiley Periodicals LLC on behalf of International Society for Magnetic Resonance in Medicine.)

Published
2024
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26. Human prostate MRI at ultrahigh-performance gradient: A feasibility study.

Author

Zhu A, Tarasek M, Hua Y, Fiveland E, Maier SE, Mazaheri Y, Fung M, Westin CF, Yeo DTB, Szczepankiewicz F, Tempany C, Akin O, and Foo TKF

Subjects
Male, Humans, Middle Aged, Aged, Prostate diagnostic imaging, Feasibility Studies, Diffusion Magnetic Resonance Imaging methods, Echo-Planar Imaging methods, Reproducibility of Results, Magnetic Resonance Imaging, Prostatic Neoplasms diagnostic imaging
Abstract

Purpose: To demonstrate the technical feasibility and the value of ultrahigh-performance gradient in imaging the prostate in a 3T MRI system., Methods: In this local institutional review board-approved study, prostate MRI was performed on 4 healthy men. Each subject was scanned in a prototype 3T MRI system with a 42-cm inner-diameter gradient coil that achieves a maximum gradient amplitude of 200 mT/m and slew rate of 500 T/m/s. PI-RADS V2.1-compliant axial T 2 -weighted anatomical imaging and single-shot echo planar DWI at standard gradient of 70 mT/m and 150 T/m/s were obtained, followed by DWI at maximum performance (i.e., 200 mT/m and 500 T/m/s). In comparison to state-of-the-art clinical whole-body MRI systems, the high slew rate improved echo spacing from 1020 to 596 μs and, together with a high gradient amplitude for diffusion encoding, TE was reduced from 55 to 36 ms., Results: In all 4 subjects (waist circumference = 81-91 cm, age = 45-65 years), no peripheral nerve stimulation sensation was reported during DWI. Reduced image distortion in the posterior peripheral zone prostate gland and higher signal intensity, such as in the surrounding muscle of high-gradient DWI, were noted., Conclusion: Human prostate MRI at simultaneously high gradient amplitude of 200 mT/m and slew rate of 500 T/m/s is feasible, demonstrating that improved gradient performance can address image distortion and T 2 decay-induced SNR issues for in vivo prostate imaging., (© 2023 International Society for Magnetic Resonance in Medicine.)

Published
2024
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27. Optimal experimental design and estimation for q-space trajectory imaging.

Author

Morez J, Szczepankiewicz F, den Dekker AJ, Vanhevel F, Sijbers J, and Jeurissen B

Subjects
Humans, Algorithms, Diffusion Magnetic Resonance Imaging methods, Least-Squares Analysis, Brain diagnostic imaging, Research Design
Abstract

Tensor-valued diffusion encoding facilitates data analysis by q-space trajectory imaging. By modeling the diffusion signal of heterogeneous tissues with a diffusion tensor distribution (DTD) and modulating the encoding tensor shape, this novel approach allows disentangling variations in diffusivity from microscopic anisotropy, orientation dispersion, and mixtures of multiple isotropic diffusivities. To facilitate the estimation of the DTD parameters, a parsimonious acquisition scheme coupled with an accurate and precise estimation of the DTD is needed. In this work, we create two precision-optimized acquisition schemes: one that maximizes the precision of the raw DTD parameters, and another that maximizes the precision of the scalar measures derived from the DTD. The improved precision of these schemes compared to a naïve sampling scheme is demonstrated in both simulations and real data. Furthermore, we show that the weighted linear least squares (WLLS) estimator that uses the squared reciprocal of the noisy signal as weights can be biased, whereas the iteratively WLLS estimator with the squared reciprocal of the predicted signal as weights outperforms the conventional unweighted linear LS and nonlinear LS estimators in terms of accuracy and precision. Finally, we show that the use of appropriate constraints can considerably increase the precision of the estimator with only a limited decrease in accuracy., (© 2022 The Authors. Human Brain Mapping published by Wiley Periodicals LLC.)

Published
2023
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28. Diffusion MRI with pulsed and free gradient waveforms: Effects of restricted diffusion and exchange.

Author

Chakwizira A, Westin CF, Brabec J, Lasič S, Knutsson L, Szczepankiewicz F, and Nilsson M

Abstract

Monitoring time dependence with diffusion MRI yields observables sensitive to compartment sizes (restricted diffusion) and membrane permeability (water exchange). However, restricted diffusion and exchange have opposite effects on the diffusion-weighted signal, which can lead to errors in parameter estimates. In this work, we propose a signal representation that incorporates the effects of both restricted diffusion and exchange up to second order in b-value and is compatible with gradient waveforms of arbitrary shape. The representation features mappings from a gradient waveform to two scalars that separately control the sensitivity to restriction and exchange. We demonstrate that these scalars span a two-dimensional space that can be used to choose waveforms that selectively probe restricted diffusion or exchange, eliminating the correlation between the two phenomena. We found that waveforms with specific but unconventional shapes provide an advantage over conventional pulsed and oscillating gradient acquisitions. We also show that parametrization of waveforms into a two-dimensional space can be used to understand protocols from other approaches that probe restricted diffusion and exchange. For example, we found that the variation of mixing time in filter-exchange imaging corresponds to variation of our exchange-weighting scalar at a fixed value of the restriction-weighting scalar. The proposed signal representation was evaluated using Monte Carlo simulations in identical parallel cylinders with hexagonal and random packing as well as parallel cylinders with gamma-distributed radii. Results showed that the approach is sensitive to sizes in the interval 4-12 μm and exchange rates in the simulated range of 0 to 20 s - 1 , but also that there is a sensitivity to the extracellular geometry. The presented theory constitutes a simple and intuitive description of how restricted diffusion and exchange influence the signal as well as a guide to protocol design capable of separating the two effects., (© 2022 The Authors. NMR in Biomedicine published by John Wiley & Sons Ltd.)

Published
2023
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29. Motion-compensated gradient waveforms for tensor-valued diffusion encoding by constrained numerical optimization.

Author

Szczepankiewicz F, Sjölund J, Dall'Armellina E, Plein S, Schneider JE, Teh I, and Westin CF

Subjects
Diffusion, Heart diagnostic imaging, Motion, Diffusion Magnetic Resonance Imaging, Image Processing, Computer-Assisted
Abstract

Purpose: Diffusion-weighted MRI is sensitive to incoherent tissue motion, which may confound the measured signal and subsequent analysis. We propose a "motion-compensated" gradient waveform design for tensor-valued diffusion encoding that negates the effects bulk motion and incoherent motion in the ballistic regime., Methods: Motion compensation was achieved by constraining the magnitude of gradient waveform moment vectors. The constraint was incorporated into a numerical optimization framework, along with existing constraints that account for b-tensor shape, hardware restrictions, and concomitant field gradients. We evaluated the efficacy of encoding and motion compensation in simulations, and we demonstrated the approach by linear and planar b-tensor encoding in a healthy heart in vivo., Results: The optimization framework produced asymmetric motion-compensated waveforms that yielded b-tensors of arbitrary shape with improved efficiency compared with previous designs for tensor-valued encoding, and equivalent efficiency to previous designs for linear (conventional) encoding. Technical feasibility was demonstrated in the heart in vivo, showing vastly improved data quality when using motion compensation. The optimization framework is available online in open source., Conclusion: Our gradient waveform design is both more flexible and efficient than previous methods, facilitating tensor-valued diffusion encoding in tissues in which motion would otherwise confound the signal. The proposed design exploits asymmetric encoding times, a single refocusing pulse or multiple refocusing pulses, and integrates compensation for concomitant gradient effects throughout the imaging volume., (© 2020 The Authors. Magnetic Resonance in Medicine published by Wiley Periodicals LLC on behalf of International Society for Magnetic Resonance in Medicine.)

Published
2021
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30. Computing and visualising intra-voxel orientation-specific relaxation-diffusion features in the human brain.

Author

de Almeida Martins JP, Tax CMW, Reymbaut A, Szczepankiewicz F, Chamberland M, Jones DK, and Topgaard D

Subjects
Brain physiology, Databases, Factual, Humans, Monte Carlo Method, White Matter physiology, Algorithms, Brain diagnostic imaging, Computer Simulation, Diffusion Magnetic Resonance Imaging methods, White Matter diagnostic imaging
Abstract

Diffusion MRI techniques are used widely to study the characteristics of the human brain connectome in vivo. However, to resolve and characterise white matter (WM) fibres in heterogeneous MRI voxels remains a challenging problem typically approached with signal models that rely on prior information and constraints. We have recently introduced a 5D relaxation-diffusion correlation framework wherein multidimensional diffusion encoding strategies are used to acquire data at multiple echo-times to increase the amount of information encoded into the signal and ease the constraints needed for signal inversion. Nonparametric Monte Carlo inversion of the resulting datasets yields 5D relaxation-diffusion distributions where contributions from different sub-voxel tissue environments are separated with minimal assumptions on their microscopic properties. Here, we build on the 5D correlation approach to derive fibre-specific metrics that can be mapped throughout the imaged brain volume. Distribution components ascribed to fibrous tissues are resolved, and subsequently mapped to a dense mesh of overlapping orientation bins to define a smooth orientation distribution function (ODF). Moreover, relaxation and diffusion measures are correlated to each independent ODF coordinate, thereby allowing the estimation of orientation-specific relaxation rates and diffusivities. The proposed method is tested on a healthy volunteer, where the estimated ODFs were observed to capture major WM tracts, resolve fibre crossings, and, more importantly, inform on the relaxation and diffusion features along with distinct fibre bundles. If combined with fibre-tracking algorithms, the methodology presented in this work has potential for increasing the depth of characterisation of microstructural properties along individual WM pathways., (© 2020 The Authors. Human Brain Mapping published by Wiley Periodicals LLC.)

Published
2021
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31. Tensor-valued diffusion MRI in under 3 minutes: an initial survey of microscopic anisotropy and tissue heterogeneity in intracranial tumors.

Author

Nilsson M, Szczepankiewicz F, Brabec J, Taylor M, Westin CF, Golby A, van Westen D, and Sundgren PC

Subjects
Adult, Algorithms, Female, Humans, Image Processing, Computer-Assisted methods, Linear Models, Male, Middle Aged, Neoplasm Metastasis, Adenoma diagnostic imaging, Anisotropy, Brain diagnostic imaging, Brain Neoplasms diagnostic imaging, Diffusion Tensor Imaging, Glioma diagnostic imaging, Meningioma diagnostic imaging, Neuroimaging
Abstract

Purpose: To evaluate the feasibility of a 3-minutes protocol for assessment of the microscopic anisotropy and tissue heterogeneity based on tensor-valued diffusion MRI in a wide range of intracranial tumors., Methods: B-tensor encoding was performed in 42 patients with intracranial tumors (gliomas, meningiomas, adenomas, and metastases). Microscopic anisotropy and tissue heterogeneity were evaluated by estimating the anisotropic kurtosis (MK A ) and isotropic kurtosis (MK I ), respectively. An extensive imaging protocol was compared with a 3-minutes protocol., Results: The fast imaging protocol yielded parameters with characteristics in terms of bias and precision similar to the full protocol. Glioblastomas had lower microscopic anisotropy than meningiomas (MK A = 0.29 ± 0.06 vs. 0.45 ± 0.08, P = 0.003). Metastases had higher tissue heterogeneity (MK I = 0.57 ± 0.07) than both the glioblastomas (0.44 ± 0.06, P < 0.001) and meningiomas (0.46 ± 0.06, P = 0.03)., Conclusion: Evaluation of the microscopic anisotropy and tissue heterogeneity in intracranial tumor patients is feasible in clinically relevant times frames., (© 2019 The Authors. Magnetic Resonance in Medicine published by Wiley Periodicals, Inc. on behalf of International Society for Magnetic Resonance in Medicine.)

Published
2020
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32. Motion-compensated b-tensor encoding for in vivo cardiac diffusion-weighted imaging.

Author

Lasič S, Szczepankiewicz F, Dall'Armellina E, Das A, Kelly C, Plein S, Schneider JE, Nilsson M, and Teh I

Subjects
Animals, Diffusion, Humans, Phantoms, Imaging, Spin Labels, Swine, Diffusion Tensor Imaging, Heart diagnostic imaging, Motion
Abstract

Motion is a major confound in diffusion-weighted imaging (DWI) in the body, and it is a common cause of image artefacts. The effects are particularly severe in cardiac applications, due to the nonrigid cyclical deformation of the myocardium. Spin echo-based DWI commonly employs gradient moment-nulling techniques to desensitise the acquisition to velocity and acceleration, ie, nulling gradient moments up to the 2nd order (M2-nulled). However, current M2-nulled DWI scans are limited to encode diffusion along a single direction at a time. We propose a method for designing b-tensors of arbitrary shapes, including planar, spherical, prolate and oblate tensors, while nulling gradient moments up to the 2nd order and beyond. The design strategy comprises initialising the diffusion encoding gradients in two encoding blocks about the refocusing pulse, followed by appropriate scaling and rotation, which further enables nulling undesired effects of concomitant gradients. Proof-of-concept assessment of in vivo mean diffusivity (MD) was performed using linear and spherical tensor encoding (LTE and STE, respectively) in the hearts of five healthy volunteers. The results of the M2-nulled STE showed that (a) the sequence was robust to cardiac motion, and (b) MD was higher than that acquired using standard M2-nulled LTE, where diffusion-weighting was applied in three orthogonal directions, which may be attributed to the presence of restricted diffusion and microscopic diffusion anisotropy. Provided adequate signal-to-noise ratio, STE could significantly shorten estimation of MD compared with the conventional LTE approach. Importantly, our theoretical analysis and the proposed gradient waveform design may be useful in microstructure imaging beyond diffusion tensor imaging where the effects of motion must be suppressed., (© 2019 The Authors. NMR in Biomedicine published by John Wiley & Sons Ltd.)

Published
2020
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33. Liquid crystal phantom for validation of microscopic diffusion anisotropy measurements on clinical MRI systems.

Author

Nilsson M, Larsson J, Lundberg D, Szczepankiewicz F, Witzel T, Westin CF, Bryskhe K, and Topgaard D

Subjects
Anisotropy, Brain diagnostic imaging, Diffusion Magnetic Resonance Imaging methods, Humans, Models, Biological, Diffusion Magnetic Resonance Imaging instrumentation, Diffusion Magnetic Resonance Imaging standards, Liquid Crystals chemistry, Phantoms, Imaging
Abstract

Purpose: To develop a phantom for validating MRI pulse sequences and data processing methods to quantify microscopic diffusion anisotropy in the human brain., Methods: Using a liquid crystal consisting of water, detergent, and hydrocarbon, we designed a 0.5-L spherical phantom showing the theoretically highest possible degree of microscopic anisotropy. Data were acquired on the Connectome scanner using echo-planar imaging signal readout and diffusion encoding with axisymmetric b-tensors of varying magnitude, anisotropy, and orientation. The mean diffusivity, fractional anisotropy (FA), and microscopic FA (µFA) parameters were estimated., Results: The phantom was observed to have values of mean diffusivity similar to brain tissue, and relaxation times compatible with echo-planar imaging echo times on the order of 100 ms. The estimated values of µFA were at the theoretical maximum of 1.0, whereas the values of FA spanned the interval from 0.0 to 0.8 as a result of varying orientational order of the anisotropic domains within each voxel., Conclusions: The proposed phantom can be manufactured by mixing three widely available chemicals in volumes comparable to a human head. The acquired data are in excellent agreement with theoretical predictions, showing that the phantom is ideal for validating methods for measuring microscopic diffusion anisotropy on clinical MRI systems. Magn Reson Med 79:1817-1828, 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-NonCommercial License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited and is not used for commercial purposes., (© 2017 The Authors Magnetic Resonance in Medicine published by Wiley Periodicals, Inc. on behalf of International Society for Magnetic Resonance in Medicine.)

Published
2018
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