Your search keyword '"Phantoms, Imaging"' showing total 1,585 results

1. An unrolled neural network for accelerated dynamic MRI based on second-order half-quadratic splitting model.

Author

Sun J, Wang C, Guo L, Fang Y, Huang J, and Qiu B

Subjects

Humans, Brain diagnostic imaging, Deep Learning, Artifacts, Phantoms, Imaging, Magnetic Resonance Imaging methods, Algorithms, Image Processing, Computer-Assisted methods, Neural Networks, Computer

Abstract

The reconstruction of dynamic magnetic resonance images from incomplete k-space data has sparked significant research interest due to its potential to reduce scan time. However, traditional iterative optimization algorithms fail to faithfully reconstruct images at higher acceleration factors and incur long reconstruction time. Furthermore, end-to-end deep learning-based reconstruction algorithms suffer from large model parameters and lack robustness in the reconstruction results. Recently, unrolled deep learning models, have shown immense potential in algorithm stability and applicability flexibility. In this paper, we propose an unrolled deep learning network based on a second-order Half-Quadratic Splitting(HQS) algorithm, where the forward propagation process of this framework strictly follows the computational flow of the HQS algorithm. In particular, we propose a degradation-sense module by associating random sampling patterns with intermediate variables to guide the iterative process. We introduce the Information Fusion Transformer(IFT) to extract both local and non-local prior information from image sequences, thereby removing aliasing artifacts resulting from random undersampling. Finally, we impose low-rank constraints within the HQS algorithm to further enhance the reconstruction results. The experiments demonstrate that each component module of our proposed model contributes to the improvement of the reconstruction task. Our proposed method achieves comparably satisfying performance to the state-of-the-art methods and it exhibits excellent generalization capabilities across different sampling masks. At the low acceleration factor, there is a 0.7% enhancement in the PSNR. Furthermore, when the acceleration factor reached 8 and 12, the PSNR achieves an improvement of 3.4% and 5.8% respectively., (Copyright © 2024 Elsevier Inc. All rights reserved.)

Published

2024

2. Homogeneous B0 coil design method for open-access ultra-low field magnetic resonance imaging: A simulation study.

Author

Karasawa T, Saikawa J, Munaka T, and Kobayashi T

Subjects

Humans, Magnetoencephalography instrumentation, Magnetoencephalography methods, Brain diagnostic imaging, Phantoms, Imaging, Magnetic Fields, Electromagnetic Fields, Magnetic Resonance Imaging methods, Magnetic Resonance Imaging instrumentation, Equipment Design, Computer Simulation

Abstract

A multimodal brain function measurement system integrating functional magnetic resonance imaging (fMRI) and magnetoencephalography (MEG) is expected to be a tool that will provide new insights into neuroscience. To integrate fMRI and MEG, an ultra-low-field MRI (ULF-MRI) scanner that can generate a static magnetic field (B0) with an electromagnetic coil and turn off the B0 during MEG measurements is desirable. While electromagnetic B0 coil has the above advantages, it also has a trade-off between size and the broadness of the magnetic field homogeneity. In this study, we proposed a method for designing a B0 multi-stage circular coil arrangement that determines the number of coils required to maximize magnetic field homogeneity and minimize the total wiring length of the coils. The optimized multi-stage coil arrangement had an external shape of 600 mm in diameter and a maximum height of 600 mm, with an aperture of 600 mm in diameter and 300 mm in height. The magnetic field homogeneity was <100 ppm over a 210 mm diameter spherical volume (DSV). Compared to a previous two coil pairs arrangement with the same magnetic field homogeneity, the diameter was 1/1.9 times smaller, indicating that the newly designed B0 coil arrangement realized a smaller size and wider magnetic field homogeneity., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Elsevier Inc. All rights reserved.)

Published

2024

3. Comparison and precision of visceral adipose tissue measurement techniques in a multisite longitudinal study using MRI.

Author

Barnes S, Kinne E, Chowdhury S, Loong S, Moretz J, and Sabate J

Subjects

Humans, Longitudinal Studies, Male, Female, Adult, Middle Aged, Prospective Studies, Reproducibility of Results, Phantoms, Imaging, Imaging, Three-Dimensional methods, Abdomen diagnostic imaging, Young Adult, Cross-Sectional Studies, Aged, Intra-Abdominal Fat diagnostic imaging, Magnetic Resonance Imaging methods

Abstract

Background: Measurement of visceral adipose tissue (VAT) using magnetic resonance imaging (MRI) is considered accurate and safe. Single slice measurements perform similar to volumetric measurements for cross-sectional observation studies but may not perform as well for longitudinal studies. This study compared the performance of single slice to volumetric VAT measurements in a prospective longitudinal study. Consistency of results across sites and over time was also evaluated., Methods: A total of 935 healthy participants were recruited and scanned with MRI twice, approximately six months apart as part of a randomized, controlled, parallel arm, unblinded study conducted at four clinical centers in the United States. A 3D Dixon MRI sequence was used to image the abdomen, and visceral fat volumes were quantified for the abdomen, reduced coverage volumes (11 and 25 slices), and at single slices positioned at anatomical landmarks. A traveling phantom was scanned twice at all imaging sites., Results: The correlation of single slice VAT measurement to full abdomen volumetric measurements ranged from 0.78 to 0.93 for cross-sectional observation measurements and 0.30 to 0.55 for longitudinal change. Reduced coverage volumetric measurement outperformed single slice measurements but still showed improved precision with more slices with cross-sectional observation and longitudinal correlations of 0.94 and 0.66 for 11 slices and 0.94 and 0.70 for 25 slices, respectively. No significant differences were observed across sites or over time with the traveling phantom and the volume measurements had a standard deviation of 14.1 mL, 2.6% of the measured volume., Conclusion: Single slice VAT measurements had significantly lower correlation with abdomen VAT volume for longitudinal change than for cross-sectional observation measurements and may not be suitable for longitudinal studies. Data from multiple sites, different scanners, and over time did not show significant differences., Competing Interests: Declaration of competing interest There are no conflicts of interest to declare., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

4. T1 mapping for Head and Neck Cancer Patients undergoing Chemoradiotherapy: Feasibility of 3D Stack of Star Imaging.

Author

Kim SE, Roberts JA, Kholmovski EG, Hitchcock Y, and Anzai Y

Subjects

Humans, Male, Middle Aged, Female, Reproducibility of Results, Aged, Adult, Oxygen, Artifacts, Head and Neck Neoplasms diagnostic imaging, Head and Neck Neoplasms therapy, Magnetic Resonance Imaging methods, Chemoradiotherapy, Feasibility Studies, Phantoms, Imaging, Imaging, Three-Dimensional methods

Abstract

Background: Measuring tissue oxygen concentration is crucial in understanding the pathophysiological process of hypoxia in head and neck cancer (HNC) and its significant role in cancer biology. This study aimed to determine the feasibility of T1 mapping using a variable flip angle (VFA) technique with stack of stars (SOS) trajectory sampling in HNC patients undergoing chemoradiotherapy (CRT)., Methods: To evaluate the ability of SOS acquisition to detect T1, a phantom study was conducted and compared to conventional Cartesian acquisition (CART). Additionally, four newly diagnosed patients were recruited and underwent two scans each at baseline and inter-treatment. The repeatability of SOS and CART acquisitions was assessed by comparing the T1 measurements of CSF from the baseline and intra-treatment MRI studies. The changes in ∆T1 of the tumors during air and oxygen inhalation between baseline and inter-treatment scans were also evaluated., Results: Our study found that the 3D VFA SOS sequence was effective in reducing motion artifacts compared to the conventional VFA sequence with CART sampling and the same scan time, as demonstrated by the results from the phantom and patient studies. In terms of repeatability, no significant correlation was observed between the variability in ΔT1 measurements of CSF obtained from SOS T1 maps. The SOS ΔT1 measurements showed higher consistency, as evidenced by the ICC values ranging from 0.52 to 0.92. The ∆T1 measurements on the primary tumors increased after the first CRT (p<0.05) for all patients who showed a positive treatment response, except for one patient (0.05

Published

2024

5. Multimodal surface coils for low field MR imaging.

Author

Zhao Y, Bhosale AA, and Zhang X

Subjects

Phantoms, Imaging, Computer Simulation, Reproducibility of Results, Humans, Radio Waves, Magnetic Fields, Magnetic Resonance Imaging instrumentation, Magnetic Resonance Imaging methods, Equipment Design, Signal-To-Noise Ratio

Abstract

Low field MRI is safer and more cost effective than the high field MRI. One of the inherent problems of low field MRI is its low signal-to-noise ratio or sensitivity. In this work, we introduce a multimodal surface coil technique for signal excitation and reception to improve the RF magnetic field (B 1 ) efficiency and potentially improve MR sensitivity. The proposed multimodal surface coil consists of multiple identical resonators that are electromagnetically coupled to form a multimodal resonator. The field distribution of its lowest frequency mode is suitable for MR imaging applications. The prototype multimodal surface coils are built, and the performance is investigated and validated through numerical simulation, standard RF measurements and tests, and comparison with the conventional surface coil at low fields. Our results show that the B 1 efficiency of the multimodal surface coil outperforms that of the conventional surface coil which is known to offer the highest B 1 efficiency among all coil categories, i.e., volume coil, half-volume coil and surface coil. In addition, in low-field MRI, the required low-frequency coils often use large value capacitance to achieve the low resonant frequency which makes frequency tuning difficult. The proposed multimodal surface coil can be conveniently tuned to the required low frequency for low-field MRI with significantly reduced capacitance value, demonstrating excellent low-frequency operation capability over the conventional surface coil., (Copyright © 2024. Published by Elsevier Inc.)

Published

2024

6. Improvement of image quality for bright-blood image in VISIBLE (volume isotropic simultaneous interleaved bright- and black-blood examination) by using k-space reordering and startup echoes.

Author

Wada T, Kikuchi K, Obara M, Tokunaga C, Yamashita K, Kobayashi K, Kato T, Ishigami K, and Togao O

Subjects

Humans, Female, Male, Middle Aged, Aged, Magnetic Resonance Imaging methods, Contrast Media, Image Processing, Computer-Assisted methods, Image Enhancement methods, Algorithms, Adult, Fourier Analysis, White Matter diagnostic imaging, Phantoms, Imaging, Signal-To-Noise Ratio

Abstract

Purpose: A volume isotropic simultaneous interleaved bright- and black-blood examination (VISIBLE) can simultaneously acquire images with suppressed vascular signals (black-blood images) and images without suppression (bright-blood images). We aimed to improve of the bright-blood images by adjusting the k-space filling and using startup echo., Methods: The k-space arrangement of bright-blood images in the conventional VISIBLE followed a low-to-high frequency order, whereas that in the proposed VISIBLE sequence was in the reversed order, and a startup echo was added. The effects of startup echo on the signal-to-noise ratio (SNR) were evaluated using phantoms, considering both white matter (WM) and post-contrast blood. Data from copper sulfate phantoms were acquired in 1D Fourier transform mode using both the conventional and proposed methods of the two VISIBLE sequences. The signal behavior with each sequence was evaluated. Fourteen patients with a total of 21 metastases were included in the study. For each patient, VISIBLE images of both conventional and proposed methods were obtained consecutively after the contrast agent administration. Using clinical images, we conducted a comparison of the SNR and contrast-to-noise ratio (CNR) for tumors, normal WM, and blood vessels between the conventional and proposed VISIBLE sequences., Results: There was no significant difference in SNRs for both black- and bright-blood images between the conventional sequence and the proposed sequence with different number of startup echoes, however, the SNR of the proposed sequence decreased with increasing number of startup echoes in both black- and bright-images. The signal behavior of the bright-blood image reached a "steady state" when the startup echo exceeded 20. The SNRs of blood vessels in the bright-blood images did not differ significantly between conventional and proposed VISIBLE sequences. The SNRs of WM in the bright-blood images was significantly larger in the conventional sequence than in the proposed sequence. The SNRs of tumors in bright blood images was significantly larger in the proposed sequence than in the conventional sequence. The CNRs between tumors and WM, vessels and WM in the bright-blood images were significantly higher in the proposed sequence than in the conventional sequence., Conclusion: The use of the startup echo in combination with the high-to-low frequency k-space ordering method resulted in improved CNR of the bright-blood images in the VISIBLE sequence., (Copyright © 2024 Elsevier Inc. All rights reserved.)

Published

2024

7. Detunable wireless resonator arrays for TMJ MRI: A comparative study.

Author

Zhu H, Zhang Q, Li R, Chen Y, Zhang G, Wang R, Lu M, and Yan X

Subjects

Humans, Phantoms, Imaging, Temporomandibular Joint Disorders diagnostic imaging, Magnetic Resonance Imaging instrumentation, Magnetic Resonance Imaging methods, Signal-To-Noise Ratio, Wireless Technology instrumentation, Temporomandibular Joint diagnostic imaging, Equipment Design

Abstract

Temporomandibular Joint Magnetic Resonance Imaging (TMJ MRI) is crucial for diagnosing temporomandibular disorders (TMDs). This study advances the use of inductively coupled wireless coils to enhance imaging quality in TMJ MRI. After investigating multiple wireless resonator configurations, including a 1-loop design with a loop diameter of 9 cm, a 2-loop design with each loop having a diameter of 7 cm, and a 3-loop design with each loop having a diameter of 5 cm, our findings indicate that the 3-loop configuration achieves the optimal signal-to-noise ratio (SNR), surpassing other wireless arrays. Bilateral deployment of wireless coils further amplifies SNR, enabling superior visualization of TMJ structures, particularly with the 3-loop design. This cost-effective and comfortable solution, featuring a detunable design, eliminates the need for system parameter adjustments. The study indicates broad adaptability across MRI platforms, enhancing TMJ imaging for routine clinical diagnostics of TMDs., Competing Interests: Declaration of competing interest Haoqin Zhu is currently employed by Sino Canada Health Institute; Rangsong Li and Yuanyuan Chen are currently employed by Sino Canada Health Engineering Research Institute; the other authors report no disclosures., (Copyright © 2023. Published by Elsevier Inc.)

Published

2024

8. 2D CAIPI accelerated 3D multi-slab diffusion weighted EPI combined with qModeL reconstruction for fast high resolution microstructure imaging.

Author

Lee CY and Mani M

Subjects

Humans, Brain diagnostic imaging, Echo-Planar Imaging methods, Image Processing, Computer-Assisted methods, Signal-To-Noise Ratio, Phantoms, Imaging, Imaging, Three-Dimensional methods, Diffusion Magnetic Resonance Imaging methods, Algorithms

Abstract

Purpose: To develop acceleration strategies for 3D multi-slab diffusion weighted imaging (3D ms-DWI) for enabling applications that require simultaneously high spatial (1 mm isotropic) and angular (> 30 directions) resolutions., Methods: 3D ms-DWI offers high SNR-efficiency, with the ability to achieve high isotropic spatial resolution, yet suffers from long scan-times for studies requiring high angular resolutions. We develop 6D k-q space acceleration strategies to reduce the scan-time. Specifically, we develop non-uniform 3D k y -k z under-sampling employing a shot-selective 2D CAIPI sampling approach. To achieve inter-shot phase-compensation, 2D navigators were employed that utilize the same CAIPI trajectory. An iterative model-based 3D multi-shot reconstruction was designed by incorporating phase into the forward encoding process. Additionally, the shot-selective non-uniform k y -k z CAIPI acceleration was randomized along the q-dimension. The 3D model-based multi-shot reconstruction is then extended to a joint reconstruction that simultaneously reconstructs all the q-space points, with the help of a spatial total variation and deep-learned q-space regularization., Results: The proposed reconstruction is shown to achieve adequate phase-compensation in both 2D CAIPI accelerated and additional k y -k z under-sampled cases. Using retrospective under-sampling experiments, we show that k-q accelerations close a factor of 12 can be achieved with a reconstruction error < 3% for both single and multi-shell data. This translates to a scan-time reduction by 3-fold for experiments with simultaneously high spatial and angular resolutions., Conclusion: The proposed method facilitates the utilization of 3D ms-DWI for simultaneously high k-q resolution applications with close to 3× reduced scan-time., (Copyright © 2024 Elsevier Inc. All rights reserved.)

Published

2024

9. Prostate diffusion-weighted imaging (DWI) in MR-guided radiotherapy: Reproducibility assessment on 1.5 T MR-Linac and 1.5 T MR-simulator.

Author

Wong OL, Yuan J, Poon DMC, Chiu ST, Yang B, Chiu G, Yu SK, and Cheung KY

Subjects

Humans, Male, Reproducibility of Results, Aged, Middle Aged, Signal-To-Noise Ratio, Artifacts, Image Processing, Computer-Assisted methods, Prostatic Neoplasms diagnostic imaging, Prostatic Neoplasms radiotherapy, Diffusion Magnetic Resonance Imaging methods, Phantoms, Imaging, Radiotherapy, Image-Guided methods, Prostate diagnostic imaging

Abstract

Purpose: Diffusion-weighted imaging (DWI) holds promise for image-guided radiotherapy (MRgRT) in prostate cancer. However, challenges persist due to image distortion, artifacts, and apparent diffusion coefficient (ADC) reproducibility issues. This study aimed to assess DWI image quality and ADC reproducibility on both a 1.5 T MR-simulator and a 1.5 T MR-Linac, employing measurements from both an ACR MRI phantom and prostate cancer patients undergoing MRgRT., Methods: DW-MRI scans were conducted on 19 patients (mean age = 69 ± 8 years, with 23 MR-visible intra-prostatic lesions) and an ACR MRI phantom using a 1.5 T MR-simulator (b-values = 0, 800, 1400s/mm 2 ) and a 1.5 T MR-Linac (b-values = 50, 500, 800 s/mm 2 ). ADC homogeneity in the phantom was evaluated via 1D profile flatness (FL) in three directions. Image quality was assessed through qualitative 5-point Likert scale ratings and quantitative ADC and signal-to-noise ratio (SNR) measurements. Intra-observer reproducibility of image quality scores was evaluated using ICC(1, 2). Geometric distortion was measured by comparing landmark sizes on the ACR phantom against the ground truth. Mean ADC and reproducibility were assessed using Bland-Altman plots., Results: Both MR-simulator and MR-Linac demonstrated high ADC homogeneity (FL > 87.5% - MR-simulator: 97.23 ± 0.62%, MR-Linac: 94.75 ± 0.62%, p < 0.05) in the phantom. Image quality scores revealed acceptable ratings (≥3) for capsule demarcation, image artifacts, and geometric distortion in patients. However, intra-prostatic lesions were barely discernible in b800 images for both MR-simulator (average score = 2.37 ± 1.33) and MR-Linac (average score = 2.16 ± 1.28). While MR-Linac DWI scans exhibited significantly more severe geometric distortion than MR-simulator scans (p < 0.01), most phantom measurements fell within the image in-plane resolution of 3 mm. Significant differences were noted in MR-simulator ADC (CTV: 1.20 ± 0.14 × 10 -3  mm 2 /s (MR-simulator) vs 1.06 ± 0.10 × 10-3 mm 2 /s (MR-Linac); GTV: 1.05 ± 0.21 × 10 -3  mm 2 /s vs 0.91 ± 0.16 × 10 mm 2 /s, all p < 0.05), with a small non-zero bias observed in the Bland-Altman analysis (CTV: 12.3%; GTV: 14.5%)., Conclusion: The significantly larger MR-simulator ADC and the small non-zero bias hint at potential systematic differences in ADC values acquired from an MR-simulator and an MR-Linac, both at 1.5 T. Although acceptable ADC homogeneity was noted, caution is warranted in interpreting MR-Linac DWI images due to occasional severe artifacts. Further studies are essential to validate DWI and ADC as reliable imaging markers in prostate cancer MRgRT., Competing Interests: Declaration of competing interest All authors confirm that they have no conflicts of interest., (Copyright © 2024 Elsevier Inc. All rights reserved.)

Published

2024

10. An accelerated alternating direction method of multiplier for MRI with TV regularisation.

Author

Zhu Z, Ding Y, Liu Y, and Huang J

Subjects

Humans, Brain diagnostic imaging, Phantoms, Imaging, Data Compression methods, Image Enhancement methods, Signal Processing, Computer-Assisted, Magnetic Resonance Imaging methods, Algorithms, Image Processing, Computer-Assisted methods

Abstract

Compressed Sensing (CS) is important in the field of image processing and signal processing, and CS-Magnetic Resonance Imaging (MRI) is used to reconstruct image from undersampled k-space data. Total Variation (TV) regularisation is a common technique to improve the sparsity of image, and the Alternating Direction Multiplier Method (ADMM) plays a key role in the variational image processing problem. This paper aims to improve the quality of MRI and shorten the reconstruction time. We consider MRI to solve a linear inverse problem, we convert it into a constrained optimization problem based on TV regularisation, then an accelerated ADMM is established. Through a series of theoretical derivations, we verify that the algorithm satisfies the convergence rate of O1/k 2 under the condition that one objective function is quadratically convex and the other is strongly convex. We select five undersampled templates for testing in MRI experiment and compare it with other algorithms, experimental results show that our proposed method not only improves the running speed but also gives better reconstruction results., Competing Interests: Declaration of competing interest The authors declare no conflict of interests., (Copyright © 2024 Elsevier Inc. All rights reserved.)

Published

2024

11. Optimization of 3D imaging time reduction by assessing spatial resolution in the slice selective direction using the ladder method.

Author

Takeuchi T, Hayashi N, Ujita K, Sato Y, Taketomi-Takahashi A, Suto T, and Tsushima Y

Subjects

Humans, Brain diagnostic imaging, Algorithms, Image Processing, Computer-Assisted methods, Male, Female, Adult, Image Enhancement methods, Reproducibility of Results, Phantoms, Imaging, Imaging, Three-Dimensional methods, Magnetic Resonance Imaging methods

Abstract

Purpose: Assessing spatial resolution in MRI is challenging due to non-linearity. Despite the widespread use of 3D imaging in clinical practice for lesion detection and multi-planar reconstruction (MPR), the extended acquisition time poses a shortcoming. To address this, the "Slice resolution" parameter is utilized; however, its impact on MPR images is unclear. This study aims to assess spatial resolution using the ladder method, investigate the effects of diverse slice resolution settings in various imaging sequences, and propose optimal conditions., Methods: Images were acquired using various 3D imaging sequences-SPACE T1WI, SPACE T2WI, and VIBE T1WI-with different slice resolutions. Axial cross-section images were acquired and reconstructed into coronal cross-sections. The ladder method was employed for objective evaluation, including spatial frequency analysis. Additionally, visual evaluation was conducted and compared with ladder method results., Results: For three imaging sequences, the evaluated value of ladder method remained relatively constant from 100 % to 80 % slice resolution. However, the evaluated value decreased in low-spatial frequency for slice resolution below 70 %., Conclusions: Results from both ladder method and visual evaluations indicated image quality remained stable when the slice resolution was decreased to 80 %, potentially enabling a 20 % reduction in imaging time while preserving resolution in other cross-sections reconstructed by MPR., (Copyright © 2024 Elsevier Inc. All rights reserved.)

Published

2024

12. POSE: POSition Encoding for accelerated quantitative MRI.

Author

Jang A and Liu F

Subjects

Humans, Image Processing, Computer-Assisted methods, Reproducibility of Results, Imaging, Three-Dimensional methods, Signal-To-Noise Ratio, Magnetic Resonance Imaging methods, Phantoms, Imaging, Brain diagnostic imaging, Monte Carlo Method, Algorithms, Computer Simulation

Abstract

Quantitative MRI utilizes multiple acquisitions with varying sequence parameters to sufficiently characterize a biophysical model of interest, resulting in undesirable scan times. Here we propose, validate and demonstrate a new general strategy for accelerating MRI using subvoxel shifting as a source of encoding called POSition Encoding (POSE). The POSE framework applies unique subvoxel shifts along the acquisition parameter dimension, thereby creating an extra source of encoding. Combining with a biophysical signal model of interest, accelerated and enhanced resolution maps of biophysical parameters are obtained. This has been validated and demonstrated through numerical Bloch equation simulations, phantom experiments and in vivo experiments using the variable flip angle signal model in 3D acquisitions as an application example. Monte Carlo simulations were performed using in vivo data to investigate our method's noise performance. POSE quantification results from numerical Bloch equation simulations of both a numerical phantom and realistic digital brain phantom concur well with the reference method, validating our method both theoretically and for realistic situations. NIST phantom experiment results show excellent overall agreement with the reference method, confirming our method's applicability for a wide range of T 1 values. In vivo results not only exhibit good agreement with the reference method, but also show g-factors that significantly outperforms conventional parallel imaging methods with identical acceleration. Furthermore, our results show that POSE can be combined with parallel imaging to further accelerate while maintaining superior noise performance over parallel imaging that uses lower acceleration factors., Competing Interests: Declaration of competing interest The authors have no conflict of interest to declare., (Copyright © 2024 Elsevier Inc. All rights reserved.)

Published

2024

13. Insertable, dual-density dielectric barrier for acoustic pressure level reduction in a high-performance human head-only MRI system.

Author

Lee SK, Tarasek MR, Park K, Yeo DT, and Foo TK

Subjects

Humans, Radio Waves, Phantoms, Imaging, Polyurethanes chemistry, Equipment Failure Analysis, Magnetic Resonance Imaging instrumentation, Magnetic Resonance Imaging methods, Equipment Design, Acoustics, Pressure, Head diagnostic imaging

Abstract

We report use of a dual-density dielectric barrier surrounding a detachable high-pass radiofrequency (RF) birdcage coil to achieve an order-of-magnitude reduction of acoustic noise in a high-performance head gradient system. The barrier consisted of a 4.5 mm-thick mass-loaded vinyl and a 6 mm-thick polyurethane foam. It was inserted into the radial gap between the birdcage coil and the RF shield in a prototype head-only gradient system at 3 T. More than 9 dB A reduction of sound pressure level was achieved on the average with representative, high acoustic-noise imaging sequences. Increased acoustic damping was apparent from acoustic impulse response functions. High dielectric constant of the mass-loaded vinyl effectively added distributed capacitance to the birdcage coil, lowering the resonance frequency, but not seriously degrading the RF transmission performance. The barrier occupied the radial space normally used for air cooling of the RF coil and the RF shield. The resulting omission of air cooling was found to be acceptable with efficient gradient thermal management and use of a high-resistivity RF shield for eddy current reduction. The proposed method can improve patient experience while preserving image quality in a high-power head-only gradient system., Competing Interests: Declaration of competing interest None., (Copyright © 2024. Published by Elsevier Inc.)

Published

2024

14. Constrained alternating minimization for parameter mapping (CAMP).

Author

Elsaid NMH, Dispenza NL, Hu C, Peters DC, Constable RT, Tagare HD, and Galiana G

Subjects

Humans, Artifacts, Brain diagnostic imaging, Reproducibility of Results, Image Enhancement methods, Phantoms, Imaging, Algorithms, Image Processing, Computer-Assisted methods, Magnetic Resonance Imaging methods

Abstract

Objective: To improve image quality in highly accelerated parameter mapping by incorporating a linear constraint that relates consecutive images., Approach: In multi-echo T 1 or T 2 mapping, scan time is often shortened by acquiring undersampled but complementary measures of k-space at each TE or TI. However, residual undersampling artifacts from the individual images can then degrade the quality of the final parameter maps. In this work, a new reconstruction method, dubbed Constrained Alternating Minimization for Parameter mapping (CAMP), is introduced. This method simultaneously extracts T 2 or T 1 * maps in addition to an image for each TE or TI from accelerated datasets, leveraging the constraints of the decay to improve the reconstructed image quality. The model enforces exponential decay through a linear constraint, resulting in a biconvex objective function that lends itself to alternating minimization. The method was tested in four in vivo volunteer experiments and validated in phantom studies and healthy subjects, using T 2 and T 1 mapping, with accelerations of up to 12., Main Results: CAMP is demonstrated for accelerated radial and Cartesian acquisitions in T 2 and T 1 mapping. The method is even applied to generate an entire T 2 weighted image series from a single TSE dataset, despite the blockwise k-space sampling at each echo time. Experimental undersampled phantom and in vivo results processed with CAMP exhibit reduced artifacts without introducing bias., Significance: For a wide array of applications, CAMP linearizes the model cost function without sacrificing model accuracy so that the well-conditioned and highly efficient reconstruction algorithm improves the image quality of accelerated parameter maps., (Copyright © 2024 Elsevier Inc. All rights reserved.)

Published

2024

15. Amide proton transfer-weighted imaging with a short acquisition time based on a self B0 correction using the turbo spin echo-Dixon method: A phantom study.

Author

Tokunaga C, Wada T, Togao O, Kobayashi K, and Kato T

Subjects

Amides chemistry, Reproducibility of Results, Algorithms, Humans, Image Processing, Computer-Assisted methods, Hydrogen-Ion Concentration, Image Interpretation, Computer-Assisted methods, Image Enhancement methods, Phantoms, Imaging, Protons, Magnetic Resonance Imaging methods

Abstract

Purpose: Conventional amide proton transfer (APT)-weighted imaging requires a chemical exchange saturation transfer (CEST) sequence with multiple saturation frequency offsets and a B0 correction sequence, plus a long acquisition time that can be reduced by applying the conventional method using CEST images with seven radiation pulses (i.e., the seven-points method). For a further reduction of acquisition times, we propose fast two-dimensional (2D) APT-weighted imaging based on a self B0 correction using the turbo spin echo (TSE)-Dixon method. We conducted a phantom study to investigate the accuracy of TSE-Dixon APT-weighted imaging., Methods: We prepared two types of phantoms with six samples for a concentrationdependent evaluation and a pH-dependent evaluation. APT-weighted images were acquired by the conventional, seven-points, and TSE-Dixon methods. Linear regression analyses assessed the dependence between each method's APT signal intensities (SIs) and the concentration or pH. We performed a one-way analysis of variance with Tukey's honestly significant difference post hoc test to compare the APT SIs among the three methods. The agreement of the APT SIs between the conventional and seven-points or TSE-Dixon methods was assessed by a Bland- Altman plot analysis., Results: The APT SIs of all three acquisition methods showed positive concentration dependence and pH dependence. No significant differences were observed in the APT SIs between the conventional and TSE-Dixon methods at each concentration. The Bland-Altman plot analyses showed that the APT SIs measured with the seven-points method resulted in 0.42% bias and narrow 95% limits of agreement (LOA) (0.93%-0.09%) compared to the conventional method. The APT SIs measured using the TSE-Dixon method showed 0.14% bias and similar 95% LOA (-0.33% to 0.61%) compared with the seven-points method. The APT SIs of all three methods showed positive pH dependence. At each pH, no significant differences in the APT SIs were observed among the methods. Bland-Altman plot analyses showed that the APT SIs measured with the seven-points method resulted in low bias (0.03%) and narrow 95% LOA (-0.30% to 0.36%) compared to the conventional method. The APT SIs measured by the TSE-Dixon method showed slightly larger bias (0.29%) and similar 95% LOA (from -0.15% to 0.72%) compared to those measured by the seven-points method., Conclusion: These results demonstrated that our proposed method has the same concentration dependence and pH dependence as the conventional method and the seven-points method. We thus expect that APT-weighted imaging with less influence of motion can be obtained in clinical examinations., Competing Interests: Declaration of competing interest The authors declare that they have no conflicts of interest., (Copyright © 2024 Elsevier Inc. All rights reserved.)

Published

2024

16. Accelerated multi-b-value multi-shot diffusion-weighted imaging based on EPI with keyhole and a low-rank tensor constraint.

Author

Tang X, Gao J, Aburas A, Wu D, Chen Z, Chen H, and Hu C

Subjects

Humans, Brain diagnostic imaging, Adult, Male, Artifacts, Computer Simulation, Female, Reproducibility of Results, Image Enhancement methods, Algorithms, Echo-Planar Imaging methods, Diffusion Magnetic Resonance Imaging methods, Phantoms, Imaging, Image Processing, Computer-Assisted methods

Abstract

Purpose: Multi-Shot (MS) Echo-Planar Imaging (EPI) may improve the in-plane resolution of multi-b-value DWI, yet it also considerably increases the scan time. Here we explored the combination of EPI with Keyhole (EPIK) and a calibrationless reconstruction algorithm for acceleration of multi-b-value MS-DWI., Methods: We firstly analyzed the impact of nonuniform phase accrual in EPIK on the reconstructed image. Based on insights gained from the analysis, we developed a calibrationless reconstruction algorithm based on a Space-Contrast-Coil Locally Low-Rank Tensor (SCC-LLRT) constraint for reconstruction of EPIK-acquired data. We compared the algorithm with a modified SPatial-Angular Locally Low-Rank (SPA-LLR) algorithm through simulations, phantoms, and in vivo study. We then compared EPIK with uniformly undersampled EPI for accelerating multi-b-value DWI in 6 healthy subjects., Results: Through theoretical derivations, we found that the reconstruction of EPIK with a SENSE-encoding-based algorithm, such as SPA-LLR, may cause additional aliasing artifacts due to the frequency-dependent distortion of the coil sensitivity. Results from simulations, phantoms, and in vivo study verified the theoretical finding by showing that the calibrationless SCC-LLRT algorithm reduced aliasing artifacts compared with SPA-LLR. Finally, EPIK with SCC-LLRT substantially reduced the ghosting artifacts compared with uniform undersampled multi-b-value DWI, decreasing the fitting errors in ADC (0.05 ± 0.01 vs 0.10 ± 0.01, P < 0.001) and IVIM mapping (0.026 ± 0.004 vs 0.06 ± 0.006, P < 0.001)., Conclusion: The SCC-LLRT algorithm reduced the aliasing artifacts of EPIK by using a calibrationless modeling of the multi-coil data. The dense sampling of k-space center offers EPIK a potential to improve image quality for acceleration of multi-b-value MS-DWI., (Copyright © 2024. Published by Elsevier Inc.)

Published

2024

17. Reduction of ADC bias in diffusion MRI with deep learning-based acceleration: A phantom validation study at 3.0 T.

Author

Lemainque T, Yoneyama M, Morsch C, Iordanishvili E, Barabasch A, Schulze-Hagen M, Peeters JM, Kuhl C, and Zhang S

Subjects

Humans, Reproducibility of Results, Algorithms, Computer Simulation, Phantoms, Imaging, Deep Learning, Diffusion Magnetic Resonance Imaging methods, Image Processing, Computer-Assisted methods, Signal-To-Noise Ratio

Abstract

Purpose: Further acceleration of DWI in diagnostic radiology is desired but challenging mainly due to low SNR in high b-value images and associated bias in quantitative ADC values. Deep learning-based reconstruction and denoising may provide a solution to address this challenge., Methods: The effects of SNR reduction on ADC bias and variability were investigated using a commercial diffusion phantom and numerical simulations. In the phantom, performance of different reconstruction methods, including conventional parallel (SENSE) imaging, compressed sensing (C-SENSE), and compressed SENSE acceleration with an artificial intelligence deep learning-based technique (C-SENSE AI), was compared at different acceleration factors and flip angles using ROI-based analysis. ADC bias was assessed by Lin's Concordance correlation coefficient (CCC) followed by bootstrapping to calculate confidence intervals (CI). ADC random measurement error (RME) was assessed by the mean coefficient of variation (CV¯) and non-parametric statistical tests., Results: The simulations predicted increasingly negative bias and loss of precision towards lower SNR. These effects were confirmed in phantom measurements of increasing acceleration, for which CCC decreased from 0.947 to 0.279 and CV¯ increased from 0.043 to 0.439, and of decreasing flip angle, for which CCC decreased from 0.990 to 0.063 and CV¯ increased from 0.037 to 0.508. At high acceleration and low flip angle, C-SENSE AI reconstruction yielded best denoised ADC maps. For the lowest investigated flip angle, CCC = {0.630, 0.771 and 0.987} and CV¯={0.508, 0.426 and 0.254} were obtained for {SENSE, C-SENSE, C-SENSE AI}, the improvement by C-SENSE AI being significant as compared to the other methods (CV: p = 0.033 for C-SENSE AI vs. C-SENSE and p < 0.001 for C-SENSE AI vs. SENSE; CCC: non-overlapping CI between reconstruction methods). For the highest investigated acceleration factor, CCC = {0.479,0.926,0.960} and CV¯={0.519,0.119,0.118} were found, confirming the reduction of bias and RME by C-SENSE AI as compared to C-SENSE (by trend) and to SENSE (CV: p < 0.001; CCC: non-overlapping CI)., Conclusion: ADC bias and random measurement error in DWI at low SNR, typically associated with scan acceleration, can be effectively reduced by deep-learning based C-SENSE AI reconstruction., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

18. Phase-sensitive deep reconstruction method for rapid multiparametric MR fingerprinting and quantitative susceptibility mapping in the brain.

Author

Martinez JA, Yu VY, Tringale KR, Otazo R, and Cohen O

Subjects

Humans, Magnetic Resonance Imaging methods, Brain diagnostic imaging, Magnetic Resonance Spectroscopy, Phantoms, Imaging, Image Processing, Computer-Assisted methods, Protons

Abstract

Introduction: This study explores the potential of Magnetic Resonance Fingerprinting (MRF) with a novel Phase-Sensitivity Deep Reconstruction Network (PS-DRONE) for simultaneous quantification of T1, T2, Proton Density, B1+, phase and quantitative susceptibility mapping (QSM)., Methods: Data were acquired at 3 T in vitro and in vivo using an optimized EPI-based MRF sequence. Phantom experiments were conducted using a standardized phantom for T1 and T2 maps and a custom-made agar-based gadolinium phantom for B1 and QSM maps. In vivo experiments included five healthy volunteers and one patient diagnosed with brain metastasis. PSDRONE maps were compared to reference maps obtained through standard imaging sequences., Results: Total scan time was 2 min for 32 slices and a resolution of [1 mm, 1 mm, 4.5 mm]. The reconstruction of T1, T2, Proton Density, B1+ and phase maps were reconstructed within 1 s. In the phantoms, PS-DRONE analysis presented accurate and strongly correlated T1 and T2 maps (r = 0.99) compared to the reference maps. B1 maps from PS-DRONE showed slightly higher values, though still correlated (r = 0.6) with the reference. QSM values showed a small bias but were strongly correlated (r = 0.99) with reference data. In the in vivo analysis, PS-DRONE-derived T1 and T2 values for gray and white matter matched reference values in healthy volunteers. PS-DRONE B1 and QSM maps showed strong correlations with reference values., Conclusion: The PS-DRONE network enables concurrent acquisition of T1, T2, PD, B1+, phase and QSM maps, within 2 min of acquisition time and 1 s of reconstruction time., Competing Interests: Declaration of competing interest None., (Copyright © 2024. Published by Elsevier Inc.)

Published

2024

19. Induced saturation transfer recovery steady states (iSTRESS) for proton exchange rate mapping with CEST MRI, a preliminary study.

Author

Shaghaghi M, Damen FC, Li W, Tai LM, and Cai K

Subjects

Humans, Brain diagnostic imaging, Hydrogen-Ion Concentration, Contrast Media, Phantoms, Imaging, Protons, Magnetic Resonance Imaging methods

Abstract

Proton exchange underpins essential mechanisms in diverse MR imaging contrasts. Omega plots have proven effective in mapping proton exchange rates (k ex ) in live human brains, enabling the differentiation of MS lesion activities and characterization of ischemic stroke. However, Omega plots require extended saturation durations (typically 5 to 10 s), resulting in high specific absorption rates (SAR) that can hinder clinical feasibility. In this study, we introduce a novel k ex mapping approach, named induced Saturation Transfer Recovery Steady-States (iSTRESS). iSTRESS integrates an excitation flip angle pulse prior to chemical exchange saturation transfer (CEST) saturation, effectively aligning the magnetization with its steady-state value. This innovation reduces saturation times and mitigates SAR concerns. The formula for iSTRESS-based k ex quantification was derived theoretically, involving two measurements with distinct excitation flip angles and saturation B 1 values. Bloch-McConnell simulations confirmed that iSTRESS-based k ex values closely matched input values (R 2  > 0.99). An iSTRESS MRI sequence was implemented on a 9.4 T preclinical MRI, imaging protein phantoms with pH values ranging from 6.2 to 7.4 (n = 4). Z-spectra were acquired using excitation flip angles of 30° and 60°, followed by CEST saturation at powers of 30 and 120 Hz respectively, with a total saturation time of <1 s, resulting in two iSTRESS states for k ex mapping. k ex maps derived from the phantom study exhibited a linear correlation (R 2  > 0.99) with Omega plot results. The developed iSTRESS method allows for k ex quantification with significantly reduced saturation times, effectively minimizing SAR concerns., (Copyright © 2024 Elsevier Inc. All rights reserved.)

Published

2024

20. Fast and accessible T2 mapping using off-resonance corrected DESPOT2 with application to 3D prostate.

Author

Coronado R, Castillo-Passi C, Besa C, and Irarrazaval P

Subjects

Male, Humans, Phantoms, Imaging, Artifacts, Healthy Volunteers, Prostate diagnostic imaging, Magnetic Resonance Imaging methods

Abstract

Purpose: Most T1 and T2 mapping take long acquisitions or needs specialized sequences not widely accessible on clinical scanners. An available solution is DESPOT1/T2 (Driven equilibrium single pulse observation of T1/T2). DESPOT1/T2 uses Spoiled gradient-echo (SPGR) and balanced Steady-State Free Precession (bSSFP) sequences, offering an accessible and reliable way for 3D accelerated T1/T2 mapping. However, bSSFP is prone to off-resonance artifacts, limiting the application of DESPOT2 in regions with high susceptibility contrasts, like the prostate. Our proposal, DESPO+, employs the full bSSFP and SPGR models with a dictionary-based method to reconstruct 3D T1/T2 maps in the prostate region without off-resonance banding., Methods: DESPO+ modifies the bSSFP acquisition of the original variable flip angle DESPOT2. DESPO+ uses variable repetition and echo times, employing a dictionary-based method of the full bSSFP and SPGR models to reconstruct T1, T2, and Proton Density (PD) simultaneously. The proposed DESPO+ method underwent testing through simulations, T1/T2 phantoms, and on fourteen healthy subjects., Results: The results reveal a significant reduction in T2 map banding artifacts compared to the original DESPOT2 method. DESPO+ approach reduced T2 errors by up to seven times compared to DESPOT2 in simulations and phantom experiments. We also synthesized in-vivo T1-weighted/T2-weighted images from the acquired maps using a spin-echo model to verify the map's quality when lacking a reference. For in-vivo imaging, the synthesized images closely resemble those from the clinical MRI protocol, reducing scan time by around 50% compared to traditional spin-echo T1-weighted/T2-weighted acquisitions., Conclusion: DESPO+ provides an off-resonance insensitive and clinically available solution, enabling high-resolution 3D T1/T2 mapping and synthesized T1-weighted/T2-weighted images for the entire prostate, all achieved within a short scan time of 3.6 min, similar to DESPOT1/T2., (Copyright © 2024 Elsevier Inc. All rights reserved.)

Published

2024

21. Twisted pair transmission line coil - a flexible, self-decoupled and robust element for 7 T MRI.

Author

Vliem J, Xiao Y, Wenz D, Xin L, Teeuwise W, Ruytenberg T, Webb A, and Zivkovic I

Subjects

Equipment Design, Phantoms, Imaging, Magnetic Resonance Imaging methods, Radio Waves

Abstract

Objective: This study evaluates the performance of a twisted pair transmission line coil as a transceive element for 7 T MRI in terms of physical flexibility, robustness to shape deformations, and interelement decoupling., Methods: Each coil element was created by shaping a twisted pair of wires into a circle. One wire was interrupted at the top, while the other was interrupted at the bottom, and connected to the matching circuit. Electromagnetic simulations were conducted to determine the optimal number of twists per length (in terms of B₁ + field efficiency, SAR efficiency, sensitivity to elongation, and interelement decoupling properties) and for investigating the fundamental operational principle of the coil through fields streamline visualisation. A comparison between the twisted pair coil and a conventional loop coil in terms of B₁ + fields, maxSAR₁₀ g , and stability of S₁₁ when the coil was deformed was performed. Experimentally measured interelement coupling between individual elements of multichannel arrays was also investigated., Results: Increasing the number of twists per length resulted in a more physically robust coil. Poynting vector streamline visualisation showed that the twisted pair coil concentrated most of the energy in the near field. The twisted pair coil exhibited comparable B₁ + fields and improved maxSAR₁₀ g to the conventional coil but demonstrated exceptional stability with respect to coil deformation and a strong self-decoupling nature when placed in an array configuration., Discussion: The findings highlight the robustness of the twisted pair coil, showcasing its stability under shape variations. This coil holds great potential as a flexible RF coil for various imaging applications using multiple-element arrays, benefiting from its inherent decoupling., (Copyright © 2023. Published by Elsevier Inc.)

Published

2024

22. Complex multi-dimensional integration for T 2 * and R 2 * mapping.

Author

Ye Y, Xu J, Zhang Z, Zhang Y, Zhao Q, Xu J, and Yuan H

Subjects

Reproducibility of Results, Computer Simulation, Signal-To-Noise Ratio, Phantoms, Imaging, Algorithms, Magnetic Resonance Imaging methods

Abstract

A dual Multi-Dimensional Integration (dMDI) method was proposed and demonstrated for T 2 * and R 2 * mapping. By constructing and jointly using both the original MDI term and an inversed MDI term, T 2 * and R 2 * mapping can be performed independently with intrinsic background noise suppression and spike elimination, allowing for high quantitative accuracy and robustness over a wide range of T 2 *. dMDI was compared to original MDI and curve fitting methods in terms of quantitative specificity, accuracy, reliability and computational efficiency. All methods were tested and compared via simulation and in vivo data. With high signal-to-noise-ratio (SNR), the proposed dMDI method yielded T 2 *and R 2 * values similar to curve fitting methods. For low SNR and background noise signals, the dMDI yielded low T 2 * and R 2 * values, thus effectively suppressing all background noise. Virtually zero spikes were observed in dMDI T 2 * and R 2 * maps in all simulation and imaging results. The dMDI method has the potential to provide improved and reliable T 2 * and R 2 * mapping results in routine and SNR-challenging scenarios., Competing Interests: Declaration of competing interest The following authors are employees of the UIH America, Inc., Houston, TX, United States: Yongquan Ye, Jian Xu and Zhongqi Zhang. The following authors are employees of the Beijing United Imaging Intelligent Imaging Technology Research Institute: Yan Zhang., (Copyright © 2024. Published by Elsevier Inc.)

Published

2024

23. Accelerated multiple-quantum-filtered sodium magnetic resonance imaging using compressed sensing at 7 T.

Author

Chen Q, Worthoff WA, and Shah NJ

Subjects

Humans, Retrospective Studies, Signal-To-Noise Ratio, Phantoms, Imaging, Image Processing, Computer-Assisted methods, Imaging, Three-Dimensional, Sodium, Magnetic Resonance Imaging methods

Abstract

Purpose: Multiple-quantum-filtered (MQF) sodium magnetic resonance imaging (MRI), such as enhanced single-quantum and triple-quantum-filtered imaging of 23 Na (eSISTINA), enables images to be weighted towards restricted sodium, a promising biomarker in clinical practice, but often suffers from clinically infeasible acquisition times and low image quality. This study aims to mitigate the above limitation by implementing a novel eSISTINA sequence at 7 T with the application of compressed sensing (CS) to accelerate eSISTINA acquisitions without a noticeable loss of information., Methods: A novel eSISTINA sequence with a 3D spiral-based sampling scheme was implemented at 7 T for the application of CS. Fully sampled datasets were obtained from one phantom and ten healthy subjects, and were then retrospectively undersampled by various undersampling factors. CS undersampled reconstructions were compared to fully sampled and undersampled nonuniform fast Fourier transform (NUFFT) reconstructions. Reconstruction performance was evaluated based on structural similarity (SSIM), signal-to-noise ratio (SNR), weightings towards total and compartmental sodium, and in vivo quantitative estimates., Results: CS-based phantom and in vivo images have less noise and better structural delineation while maintaining the weightings towards total, non-restricted (predominantly extracellular), and restricted (primarily intracellular) sodium. CS generally outperforms NUFFT with a higher SNR and a better SSIM, except for the SSIM in TQ brain images, which is likely due to substantial noise contamination. CS enables in vivo quantitative estimates with <15% errors at an undersampling factor of up to two., Conclusions: Successful implementation of an eSISTINA sequence with an incoherent sampling scheme at 7 T was demonstrated. CS can accelerate eSISTINA by up to twofold at 7 T with reduced noise levels compared to NUFFT, while maintaining major structural information, reasonable weightings towards total and compartmental sodium, and relatively reliable in vivo quantification. The associated reduction in acquisition time has the potential to facilitate the clinical applicability of MQF sodium MRI., Competing Interests: Declaration of competing interest None., (Copyright © 2023. Published by Elsevier Inc.)

Published

2024

24. Fast T 2 mapping of short-T 2 tissues in knee using 3D radial dual-echo balanced steady-state free precession.

Author

Li B, Ding Z, and She H

Subjects

Humans, Knee Joint diagnostic imaging, Knee diagnostic imaging, Magnetic Resonance Imaging methods, Phantoms, Imaging, Imaging, Three-Dimensional methods, Patellar Ligament

Abstract

Background: T 2 mapping of short-T 2 tissues in the knee (meniscus, tendon, and ligament) is needed to aid the clinical MRI knee diagnosis, which is hard to realize using traditional clinical methods., Purpose: To accelerate the acquisition of T 2 values for short-T 2 tissues in the knee by analyzing the signal equation of balanced steady-state free precession (bSSFP) sequence in MRI., Methods: Effect of half-radial acquisition on pixel bandwidth was analyzed mathematically. A modified 3D radial dual-echo bSSFP sequence was proposed for 0.53 mm isotropic resolution knee imaging with 2 different TEs at 3 T, which alleviated the problem of off-resonance artifacts caused by traditional half-radial acquisition scheme. A novel pixel-based optimization method was proposed for efficient T 2 mapping of short-T 2 tissues in the knee given off-resonance values. Simulation was conducted to evaluate the sensitivity of the proposed method to other parameters. Phantom results were compared with 2D spin-echo (SE), and in vivo results were compared with SE and previously studies., Results: Simulation showed that the proposed method is insensitive to T 1 and B 1 variations (estimation error < 1% for T 1 /B 1 error of ±90%), avoiding the need for separated T 1 and B 1 scans. High isotropic resolution knee imaging was achieved using the modified dual-echo bSSFP. The total scan time was within 3.5 min, including a separate off-resonance scan for T 2 measurement. Measured mean T 2 values for phantoms correlated well with SE (R 2  = 0.99), and no significant difference was observed (P = 0.45). In vivo meniscus T 2 measurements and ligament T 2 measurements agreed with the literature, while tendon T 2 measurements were much lower (31.7% lower for patellar tendon, and 13.5% lower for quadriceps tendon), which might result in its bi-component property., Conclusions: The proposed method provides an efficient way for fast, robust, high-resolution imaging and T 2 mapping of short-T 2 tissues in the knee., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Elsevier Inc. All rights reserved.)

Published

2024

25. On retrospective k-space subsampling schemes for deep MRI reconstruction.

Author

Yiasemis G, Sánchez CI, Sonke JJ, and Teuwen J

Subjects

Retrospective Studies, Radionuclide Imaging, Phantoms, Imaging, Image Processing, Computer-Assisted methods, Algorithms, Magnetic Resonance Imaging methods

Abstract

Acquiring fully-sampled MRI k-space data is time-consuming, and collecting accelerated data can reduce the acquisition time. Employing 2D Cartesian-rectilinear subsampling schemes is a conventional approach for accelerated acquisitions; however, this often results in imprecise reconstructions, even with the use of Deep Learning (DL), especially at high acceleration factors. Non-rectilinear or non-Cartesian trajectories can be implemented in MRI scanners as alternative subsampling options. This work investigates the impact of the k-space subsampling scheme on the quality of reconstructed accelerated MRI measurements produced by trained DL models. The Recurrent Variational Network (RecurrentVarNet) was used as the DL-based MRI-reconstruction architecture. Cartesian, fully-sampled multi-coil k-space measurements from three datasets were retrospectively subsampled with different accelerations using eight distinct subsampling schemes: four Cartesian-rectilinear, two Cartesian non-rectilinear, and two non-Cartesian. Experiments were conducted in two frameworks: scheme-specific, where a distinct model was trained and evaluated for each dataset-subsampling scheme pair, and multi-scheme, where for each dataset a single model was trained on data randomly subsampled by any of the eight schemes and evaluated on data subsampled by all schemes. In both frameworks, RecurrentVarNets trained and evaluated on non-rectilinearly subsampled data demonstrated superior performance, particularly for high accelerations. In the multi-scheme setting, reconstruction performance on rectilinearly subsampled data improved when compared to the scheme-specific experiments. Our findings demonstrate the potential for using DL-based methods, trained on non-rectilinearly subsampled measurements, to optimize scan time and image quality., (Copyright © 2023. Published by Elsevier Inc.)

Published

2024

26. A hybrid FDTD/MoM algorithm with a non-uniform grid for MRI RF coil design

Author

Yang, Liu, Qiuliang, Wang, and Feng, Liu

Subjects

Electromagnetic Fields, Radio Waves, Phantoms, Imaging, Biomedical Engineering, Biophysics, Radiology, Nuclear Medicine and imaging, Magnetic Resonance Imaging, Algorithms

Abstract

In ultra-high-field (UHF) magnetic resonance imaging (MRI) applications, the design and analysis of high-frequency radio frequency (RF) coils requires full-wave electromagnetic (EM) methods that can handle complex field-tissue interactions. Using a Huygens' equivalent surface, the Method of Moments (MoM) and the Finite-Difference Time-Domain (FDTD) algorithm can be combined to accurately model the high-frequency RF coils. In previous research, a uniform FDTD mesh structure was considered, providing a compromised solution for coil-tissue interactions. This paper proposes a hybrid FDTD/MoM algorithm with non-uniform meshes. The fine mesh domain is set at the Huygens' surface, and the other domain uses coarse meshes. The proposed algorithms are strictly validated, and their computational performance is compared against conventional methods. Results show that the new algorithm can improve the calculation efficiency without losing accuracy. Specifically, compared with the uniform FDTD method, the numerical difference between both hybrid methods remains at 3.2%. Still, the calculation time of the non-uniform grid algorithm is reduced by 64.2%, demonstrating the effectiveness of the new algorithm for modeling RF coils for UHF-MRI applications.

Published

2023

27. Low rank off-resonance correction for double half-echo k-space acquisitions

Author

Mark, Bydder, Fadil, Ali, Andres, Saucedo, Vahid, Ghodrati, Alexei, Samsonov, Massoud, Akhtari, Chencai, Wang, Akifumi, Hagiwara, Jingwen, Yao, and Ben, Ellingson

Subjects

Phantoms, Imaging, Echo-Planar Imaging, Sodium, Image Processing, Computer-Assisted, Biomedical Engineering, Biophysics, Radiology, Nuclear Medicine and imaging, Image Enhancement, Artifacts, Magnetic Resonance Imaging, Algorithms

Abstract

The present study describes a model-based approach for correcting off-resonance in the context of double half-echo k-space acquisitions. This technique employs center-out readouts in forward and reverse directions to reduce echo-times but is sensitive to off-resonance, which manifests as pixel shifts in both directions. Demodulating the k-space signal with a constant off-resonance term per slice removes pixel shifts and results in a marked reduction in blurring. Phantom and in vivo datasets are demonstrated from low bandwidth sodium imaging.

Published

2022

28. Parallel transmission 2D RARE imaging at 7T with transmit field inhomogeneity mitigation and local SAR control

Author

Filiz, Yetisir, Benedikt A, Poser, P Ellen, Grant, Elfar, Adalsteinsson, Lawrence L, Wald, Bastien, Guerin, MRI, and RS: FPN CN 5

Subjects

Phantoms, Imaging, Image Interpretation, Computer-Assisted, Biomedical Engineering, Biophysics, Brain, Radiology, Nuclear Medicine and imaging, Magnetic Resonance Imaging, Algorithms

Abstract

PURPOSE: We develop and test a parallel transmit (pTx) pulse design framework to mitigate transmit field inhomogeneity with control of local specific absorption rate (SAR) in 2D rapid acquisition with relaxation enhancement (RARE) imaging at 7T.METHODS: We design large flip angle RF pulses with explicit local SAR constraints by numerical simulation of the Bloch equations. Parallel computation and analytical expressions for the Jacobian and the Hessian matrices are employed to reduce pulse design time. The refocusing-excitation "spokes" pulse pairs are designed to satisfy the Carr-Purcell-Meiboom-Gill (CPMG) condition using a combined magnitude least squares-least squares approach.RESULTS: In a simulated dataset, the proposed approach reduced peak local SAR by up to 56% for the same level of refocusing uniformity error and reduced refocusing uniformity error by up to 59% (from 32% to 7%) for the same level of peak local SAR compared to the circularly polarized birdcage mode of the pTx array. Using explicit local SAR constraints also reduced peak local SAR by up to 46% compared to an RF peak power constrained design. The excitation and refocusing uniformity error were reduced from 20%-33% to 4%-6% in single slice phantom experiments. Phantom experiments demonstrated good agreement between the simulated excitation and refocusing uniformity profiles and experimental image shading.CONCLUSION: PTx-designed excitation and refocusing CPMG pulse pairs can mitigate transmit field inhomogeneity in the 2D RARE sequence. Moreover, local SAR can be decreased significantly using pTx, potentially leading to better slice coverage, enabling larger flip angles or faster imaging.

Published

2022

29. Increased brain volumetric measurement precision from multi-site 3D T1-weighted 3 T magnetic resonance imaging by correcting geometric distortions

Author

Jennifer Mandzia, Miracle Ozzoude, Sandra E. Black, Sean P. Symons, Robert Bartha, Igor Solovey, Ondri Investigators, Demetrios J. Sahlas, Stephen R. Arnott, Tom Gee, Christopher J.M. Scott, Dar Dowlatshahi, Dana N. Broberg, Gustavo Saposnik, Nuwan D. Nanayakkara, Richard H. Swartz, Shuai Liang, Stephen C. Strother, Melissa F. Holmes, Sujeevini Sujanthan, Joel Ramirez, Ayman Hassan, Gregory M. Szilagyi, Courtney Berezuk, Seyyed M. H. Haddad, Mojdeh Zamyadi, Vladimir S. Fonov, Sabrina Adamo, Leanne K. Casaubon, and Athena E. Theyers

Subjects

Physics, Scanner, medicine.diagnostic_test, Phantoms, Imaging, Coefficient of variation, Biomedical Engineering, Biophysics, Isocenter, Brain, Magnetic resonance imaging, Volumetric measurement, Magnetic Resonance Imaging, Standard deviation, Imaging phantom, Distortion, medicine, Humans, Radiology, Nuclear Medicine and imaging, Biomedical engineering

Abstract

Magnetic resonance imaging (MRI) scanner-specific geometric distortions may contribute to scanner induced variability and decrease volumetric measurement precision for multi-site studies. The purpose of this study was to determine whether geometric distortion correction increases the precision of brain volumetric measurements in a multi-site multi-scanner study. Geometric distortion variation was quantified over a one-year period at 10 sites using the distortion fields estimated from monthly 3D T1-weighted MRI geometrical phantom scans. The variability of volume and distance measurements were quantified using synthetic volumes and a standard quantitative MRI (qMRI) phantom. The effects of geometric distortion corrections on MRI derived volumetric measurements of the human brain were assessed in two subjects scanned on each of the 10 MRI scanners and in 150 subjects with cerebrovascaular disease (CVD) acquired across imaging sites.Geometric distortions were found to vary substantially between different MRI scanners but were relatively stable on each scanner over a one-year interval. Geometric distortions varied spatially, increasing in severity with distance from the magnet isocenter. In measurements made with the qMRI phantom, the geometric distortion correction decreased the standard deviation of volumetric assessments by 35% and distance measurements by 42%. The average coefficient of variance decreased by 16% in gray matter and white matter volume estimates in the two subjects scanned on the 10 MRI scanners. Geometric distortion correction using an up-to-date correction field is recommended to increase precision in volumetric measurements made from MRI images.

Published

2022

30. Near field communication (NFC) device: Evaluation of MRI issues

Author

Matthew, Sautter, Nicholas, Sautter, and Frank G, Shellock

Subjects

Magnetic Fields, Phantoms, Imaging, Communication, Biomedical Engineering, Biophysics, Humans, Radiology, Nuclear Medicine and imaging, Artifacts, Magnetic Resonance Imaging

Abstract

Near field communication (NFC) is a wireless, short-range, secure communication technology that may be used for healthcare-related applications. An NFC device was recently developed that was intended for implantation in the dorsal fascia, above the interosseous compartment of the hand. This implant uses a ferrite rod to increase the distance of communication between devices. The purpose of this investigation was to evaluate MRI issues for this NFC device using standardized techniques and well-accepted methodology.The NFC device (Vivokey Spark 2, Cryptobionic Implant, Vivokey Technologies, www.vivokey.com) was assessed for magnetic field interactions (force and torque) at 3-Tesla, magnetic field interactions according to the simulated intended use of the implant, MRI-related heating at 1.5-Tesla/64-MHz and 3-Tesla/128-MHz, functional change associated with MRI conditions at 1.5-Tesla/64-MHz and 3-Tesla/128-MHz, and artifacts at 3-Tesla.The mean deflection angle was 90° ± 0 and torque was "positive". However, tests evaluating the simulated intended use of the NFC device demonstrated no movement, displacement, or rotational alignment. The highest temperature changes at 1.5-Tesla/64-MHz and 3-Tesla/128-MHz were 1.7 °C and 1.9 °C, respectively. There was no change in the operational capabilities of the NFC device related to the MRI exposures. Artifacts were relatively large in comparison to the size of the NFC device.The findings indicated that the particular NFC device that underwent evaluation is "MR Conditional" for a patient undergoing MRI at 1.5-Tesla or 3-Tesla, operating the scanner in the Normal Operating Mode (i.e., default whole-body averaged SAR of 2.0-W/kg). Notably, this is the first NFC device evaluated for MRI-related issues.

Published

2022

31. Motion-resolved and free-breathing liver MRF

Author

Peng Cao, Zuojun Wang, Chenyang Liu, Tian Li, Edward S. Hui, and Jing Cai

Subjects

Motion, Magnetic Resonance Spectroscopy, Liver, Phantoms, Imaging, Image Processing, Computer-Assisted, Biomedical Engineering, Biophysics, Humans, Radiology, Nuclear Medicine and imaging, Magnetic Resonance Imaging

Abstract

To develop a motion-resolved and free-breathing liver magnetic resonance fingerprinting (MRF) protocol.The deformation maps were obtained from the first singular image of MRF data. The reconstruction method enforced the consistency of the MRF data with the deformation maps by adding the deformation maps to the encoding matrix. A sliding window reconstruction was inherently assumed, with a window size of 60 repetition times (TRs) and a step size of 30 TRs. L1 wavelet regularization was applied to reduce the undersampling artifact. MRF was tested on four healthy volunteers with parameters: 13 s/slice, 0.39 s/frame, and 33 time frames/slice.For measuring the accuracy of the deformation map, the typical normalized root mean square error (NRMSE) of the first singular image after motion correction was 0.19. In the sagittal scan, the liver T1 and T2 were 808.7±96.8 ms and 52.7±11.6 ms, respectively. They agreed with our previously reported values, i.e., T1 = 759 ms and T2 = 51 ms at 3 T, using free-breathing liver MRF. Compared to breath-hold MRF, the NRMSEs for T1 and T2 maps (without considering vessel pixels) from the proposed method were 0.13 and 0.18, respectively.We demonstrated a motion-resolved MRF with a nominal frame rate of 2.5 Hz for free-breathing liver imaging.

Published

2022

32. Implementation of the QRAPMASTER data analysis using dictionary matching and quantitative evaluation of the magnetization transfer effect

Author

Ryoichi, Kose, Katsumi, Kose, and Yasuhiko, Terada

Subjects

Data Analysis, Phantoms, Imaging, Image Processing, Computer-Assisted, Biomedical Engineering, Biophysics, Reproducibility of Results, Radiology, Nuclear Medicine and imaging, Magnetic Resonance Imaging

Abstract

To clarify the magnetization transfer (MT) effect on TA phantom consisting of MnClThe linearity and accuracy of the regression lines between the TThis study demonstrated that the T

Published

2022

33. A hybrid 2D-FDTD/3D-MoM method used for the analysis of MRI RF coils.

Author

Liu Y, Wang Q, and Liu F

Subjects

Humans, Computer Simulation, Electromagnetic Fields, Phantoms, Imaging, Radio Waves, Equipment Design, Magnetic Resonance Imaging methods, Algorithms

Abstract

The design of radiofrequency (RF) coils is crucial for ultra-high field (UHF) magnetic resonance imaging (MRI) systems. To analyze RF coils, various numerical methods, such as finite-difference time-domain (FDTD) and method of moments (MoM), are usually adopted. In this paper, we present a novel hybrid approach that combines a two-dimensional (2D) FDTD with a three-dimensional (3D) MoM to analyze MRI RF problems. In our algorithm, the MoM is utilized for calculating the coil current, and FDTD is assigned for solving the electromagnetic (EM) fields in the imaging region. The hybrid method achieves superior efficiency and acceptable accuracy than using either method individually. To validate the hybrid method, we analyze an ellipse coil loaded with a uniform phantom and a realistic human head model, with the objective of tailoring the magnetic field intensity by adding a multilayer dielectric pad (DP). The results show an improvement in the magnetic field after optimizing the DP configuration. These simulation studies indicate the potential of the new numerical method for the design and analysis of RF systems for ultra-high field applications., Competing Interests: Declaration of Competing Interest The authors declare that they have no conflict of interest., (Copyright © 2023. Published by Elsevier Inc.)

Published

2024

34. Digital reference objects for evaluating algorithm performance in MR image formation.

Author

Wülker C, Gessert NT, Doneva M, Kastryulin S, Ercan E, and Nielsen T

Subjects

Fourier Analysis, Phantoms, Imaging, Image Processing, Computer-Assisted methods, Tomography, X-Ray Computed methods, Algorithms

Abstract

Purpose: Digital Reference Objects (DROs) are mathematical phantoms that can serve as a basis for evaluating MR image quality (IQ) in an objective way. Their main purpose is to facilitate the establishment of fully automated and perfectly reproducible IQ metrics to objectively compare different algorithms in MR image formation in a standardized manner. They also allow to re-build parts of standard phantoms., Methods: We sample DROs directly in k-space, using analytical formulas for the continuous Fourier transform of primitive shapes. We demonstrate this DRO approach by applying a state-of-the-art CNN-based denoising algorithm that is robust to varying noise levels to noisy images of the resolution section of the well-known ACR phantom for IQ assessment, reconstructed from both measured and simulated k-space data., Results: Applying the CNN-based denoising algorithm to the measured and simulated version of the ACR phantom resolution section produced virtually identical results, as confirmed by visual and quantitative comparison., Conclusions: DROs can help guide technology selection during the development of new algorithms in MR image formation, e.g., via deep learning. This could be an important step towards reproducible MR image formation., (Copyright © 2023 Elsevier Inc. All rights reserved.)

Published

2024

35. Compensation of concomitant field effects in double diffusion encoding by means of added oscillating gradients.

Author

Rauch J, Laun FB, Bachert P, Ladd ME, and Kuder TA

Subjects

Humans, Signal-To-Noise Ratio, Phantoms, Imaging, Healthy Volunteers, Brain diagnostic imaging, Artifacts

Abstract

Maxwell or concomitant fields imprint additional phases on the transverse magnetization. This concomitant phase may cause severe image artifacts like signal voids or distort the quantitative parameters due to the induced intravoxel dephasing. In particular, double diffusion encoding (DDE) schemes with two pairs of bipolar diffusion-weighting gradients separated by a refocusing radiofrequency (RF) pulse are prone to concomitant field-induced artifacts. In this work, a method for reducing concomitant field effects in these DDE sequences based on additional oscillating gradients is presented. These oscillating gradient pulses obtained by constrained optimization were added to the original gradient waveforms. The modified sequences reduced the accumulated concomitant phase without significant changes in the original sequence characteristics. The proposed method was applied to a DDE acquisition scheme consisting of 60 pairs of diffusion wave vectors. For phantom as well as for in vivo experiments, a considerable increase in the signal-to-noise ratio (SNR) was obtained. For phantom measurements with a diffusion weighting of b = 2000 s/mm 2 for each of the gradient pairs, an SNR increase of up to 40% was observed for a transversal slice that had a distance of 5 cm from the isocenter. For equivalent slice parameters, in vivo measurements in the brain of a healthy volunteer exhibited an increase in SNR of up to 35% for b = 750 s/mm 2 for each weighting. These findings are supported by corresponding simulations, which also predict a positive effect on the SNR. In summary, the presented method leads to an SNR gain without additional RF refocusing pulses., Competing Interests: Declaration of Competing Interest None., (Copyright © 2023 Elsevier Inc. All rights reserved.)

Published

2024

36. Simultaneous T 1 , T 2 and T 2 ⁎ mapping of the liver with multi-shot MI-SAGE.

Author

Zhang K, Triphan SMF, Wielpütz MO, Ziener CH, Ladd ME, Schlemmer HP, Kauczor HU, Kurz FT, and Sedlaczek O

Subjects

Breath Holding, Phantoms, Imaging, Magnetic Resonance Imaging methods, Liver diagnostic imaging

Abstract

Purpose: To apply multi-shot high-resolution multi inversion spin and gradient echo (MI-SAGE) acquisition for simultaneous liver T 1 , T 2 and T 2 * mapping., Methods: Inversion prepared spin- and gradient-echo EPI was developed with ascending slice order across measurements for efficient acquisition with T 1 , T 2 , and T 2 ⁎ weighting. Multi-shot EPI was also implemented to minimize distortion and blurring while enabling high in-plane resolution. A dictionary-matching approach was used to fit the images to quantitative parameter maps, which were compared to T 1 measured by modified Look-Locker (MOLLI), T 1 measured by variable flip angle (VFA), T 2 measured by multiple echo time-based Half Fourier Single-shot Turbo spin-Echo (HASTE), T 2 measured by radial turbo-spin-echo (rTSE) and T 2 ⁎ measured by multiple gradient echo (MGRE) sequences., Results: The multi-shot variant of the sequence achieved higher in-plane resolution of 1.7 × 1.7 mm 2 with good image quality in 28 s. Derived quantitative maps showed comparable values to conventional mapping methods. As measured in phantom and in vivo, MOLLI, MESE and MGRE give closest values to MISAGE. VFA, HASTE and rTSE show obvious overestimation., Conclusions: The proposed multi-shot inversion prepared spin- and gradient-echo EPI sequence allows for high-resolution quantitative T 1 , T 2 and T 2 liver tissue characterization in a single breath-hold scan., (Copyright © 2023 Elsevier Inc. All rights reserved.)

Published

2024

37. Estimation of effective b-value for a diffusion-weighted double-echo steady-state sequence with bipolar gradients.

Author

Katscher U, Meineke J, Zhang S, Steinhorst B, and Keupp J

Subjects

Motion, Phantoms, Imaging, Echo-Planar Imaging, Magnetic Resonance Imaging methods, Diffusion Magnetic Resonance Imaging methods

Abstract

Diffusion-weighted double-echo steady-state (dwDESS) MRI with bipolar diffusion gradients is a promising candidate to obtain diffusion weighted images (DWI) free of geometric distortions and with low motion sensitivity. However, a wider clinical application of dwDESS is currently hindered as no method is reported to explicitly calculate the effective b-value of the obtained DWI from the diffusion-gradients applied in the sequence. To this end, a previously described signal model was adapted for dwDESS with bipolar diffusion gradients, which allows to estimate an effective b-value, dubbed b'. Evaluation in phantom examinations was performed on a clinical 1.5 T MR system. Experimental results were compared with theoretical predictions, including the apparent diffusion coefficient (ADC) based on b-values from a standard EPI-DWI sequence and ADC' based on the effective b' from the dwDESS sequence. The adapted signal model was able to describe the experimental results, and the obtained values of ADC' were in line with conventional ADC measurements., Competing Interests: Declaration of Competing Interest None., (Copyright © 2023. Published by Elsevier Inc.)

Published

2024

38. Fast and robust pulsed chemical exchange saturation transfer (CEST) MRI using a quasi-steady-state (QUASS) algorithm at 3 T.

Author

Wu Q, Qi Y, Gong P, Huang B, Cheng G, Liang D, Zheng H, Sun PZ, and Wu Y

Subjects

Humans, Protons, Hydrogen-Ion Concentration, Phantoms, Imaging, Algorithms, Creatine, Magnetic Resonance Imaging methods

Abstract

Chemical exchange saturation transfer (CEST) has emerged as a powerful technique to image dilute labile protons. However, its measurement depends on the RF saturation duration (T sat ) and relaxation delay (T rec ). Although the recently developed quasi-steady-state (QUASS) solution can reconstruct equilibrium CEST effects under continuous-wave RF saturation, it does not apply to pulsed-CEST MRI on clinical scanners with restricted hardware or specific absorption rate limits. This study proposed a QUASS algorithm for pulsed-CEST MRI and evaluated its performance in muscle CEST measurement. An approximated expression of a steady-state pulsed-CEST signal was incorporated in the off-resonance spin-lock model, from which the QUASS pulsed-CEST effect was derived. Numerical simulation, creatine phantom, and healthy volunteer scans were conducted at 3 T. The CEST effect was quantified with asymmetry analysis in the simulation and phantom experiments. CEST effects of creatine, amide proton transfer, phosphocreatine, and combined magnetization transfer and nuclear Overhauser effects were isolated from a multi-pool Lorentzian model in muscles. Apparent and QUASS CEST measurements were compared under different T sat /T rec and duty cycles. Paired Student's t-test was employed with P < 0.05 as statistically significant. The simulation, phantom, and human studies showed the strong impact of T sat /T rec on apparent CEST measurements, which were significantly smaller than the corresponding QUASS CEST measures, especially under short T sat /T rec times. In comparison, the QUASS algorithm mitigates such impact and enables accurate CEST measurements under short T sat /T rec times. In conclusion, the QUASS algorithm can accelerate robust pulsed-CEST MRI, promising the efficient detection and evaluation of muscle diseases in clinical settings., Competing Interests: Declaration of Competing Interest None of the authors have a conflict of interest to disclose., (Copyright © 2023 Elsevier Inc. All rights reserved.)

Published

2024

39. A framework for validating open-source pulse sequences

Author

Gehua Tong, Andreia S. Gaspar, Sairam Geethanath, Rita G. Nunes, Keerthi Sravan Ravi, John Thomas Vaughan, and Enlin Qian

Subjects

Measure (data warehouse), Sequence, Scanner, Phantoms, Imaging, Computer science, business.industry, Biomedical Engineering, Biophysics, Pulse sequence, Usability, computer.software_genre, Magnetic Resonance Imaging, Open source, Reference values, NIST, Radiology, Nuclear Medicine and imaging, Data mining, business, computer

Abstract

Open-source pulse sequence programs offer an accessible and transparent approach to sequence development and deployment. However, a common framework for testing, documenting, and sharing open-source sequences is still needed to ensure sequence usability and repeatability. We propose and demonstrate such a framework by implementing two sequences, Inversion Recovery Spin Echo (IRSE) and Turbo Spin Echo (TSE), with PyPulseq, and testing them on a commercial 3 T scanner. We used the ACR and ISMRM/NIST phantoms for qualitative imaging and T1/T2 mapping, respectively. The qualitative sequences show good agreement with vendor-provided counterparts (mean Structural Similarity Index Measure (SSIM) = 0.810 for IRSE and 0.826 for TSE). Both sequences passed five out of the seven standard ACR tests, performing at similar levels to vendor counterparts. Compared to reference values, the coefficient of determination R2 was 0.9946 for IRSE T1 mapping and 0.9331 for TSE T2 mapping. All sequences passed the scanner safety check for a 70 kg, 175 cm subject. The framework was demonstrated by packaging the sequences and sharing them on GitHub with data and documentation on the file generation, acquisition, reconstruction, and post-processing steps. The same sequences were tested at a second site using a 1.5 T scanner with the information shared. PDF templates for both sequence developers and users were created and filled.

Published

2022

40. Robust brain MR image compressive sensing via re-weighted total variation and sparse regression

Author

Mingyan Zhang, Fan Zhang, Mingli Zhang, Alan C. Evans, and Ahmad Chaddad

Subjects

Phantoms, Imaging, Computer science, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Biomedical Engineering, Biophysics, Brain, Variation (game tree), Data Compression, Magnetic Resonance Imaging, Regularization (mathematics), Imaging phantom, Image (mathematics), Compressed sensing, Image Processing, Computer-Assisted, Redundancy (engineering), Radiology, Nuclear Medicine and imaging, Mr images, Algorithm, Algorithms, Sparse regression

Abstract

Total variation (TV) and non-local self-similarity (NSS) are powerful tools for successfully enhancing compressive sensing performance. However, standard TV approaches often over-smooth detailed edges in the image, due to the uniform regularization of gradient magnitude. In this paper, a novel compressed sensing method for the reconstruction of medical images is proposed, the image edges are well preserved with the proposed reweighted TV. The redundancy of the NSS patch also is leveraged through the sparse regression model. The proposed model was solved with an efficient strategy of the Alternating Direction Method of Multipliers (ADMM) algorithm. Experimental results on thesimulated phantom, brain Magnetic resonance imaging (MRI) show that the proposed method outperforms the state-of-the-art compressed sensing approaches.

Published

2022

41. Evaluation of liver T1 using MOLLI gradient echo readout under the influence of fat

Author

Chia Ying Liu, Chikara Noda, Joao A.C. Lima, Bharath Ambale-Venkatesh, David A. Bluemke, and Yoshimori Kassai

Subjects

Adult, Physics, Phantoms, Imaging, Liver fibrosis, Biomedical Engineering, Biophysics, Reproducibility of Results, Inversion recovery, Middle Aged, Magnetic Resonance Imaging, Imaging phantom, Out of phase, Nuclear magnetic resonance, Liver, Linear Models, Humans, Female, Radiology, Nuclear Medicine and imaging, Fat fraction, Gradient echo

Abstract

The effect of hepatic steatosis on the gradient-echo (GRE) based Modified Look-Locker Inversion Recovery (MOLLI) technique for T1 mapping has not been evaluated. The purpose of this study was to evaluate a GRE based MOLLI technique for hepatic T1 mapping and determine the relationship of T1 differences (ΔT1) on in-phase (IP) and out-of-phase (OP) to fat fraction (FF) measurement.3 T MRI included MOLLI T1 mapping with TE = 1.3 (OP), 2.4 (IP), and 1.8 ms, and chemical-shift-encoded sequence with spectral modeling of fat to generate FF map as a reference. Bloch simulations and oil/water phantoms were used to characterize the response of the MOLLI T1 in various FF 30% since MOLLI T1 estimation was erratic beyond this limit. Curve fit between ΔT1 and FF from simulation was applied to validate the phantom and the in-vivo results. Thirty-eight normal volunteers were included (16 women, Age 44 ± 12 years, BMI 27 ± 5.3 kg/mPhantom results were consistent with the Bloch simulations. The simulated relationship between FF (0-30%) and ΔT1 could be modeled precisely by a cubic equation with R2 = 1. In-vivo MOLLI ΔT1 and estimated FF were correlated to the reference FF (both R2 ≥ 0.96 and P 0.001). TE = 1.8 ms demonstrated less T1 bias (-1.34%) compared to TE = OP (5.32%) or IP (-3.8%, both P 0.001).At 3 T, TE of 1.8 ms can be used to reduce the T1 bias and deliver consistent T1 values when FF is30%.

Published

2022

42. 2D RF pulse design for optimized reduced field-of-view imaging at 1.5T and 3T

Author

Orhun Caner Eren, Emine Ulku Saritas, Bahadir Alp Barlas, Eren, Orhun Caner, Barlas, Bahadır Alp, and Sarıtaş, Emine Ülkü

Subjects

Male, Computer science, Acoustics, media_common.quotation_subject, Biomedical Engineering, Biophysics, Field of view, Imaging phantom, Reduction (complexity), Reduced field-of-view imaging, Robustness (computer science), Humans, Contrast (vision), Radiology, Nuclear Medicine and imaging, Sensitivity (control systems), Off-resonance robustness, media_common, Echo-Planar Imaging, Phantoms, Imaging, Brain, Diffusion weighted imaging, Two-dimensional RF pulse, Magnetic Resonance Imaging, Diffusion Magnetic Resonance Imaging, Excitation profile, Excitation, Diffusion MRI

Abstract

Two-dimensional spatially selective radiofrequency (2DRF) excitation pulses are widely used for reduced field-of-view (FOV) targeted high-resolution diffusion weighted imaging (DWI), especially for anatomically small regions such as the spinal cord and prostate. The reduction in FOV achieved by 2DRF pulses significantly improve the in-plane off-resonance artifacts in single-shot echo planar imaging (ss-EPI). However, long durations of 2DRF pulses create a sensitivity to through-plane off-resonance effects, especially at 3 T where the off-resonance field doubles with respect to 1.5 T. This work proposes a parameter-based optimization approach to design 2DRF pulses with blips along the slice-select axis, with the goal of maximizing slab sharpness while minimizing off-resonance effects on 1.5 T and 3 T MRI scanners, separately. Extensive Bloch simulations are performed to evaluate the off-resonance robustness of 2DRF pulses. Three different metrics are proposed to quantify the similarity between the actual and ideal 2D excitation profiles, based on the signals within and outside the targeted reduced-FOV region. In addition, simulations on a digital brain phantom are performed for visual comparison purposes. The results show that maintaining a sharp profile is the primary design requirement at 1.5 T, necessitating the usage of relatively high slab sharpness with a time-bandwidth product (TBW) around 8–10. In contrast, off-resonance robustness is the primary design requirement at 3 T, requiring the usage of a moderate slap sharpness with TBW around 5–7.

Published

2022

43. Cardiovascular magnetic resonance virtual tagging with B-spline-based free-form deformation

Author

Tosiaki Miyati and Hajime Sagawa

Subjects

Magnetic Resonance Spectroscopy, medicine.diagnostic_test, Phantoms, Imaging, business.industry, Computer science, B-spline, Distortion (optics), Biomedical Engineering, Biophysics, Magnetic Resonance Imaging, Cine, Heart, Magnetic resonance imaging, Magnetic resonance tagging, Magnetic Resonance Imaging, Imaging phantom, Displacement field, medicine, Humans, Radiology, Nuclear Medicine and imaging, Free-form deformation, Computer vision, Artificial intelligence, Wall motion, business

Abstract

Purpose We developed a virtual tagging technique that reconstructs tagging images using the displacement field obtained by applying B-spline free-form deformation (FFD) between diastolic images and images of other cardiac phases in cardiac cine MRI. The purpose of this study was to validate its characteristics and usefulness in phantom and patient studies. Methods Digital phantoms simulating uniform and non-uniform wall motion models were created, and virtual tagging images were reconstructed with various matrix sizes and tag resolutions to evaluate the accuracy of FFD and the characteristics of the tags. In the patient study, FFD's accuracy was assessed at three levels (base, middle, and apex) in healthy patients. In patients with heart failure, virtual tagging images were compared with strain maps obtained by feature tracking and virtual tagging. Results In the phantom study, blurring of tags was observed when tags were reconstructed with high resolution using a small matrix size. In the patient study, the accuracy of FFD was lower in the base than in the apex. Patients with heart failure had decreased distortion of the displacement field vector and virtual tags, indicating decreased local wall motion, consistent with areas of abnormalities found in strain maps. Conclusion The virtual tagging technique does not require additional imaging and can visualize regional LV motion abnormalities via deformation of the tag as well as conventional cardiovascular magnetic resonance tagging.

Published

2021

44. MRI phantom for tissue simulation with respect to diffusion coefficient and kurtosis - Validation with injection of liposomal theranostics

Author

Katarzyna Szcześniak and Beata Wereszczyńska

Subjects

Materials science, Biomedical Engineering, Biophysics, Safflower oil, Imaging phantom, 030218 nuclear medicine & medical imaging, Diffusion, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Humans, Radiology, Nuclear Medicine and imaging, Water diffusion, Precision Medicine, Diffusion (business), Liposome, Phantoms, Imaging, equipment and supplies, Magnetic Resonance Imaging, Silicone oil, body regions, Diffusion Magnetic Resonance Imaging, chemistry, Kurtosis, Particle size, 030217 neurology & neurosurgery, Biomedical engineering

Abstract

This study presents gelatine-based and agar-based phantoms with an addition of glycerol, safflower oil, silicone oil and cellulose microcrystalline with a potential to cover the entire range of tissue diffusion coefficients and kurtosis values. Forty types of phantoms were prepared and examined for NMR relaxation times T1 and T2 and diffusional metrics D, K and ADC. Wide ranges of values of D (0.0003–0.0031 mm2s−1), K (0.00–7.24) and ADC (0.0002–0.0031 mm2s−1) were observed. Two of the phantoms closely mimic muscle and cortical gray matter with respect to water diffusion parameters. Although many of the presented phantoms display both D and K values within the range of human tissues, they match different tissues with respect to D and K. The imaging results for the gray matter simulating phantom injected with the liposomal solution, bear a resemblance to the particle size effect described in the literature. The phantoms presented in this work are simple in preparation and affordable tissue-simulating materials to be used primarily in development of diffusion kurtosis-based MRI methods and possibly in a preliminary assessment of MRI contrast agents. Further adjustments of the chemical compositions could potentially lead to development of new types of phantoms mimicking diffusional properties of more kinds of soft tissues.

Published

2021

45. A parallel spatial and Bloch manifold regularized iterative reconstruction method for MR Fingerprinting

Author

Simon Arberet, Peter Speier, Mariappan S. Nadar, Gregor Körzdörfer, Mathias Nittka, Heiko Meyer, Boris Mailhe, and Xiao Chen

Subjects

Sequence, Phantoms, Imaging, Physics::Medical Physics, Biomedical Engineering, Biophysics, Brain, Iterative reconstruction, Magnetic Resonance Imaging, Regularization (mathematics), Imaging phantom, Manifold, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Bloch equations, Computer Science::Computer Vision and Pattern Recognition, Image Processing, Computer-Assisted, Humans, NIST, Radiology, Nuclear Medicine and imaging, Noise (video), Algorithm, Algorithms, 030217 neurology & neurosurgery

Abstract

Magnetic Resonance Fingerprinting (MRF) reconstructs tissue maps based on a sequence of very highly undersampled images. In order to be able to perform MRF reconstruction, state-of-the-art MRF methods rely on priors such as the MR physics (Bloch equations) and might also use some additional low-rank or spatial regularization. However to our knowledge these three regularizations are not applied together in a joint reconstruction. The reason is that it is indeed challenging to incorporate effectively multiple regularizations in a single MRF optimization algorithm. As a result most of these methods are not robust to noise especially when the sequence length is short. In this paper, we propose a family of new methods where spatial and low-rank regularizations, in addition to the Bloch manifold regularization, are applied on the images. We show on digital phantom and NIST phantom scans, as well as volunteer scans that the proposed methods bring significant improvement in the quality of the estimated tissue maps.

Published

2021

46. Fat-saturated dark-blood cardiac T2 mapping in a single breath-hold

Author

Hamid Mojibian, Vinh Q. Nguyen, Steffen Huber, Lauren A. Baldassarre, Chenxi Hu, and Dana C. Peters

Subjects

T2 mapping, Biomedical Engineering, Biophysics, Imaging phantom, 030218 nuclear medicine & medical imaging, Breath Holding, 03 medical and health sciences, 0302 clinical medicine, Fat saturation, Image Interpretation, Computer-Assisted, Humans, Medicine, Radiology, Nuclear Medicine and imaging, Endocardium, Phantoms, Imaging, business.industry, Reproducibility of Results, Gold standard (test), Single breath, Magnetic Resonance Imaging, Epicardial fat, Dark blood, business, Pericardium, 030217 neurology & neurosurgery, Biomedical engineering

Abstract

Purpose Conventional cardiac T2 mapping suffers from the partial-voluming effect in the endocardium and epicardium due to the co-presence of intra-cavity blood and epicardial fat. The aim of the study is to develop a novel single-breath-hold Fat-Saturated Dark-Blood (FSDB) cardiac T2-mapping technique to mitigate the partial-voluming and improve T2 accuracy. Methods The proposed FSDB T2-mapping technique combines T2-prepared bSSFP, a novel use of double inversion-recovery with heart-rate-adaptive TI, and spectrally-selective fat saturation to mitigate partial-voluming from both the blood and fat. FSDB T2 mapping was compared to conventional T2 mapping via simulations, phantom imaging, healthy-subject imaging (n = 8), and patient imaging (n = 7). In the healthy subjects, a high-resolution coplanar anatomical imaging was performed to provide a gold standard for segmentation of endocardium and epicardium. T2 maps were registered to the gold standard image to evaluate any inter-layer T2 difference, which is a surrogate for partial-voluming. Results Simulations and phantom imaging showed that FSDB T2 mapping was accurate in a range of heartrates, off-resonance, and T2 values, and blood/fat reasonably nulled in a range of heartrates. In healthy subjects, FSDB T2 mapping showed similar T2 values over different myocardial layers in all 3 short-axis slices (e.g. basal epicardial/mid-wall/endocardial T2 = 42 ± 2 ms/41 ± 1 ms/42 ± 1 ms), whereas conventional T2 mapping showed considerably increased T2 in the endocardium and epicardium (e.g. basal epicardial/mid-wall/endocardial T2 = 48 ± 3 ms/43 ± 1 ms/49 ± 3 ms). The homogeneous T2 in the FSDB T2 mapping increased the apparent LV-wall thickness by 25–41% compared with the conventional method. Conclusions The proposed technique improves accuracy of myocardial T2 mapping against partial-voluming associated with both fat and blood, facilitating a multi-layer T2 evaluation of the myocardium. This technique may improve utility of cardiac T2 mapping in diseases affecting the endocardium and epicardium, and in patients with a small heart.

Published

2021

47. Virtual non-contrast enhanced magnetic resonance imaging (VNC-MRI)

Author

Thomas Lindner, Jens Fiehler, and Hanna Debus

Subjects

Scanner, Computer science, media_common.quotation_subject, Biomedical Engineering, Biophysics, Signal, Imaging phantom, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Flip angle, medicine, Humans, Contrast (vision), Radiology, Nuclear Medicine and imaging, Non contrast enhanced, media_common, medicine.diagnostic_test, Phantoms, Imaging, Reproducibility of Results, Magnetic resonance imaging, Magnetic Resonance Imaging, Intensity (physics), Tomography, X-Ray Computed, Algorithms, 030217 neurology & neurosurgery, Biomedical engineering

Abstract

Purpose Application of contrast agents (CA) is widely used in various clinical fields like oncology. Similar to approaches used in computed tomography, virtual non-contrast enhanced (VNC) images can be generated with the goal to supersede true non-contrast enhanced (TNC) images. Methods In MRI a T1-mapping sequence with variable flip angle (VFA) was used to acquire two images with different image contrast at the same time. To generate VNC images postprocessing based on this technique, an image-space based material decomposition algorithm was used. The inverse of a sensitivity matrix, consisting of intensity values for both VFA images and every material respectively, was used to determine the three material fractions and to calculate the final VNC images. The technique was tested on a 3 T scanner using a phantom and two in-vivo scans of patients with glioma and glioblastoma respectively. In all these cases the required six values were manually derived from the respective material or the background from both VFA images. Results Postprocessing results of the phantom show that the chosen materials can be separated and visualized individually and unwanted materials can be suppressed. In the VNC images of in-vivo scans the signal of the CA is removed successfully. Conclusion It was shown that VNC images that match the visual impression of the TNC images can be generated, resulting in possibly reduced scan times and avoided mismatches due to movement of the patient.

Published

2021

48. Dark band artifact in transcranial MR-guided focused ultrasound: Mechanism and mitigation with passive crossed wire antennas.

Author

Yan X, Allen S, Lu M, Moore D, Meyer CH, and Grissom WA

Subjects

Humans, Brain diagnostic imaging, Ultrasonography, Phantoms, Imaging, Magnetic Resonance Imaging methods, Artifacts, Essential Tremor

Abstract

Current FDA-approved transcranial MR-guided focused ultrasound (tcMRgFUS) transducers cause a curved dark band in 3 T brain images that runs through midbrain targets of ablative treatments for essential tremor and other applications, and signal is reduced by at least 25% elsewhere in the brain. This limits the set of scans that can be performed to guide and assess the effects of treatment. An electromagnetic simulation study was performed to elucidate the mechanisms causing the dark band. Based on the results, a pair of passive antennas in a "propeller-beanie" configuration were designed to manipulate the reflected waves to avoid signal cancellation within the brain. The antennas were optimized and validated with in-vivo experiments and hydrophone measurements. The simulation study revealed that the dark band is caused by RF waves reflected from the transducer's ground plane, which cancel with incoming waves from the scanner's body coil. The passive antennas shifted the dark band out of the brain and increased transmit efficiency in the center of brain 2.3 times while improving field homogeneity by 50%. They also increased receive sensitivity and SNR in anatomic and temperature imaging. They caused no detectable distortion in hydrophone-measured focal pressure profiles. The conductive ground planes and coupling media used in tcMRgFUS and other piezoelectric FUS transducers interact with a 3 T scanner's RF fields to reduce transmit efficiency and SNR. For tcMRgFUS scenario, "propeller beanie" passive reflecting antennas alleviated these effects. This could make a broader set of imaging sequences available to guide tcMRgFUS treatment., Competing Interests: Declaration of Competing Interest The topic of this work has been submitted for a United States patent application., (Copyright © 2023 Elsevier Inc. All rights reserved.)

Published

2023

49. A 16-channel loop array for in vivo macaque whole-brain imaging at 7 T.

Author

Lou F, Tang X, Quan Z, Qian M, Wang J, Qu S, Gao Y, Wang Y, Pan G, Lai HY, Roe AW, and Zhang X

Subjects

Animals, Magnetic Resonance Imaging methods, Head, Signal-To-Noise Ratio, Neuroimaging methods, Phantoms, Imaging, Equipment Design, Macaca, Brain diagnostic imaging

Abstract

Combining multimodal approaches with functional magnetic resonance imaging (fMRI) has catapulted the research on brain circuitries of non-human primates (NHPs) into a new era. However, many studies are constrained by a lack of appropriate RF coils. In this study, a single loop transmit and 16-channel receive array coil was constructed for brain imaging of macaques at 7 Tesla (7 T). The 16 receive channels were mounted on a 3D-printed helmet-shaped form closely fitting the macaque head, with fourteen openings arranged for multimodal devices around the cortical regions. Coil performance was evaluated by quantifying and comparing signal-to-noise ratio (SNR) maps, noise correlations, g-factor maps and flip-angle maps with a 28-channel commercial knee coil. The in vivo results suggested that the macaque coil has higher SNR in cortical regions and better acceleration ability in parallel imaging, which may benefit revealing mesoscale organizations in the brain., (Copyright © 2023 Elsevier Inc. All rights reserved.)

Published

2023

50. A hybrid FDTD/MoM algorithm with a conformal Huygens' equivalent surface for MRI RF coil design and analysis.

Author

Liu Y, Wang Q, and Liu F

Subjects

Radio Waves, Phantoms, Imaging, Electromagnetic Fields, Magnetic Resonance Imaging methods, Algorithms

Abstract

Accurate design and analysis of radiofrequency (RF) coils are crucial for ultra-high field (UHF) magnetic resonance imaging (MRI) applications. To improve the numerical accuracy of electromagnetic (EM) simulations, we propose a hybrid finite difference time domain (FDTD)/method of moments (MoM) method. Unlike conventional cuboid-like Huygens' equivalent surfaces (HES), we proposed to use a conformal HES to interface the EM data of the FDTD and MoM zone. The shape and size of the conformal surface can be adjusted to fit different RF coil models, thus broadening the application range of the hybrid FDTD/MoM method. Two numerical models: an 8-channel ellipse array, and an 8-channel bent dipole array, are simulated and compared with the conventional HES counterpart. Numerical results demonstrate the capability of the conformal HES method in the analysis of RF coils., Competing Interests: Declaration of Competing Interest The authors declare that they have no conflict of interest., (Copyright © 2023. Published by Elsevier Inc.)

Published

2023