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1. Simple motion correction strategy reduces respiratory-induced motion artifacts for k-t accelerated and compressed-sensing cardiovascular magnetic resonance perfusion imaging

Author

Ruixi Zhou, Wei Huang, Yang Yang, Xiao Chen, Daniel S. Weller, Christopher M. Kramer, Sebastian Kozerke, and Michael Salerno

Subjects
CMR perfusion, Motion compensation, K-t acceleration, Image reconstruction, Myocardial perfusion, Diseases of the circulatory (Cardiovascular) system, RC666-701
Abstract

Abstract Background Cardiovascular magnetic resonance (CMR) stress perfusion imaging provides important diagnostic and prognostic information in coronary artery disease (CAD). Current clinical sequences have limited temporal and/or spatial resolution, and incomplete heart coverage. Techniques such as k-t principal component analysis (PCA) or k-t sparcity and low rank structure (SLR), which rely on the high degree of spatiotemporal correlation in first-pass perfusion data, can significantly accelerate image acquisition mitigating these problems. However, in the presence of respiratory motion, these techniques can suffer from significant degradation of image quality. A number of techniques based on non-rigid registration have been developed. However, to first approximation, breathing motion predominantly results in rigid motion of the heart. To this end, a simple robust motion correction strategy is proposed for k-t accelerated and compressed sensing (CS) perfusion imaging. Methods A simple respiratory motion compensation (MC) strategy for k-t accelerated and compressed-sensing CMR perfusion imaging to selectively correct respiratory motion of the heart was implemented based on linear k-space phase shifts derived from rigid motion registration of a region-of-interest (ROI) encompassing the heart. A variable density Poisson disk acquisition strategy was used to minimize coherent aliasing in the presence of respiratory motion, and images were reconstructed using k-t PCA and k-t SLR with or without motion correction. The strategy was evaluated in a CMR-extended cardiac torso digital (XCAT) phantom and in prospectively acquired first-pass perfusion studies in 12 subjects undergoing clinically ordered CMR studies. Phantom studies were assessed using the Structural Similarity Index (SSIM) and Root Mean Square Error (RMSE). In patient studies, image quality was scored in a blinded fashion by two experienced cardiologists. Results In the phantom experiments, images reconstructed with the MC strategy had higher SSIM (p

Published
2018
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2. Correction to: Simple motion correction strategy reduces respiratory-induced motion artifacts for k-t accelerated and compressed-sensing cardiovascular magnetic resonance perfusion imaging

Author

Ruixi Zhou, Wei Huang, Yang Yang, Xiao Chen, Daniel S. Weller, Christopher M. Kramer, Sebastian Kozerke, and Michael Salerno

Subjects
Diseases of the circulatory (Cardiovascular) system, RC666-701
Abstract

Figure 1 of this original publication contained a minor error as one of the lines in the “Reconstruction pipline” was not visible. The updated Fig. 1 is published in this correction article.

Published
2018
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22. Free‐breathing self‐gated <scp>continuous‐IR</scp> spiral <scp>T1</scp> mapping: Comparison of dual flip‐angle and <scp>Bloch‐Siegert B1</scp> ‐corrected techniques

Author

Ruixi Zhou, Junyu Wang, Daniel S. Weller, Yang Yang, John P. Mugler, and Michael Salerno

Subjects
Phantoms, Imaging, Respiration, Humans, Reproducibility of Results, Heart, Radiology, Nuclear Medicine and imaging, Magnetic Resonance Imaging
Abstract

To develop a B1-corrrected single flip-angle continuous acquisition strategy with free-breathing and cardiac self-gating for spiral T1 mapping, and compare it to a previous dual flip-angle technique.Data were continuously acquired using a spiral-out trajectory, rotated by the golden angle in time. During the first 2 s, off-resonance Fermi RF pulses were applied to generate a Bloch-Siegert shift B1 map, and the subsequent data were acquired with an inversion RF pulse applied every 4 s to create a T1* map. The final T1 map was generated from the B1 and the T1* maps by using a look-up table that accounted for slice profile effects, yielding more accurate T1 values. T1 values were compared to those from inversion recovery (IR) spin echo (phantom only), MOLLI, SAturation-recovery single-SHot Acquisition (SASHA), and previously proposed dual flip-angle results. This strategy was evaluated in a phantom and 25 human subjects.The proposed technique showed good agreement with IR spin-echo results in the phantom experiment. For in-vivo studies, the proposed technique and the previously proposed dual flip-angle method were more similar to SASHA results than to MOLLI results.B1-corrected single flip-angle T1 mapping successfully acquired B1 and T1 maps in a free-breathing, continuous-IR spiral acquisition, providing a method with improved accuracy to measure T1 using a continuous Look-Locker acquisition, as compared to the previously proposed dual excitation flip-angle technique.

Published
2022
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39. High spatial resolution spiral first‐pass myocardial perfusion imaging with whole‐heart coverage at 3 T

Author

Changyu Sun, Ruixi Zhou, Christopher M. Kramer, Matthew Van Houten, Yang Yang, Michael Salerno, Daniel S. Weller, Junyu Wang, Frederick H. Epstein, and Craig H. Meyer

Subjects
medicine.diagnostic_test, Image quality, business.industry, Perfusion Imaging, Myocardial Perfusion Imaging, Perfusion scanning, medicine.disease, 030218 nuclear medicine & medical imaging, Coronary artery disease, Motion, 03 medical and health sciences, Myocardial perfusion imaging, 0302 clinical medicine, Image Processing, Computer-Assisted, medicine, Humans, Radiology, Nuclear Medicine and imaging, Nuclear medicine, business, Pericardium, Perfusion, Image resolution, 030217 neurology & neurosurgery, Endocardium, Spiral
Abstract

PURPOSE To develop and evaluate a high spatial resolution (1.25 × 1.25 mm2 ) spiral first-pass myocardial perfusion imaging technique with whole-heart coverage at 3T, to better assess transmural differences in perfusion between the endocardium and epicardium, to quantify the myocardial ischemic burden, and to improve the detection of obstructive coronary artery disease. METHODS Whole-heart high-resolution spiral perfusion pulse sequences and corresponding motion-compensated reconstruction techniques for both interleaved single-slice (SS) and simultaneous multi-slice (SMS) acquisition with or without outer-volume suppression (OVS) were developed. The proposed techniques were evaluated in 34 healthy volunteers and 8 patients (55 data sets). SS and SMS images were reconstructed using motion-compensated L1-SPIRiT and SMS-Slice-L1-SPIRiT, respectively. Images were blindly graded by 2 experienced cardiologists on a 5-point scale (5, excellent; 1, poor). RESULTS High-quality perfusion imaging was achieved for both SS and SMS acquisitions with or without OVS. The SS technique without OVS had the highest scores (4.5 [4, 5]), which were greater than scores for SS with OVS (3.5 [3.25, 3.75], P < .05), MB = 2 without OVS (3.75 [3.25, 4], P < .05), and MB = 2 with OVS (3.75 [2.75, 4], P < .05), but significantly higher than those for MB = 3 without OVS (4 [4, 4], P = .95). SMS image quality was improved using SMS-Slice-L1-SPIRiT as compared to SMS-L1-SPIRiT (P < .05 for both reviewers). CONCLUSION We demonstrated the successful implementation of whole-heart spiral perfusion imaging with high resolution at 3T. Good image quality was achieved, and the SS without OVS showed the best image quality. Evaluation in patients with expected ischemic heart disease is warranted.

Published
2021
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40. Dual‐excitation flip‐angle simultaneous cine and T 1 mapping using spiral acquisition with respiratory and cardiac self‐gating

Author

Yang Yang, Michael Salerno, Junyu Wang, Haris Jeelani, Ruixi Zhou, Daniel S. Weller, and John P. Mugler

Subjects
Scanner, Heartbeat, Image quality, business.industry, Computer science, Pulse sequence, Signal, Imaging phantom, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Flip angle, Radiology, Nuclear Medicine and imaging, Computer vision, Artificial intelligence, business, 030217 neurology & neurosurgery, Spiral
Abstract

Purpose To develop a free-breathing cardiac self-gated technique that provides cine images and B 1 + slice profile-corrected T1 maps from a single acquisition. Methods Without breath-holding or electrocardiogram gating, data were acquired continuously on a 3T scanner using a golden-angle gradient-echo spiral pulse sequence, with an inversion RF pulse applied every 4 seconds. Flip angles of 3° and 15° were used for readouts after the first four and second four inversions. Self-gating cardiac triggers were extracted from heart image navigators, and respiratory motion was corrected by rigid registration on each heartbeat. Cine images were reconstructed from the steady-state portion of 15° readouts using a low-rank plus sparse reconstruction. The T1 maps were fit using a projection onto convex sets approach from images reconstructed using slice profile-corrected dictionary learning. This strategy was evaluated in a phantom and 14 human subjects. Results The self-gated signal demonstrated close agreement with the acquired electrocardiogram signal. The image quality for the proposed cine images and standard clinical balanced SSFP images were 4.31 (±0.50) and 4.65 (±0.30), respectively. The slice profile-corrected T1 values were similar to those of the inversion-recovery spin-echo technique in phantom, and had a higher global T1 value than that of MOLLI in human subjects. Conclusions Cine and T1 mapping using spiral acquisition with respiratory and cardiac self-gating successfully acquired T1 maps and cine images in a single acquisition without the need for electrocardiogram gating or breath-holding. This dual-excitation flip-angle approach provides a novel approach for measuring T1 while accounting for B 1 + and slice profile effect on the apparent T 1 ∗ .

Published
2021
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43. DEep learning‐based rapid Spiral Image REconstruction (DESIRE) for high‐resolution spiral first‐pass myocardial perfusion imaging

Author

Junyu Wang, Daniel S. Weller, Christopher M. Kramer, and Michael Salerno

Subjects
Deep Learning, Image Processing, Computer-Assisted, Myocardial Perfusion Imaging, Humans, Molecular Medicine, Radiology, Nuclear Medicine and imaging, Prospective Studies, Magnetic Resonance Imaging, Spectroscopy, Retrospective Studies
Abstract

The objective of the current study was to develop and evaluate a DEep learning-based rapid Spiral Image REconstruction (DESIRE) technique for high-resolution spiral first-pass myocardial perfusion imaging with whole-heart coverage, to provide fast and accurate image reconstruction for both single-slice (SS) and simultaneous multislice (SMS) acquisitions. Three-dimensional U-Net-based image enhancement architectures were evaluated for high-resolution spiral perfusion imaging at 3 T. The SS and SMS MB = 2 networks were trained on SS perfusion images from 156 slices from 20 subjects. Structural similarity index (SSIM), peak signal-to-noise ratio (PSNR), and normalized root mean square error (NRMSE) were assessed, and prospective images were blindly graded by two experienced cardiologists (5: excellent; 1: poor). Excellent performance was demonstrated for the proposed technique. For SS, SSIM, PSNR, and NRMSE were 0.977 [0.972, 0.982], 42.113 [40.174, 43.493] dB, and 0.102 [0.080, 0.125], respectively, for the best network. For SMS MB = 2 retrospective data, SSIM, PSNR, and NRMSE were 0.961 [0.950, 0.969], 40.834 [39.619, 42.004] dB, and 0.107 [0.086, 0.133], respectively, for the best network. The image quality scores were 4.5 [4.1, 4.8], 4.5 [4.3, 4.6], 3.5 [3.3, 4], and 3.5 [3.3, 3.8] for SS DESIRE, SS L1-SPIRiT, MB = 2 DESIRE, and MB = 2 SMS-slice-L1-SPIRiT, respectively, showing no statistically significant difference (p = 1 and p = 1 for SS and SMS, respectively) between L1-SPIRiT and the proposed DESIRE technique. The network inference time was ~100 ms per dynamic perfusion series with DESIRE, while the reconstruction time of L1-SPIRiT with GPU acceleration was ~ 30 min. It was concluded that DESIRE enabled fast and high-quality image reconstruction for both SS and SMS MB = 2 whole-heart high-resolution spiral perfusion imaging.

Published
2021
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44. Free‐breathing cine imaging with motion‐corrected reconstruction at 3T using SPiral Acquisition with Respiratory correction and Cardiac Self‐gating (SPARCS)

Author

Yang Yang, Michael Salerno, Mathews Jacob, Daniel S. Weller, John P. Mugler, Ruixi Zhou, Christopher M. Kramer, Roshin C. Mathew, and Abdul Haseeb Ahmed

Subjects
Cardiac function curve, Heartbeat, Image quality, Cardiac-Gated Imaging Techniques, Magnetic Resonance Imaging, Cine, Article, 030218 nuclear medicine & medical imaging, Breath Holding, 03 medical and health sciences, 0302 clinical medicine, Data acquisition, Image Interpretation, Computer-Assisted, Humans, Medicine, Radiology, Nuclear Medicine and imaging, cardiovascular diseases, Spiral, Ejection fraction, business.industry, Respiration, Heart, Pulse sequence, cardiovascular system, Golden angle, business, Nuclear medicine, 030217 neurology & neurosurgery
Abstract

PURPOSE To develop a continuous-acquisition cardiac self-gated spiral pulse sequence and a respiratory motion-compensated reconstruction strategy for free-breathing cine imaging. METHODS Cine data were acquired continuously on a 3T scanner for 8 seconds per slice without ECG gating or breath-holding, using a golden-angle gradient echo spiral pulse sequence. Cardiac motion information was extracted by applying principal component analysis on the gridded 8 × 8 k-space center data. Respiratory motion was corrected by rigid registration on each heartbeat. Images were reconstructed using a low-rank and sparse (L+S) technique. This strategy was evaluated in 37 healthy subjects and 8 subjects undergoing clinical cardiac MR studies. Image quality was scored (1-5 scale) in a blinded fashion by 2 experienced cardiologists. In 13 subjects with whole-heart coverage, left ventricular ejection fraction (LVEF) from SPiral Acquisition with Respiratory correction and Cardiac Self-gating (SPARCS) was compared to that from a standard ECG-gated breath-hold balanced steady-state free precession (bSSFP) cine sequence. RESULTS The self-gated signal was successfully extracted in all cases and demonstrated close agreement with the acquired ECG signal (mean bias, -0.22 ms). The mean image score across all subjects was 4.0 for reconstruction using the L+S model. There was good agreement between the LVEF derived from SPARCS and the gold-standard bSSFP technique. CONCLUSION SPARCS successfully images cardiac function without the need for ECG gating or breath-holding. With an 8-second data acquisition per slice, whole-heart cine images with clinically acceptable spatial and temporal resolution and image quality can be acquired in

Published
2019
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45. Machine learning architecture to predict drug response based on cancer cell FLIM images

Author

Karsten H. Siller, Daniel S. Weller, Horst Wallrabe, Jiaxin Zhang, Ammasi Periasamy, and Shagufta Rehman Alam

Subjects
Flavin adenine dinucleotide, chemistry.chemical_compound, chemistry, Principal component analysis, LNCaP, Feature extraction, NAD+ kinase, Nicotinamide adenine dinucleotide, Mixture model, Biological system, Autoencoder
Abstract

With different states of two intrinsic fluorophores, nicotinamide adenine dinucleotide (phosphate) (NAD(P)H) and flavin adenine dinucleotide (FAD), we developed a single-layer autoencoder (AE) for feature extraction, which outputs condensed features representing the full metabolic FLIM information with lower dimensionality. We also described distributions of AE features and fluorescence lifetime redox ratio (FLIRR) from single cells by Gaussian mixture models (GMM), and predicted the values of FLIRR based on feature data from each time point for the HeLa cell lines and Caucasian-American (LNCaP) prostate cancer cell lines by the polynomial regression model and the random forest regression model.

Published
2021
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46. Dual excitation flip angle simultaneous Cine And T(1) mapping using SPiral Acquisition with Respiratory and Cardiac Self-gating (CAT-SPARCS)

Author

Ruixi, Zhou, Daniel S, Weller, Yang, Yang, Junyu, Wang, Haris, Jeelani, John P, Mugler, and Michael, Salerno

Subjects
Breath Holding, Phantoms, Imaging, Image Interpretation, Computer-Assisted, Humans, Magnetic Resonance Imaging, Cine, Reproducibility of Results, Heart, Article
Abstract

PURPOSE: To develop a free-breathing cardiac self-gated technique that provides cine images and [Formula: see text] and slice profile corrected T(1) maps from a single acquisition. METHODS: Without breath-holding or ECG-gating, data were acquired continuously on a 3 Tesla scanner using a golden-angle gradient-echo spiral pulse sequence, with an inversion RF pulse applied every four seconds. 3° and 15° flip angles were used for readouts after the first four and second four inversions. Self-gating cardiac triggers were extracted from heart image navigators and respiratory motion was corrected by rigid registration on each heartbeat. Cine images were reconstructed from the steady state portion of 15° readouts using a low-rank plus sparse reconstruction. T(1) maps were fit using a projection onto convex sets approach from images reconstructed using slice profile corrected dictionary learning. This strategy was evaluated in a phantom and 14 human subjects. RESULTS: The self-gated signal demonstrated close agreement with the acquired ECG signal. The image quality for the proposed cine images and standard clinical bSSFP images were 4.31 (± 0.50) and 4.65 (± 0.30) respectively. The slice profile corrected T(1) values were similar to those of the inversion-recovery spin-echo technique in phantom, and had a higher global T(1) value than that of MOLLI in human subjects. CONCLUSIONS: CAT-SPARCS successfully acquired T(1) maps and cine images in a single acquisition without the need for ECG-gating or breath-holding. This dual excitation flip angle approach provides a novel approach for measuring T(1) while accounting for [Formula: see text] and slice profile effect on the apparent [Formula: see text].

Published
2021

47. Content-aware compressive magnetic resonance image reconstruction

Author

Michael Salerno, Craig H. Meyer, and Daniel S. Weller

Subjects
Computer science, Noise reduction, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Biomedical Engineering, Biophysics, 02 engineering and technology, Iterative reconstruction, Regularization (mathematics), Article, 030218 nuclear medicine & medical imaging, law.invention, 03 medical and health sciences, 0302 clinical medicine, Wavelet, law, Image Processing, Computer-Assisted, 0202 electrical engineering, electronic engineering, information engineering, medicine, Humans, Radiology, Nuclear Medicine and imaging, Cartesian coordinate system, medicine.diagnostic_test, business.industry, Brain, 020206 networking & telecommunications, Pattern recognition, Magnetic resonance imaging, Data Compression, Image Enhancement, Magnetic Resonance Imaging, Compressed sensing, Computer Science::Computer Vision and Pattern Recognition, Artificial intelligence, Parallel imaging, business, Algorithms
Abstract

This paper describes an adaptive approach to regularizing model-based reconstructions in magnetic resonance imaging to account for local structure or image content. In conjunction with common models like wavelet and total variation sparsity, this content-aware regularization avoids oversmoothing or compromising image features while suppressing noise and incoherent aliasing from accelerated imaging. To evaluate this regularization approach, the experiments reconstruct images from single- and multi-channel, Cartesian and non-Cartesian, brain and cardiac data. These reconstructions combine common analysis-form regularizers and autocalibrating parallel imaging (when applicable). In most cases, the results show widespread improvement in structural similarity and peak-signal-to-error ratio relative to the fully sampled images. These results suggest that this content-aware regularization can preserve local image structures such as edges while providing denoising power superior to sparsity-promoting or sparsity-reweighted regularization.

Published
2018
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48. Art for Institutional Change: Legitimizing Women in STEM Through Visibility

Author

Daniel S. Weller, Catherine Uffman, Gertrude Fraser, and Caitlin Donahue Wylie

Subjects
Gender equity, Portrait, Oral history, ComputingMilieux_THECOMPUTINGPROFESSION, Institutional change, Visibility (geometry), ComputingMilieux_COMPUTERSANDEDUCATION, Organizational culture, Behavioural sciences, Narrative, Gender studies, General Medicine, Sociology
Abstract

The ADVANCE program strives to change institutional culture to promote gender equity among faculty in science, engineering, and social and behavioral sciences. This is a challenging goal, as most ADVANCE teams have experienced. We found that one powerful way to approach changing individuals’ perspectives and institutions’ cultures is through art. Our ADVANCE team at the University of Virginia built three exhibits—two physical exhibits on campus and one online exhibit—to portray and celebrate our women faculty through photographic portraits and oral history narratives of their experiences. Our aim was to make women visible in spaces in which they were historically barred or overlooked, such as in particular disciplines as well as at UVA itself, which only admitted women students in the 1970s. This paper documents how and why we used art to challenge assumptions about women scholars and how we evaluated the exhibits’ impact on the UVA community.

Published
2019
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49. Erratum to: Dual excitation flip angle simultaneous cine and T 1 mapping using SPiral Acquisition with Respiratory and Cardiac Self‐gating (CAT‐SPARCS) (Magn Reson Med 2021; 86:82‐96)

Author

Ruixi Zhou, John P. Mugler, Daniel S. Weller, Haris Jeelani, Junyu Wang, Yang Yang, and Michael Salerno

Subjects
Physics, Nuclear magnetic resonance, Flip angle, Self gating, Radiology, Nuclear Medicine and imaging, DUAL (cognitive architecture), Spiral, Excitation
Published
2021
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50. Mechanism of seizure-induced retrograde amnesia

Author

J. Julius Zhu, Cedric L. Williams, Aijaz Ahmad Naik, Huayu Sun, Daniel S. Weller, and Jaideep Kapur

Subjects
0301 basic medicine, Dendritic spine, Hippocampus, Engram, Biology, Article, 03 medical and health sciences, 0302 clinical medicine, Seizures, medicine, Humans, CA1 Region, Hippocampal, Neuronal Plasticity, Pyramidal Cells, General Neuroscience, Excitatory Postsynaptic Potentials, Retrograde amnesia, Long-term potentiation, T-maze, medicine.disease, 030104 developmental biology, nervous system, Synapses, Synaptic plasticity, Excitatory postsynaptic potential, Amnesia, Retrograde, Neuroscience, 030217 neurology & neurosurgery
Abstract

Seizures cause retrograde amnesia, but underlying mechanisms are poorly understood. We tested whether seizure activated neuronal circuits overlap with spatial memory engram and whether seizures saturate LTP in engram cells. A seizure caused retrograde amnesia for spatial memory task. Spatial learning and a seizure caused cFos expression and synaptic plasticity overlapping set of neurons in the CA1 of the hippocampus. Recordings from learning-labeled CA1 pyramidal neurons showed potentiated synapses. Seizure-tagged neurons were also more excitable with larger rectifying excitatory postsynaptic currents than surrounding unlabeled neurons. These neurons had enlarged dendritic spines and saturated LTP. A seizure immediately after learning, reset the memory engram. Seizures cause retrograde amnesia through shared ensembles and mechanisms.

Published
2021
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