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1. CBCT scatter correction with dual-layer flat-panel detector

Author

Zhang, Xin, Xie, Jixiong, Su, Ting, Zhu, Jiongtao, Cui, Han, Tan, Yuhang, Xia, Dongmei, Zheng, Hairong, Liang, Dong, and Ge, Yongshuai

Subjects
Physics - Medical Physics
Abstract

Background: Recently, the popularity of dual-layer flat-panel detector (DL-FPD) based dual-energy cone-beam CT (DE-CBCT) imaging has been increasing. However, the image quality of DE-CBCT remains constrained by the Compton scattered X-ray photons. Purpose: The objective of this study is to develop an energy-modulated scatter correction method for DL-FPD based CBCT imaging. Methods: In DL-FPD, a certain portion of the X-ray photons (mainly low-energy primary and scattered photons) passing through the object are captured by the top detector layer, while the remaining X-ray photons (mainly high-energy primary and scattered photons) are collected by the bottom detector layer. Based on the two set of distinct low-energy and high-energy measurements, a linear signal model was approximated for the dual-energy primary and scattered signals on DL-FPD. The distributions of X-ray scatters were quickly estimated using this signal model. Monte Carlo (MC) simulation of a water phantom was conducted to verify this newly developed scatter estimation method. Moreover, physical experiments of water phantom, head phantom, and abdominal phantom were carried out to validate the real performance of this proposed scatter correction method. Results: The MC results showed that the e-Grid method was able to generate scatter distributions close to the ground truth. Moreover, the physical experiments demonstrated that the e-Grid method can greatly reduce the shading artifacts in both low-energy and high-energy CBCT images acquired from DL-FPD. On average, the image non-uniformity (NU) was reduced by over 77% in the low-energy CBCT image and by over 66% in the high-energy CBCT image. A a consequence, the accuracy of the decomposed multi-material bases was substantially improved.

Published
2024

2. Explanations of MTF discrepancy in grating-based X-ray differential phase contrast CT imaging

Author

Tan, Yuhang, Yang, Jiecheng, Zheng, Hairong, Liang, Dong, Zhu, Peiping, and Ge, Yongshuai

Subjects
Physics - Medical Physics, Physics - Optics, J.2
Abstract

As a multi-contrast X-ray computed tomography (CT) imaging system, the grating-based Talbot-Lau interferometer is able to generate the absorption contrast and differential phase contrast (DPC) images concurrently. However, experiments found that the absorption CT (ACT) images have better spatial resolution, i.e., higher modulation transfer function (MTF), than the differential phase contrast CT (DPCT) images. Until now, the root cause of such observed discrepancy has not been rigorously investigated. Through physical experiments, this study revealed that the phase grating in the Talbot-Lau interferometer induces direct superposition of paired split absorption signals and inverse superposition of paired split phase signals via diffraction. Further simulation experiments demonstrated that this splitting leads to a reduction in MTF in both ACT and DPCT images, with distinct superposition mechanisms contributing to the lower MTF in DPCT. Besides, such MTF discrepancy may also be affected in a minor extent by object composition, sample size, beam spectra and detector pixel size. Based on this study, the spatial resolution could be optimized when designing a grating-based DPC imaging system., Comment: 7 pages,3 figures

Published
2024

3. Super resolution dual-layer CBCT imaging with model-guided deep learning

Author

Zhu, Jiongtao, Su, Ting, Zhang, Xin, Cui, Han, Tan, Yuhang, Zheng, Hairong, Liang, Dong, Guo, Jinchuan, and Ge, Yongshuai

Subjects
Physics - Medical Physics
Abstract

Objective: This study aims at investigating a novel super resolution CBCT imaging technique with the dual-layer flat panel detector (DL-FPD). Approach: In DL-FPD based CBCT imaging, the low-energy and high-energy projections acquired from the top and bottom detector layers contain intrinsically mismatched spatial information, from which super resolution CBCT images can be generated. To explain, a simple mathematical model is established according to the signal formation procedure in DL-FPD. Next, a dedicated recurrent neural network (RNN), named as suRi-Net, is designed by referring to the above imaging model to retrieve the high resolution dual-energy information. Different phantom experiments are conducted to validate the performance of this newly developed super resolution CBCT imaging method. Main Results: Results show that the proposed suRi-Net can retrieve high spatial resolution information accurately from the low-energy and high-energy projections having lower spatial resolution. Quantitatively, the spatial resolution of the reconstructed CBCT images of the top and bottom detector layers is increased by about 45% and 54%, respectively. Significance: In future, suRi-Net provides a new approach to achieve high spatial resolution dual-energy imaging in DL-FPD based CBCT systems.

Published
2023

5. Model-driven CT reconstruction algorithm for nano-resolution X-ray phase contrast imaging

Author

Cai, Xuebao, Tan, Yuhang, Su, Ting, Liang, Dong, Zheng, Hairong, Xu, Jinyou, Zhu, Peiping, and Ge, Yongshuai

Subjects
Electrical Engineering and Systems Science - Image and Video Processing, Physics - Medical Physics, Physics - Optics
Abstract

The low-density imaging performance of a zone plate based nano-resolution hard X-ray computed tomography (CT) system can be significantly improved by incorporating a grating-based Lau interferometer. Due to the diffraction, however, the acquired nano-resolution phase signal may suffer splitting problem, which impedes the direct reconstruction of phase contrast CT (nPCT) images. To overcome, a new model-driven nPCT image reconstruction algorithm is developed in this study. In it, the diffraction procedure is mathematically modeled into a matrix B, from which the projections without signal splitting can be generated invertedly. Furthermore, a penalized weighed least-square model with total variation (PWLS-TV) is employed to denoise these projections, from which nPCT images with high accuracy are directly reconstructed. Numerical and physical experiments demonstrate that this new algorithm is able to work with phase projections having any splitting distances. Results also reveal that nPCT images with higher signal-to-noise-ratio (SNR) would be reconstructed from projections with larger signal splittings. In conclusion, a novel model-driven nPCT image reconstruction algorithm with high accuracy and robustness is verified for the Lau interferometer based hard X-ray nano-resolution phase contrast imaging.

Published
2023

6. Super resolution dual-energy cone-beam CT imaging with dual-layer flat-panel detector

Author

Su, Ting, Zhu, Jiongtao, Zhang, Xin, Zeng, Dong, Tan, Yuhang, Cui, Han, Zheng, Hairong, Ma, Jianhua, Liang, Dong, and Ge, Yongshuai

Subjects
Physics - Medical Physics
Abstract

For medical cone-beam computed tomography (CBCT) imaging, the native receptor array of the flat-panel detector (FPD) is usually binned into a reduced matrix size. By doing so, the signal readout speed can be increased by over 4-9 times at the expense of sacrificing the spatial resolution by at least 50%-67%. Clearly, such tradition poses a main bottleneck in generating high spatial resolution and high temporal resolution CBCT images at the same time. In addition, the conventional FPD is also difficult in generating dual-energy CBCT images. In this paper, we propose an innovative super resolution dual-energy CBCT imaging method, named as suRi, based on dual-layer FPD (DL-FPD) to overcome these aforementioned difficulties at once. With suRi, specifically, an 1D or 2D sub-pixel (half pixel in this study) shifted binning is applied to replace the conventionally aligned binning to double the spatial sampling rate during the dual-energy data acquisition. As a result, the suRi approach provides a new strategy to enable high signal readout speed and high spatial resolution CBCT imaging with FPD. Moreover, a penalized likelihood material decomposition algorithm is developed to directly reconstruct the high resolution bases from the dual-energy CBCT projections containing spatial sub-pixel shifts. Experiments based on the single-layer FPD and DL-FPD are performed with physical phantoms and biological specimen to validate this newly developed suRi method. The synthesized monochromatic CT imaging results demonstrate that suRi can significantly improve the spatial image resolution by 46.15%. We believe the developed suRi method would be capable to greatly enhance the imaging performance of the DL-FPD based dual-energy CBCT systems in future.

Published
2022

7. CMOS based high-resolution dynamic X-ray imaging with inorganic perovskite

Author

Liu, Yanliang, Gao, Chaosong, Zhu, Jiongtao, Zhang, Xin, Wu, Meng, Su, Ting, Wang, Jiahong, Sheng, Zonghai, Liu, Wenjun, Shi, Tongyu, He, Xingchen, Liang, Dong, Zheng, Hairong, Yu, Xue-Feng, Sun, Xiangming, and Ge, Yongshuai

Subjects
Physics - Applied Physics
Abstract

High-resolution dynamic X-ray detector is crucial for time-resolved digital radiography (DR) imaging and fast 3D medical computed tomography (CT) imaging. Recently, perovskites have become promising alternatives to conventional semi-conductor materials, e.g., Si, a-Se and CdTe, for direct X-ray detection. However, the feasibility of their combination with high-speed pixelated complementary metal-oxide-semiconductor (CMOS) arrays remains unknown. This work originally reports an innovative direct-conversion X-ray detector fabricated with 300 micrometer thick inorganic perovskite film printed on a tailored CMOS array. In-house measurements demonstrate that the CsPbBr3 film has excellent optoelectric properties of an electron mobility-lifetime product of 3.40x10$^{-5}$ cm$^2$ V$^{-1}$, and the X-ray detector exhibits high sensitivity of 9341uC Gy$_{\rm air}^{-1}$ cm$^{-2}$, and low detection limit of 588 nGy$_{\rm air}^{-1}$. This CMOS X-ray imaging detector achieves a high spatial resolution up to 5.5 lp/mm (close to the resolution limit of 6.0 lp/mm), and >300 frame per second (fps) readout speed. DR image of a resolution pattern phantom and a anesthesia mice, CT images of a biological specimen are acquired for the first time.

Published
2022

8. Dual-domain Attention-based Deep Network for Sparse-view CT Artifact Reduction

Author

Gao, Xiang, Su, Ting, Zhu, Jiongtao, Yang, Jiecheng, Zhang, Yunxin, Mi, Donghua, Zheng, Hairong, Long, Xiaojing, Liang, Dong, and Ge, Yongshuai

Subjects
Physics - Medical Physics
Abstract

Due to the wide applications of X-ray computed tomography (CT) in medical imaging activities, radiation exposure has become a major concern for public health. Sparse-view CT is a promising approach to reduce the radiation dose by down-sampling the total number of acquired projections. However, the CT images reconstructed by this sparse-view imaging approach suffer from severe streaking artifacts and structural information loss. In this work, an end-to-end dual-domain attention-based deep network (DDANet) is proposed to solve such an ill-posed CT image reconstruction problem. The image-domain CT image and the projection-domain sinogram are put into the two parallel sub-networks of the DDANet to independently extract the distinct high-level feature maps. In addition, a specified attention module is introduced to fuse the aforementioned dual-domain feature maps to allow complementary optimizations of removing the streaking artifacts and mitigating the loss of structure. Numerical simulations, anthropomorphic thorax phantom and in vivo pre-clinical experiments are conducted to verify the sparse-view CT imaging performance of the DDANet. Results demonstrate that this newly developed approach is able to robustly remove the streaking artifacts while maintaining the fine structures. As a result, the DDANet provides a promising solution in achieving high quality sparse-view CT imaging.

Published
2022

9. X-ray phase-sensitive microscope imaging with a grating interferometer: theory and simulation

Author

Yang, Jiecheng, Ge, Yongshuai, Liang, Dong, and Zheng, Hairong

Subjects
Physics - Optics, Physics - Instrumentation and Detectors
Abstract

In this work, a general theoretical framework is presented to explain the formation of the phase signal in an X-ray microscope integrated with a grating interferometer, which simultaneously enables the high spatial resolution imaging and the improved image contrast. Using this theory, several key parameters of phase contrast imaging can be predicted, for instance, the fringe visibility and period, the conversion condition from the differential phase imaging (DPI) to the phase difference imaging (PDI). Additionally, numerical simulations are performed with certain X-ray optical components and imaging geometry. Results demonstrate the accuracy of this developed quantitative analysis method of X-ray phase-sensitive microscope imaging., Comment: 8 pages, 3 figures

Published
2021
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11. DIRECT-Net: a unified mutual-domain material decomposition network for quantitative dual-energy CT imaging

Author

Su, Ting, Sun, Xindong, Zhang, Yikun, Wu, Haodi, Chen, Jianwei, Yang, Jiecheng, Chen, Yang, Zheng, Hairong, Liang, Dong, and Ge, Yongshuai

Subjects
Physics - Medical Physics, Electrical Engineering and Systems Science - Image and Video Processing
Abstract

By acquiring two sets of tomographic measurements at distinct X-ray spectra, the dual-energy CT (DECT) enables quantitative material-specific imaging. However, the conventionally decomposed material basis images may encounter severe image noise amplification and artifacts, resulting in degraded image quality and decreased quantitative accuracy. Iterative DECT image reconstruction algorithms incorporating either the sinogram or the CT image prior information have shown potential advantages in noise and artifact suppression, but with the expense of large computational resource, prolonged reconstruction time, and tedious manual selections of algorithm parameters. To partially overcome these limitations, we develop a domain-transformation enabled end-to-end deep convolutional neural network (DIRECT-Net) to perform high quality DECT material decomposition. Specifically, the proposed DIRECT-Net has immediate accesses to mutual-domain data, and utilizes stacked convolution neural network (CNN) layers for noise reduction and material decomposition. The training data are numerically simulated based on the underlying physics of DECT imaging.The XCAT digital phantom, iodine solutions phantom, and biological specimen are used to validate the performance of DIRECT-Net. The qualitative and quantitative results demonstrate that this newly developed DIRECT-Net is promising in suppressing noise, improving image accuracy, and reducing computation time for future DECT imaging.

Published
2020

12. DIR-DBTnet: Deep iterative reconstruction network for 3D digital breast tomosynthesis imaging

Author

Su, Ting, Deng, Xiaolei, Wang, Zhenwei, Yang, Jiecheng, Chen, Jianwei, Zheng, Hairong, Liang, Dong, and Ge, Yongshuai

Subjects
Physics - Medical Physics, Electrical Engineering and Systems Science - Image and Video Processing
Abstract

Purpose: The goal of this study is to develop a novel deep learning (DL) based reconstruction framework to improve the digital breast tomosynthesis (DBT) imaging performance. Methods: In this work, the DIR-DBTnet is developed for DBT image reconstruction by unrolling the standard iterative reconstruction algorithm within the deep learning framework. In particular, such network learns the regularizer and the iteration parameters automatically through network training with a large amount of simulated DBT data. Afterwards, both numerical and experimental data are used to evaluate its performance. Quantitative metrics such as the artifact spread function (ASF), breast density, and the signal difference to noise ratio (SDNR) are used for image quality assessment. Results: For both numerical and experimental data, the proposed DIR-DBTnet generates reduced in-plane shadow artifacts and out-of-plane artifacts compared with the filtered back projection (FBP) and total variation (TV) methods. Quantitatively, the full width half maximum (FWHM) of the measured ASF curve from the numerical data is 33.4% and 19.7% smaller than those obtained with the FBP and TV methods, respectively; the breast density of the network reconstructed DBT images is more accurate and consistent with the ground truth. Conclusions: In conclusion, a deep iterative reconstruction network, DIR-DBTnet, has been proposed. Both qualitative and quantitative analyses of the numerical and experimental results show superior DBT imaging performance than the FBP and iterative algorithms.

Published
2020
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13. Estimation of angular sensitivity for X-ray interferometers with multiple phase gratings

Author

Chen, Jianwei, Yang, Jiecheng, Zhu, Peiping, Su, Ting, Zhang, Huitao, Zheng, Hairong, Liang, Dong, and Ge, Yongshuai

Subjects
Physics - Instrumentation and Detectors, Physics - Optics
Abstract

Recently, X-ray interferometers with more than one phase grating have been developed for differential phase contrast (DPC) imaging. In this study, a novel framework is developed to predict such interferometers' angular sensitivity responses (the minimum detectable refraction angle). Experiments are performed on the dual and triple phase grating interferometers, separately. Measurements show strong consistency with the predicted sensitivity values. Using this new approach, the DPC imaging performance of X-ray interferometers with multiple phase gratings can be further optimized for future biomedical applications.

Published
2020

15. X-ray differential phase contrast imaging on asymmetric dual-phase grating interferometer with source grating: theory and experiment

Author

Ge, Yongshuai, Chen, Jianwei, Zhu, Peiping, Yang, Jun, Luo, Ronghui, Shi, Wei, Zhang, Kai, Guo, Jinchuang, Hairong, Zheng, and Liang, Dong

Subjects
Physics - Optics, Physics - Medical Physics
Abstract

Recently, the dual-phase grating based X-ray differential phase contrast imaging technique has shown better radiation dose efficiency performance than the Talbot-Lau system. In this paper, we provide a theoretical analyses framework derived from wave optics to ease the design of such interferometer systems, including the inter-grating distances, the diffraction fringe period, the phase grating periods, and especially the source grating period if a medical grade X-ray tube with large focal spot is utilized. In addition, a geometrical explanation of the dual-phase grating system similar to the standard thin lens imaging theory is derived with an optical symmetry assumption for the first time. Finally, both numerical and experimental studies have been performed to validate the theory., Comment: 21 pages, 7 figures

Published
2019

16. Model-based Deep Medical Imaging: the roadmap of generalizing iterative reconstruction model using deep learning

Author

Cheng, Jing, Wang, Haifeng, Zhu, Yanjie, Liu, Qiegen, Zhang, Qiyang, Su, Ting, Chen, Jianwei, Ge, Yongshuai, Hu, Zhanli, Liu, Xin, Zheng, Hairong, Ying, Leslie, and Liang, Dong

Subjects
Computer Science - Computer Vision and Pattern Recognition, Electrical Engineering and Systems Science - Signal Processing, Mathematics - Optimization and Control, Physics - Medical Physics, Statistics - Machine Learning
Abstract

Medical imaging is playing a more and more important role in clinics. However, there are several issues in different imaging modalities such as slow imaging speed in MRI, radiation injury in CT and PET. Therefore, accelerating MRI, reducing radiation dose in CT and PET have been ongoing research topics since their invention. Usually, acquiring less data is a direct but important strategy to address these issues. However, less acquisition usually results in aliasing artifacts in reconstructions. Recently, deep learning (DL) has been introduced in medical image reconstruction and shown potential on significantly speeding up MR reconstruction and reducing radiation dose. In this paper, we propose a general framework on combining the reconstruction model with deep learning to maximize the potential of deep learning and model-based reconstruction, and give the examples to demonstrate the performance and requirements of unrolling different algorithms using deep learning., Comment: part of the preliminary work will be presented at MICCAI2019

Published
2019

17. Automatic image-domain Moire artifact reduction method in grating-based x-ray interferometry imaging

Author

Chen, Jianwei, Zhu, Jiongtao, Shi, Wei, Zheng, Hairong, Liang, Dong, and Ge, Yongshuai

Subjects
Physics - Medical Physics
Abstract

The aim of this study is to demonstrate the feasibility of removing the image Moire artifacts caused by system inaccuracies in grating-based x-ray interferometry imaging system via convolutional neural network (CNN) technique. Instead of minimizing these inconsistencies between the acquired phase stepping data via certain optimized signal retrieval algorithms, our newly proposed CNN-based method reduces the Moire artifacts in the image-domain via a learned image post-processing procedure. To ease the training data preparations, we propose to synthesize them with numerical natural images and experimentally obtained Moire artifact-only-images. Moreover, a fast signal processing method has also been developed to generate the needed large number of high quality Moire artifact-only images from finite number of acquired experimental phase stepping data. Experimental results show that the CNN method is able to remove Moire artifacts effectively, while maintaining the signal accuracy and image resolution.

Published
2019
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19. Deconvolution-Based Backproject-Filter (BPF) Computed Tomography Image Reconstruction Method Using Deep Learning Technique

Author

Ge, Yongshuai, Zhang, Qiyang, Hu, Zhanli, Chen, Jianwei, Shi, Wei, Zheng, Hairong, and Liang, Dong

Subjects
Physics - Medical Physics
Abstract

For conventional computed tomography (CT) image reconstruction tasks, the most popular method is the so-called filtered-back-projection (FBP) algorithm. In it, the acquired Radon projections are usually filtered first by a ramp kernel before back-projected to generate CT images. In this work, as a contrary, we realized the idea of image-domain backproject-filter (BPF) CT image reconstruction using the deep learning techniques for the first time. With a properly designed convolutional neural network (CNN), preliminary results demonstrate that it is feasible to reconstruct CT images with maintained high spatial resolution and accurate pixel values from the highly blurred back-projection image, i.e., laminogram. In addition, experimental results also show that this deconvolution-based CT image reconstruction network has the potential to reduce CT image noise (up to 20%), indicating that patient radiation dose may be reduced. Due to these advantages, this proposed CNN-based image-domain BPF type CT image reconstruction scheme provides promising prospects in generating high spatial resolution, low-noise CT images for future clinical applications.

Published
2018

20. Driver behaviour recognition based on recursive all‐pair field transform time series model.

Author

Xu, HuiZhi, Xing, ZhaoHao, Ge, YongShuai, Hao, DongSheng, and Chang, MengYing

Subjects
INTELLIGENT transportation systems, TRANSPORTATION management, OPTICAL flow, FEATURE extraction, COMPUTER vision
Abstract

To standardize driver behaviour and enhance transportation system safety, a dynamic driver behaviour recognition method based on the Recurrent All‐Pairs Field Transforms (RAFT) temporal model is proposed. This study involves the creation of two datasets, namely, Driver‐img and Driver‐vid, including driver behaviour images and videos across various scenarios. These datasets are subject to preprocessing using RAFT optical flow techniques to enhance the cognitive process of the network. This approach employs a two‐stage temporal model for driver behaviour recognition. In the initial stage, the MobileNet network is optimized and the GYY module is introduced, which includes residuals and global average pooling layers, thereby enhancing the network's feature extraction capabilities. In the subsequent stage, a bidirectional GRU network is constructed to learn driver behaviour video features with temporal information. Additionally, a method for compressing and padding video frames is proposed, which serves as input to the GRU network and enables intent prediction 0.2 s prior to driver actions. Model performance is assessed through accuracy, recall, and F1 score, with experimental results indicating that RAFT preprocessing enhances accuracy, reduces training time, and improves overall model stability, facilitating the recognition of driver behaviour intent. [ABSTRACT FROM AUTHOR]

Published
2024
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24. HEAL: High-Frequency Enhanced and Attention-Guided Learning Network for Sparse-View CT Reconstruction.

Author

Li, Guang, Deng, Zhenhao, Ge, Yongshuai, and Luo, Shouhua

Subjects
COMPUTED tomography, IONIZING radiation, DEEP learning, RADIATION doses, HEALING
Abstract

X-ray computed tomography (CT) imaging technology has become an indispensable diagnostic tool in clinical examination. However, it poses a risk of ionizing radiation, making the reduction of radiation dose one of the current research hotspots in CT imaging. Sparse-view imaging, as one of the main methods for reducing radiation dose, has made significant progress in recent years. In particular, sparse-view reconstruction methods based on deep learning have shown promising results. Nevertheless, efficiently recovering image details under ultra-sparse conditions remains a challenge. To address this challenge, this paper proposes a high-frequency enhanced and attention-guided learning Network (HEAL). HEAL includes three optimization strategies to achieve detail enhancement: Firstly, we introduce a dual-domain progressive enhancement module, which leverages fidelity constraints within each domain and consistency constraints across domains to effectively narrow the solution space. Secondly, we incorporate both channel and spatial attention mechanisms to improve the network's feature-scaling process. Finally, we propose a high-frequency component enhancement regularization term that integrates residual learning with direction-weighted total variation, utilizing directional cues to effectively distinguish between noise and textures. The HEAL network is trained, validated and tested under different ultra-sparse configurations of 60 views and 30 views, demonstrating its advantages in reconstruction accuracy and detail enhancement. [ABSTRACT FROM AUTHOR]

Published
2024
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28. The fast light of CsI(Na) crystals

Author

Sun, Xilei, Lu, Junguang, Hu, Tao, Zhou, Li, Cao, Jun, Wang, Yifang, Zhan, Liang, Yu, Boxiang, Cai, Xiao, Fang, Jian, Xie, Yuguang, An, Zhenghua, Wang, Zhigang, Xue, Zhen, Zhang, Aiwu, Lu, Qiwen, Ning, Feipeng, Ge, Yongshuai, and Liu, Yingbiao

Subjects
Physics - Instrumentation and Detectors
Abstract

The responds of different common alkali halide crystals to alpha-rays and gamma-rays are tested in our research. It is found that only CsI(Na) crystals have significantly different waveforms between alpha and gamma scintillations, while others have not this phenomena. It is suggested that the fast light of CsI(Na) crystals arises from the recombination of free electrons with self-trapped holes of the host crystal CsI. Self-absorption limits the emission of fast light of CsI(Tl) and NaI(Tl) crystals., Comment: 5 pages, 11 figures Submit to Chinese Physics C

Published
2011
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29. Neutron-gamma discrimination of CsI(Na) crystals for dark matter searches

Author

Sun, Xilei, Lu, Junguang, Hu, Tao, Zhou, Li, Cao, Jun, Wang, Yifang, Zhan, Liang, Yu, Boxiang, Cai, Xiao, Fang, Jian, Xie, Yuguang, An, Zhenghua, Wang, Zhigang, Xue, Zhen, Lu, Qiwen, Ning, Feipeng, Ge, Yongshuai, and Liu, Yingbiao

Subjects
Physics - Instrumentation and Detectors, Astrophysics - Cosmology and Extragalactic Astrophysics, Astrophysics - Instrumentation and Methods for Astrophysics, High Energy Physics - Experiment
Abstract

The luminescent properties of CsI(Na) crystals are studied in this report. By using a TDS3054C oscilloscope with a sampling frequency of 5 GS/s, we find out that nuclear recoil signals are dominated by very fast light pulse with a decay time of ~20 ns, while {\gamma}-ray signals have a decay time of ~600 ns. The wavelength of nuclear recoil and {\gamma}-ray signals are also different. The study of n/{\gamma} separation shows that the rejection factor can reach an order of 10-7 with signal efficiency more than 80% at an equivalent electron recoil energy of 20 keV or more. Such a property makes CsI(Na) an ideal candidate for dark matter searches., Comment: 11 pages, 15 figures

Published
2011
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30. Super-resolution dual-layer CBCT imaging with model-guided deep learning.

Author

Zhu, Jiongtao, Su, Ting, Zhang, Xin, Cui, Han, Tan, Yuhang, Zheng, Hairong, Liang, Dong, Guo, Jinchuan, and Ge, Yongshuai

Subjects
CONE beam computed tomography, DEEP learning, RECURRENT neural networks, HIGH resolution imaging, COMPUTED tomography, SPATIAL resolution
Abstract

Objective. This study aims at investigating a novel super resolution CBCT imaging approach with a dual-layer flat panel detector (DL-FPD). Approach. With DL-FPD, the low-energy and high-energy projections acquired from the top and bottom detector layers contain over-sampled spatial information, from which super-resolution CT images can be reconstructed. A simple mathematical model is proposed to explain the signal formation procedure in DL-FPD, and a dedicated recurrent neural network, named suRi-Net, is developed based upon the above imaging model to nonlinearly retrieve the high-resolution dual-energy information. Physical benchtop experiments are conducted to validate the performance of this newly developed super-resolution CBCT imaging method. Main Results. The results demonstrate that the proposed suRi-Net can accurately retrieve high spatial resolution information from the low-energy and high-energy projections of low spatial resolution. Quantitatively, the spatial resolution of the reconstructed CBCT images from the top and bottom detector layers is increased by about 45% and 54%, respectively. Significance. In the future, suRi-Net will provide a new approach to perform high spatial resolution dual-energy imaging in DL-FPD-based CBCT systems. [ABSTRACT FROM AUTHOR]

Published
2024
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31. Performance evaluation of quantitative material decomposition in slow kVp switching dual-energy CT.

Author

Ma, Chenchen, Su, Ting, Zhu, Jiongtao, Zhang, Xin, Zheng, Hairong, Liang, Dong, Wang, Na, Zhang, Yunxin, and Ge, Yongshuai

Subjects
DUAL energy CT (Tomography)
Abstract

BACKGROUND: Slow kVp switching technique is an important approach to realize dual-energy CT (DECT) imaging, but its performance has not been thoroughly investigated yet. OBJECTIVE: This study aims at comparing and evaluating the DECT imaging performance of different slow kVp switching protocols, and thus helps determining the optimal system settings. METHODS: To investigate the impact of energy separation, two different beam filtration schemes are compared: the stationary beam filtration and dynamic beam filtration. Moreover, uniform tube voltage modulation and weighted tube voltage modulation are compared along with various modulation frequencies. A model-based direct decomposition algorithm is employed to generate the water and iodine material bases. Both numerical and physical experiments are conducted to verify the slow kVp switching DECT imaging performance. RESULTS: Numerical and experimental results demonstrate that the material decomposition is less sensitive to beam filtration, voltage modulation type and modulation frequency. As a result, robust material-specific quantitative decomposition can be achieved in slow kVp switching DECT imaging. CONCLUSIONS: Quantitative DECT imaging can be implemented with slow kVp switching under a variety of system settings. [ABSTRACT FROM AUTHOR]

Published
2024
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35. Super Resolution Dual-Energy Cone-Beam CT Imaging With Dual-Layer Flat-Panel Detector

Author

Su, Ting, Zhu, Jiongtao, Zhang, Xin, Tan, Yuhang, Cui, Han, Zeng, Dong, Guo, Jinchuan, Zheng, Hairong, Ma, Jianhua, Liang, Dong, and Ge, Yongshuai

Abstract

In flat-panel detector (FPD) based cone-beam computed tomography (CBCT) imaging, the native receptor array is usually binned into a smaller matrix size. By doing so, the signal readout speed could be increased by 4–9 times at the expense of a spatial resolution loss of 50%-67%. Clearly, such manipulation poses a key bottleneck in generating high spatial and high temporal resolution CBCT images at the same time. In addition, the conventional FPD is also difficult in generating dual-energy CBCT images. In this paper, we propose an innovative super resolution dual-energy CBCT imaging method, named as suRi, based on dual-layer FPD (DL-FPD) to overcome these aforementioned difficulties at once. With suRi, specifically, a 1D or 2D sub-pixel (half pixel in this study) shifted binning is applied instead of the conventionally aligned binning to double the spatial sampling rate during the dual-energy data acquisition. As a result, the suRi approach provides a new strategy to enable high spatial resolution CBCT imaging while at high readout speed. Moreover, a penalized likelihood material decomposition algorithm is developed to directly reconstruct the high resolution bases from these dual-energy CBCT projections containing sub-pixel shifts. Numerical and physical experiments are performed to validate this newly developed suRi method with phantoms and biological specimen. Results demonstrate that suRi can significantly improve the spatial resolution of the CBCT image. We believe this developed suRi method would greatly enhance the imaging performance of the DL-FPD based dual-energy CBCT systems in future.

Published
2024
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38. PbI 2 ‐DMSO Assisted In Situ Growth of Perovskite Wafers for Sensitive Direct X‐Ray Detection

Author

Liu, Wenjun, primary, Shi, Tongyu, additional, Zhu, Jiongtao, additional, Zhang, Zhenyu, additional, Li, Dong, additional, He, Xingchen, additional, Fan, Xiongsheng, additional, Meng, Lingqiang, additional, Wang, Jiahong, additional, He, Rui, additional, Ge, Yongshuai, additional, Liu, Yanliang, additional, Chu, Paul K., additional, and Yu, Xue‐Feng, additional

Published
2022
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40. CsPbBr3-DMSO merged perovskite micro-bricks for efficient X-ray detection.

Author

Shi, Tongyu, Liu, Wenjun, Zhu, Jiongtao, Fan, Xiongsheng, Zhang, Zhengyu, He, Xingchen, He, Rui, Wang, Jiahong, Chen, Kezhen, Ge, Yongshuai, Sun, Xiangming, Liu, Yanliang, Chu, Paul K., and Yu, Xue-Feng

Subjects
X-ray detection, CRYSTAL defects, DIMETHYL sulfoxide, PEROVSKITE, CRYSTAL grain boundaries, BRICKS, DETECTION limit
Abstract

Inorganic perovskite wafers with good stability and adjustable sizes are promising in X-ray detection but the high synthetic temperature is a hindrance. Herein, dimethyl sulfoxide (DMSO) is used to prepare the CsPbBr3 micro-bricks powder at room temperature. The CsPbBr3 powder has a cubic shape with few crystal defects, small charge trap density, and high crystallinity. A trace amount of DMSO attaches to the surface of the CsPbBr3 micro-bricks via Pb-O bonding, forming the CsPbBr3-DMSO adduct. During hot isostatic processing, the released DMSO vapor merges the CsPbBr3 micro-bricks, producing a compact and dense CsPbBr3 wafer with minimized grain boundaries and excellent charge transport properties. The CsPbBr3 wafer shows a large mobility-lifetime (μτ) product of 5.16 × 104 cm2·V1, high sensitivity of 14,430 μC·Gyair−1·cm−2, low detection limit of 564 nGyair·s−1, as well as robust stability in X-ray detection. The results reveal a novel strategy with immense practical potential pertaining to high-contrast X-ray detection. [ABSTRACT FROM AUTHOR]

Published
2023
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49. PbI2‐DMSO Assisted In Situ Growth of Perovskite Wafers for Sensitive Direct X‐Ray Detection.

Author

Liu, Wenjun, Shi, Tongyu, Zhu, Jiongtao, Zhang, Zhenyu, Li, Dong, He, Xingchen, Fan, Xiongsheng, Meng, Lingqiang, Wang, Jiahong, He, Rui, Ge, Yongshuai, Liu, Yanliang, Chu, Paul K., and Yu, Xue‐Feng

Subjects
X-ray detection, DIMETHYL sulfoxide, PEROVSKITE, ISOSTATIC pressing, CRYSTAL growth, CRYSTAL grain boundaries
Abstract

Although perovskite wafers with a scalable size and thickness are suitable for direct X‐ray detection, polycrystalline perovskite wafers have drawbacks such as the high defect density, defective grain boundaries, and low crystallinity. Herein, PbI2‐DMSO powders are introduced into the MAPbI3 wafer to facilitate crystal growth. The PbI2 powders absorb a certain amount of DMSO to form the PbI2‐DMSO powders and PbI2‐DMSO is converted back into PbI2 under heating while releasing DMSO vapor. During isostatic pressing of the MAPbI3 wafer with the PbI2‐DMSO solid additive, the released DMSO vapor facilitates in situ growth in the MAPbI3 wafer with enhanced crystallinity and reduced defect density. A dense and compact MAPbI3 wafer with a high mobility‐lifetime (µτ) product of 8.70 × 10−4 cm2 V−1 is produced. The MAPbI3‐based direct X‐ray detector fabricated for demonstration shows a high sensitivity of 1.58 × 104 µC Gyair−1 cm−2 and a low detection limit of 410 nGyair s−1. [ABSTRACT FROM AUTHOR]

Published
2023
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50. Peroxisome proliferator‑activated receptor γ alleviates human umbilical vein endothelial cell injury in deep vein thrombosis by blocking endoplasmic reticulum stress.

Author

Zhang, Yunxin, Ge, Yongshuai, Tao, Liyuan, Liu, Mingyuan, Jia, Wei, Tian, Xuan, Jiang, Peng, Cheng, Zhiyuan, Li, Jinyong, and Liu, Jianlong

Subjects
*VENOUS thrombosis, *PEROXISOME proliferator-activated receptors, *UMBILICAL veins, *WESTERN immunoblotting, *ENDOPLASMIC reticulum
Abstract

The present study aimed to explore the role of peroxisome proliferator-activated receptor γ (PPARγ) in the development of deep vein thrombosis (DVT), as well as to discover the potential regulatory mechanism of PPARγ. Human umbilical vein endothelial cells (HUVECs) were treated with modified glycated human serum albumin (M-HSA) to mimic DVT. PPARγ expression and activity were detected using western blot analysis and the corresponding activity detection kit, respectively. Cell Counting Kit-8 and the terminal deoxynucleotidyl-transferase-mediated dUTP nick end labeling assays were employed to detect cell viability and apoptosis, respectively. The levels of thrombosis-related factors and inflammatory cytokines were detected by ELISA. The levels of oxidative stress-related factors were determined by the corresponding commercial kits. In addition, tunicamycin (TM), the agonist of endoplasmic reticulum stress (ERS), was applied to investigate the potential mechanism. The results indicated that M-HSA caused reduced expression and activity of PPARγ in HUVECs; these effects were reversed by PPARγ overexpression, which significantly inhibited M-HSA-induced cell viability loss, cell apoptosis, inflammation and oxidative stress in HUVECs. In addition, ERS was activated following M-HSA stimulation in HUVECs, but was suppressed by PPARγ overexpression. Furthermore, TM partly abolished the protective role of PPARγ overexpression against cell viability loss, cell apoptosis, inflammation and oxidative stress in M-HSA-induced HUVECs. In summary, PPARγ antagonized M-HSA-induced HUVEC injury by suppressing the activation of ERS, which provides a novel strategy for the treatment of DVT. [ABSTRACT FROM AUTHOR]

Published
2024
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