Yanqiu Feng scite author profile

Content-based image retrieval (CBIR) techniques have currently gained increasing popularity in the medical field because they can use numerous and valuable archived images to support clinical decisions. In this paper, we concentrate on developing a CBIR system for retrieving brain tumors in T1-weighted contrast-enhanced MRI images. Specifically, when the user roughly outlines the tumor region of a query image, brain tumor images in the database of the same pathological type are expected to be returned. We propose a novel feature extraction framework to improve the retrieval performance. The proposed framework consists of three steps. First, we augment the tumor region and use the augmented tumor region as the region of interest to incorporate informative contextual information. Second, the augmented tumor region is split into subregions by an adaptive spatial division method based on intensity orders; within each subregion, we extract raw image patches as local features. Third, we apply the Fisher kernel framework to aggregate the local features of each subregion into a respective single vector representation and concatenate these per-subregion vector representations to obtain an image-level signature. After feature extraction, a closed-form metric learning algorithm is applied to measure the similarity between the query image and database images. Extensive experiments are conducted on a large dataset of 3604 images with three types of brain tumors, namely, meningiomas, gliomas, and pituitary tumors. The mean average precision can reach 94.68%. Experimental results demonstrate the power of the proposed algorithm against some related state-of-the-art methods on the same dataset.

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Improved MRIR₂* relaxometry of iron‐loaded liver with noise correction

Feng

Gatehouse

et al. 2013

Magnetic Resonance in Med

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Accurate and reproducible MRI R2 * relaxometry for tissue iron quantification is important in managing transfusion-dependent patients. MRI data are often acquired using array coils and reconstructed by the root-sum-square algorithm, and as such, measured signals follow the noncentral chi distribution. In this study, two noise-corrected models were proposed for the liver R2 * quantification: fitting the signal to the first moment and fitting the squared signal to the second moment in the presence of the noncentral chi noise. These two models were compared with the widely implemented offset and truncation models on both simulation and in vivo data. The results demonstrated that the "slow decay component" of the liver R2 * was mainly caused by the noise. The offset model considerably overestimated R2 * values by incorrectly adding a constant to account for the slow decay component. The truncation model generally produced accurate R2 * measurements by only fitting the initial data well above the noise level to remove the major source of errors, but underestimated very high R2 * values due to the sequence limit of obtaining very short echo time images. Both the first and second-moment noise-corrected models constantly produced accurate and precise R2 * measurements by correctly addressing the noise problem.

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Robust EPI Nyquist ghost removal by incorporating phase error correction with sensitivity encoding (PEC‐SENSE)

Xie

Lyu

Liu

et al. 2017

Magnetic Resonance in Med

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In vivo comparison of myocardial T1 with T2 and T2* in thalassaemia major

Feng

Carpenter

et al. 2013

Magnetic Resonance Imaging

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In patients with iron overload, myocardial T2 and T1 are correlated with T2*. In patients with low or normal myocardial iron concentration, other factors become dominant in affecting T2* values as shown by scattered T2* data. Myocardial T1 correlates linearly with T2 measurements in all patients suggesting that these two relaxation parameters avoid extrinsic magnetic field inhomogeneity effects and may potentially provide improved myocardial tissue characterization.

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Predicting DNA-binding proteins: approached from Chou’s pseudo amino acid composition and other specific sequence features

et al. 2007

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DNA-binding proteins play a pivotal role in gene regulation. It is vitally important to develop an automated and efficient method for timely identification of novel DNA-binding proteins. In this study, we proposed a method based on alone the primary sequences of proteins to predict the DNA-binding proteins. DNA-binding proteins were encoded by autocross-covariance transform, pseudo-amino acid composition, dipeptide composition, respectively and also the different combinations of the three encoded methods; further, these feature matrices were applied to support vector machine classifiers to predict the DNA-binding proteins. All modules were trained and validated by the jackknife cross-validation test. Through comparing the performance of these substituted modules, the best result was obtained from pseudo-amino acid composition with the overall accuracy of 96.6% and the sensitivity of 90.7%. The results suggest that it can efficiently predict the novel DNA-binding proteins only using the primary sequences.

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Denoising of 3D magnetic resonance images by using higher-order singular value decomposition

Zhang

Jia

et al. 2015

Medical Image Analysis

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Denoise diffusion-weighted images using higher-order singular value decomposition

Zhang

Peng

et al. 2017

NeuroImage

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Robust SENSE reconstruction of simultaneous multislice EPI with low‐rank enhanced coil sensitivity calibration and slice‐dependent 2D Nyquist ghost correction

Lyu

Barth

Xie

et al. 2018

Magnetic Resonance in Med

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Yanqiu Feng

Retrieval of Brain Tumors by Adaptive Spatial Pooling and Fisher Vector Representation

Improved MRIR₂* relaxometry of iron‐loaded liver with noise correction

Robust EPI Nyquist ghost removal by incorporating phase error correction with sensitivity encoding (PEC‐SENSE)

In vivo comparison of myocardial T1 with T2 and T2* in thalassaemia major

Predicting DNA-binding proteins: approached from Chou’s pseudo amino acid composition and other specific sequence features

Denoising of 3D magnetic resonance images by using higher-order singular value decomposition

Denoise diffusion-weighted images using higher-order singular value decomposition

Robust SENSE reconstruction of simultaneous multislice EPI with low‐rank enhanced coil sensitivity calibration and slice‐dependent 2D Nyquist ghost correction

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Yanqiu Feng

Retrieval of Brain Tumors by Adaptive Spatial Pooling and Fisher Vector Representation

Improved MRIR2* relaxometry of iron‐loaded liver with noise correction

Robust EPI Nyquist ghost removal by incorporating phase error correction with sensitivity encoding (PEC‐SENSE)

In vivo comparison of myocardial T1 with T2 and T2* in thalassaemia major

Predicting DNA-binding proteins: approached from Chou’s pseudo amino acid composition and other specific sequence features

Denoising of 3D magnetic resonance images by using higher-order singular value decomposition

Denoise diffusion-weighted images using higher-order singular value decomposition

Robust SENSE reconstruction of simultaneous multislice EPI with low‐rank enhanced coil sensitivity calibration and slice‐dependent 2D Nyquist ghost correction

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Product

Resources

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Improved MRIR₂* relaxometry of iron‐loaded liver with noise correction