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5. Flotation process and process mineralogy analysis of certain zinc sulphide ores.

Author

Zeng Ling-Ming, Ou Le-Ming, Zeng Ling-Ming, and Ou Le-Ming

Abstract

Zinc sulphide ore bulk flotation process samples were investigated using mineral liberation analysis (MLA) to confirm the dissemination properties of sphalerite and intergrowth minerals. The MLA results indicate that the liberation degree of sphalerite in copper tailings is 85.97%; the minerals would be recovered by quick flotation rather than regrinding. The liberation degree in tailings is 82.09% with the minerals mostly of particle sizes less than 10 microns. A quick flotation process is proposed to reform the original bulk flotation process. Closed circuit test results show that, compared with the original process, the zinc grade and recovery rate of concentrate in the new process increase by 0.90% and 0.38%, respectively. MLA of the test products suggest the new process can solve problems of sphalerite overgrinding and intergrowth minerals dissociation during regrinding. The industrial test result indicates that compared with the original process, the zinc grade of the concentrate is more than 48% and the recovery rate increases by 0.867%, which proves the feasibility of quick flotation in industrial application., Zinc sulphide ore bulk flotation process samples were investigated using mineral liberation analysis (MLA) to confirm the dissemination properties of sphalerite and intergrowth minerals. The MLA results indicate that the liberation degree of sphalerite in copper tailings is 85.97%; the minerals would be recovered by quick flotation rather than regrinding. The liberation degree in tailings is 82.09% with the minerals mostly of particle sizes less than 10 microns. A quick flotation process is proposed to reform the original bulk flotation process. Closed circuit test results show that, compared with the original process, the zinc grade and recovery rate of concentrate in the new process increase by 0.90% and 0.38%, respectively. MLA of the test products suggest the new process can solve problems of sphalerite overgrinding and intergrowth minerals dissociation during regrinding. The industrial test result indicates that compared with the original process, the zinc grade of the concentrate is more than 48% and the recovery rate increases by 0.867%, which proves the feasibility of quick flotation in industrial application.

6. [Feasibility Study of Ultra-High-Resolution Low-Dose Temporal Bone CT with 1 024×1 024 Reconstruction Matrix Size].

Author

Zeng LM, Huang T, Liu JL, Deng H, Cao LB, Li X, Ding G, Dai H, and Li ZL

Subjects
Adult, Feasibility Studies, Humans, Male, Phantoms, Imaging, Radiation Dosage, Signal-To-Noise Ratio, Temporal Bone diagnostic imaging, Tomography, X-Ray Computed
Abstract

Objective: To investigate the feasibility of low-dose CT scan of the temporal bone combined with reconstruction matrix size of 1 024×1 024 and the effect of the reconstruction matrix size on image quality., Methods: Normal-dose and low-dose bilateral temporal bone CT scans were performed on twelve adult male cadaveric skull specimens using the 160-slice multi-detector CT scanning of United Imaging Healthcare. Normal-dose CT images were reconstructed with matrix sizes of 512×512 and 1 024×1 024, while low-dose CT images were reconstructed with the matrix size of 1 024×1 024. CT value, noise, signal-to-noise ratio, contrast-to-noise ratio, the visualization scoring of 15 anatomical structures of the temporal bone, and the result of three-dimensional reconstruction of the ossicular chain were compared among the three groups., Results: The radiation dose of low-dose CT scanning was reduced by about 50% compared with that of normal-dose CT. There was no significant difference in CT values of air, soft tissues and bones among the three groups. Low-dose temporal bone CT with the matrix size of 1 024×1 024 had higher noise, but much better visualization of temporal bone structure than the normal-dose temporal bone CT with matrix size of 512×512. Both the three-dimensional reconstructions of normal-dose and low-dose 1 024×1 024 matrix images were satisfactory and showed no significant difference. The morphology, size and relative position of malleus, incus, stapes, cochlea, and labyrinth, as well as the location of the ossicular chain in the cranium were all clearly displayed., Conclusion: Low-dose temporal bone CT with the matrix size of 1 024×1 024 can be used to effectively reduce the radiation dose and significantly improve the spatial resolution and the visualization of the temporal bone anatomical structures compared with the normal-dose temporal bone CT with a matrix size of 512×512., (Copyright© by Editorial Board of Journal of Sichuan University (Medical Sciences).)

Published
2021
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7. [Application of Deep Learning Reconstruction Algorithm in Low-Dose Thin-Slice Liver CT of Healthy Volunteers].

Author

Zeng LM, Xu X, Zeng W, Peng WL, Zhang JG, Hu SX, Liu KL, Xia CC, and Li ZL

Subjects
Algorithms, Healthy Volunteers, Humans, Liver diagnostic imaging, Radiation Dosage, Radiographic Image Interpretation, Computer-Assisted, Tomography, X-Ray Computed, Deep Learning
Abstract

Objective: To explore the clinical feasibility of applying deep learning (DL) reconstruction algorithm in low-dose thin-slice liver CT examination of healthy volunteers by comparing the reconstruction algorithm based on DL, filtered back projection (FBP) reconstruction algorithm and iterative reconstruction (IR) algorithm., Methods: A standard water phantom with a diameter of 180 mm was scanned, using the 160 slice multi-detector CT scanning of United Imaging Healthcare, to compare the noise power spectrums of DL, FBP and IR algorithms. 100 healthy volunteers were prospectively enrolled, with 50 assigned to the normal dose group (ND) and 50 to the low dose group (LD). IR algorithm was used in the ND group to reconstruct images, while DL, FBP and IR algorithms were used in the LD group to reconstruct images. One-way analysis of variance was used to compare the liver CT values, the liver noise, liver signal-to-noise ratio (SNR), contrast noise ratio (CNR) and figure of merit (FOM) of the images of ND-IR, LD-FBP, LD-IR and LD-DL. The Kruskal-Wallis test was used to analyse subjective scores of anatomical structures., Results: The DL algorithm had the lowest average peak value of noise power spectrum, and its shape was similar to that of medium-level IR algorithm. Liver CT values of ND-IR, LD-FBP, LD-IR and LD-DL did not show statistically significant difference. The noise of LD-DL was lower than that of LD-FBP, LD-IR and ND-IR ( P <0.05), and the SNR, CNR and FOM of LD-DL were higher than those of LD-FBP, LD-IR and ND-IR ( P <0.05). The subjective scores of anatomical structures of LD-DL did not show significant difference compared to those of ND-IR ( P >0.05), and were higher than those of LD-FBP and LD-IR. The radiation dose of the LD group was reduced by about 50.2% compared with that of the ND group., Conclusion: The DL algorithm with noise shape similar to the medium iterative grade IR commonly used in clinical practice showed higher noise reduction ability than IR did. Compared with FBP, the DL algorithm had smoother noise shape, but much better noise reduction ability. The application of DL algorithm in low-dose thin-slice liver CT of healthy volunteers can help achieve the standard image quality of liver CT., (Copyright© by Editorial Board of Journal of Sichuan University (Medical Sciences).)

Published
2021
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8. [Noise Reduction Effect of Deep-learning-based Image Reconstruction Algorithms in Thin-section Chest CT].

Author

Zeng W, Zeng LM, Xu X, Hu SX, Liu KL, Zhang JG, Peng WL, Xia CC, and Li ZL

Subjects
Algorithms, Humans, Image Processing, Computer-Assisted, Radiation Dosage, Radiographic Image Interpretation, Computer-Assisted, Tomography, X-Ray Computed, Deep Learning
Abstract

Objective: To evaluate the noise reduction effect of deep learning-based reconstruction algorithms in thin-section chest CT images by analyzing images reconstructed with filtered back projection (FBP), adaptive statistical iterative reconstruction (ASIR), and deep learning image reconstruction (DLIR) algorithms., Methods: The chest CT scan raw data of 47 patients were included in this study. Images of 0.625 mm were reconstructed using six reconstruction methods, including FBP, ASIR hybrid reconstruction (ASIR50%, ASIR70%), and deep learning low, medium and high modes (DL-L, DL-M, and DL-H). After the regions of interest were outlined in the aorta, skeletal muscle and lung tissue of each group of images, the CT values, SD values and signal-to-noise ratio (SNR) of the regions of interest were measured, and two radiologists evaluated the image quality., Results: CT values, SD values and SNR of the images obtained by the six reconstruction methods showed statistically significant difference ( P <0.001). There were statistically significant differences in the image quality scores of the six reconstruction methods ( P <0.001). Images reconstruced with DL-H have the lowest noise and the highest overall quality score., Conclusion: The model based on deep learning can effectively reduce the noise of thin-section chest CT images and improve the image quality. Among the three deep-learning models, DL-H showed the best noise reduction effect., (Copyright© by Editorial Board of Journal of Sichuan University (Medical Sciences).)

Published
2021
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9. [The Clinical Effectiveness of Neural Network-based Boundary Recognition of Upper Abdominal Organs on CT Images].

Author

Xia CC, Zhang K, Liu XM, Pu J, Peng WL, Xu X, Zeng LM, Zeng W, and Li ZL

Subjects
Abdomen diagnostic imaging, Humans, Spleen diagnostic imaging, Treatment Outcome, Neural Networks, Computer, Tomography, X-Ray Computed
Abstract

Objective: To assess the clinical effectiveness of boundary recognition of upper abdomen organs on CT images based on neural network model and the combination of different slices., Methods: A total of 2 000 patients who underwent upper abdomen enhanced CT scans from March 2018 to March 2019 were included in the study. The quality of the CT images met the requirements for clinical diagnosis. Eight boundary layers (the upper and lower edge of liver, the upper and lower edge of spleen, the lower edge of left kidney, the lower edge of right kidney, the lower edge of the stomach and the lower edge of the gallbladder) of the main organs in the upper abdomen were labeled. The model training (training set, verification set and test set) based on different neural network methods and combinations of different slices were then performed to assess the accuracy of boundary recognition. Furthermore, clinical data from 50 cases were used as test group for assessing the accuracy and clinical effectiveness of this model., Results: The fusion model created by integrating the two models according to different weight ratios yielded the highest accuracy, and then followed the EfficientNet-b3 model, with the Xception model showing the lowest accuracy. In each model, the boundary recognition accuracy of 5-slice image is higher than that of 3-silce image, and that of 1-slice image is the lowest. The recognition accuracy of fusion model of the 5-continuous-slice image for upper edge of liver, lower edge of liver, upper edge of spleen, lower edge of spleen, lower edge of left kidney, lower edge of right kidney, lower edge of stomach and lower edge of gallbladder was 91%, 87%, 92%, 85%, 92%, 95%, 76% and 74%, respectively. The fusion model was checked with the effectiveness data of 50 cases, yielding 88%, 86%, 88%, 80%, 82%, 80%, 69%, and 65% accuracy for 8-slice image, respectively, and the accuracy of meeting clinical application requirement was as high as 98%, 98%, 95%, 98%, 99%, 98%, 80% and 77%, respectively., Conclusion: By increasing boundary change logics in the continuous slices, the fusion model integrating different weight proportions demonstrates the highest accuracy for identifying the boundary of upper abdominal organs on CT images, achieving high examination effectiveness in clinical practice., (Copyright© by Editorial Board of Journal of Sichuan University (Medical Sciences).)

Published
2021
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10. [The Application Value of Artificial Intelligence-based Filtering and Interpolated Image Reconstruction Algorithm in Abdominal Magnetic Resonance Image Denoising].

Author

Xu X, Peng WL, Zhang JG, Liu KL, Hu SX, Zeng LM, Xia CC, and Li ZL

Subjects
Algorithms, Humans, Image Processing, Computer-Assisted, Retrospective Studies, Artificial Intelligence, Magnetic Resonance Imaging
Abstract

Objective: To compare the noise reduction performance of conventional filtering and artificial intelligence-based filtering and interpolation (AIFI) and to explore for optimal parameters of applying AIFI in the noise reduction of abdominal magnetic resonance imaging (MRI)., Methods: Sixty patients who underwent upper abdominal MRI examination in our hospital were retrospectively included. The raw data of T1-weighted image (T1WI), T2-weighted image (T2WI), and dualecho sequences were reconstructed with two image denoising techniques, conventional filtering and AIFI of different levels of intensity. The difference in objective image quality indicators, peak signal-to-noise ratio (pSNR) and image sharpness, of the different denoising techniques was compared. Two radiologists evaluated the image noise, contrast, sharpness, and overall image quality. Their scores were compared and the interobserver agreement was calculated., Results: Compared with the original images, improvement of varying degrees were shown in the pSNR and the sharpness of the images of the three sequences, T1W1, T2W2, and dual echo sequence, after denoising filtering and AIFI were used (all P <0.05). In addition, compared with conventional filtering, the objective quality scores of the reconstructed images were improved when conventional filtering was combined with AIFI reconstruction methods in T1WI sequence, AIFI level≥3 was used in T2WI and echo1 sequence, and AIFI level≥4 was used in echo2 sequence (all P <0.05). The subjective scores given by the two radiologists for the image noise, contrast, sharpness, and overall image quality in each sequence of conventional filtering reconstruction, AIFI reconstruction (except for AIFI level=1), and two-method combination reconstruction were higher than those of the original images (all P <0.05). However, the image contrast scores were reduced for AIFI level=5. There was good interobserver agreement between the two radiologists (all r >0.75, P <0.05). After multidimensional comparison, the optimal parameters of using AIFI technique for noise reduction in abdominal MRI were conventional filtering+AIFI level=3 in the T1WI sequence and AIFI level=4 in the T2WI and dualecho sequences., Conclusion: AIFI is superior to filtering in imaging denoising at medium and high levels. It is a promising noise reduction technique. The optimal parameters of using AIFI for abdominal MRI are Filtering+AIFI level=3 in the T1WI sequence and AIFI level=4 in T2WI and dualecho sequences., (Copyright© by Editorial Board of Journal of Sichuan University (Medical Sciences).)

Published
2021
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11. [Application of 3.0T Time-of-flight Magnetic Resonance Angiography with Sparse Undersampling and Iterative Reconstruction in the Diagnosis of Unruptured Intracranial Aneurysms].

Author

Xu X, Zhang JG, Peng WL, Liu KL, Hu SX, Zeng LM, Xia CC, and Li ZL

Subjects
Angiography, Digital Subtraction, Humans, Sensitivity and Specificity, Tomography, X-Ray Computed, Intracranial Aneurysm diagnostic imaging, Magnetic Resonance Angiography
Abstract

Objective: To evaluate the diagnostic value of 3.0T time-of-flight MR angiography with sparse undersampling and iterative reconstruction (TOFu-MRA) for unruptured intracranial aneurysms (UIAs) on the basis of using digital subtraction angiography (DSA) as the reference standard., Methods: A total of 65 patients with suspected UIAs were prospectively enrolled and all patients underwent TOFu-MRA and DSA. Relying on DSA as the reference standard, the sensitivity (SEN), specificity (SPE), positive predictive value (PPV) and negative predictive value (NPV) of using TOFu-MRA in UIA diagnosis were calculated, and the inter-observer agreement between two doctors was determined. Comparison of maximum intensity projection (MIP) and volume rendering (VR) image datasets was made to evaluate the agreement between DSA results and TOFu-MRA in the measurement of UIA morphological parameters, including the neck width (D neck ), height (H) , and width (D width ) of UIAs., Results: The study covered 55 UIAs from 46 patients. The SEN, SPE, PPV and NPV of the two doctors using TOFu-MRA in UIA diagnosis were as follows: (95.7%, 95.7%), (94.7%, 94.7%), (97.8%, 97.8%) and (90.0%, 90.0%), respectively for patient-based assessment; (96.4%, 94.5%), (94.7%, 94.7%), (98.1%, 98.1%) and (90.0%, 85.7%), respectively, for aneurysm-based assessment. There is a strong inter-observer agreement (Kappa=0.93 for patient-based assessment and 0.96 for aneurysm-based assessment) between the two doctors. Moreover, Bland-Altman analysis showed that more than 95% points fell within the limits of agreement (LoA), suggesting strong agreement between the two examination methods for the measurement of UIAs morphological parameters., Conclusion: TOFu-MRA showed good diagnostic efficacy for UIAs and the results were in good agreement with those of DSA, the reference standard, for assessing UIA morphological parameter. TOFu-MRA can be used as a first choice for noninvasive diagnostic evaluation of UIAs., (Copyright© by Editorial Board of Journal of Sichuan University (Medical Sciences).)

Published
2021
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