Your search keyword '"Xuetao Shi"' showing total 5 results

1. A novel time-difference electrical impedance tomography algorithm using multi-frequency information

Author

Lu Cao, Haoting Li, Canhua Xu, Meng Dai, Zhenyu Ji, Xuetao Shi, Xiuzhen Dong, Feng Fu, and Bin Yang

Subjects

Electrical impedance tomography (EIT), Fraction model, Image reconstruction algorithm, Inverse problem, Medical technology, R855-855.5

Abstract

Abstract Background Electrical impedance tomography (EIT) is a noninvasive, radiation-free, and low-cost imaging modality for monitoring the conductivity distribution inside a patient. Nowadays, time-difference EIT (tdEIT) is used extensively as it has fast imaging speed and can reflect the dynamic changes of diseases, which make it attractive for a number of medical applications. Moreover, modeling errors are compensated to some extent by subtraction of voltage measurements collected before and after the change. However, tissue conductivity varies with frequency and tdEIT does not efficiently exploit multi-frequency information as it only uses measurements associated with a single frequency. Methods This paper proposes a tdEIT algorithm that imposes spectral constraints on the framework of the linear least squares problem. Simulation and phantom experiments are conducted to compare the proposed spectral constraints algorithm (SC) with the damped least squares algorithm (DLS), which is a stable tdEIT algorithm used in clinical practice. The condition number and rank of the matrices needing inverses are analyzed, and image quality is evaluated using four indexes. The possibility of multi-tissue imaging and the influence of spectral errors are also explored. Results Significant performance improvement is achieved by combining multi-frequency and time-difference information. The simulation results show that, in one-step iteration, both algorithms have the same condition number and rank, but SC effectively reduces image noise by 20.25% compared to DLS. In addition, deformation error and position error are reduced by 8.37% and 7.86%, respectively. In two-step iteration, the rank of SC is greatly increased, which suggests that more information is employed in image reconstruction. Image noise is further reduced by an average of 32.58%, and deformation error and position error are also reduced by 20.20% and 31.36%, respectively. The phantom results also indicate that SC has stronger noise suppression and target identification abilities, and this advantage is more obvious with iteration. The results of multi-tissue imaging show that SC has the unique advantage of automatically extracting a single tissue to image. Conclusions SC enables tdEIT to utilize multi-frequency information in cases where the spectral constraints are known and then provides higher quality images for applications.

Published

2019

2. Optimal combination of electrodes and conductive gels for brain electrical impedance tomography

Author

Lin Yang, Heng Li, Junjie Ding, Weichen Li, Xiuzhen Dong, Zhihong Wen, and Xuetao Shi

Subjects

Brain EIT, Electrode, Conductive gel, Combination, Medical technology, R855-855.5

Abstract

Abstract Background Electrical impedance tomography (EIT) is an emerging imaging technology that has been used to monitor brain injury and detect acute stroke. The time and frequency properties of electrode–skin contact impedance are important for brain EIT because brain EIT measurement is performed over a long period when used to monitor brain injury, and is carried out across a wide range of frequencies when used to detect stroke. To our knowledge, no study has simultaneously investigated the time and frequency properties of both electrode and conductive gel for brain EIT. Methods In this study, the contact impedance of 16 combinations consisting of 4 kinds of clinical electrode and five types of commonly used conductive gel was measured on ten volunteers’ scalp for a period of 1 h at frequencies from 100 Hz to 1 MHz using the two-electrode method. And then the performance of each combination was systematically evaluated in terms of the magnitude of contact impedance, and changes in contact impedance with time and frequency. Results Results showed that combination of Ag+/Ag+Cl− powder electrode and low viscosity conductive gel performed best overall (Ten 20® in this study); it had a relatively low magnitude of contact impedance and superior performance regarding contact impedance with time (p

Published

2018

3. A novel time-difference electrical impedance tomography algorithm using multi-frequency information

Author

Zhenyu Ji, Meng Dai, Haoting Li, Feng Fu, Xiuzhen Dong, Canhua Xu, Lu Cao, Xuetao Shi, and Bin Yang

Subjects

lcsh:Medical technology, Time Factors, Image quality, Computer science, 0206 medical engineering, Biomedical Engineering, 02 engineering and technology, Iterative reconstruction, Imaging phantom, Biomaterials, Electrical impedance tomography (EIT), Electric Impedance, Image Processing, Computer-Assisted, Image noise, Radiology, Nuclear Medicine and imaging, Tomography, Condition number, Electrical impedance tomography, Radiological and Ultrasound Technology, Phantoms, Imaging, Research, Image reconstruction algorithm, General Medicine, Inverse problem, 020601 biomedical engineering, lcsh:R855-855.5, Fraction model, Algorithm, Algorithms, Linear least squares

Abstract

Background Electrical impedance tomography (EIT) is a noninvasive, radiation-free, and low-cost imaging modality for monitoring the conductivity distribution inside a patient. Nowadays, time-difference EIT (tdEIT) is used extensively as it has fast imaging speed and can reflect the dynamic changes of diseases, which make it attractive for a number of medical applications. Moreover, modeling errors are compensated to some extent by subtraction of voltage measurements collected before and after the change. However, tissue conductivity varies with frequency and tdEIT does not efficiently exploit multi-frequency information as it only uses measurements associated with a single frequency. Methods This paper proposes a tdEIT algorithm that imposes spectral constraints on the framework of the linear least squares problem. Simulation and phantom experiments are conducted to compare the proposed spectral constraints algorithm (SC) with the damped least squares algorithm (DLS), which is a stable tdEIT algorithm used in clinical practice. The condition number and rank of the matrices needing inverses are analyzed, and image quality is evaluated using four indexes. The possibility of multi-tissue imaging and the influence of spectral errors are also explored. Results Significant performance improvement is achieved by combining multi-frequency and time-difference information. The simulation results show that, in one-step iteration, both algorithms have the same condition number and rank, but SC effectively reduces image noise by 20.25% compared to DLS. In addition, deformation error and position error are reduced by 8.37% and 7.86%, respectively. In two-step iteration, the rank of SC is greatly increased, which suggests that more information is employed in image reconstruction. Image noise is further reduced by an average of 32.58%, and deformation error and position error are also reduced by 20.20% and 31.36%, respectively. The phantom results also indicate that SC has stronger noise suppression and target identification abilities, and this advantage is more obvious with iteration. The results of multi-tissue imaging show that SC has the unique advantage of automatically extracting a single tissue to image. Conclusions SC enables tdEIT to utilize multi-frequency information in cases where the spectral constraints are known and then provides higher quality images for applications.

Published

2019

4. Fast detection and data compensation for electrodes disconnection in long-term monitoring of dynamic brain electrical impedance tomography

Author

Weichen Li, Canhua Xu, Feng Fu, Xuetao Shi, Meng Dai, Lin Yang, Haoting Li, Xiuzhen Dong, and Ge Zhang

Subjects

Time Factors, Computer science, 0206 medical engineering, Wavelet Analysis, Biomedical Engineering, Weighted-correlation coefficient, 02 engineering and technology, Iterative reconstruction, Data loss, Imaging phantom, Electrode disconnection, Biomaterials, 03 medical and health sciences, 0302 clinical medicine, Wavelet, Data acquisition, Electric Impedance, Image Processing, Computer-Assisted, Humans, Radiology, Nuclear Medicine and imaging, Computer vision, Grey model, Electrodes, Tomography, Electrical impedance tomography, Radiological and Ultrasound Technology, business.industry, Research, Electrical engineering, Brain, Wavelet transform, General Medicine, Brain electrical impedance tomography, 020601 biomedical engineering, Artificial intelligence, Artifacts, business, 030217 neurology & neurosurgery

Abstract

Background Electrode disconnection is a common occurrence during long-term monitoring of brain electrical impedance tomography (EIT) in clinical settings. The data acquisition system suffers remarkable data loss which results in image reconstruction failure. The aim of this study was to: (1) detect disconnected electrodes and (2) account for invalid data. Methods Weighted correlation coefficient for each electrode was calculated based on the measurement differences between well-connected and disconnected electrodes. Disconnected electrodes were identified by filtering out abnormal coefficients with discrete wavelet transforms. Further, previously valid measurements were utilized to establish grey model. The invalid frames after electrode disconnection were substituted with the data estimated by grey model. The proposed approach was evaluated on resistor phantom and with eight patients in clinical settings. Results The proposed method was able to detect 1 or 2 disconnected electrodes with an accuracy of 100%; to detect 3 and 4 disconnected electrodes with accuracy of 92 and 84% respectively. The time cost of electrode detection was within 0.018 s. Further, the proposed method was capable to compensate at least 60 subsequent frames of data and restore the normal image reconstruction within 0.4 s and with a mean relative error smaller than 0.01%. Conclusions In this paper, we proposed a two-step approach to detect multiple disconnected electrodes and to compensate the invalid frames of data after disconnection. Our method is capable of detecting more disconnected electrodes with higher accuracy compared to methods proposed in previous studies. Further, our method provides estimations during the faulty measurement period until the medical staff reconnects the electrodes. This work would improve the clinical practicability of dynamic brain EIT and contribute to its further promotion.

Published

2017

5. Fast detection and data compensation for electrodes disconnection in long-term monitoring of dynamic brain electrical impedance tomography.

Author

Ge Zhang, Meng Dai, Lin Yang, Weichen Li, Haoting Li, Canhua Xu, Xuetao Shi, Xiuzhen Dong, Feng Fu, Zhang, Ge, Dai, Meng, Yang, Lin, Li, Weichen, Li, Haoting, Xu, Canhua, Shi, Xuetao, Dong, Xiuzhen, and Fu, Feng

Subjects

ELECTRODES, ELECTRICAL impedance tomography, PATIENT monitoring, BRAIN tomography, WAVELET transforms, BRAIN physiology, TOMOGRAPHY, DIGITAL image processing, BIOELECTRIC impedance, SIGNAL processing, TIME, MEDICAL artifacts, EQUIPMENT & supplies

Abstract

Background: Electrode disconnection is a common occurrence during long-term monitoring of brain electrical impedance tomography (EIT) in clinical settings. The data acquisition system suffers remarkable data loss which results in image reconstruction failure. The aim of this study was to: (1) detect disconnected electrodes and (2) account for invalid data.Methods: Weighted correlation coefficient for each electrode was calculated based on the measurement differences between well-connected and disconnected electrodes. Disconnected electrodes were identified by filtering out abnormal coefficients with discrete wavelet transforms. Further, previously valid measurements were utilized to establish grey model. The invalid frames after electrode disconnection were substituted with the data estimated by grey model. The proposed approach was evaluated on resistor phantom and with eight patients in clinical settings.Results: The proposed method was able to detect 1 or 2 disconnected electrodes with an accuracy of 100%; to detect 3 and 4 disconnected electrodes with accuracy of 92 and 84% respectively. The time cost of electrode detection was within 0.018 s. Further, the proposed method was capable to compensate at least 60 subsequent frames of data and restore the normal image reconstruction within 0.4 s and with a mean relative error smaller than 0.01%.Conclusions: In this paper, we proposed a two-step approach to detect multiple disconnected electrodes and to compensate the invalid frames of data after disconnection. Our method is capable of detecting more disconnected electrodes with higher accuracy compared to methods proposed in previous studies. Further, our method provides estimations during the faulty measurement period until the medical staff reconnects the electrodes. This work would improve the clinical practicability of dynamic brain EIT and contribute to its further promotion. [ABSTRACT FROM AUTHOR]

Published

2017