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Peng Du
Publications
- 2024
- [j79]Sam Simmonds, Leo K. Cheng, Wharengaro Ruha, Andrew J. Taberner, Peng Du, Timothy R. Angeli-Gordon:
Measurement and Analysis of In Vivo Gastroduodenal Slow Wave Patterns Using Anatomically-Specific Cradles and Electrodes. IEEE Trans. Biomed. Eng. 71(4): 1289-1297 (2024) - 2023
- [j72]Chad E. Drake, Leo K. Cheng, Nicole D. Muszynski, Suseela Somarajan, Niranchan Paskaranandavadivel, Timothy R. Angeli-Gordon, Peng Du, Leonard A. Bradshaw, Recep Avci:
Electroanatomical mapping of the stomach with simultaneous biomagnetic measurements. Comput. Biol. Medicine 165: 107384 (2023) - [j67]Chad E. Drake, Leo K. Cheng, Niranchan Paskaranandavadivel, Saeed Alighaleh, Timothy R. Angeli-Gordon, Peng Du, Leonard A. Bradshaw, Recep Avci:
Stomach Geometry Reconstruction Using Serosal Transmitting Coils and Magnetic Source Localization. IEEE Trans. Biomed. Eng. 70(3): 1036-1044 (2023) - [j66]Xiaokai Wang, Jiayue Cao, Kuan Han, Minkyu Choi, Yushi She, Ulrich M. Scheven, Recep Avci, Peng Du, Leo K. Cheng, Madeleine R. Di Natale, John B. Furness, Zhongming Liu:
Diffeomorphic Surface Modeling for MRI-Based Characterization of Gastric Anatomy and Motility. IEEE Trans. Biomed. Eng. 70(7): 2046-2057 (2023) - [c110]Omkar N. Athavale, Leo K. Cheng, Recep Avci, Alys R. Clark, Peng Du:
Cervical Vagus Nerve Stimulation Disrupts Gastric Slow Wave Activity in Rats. EMBC 2023: 1-4 - [c109]Savindi Wijenayaka, Alys R. Clark, Recep Avci, Leo K. Cheng, Peng Du:
Atrous spatial pyramid pooling and multi-image data fusion for smooth muscle segmentation in upper gastrointestinal sphincters. EMBC 2023: 1-4 - 2022
- [j54]Recep Avci, Chad E. Eichler, Niranchan Paskaranandavadivel, Peng Du, Timothy R. Angeli-Gordon, Leonard A. Bradshaw, Leo K. Cheng:
Characterizing Spatial Signatures of Gastric Electrical Activity Using Biomagnetic Source Localization. IEEE Trans. Biomed. Eng. 69(11): 3551-3558 (2022) - [c102]Sam Simmonds, Leo K. Cheng, Wharengaro Ruha, Andrew J. Taberner, Peng Du, Timothy R. Angeli-Gordon:
Anatomically-Specific, 3D-Printed Cradles Enable In Vivo Mapping of the Bioelectrical Activation across the Gastroduodenal Junction. EMBC 2022: 377-380 - [c101]Jack Xu, Leo K. Cheng, Recep Avci, Peng Du:
Reconstruction of the Gastro-esophageal Junction Based on Ultramill Imaging for Biomechanical Analysis. EMBC 2022: 1594-1597 - [c100]Omkar N. Athavale, Leo K. Cheng, Alys R. Clark, Recep Avci, Peng Du:
Mathematical Modeling of Gastric Slow Waves During Electrical Field Stimulation. EMBC 2022: 2266-2269 - [c99]Sue Ann Mah, Recep Avci, Peng Du, Jean-Marie Vanderwinden, Leo K. Cheng:
Deciphering Stomach Myoelectrical Slow Wave Conduction Patterns via Confocal Imaging of Gastric Pacemaker Cells and Fractal Geometry. EMBC 2022: 3514-3517 - [c98]Amy S. Garrett, Mathias W. Roesler, Omkar N. Athavale, Peng Du, Alys R. Clark, Leo K. Cheng:
In vivo multi-channel measurement of electrical activity of the non-pregnant rat uterus. EMBC 2022: 3682-3685 - [c97]Timothy R. Angeli-Gordon, Chad E. Eichler, Leo K. Cheng, Niranchan Paskaranandavadivel, Peng Du, Leonard A. Bradshaw, Recep Avci:
Anatomically Constrained Gastric Slow Wave Localization using Biomagnetic Data. EMBC 2022: 3935-3938 - [c96]Peikai Zhang, Omkar N. Athavale, Ryan A. L. Cowan, Alys R. Clark, Recep Avci, Leo K. Cheng, Jadranka Travas-Sejdic, Peng Du:
Wet-printing of PEDOT: PSS Microelectrodes for Gastric Slow Wave Recording. EMBC 2022: 4868-4871 - [c95]Recep Avci, Joseph D. Wickens, Mehrdad Sangi, Omkar N. Athavale, Madeleine R. Di Natale, John B. Furness, Peng Du, Leo K. Cheng:
A Computational Model of Biophysical Properties of the Rat Stomach Informed by Comprehensive Analysis of Muscle Anatomy. EMBC 2022: 4954-4957 - 2021
- [j52]Chad E. Eichler, Leo K. Cheng, Niranchan Paskaranandavadivel, Peng Du, Leonard A. Bradshaw, Recep Avci:
Effects of magnetogastrography sensor configurations in tracking slow wave propagation. Comput. Biol. Medicine 129: 104169 (2021) - [c87]Sue Ann Mah, Recep Avci, Peng Du, Jean-Marie Vanderwinden, Leo K. Cheng:
Antral Variation of Murine Gastric Pacemaker Cells Informed by Confocal Imaging and Machine Learning Methods. EMBC 2021: 3105-3108 - [c86]Chad E. Eichler, Leo K. Cheng, Niranchan Paskaranandavadivel, Saeed Alighaleh, Timothy R. Angeli-Gordon, Peng Du, Leonard A. Bradshaw, Recep Avci:
Reconstruction of stomach geometry using magnetic source localization. EMBC 2021: 4234-4237 - 2020
- [j42]Stefan Calder, Gregory O'Grady, Leo K. Cheng, Peng Du:
A Simulated Anatomically Accurate Investigation Into the Effects of Biodiversity on Electrogastrography. IEEE Trans. Biomed. Eng. 67(3): 868-875 (2020) - [c82]Sue Ann Mah, Recep Avci, Peng Du, Jean-Marie Vanderwinden, Leo K. Cheng:
Supervised Machine Learning Segmentation and Quantification of Gastric Pacemaker Cells. EMBC 2020: 1408-1411 - [c80]Recep Avci, Niranchan Paskaranandavadivel, Peng Du, Jean-Marie Vanderwinden, Leo K. Cheng:
Continuum Based Bioelectrical Simulations using Structurally Realistic Gastrointestinal Pacemaker Cell Networks. EMBC 2020: 2483-2486 - [c79]Chad E. Eichler, Leo K. Cheng, Peng Du, Stefan Calder, Niranchan Paskaranandavadivel, Leonard A. Bradshaw, Recep Avci:
Simulation-based Analysis of Magnetogastrography Sensor Configurations for Characterizing Gastric Slow Wave Dysrhythmias. EMBC 2020: 2512-2515 - 2019
- [c75]Recep Avci, Niranchan Paskaranandavadivel, Stefan Calder, Peng Du, Leonard A. Bradshaw, Leo K. Cheng:
Source localization for gastric electrical activity using simulated magnetogastrographic data. EMBC 2019: 2336-2339 - 2018
- [j32]Rui Wang, Zaid Abukhalaf, Amir Javan-Khoshkholgh, Tim H.-H. Wang, Shameer Sathar, Peng Du, Timothy R. Angeli, Leo K. Cheng, Greg O'Grady, Niranchan Paskaranandavadivel, Aydin Farajidavar:
A Miniature Configurable Wireless System for Recording Gastric Electrophysiological Activity and Delivering High-Energy Electrical Stimulation. IEEE J. Emerg. Sel. Topics Circuits Syst. 8(2): 221-229 (2018) - 2017
- [j27]Stefan Calder, Greg O'Grady, Leo K. Cheng, Peng Du:
A Theoretical Analysis of Electrogastrography (EGG) Signatures Associated With Gastric Dysrhythmias. IEEE Trans. Biomed. Eng. 64(7): 1592-1601 (2017) - [c57]Anna Qian, Shawn Means, Leo K. Cheng, James Sneyd, Peng Du:
A mathematical model of the effects of anoctamin-1 loss on intestinal slow wave entrainment. EMBC 2017: 2688-2691 - [c56]Niranchan Paskaranandavadivel, Saeed Alighaleh, Peng Du, Gregory O'Grady, Leo K. Cheng:
Suppression of ventilation artifacts for gastrointestinal slow wave recordings. EMBC 2017: 2769-2772 - [c55]Stefan Calder, Greg O'Grady, Leo K. Cheng, Peng Du:
Anatomical variations of the stomach effects on electrogastrography. EMBC 2017: 4219-4222 - 2015
- [c48]Joy Putney, Gregory O'Grady, Timothy R. Angeli, Niranchan Paskaranandavadivel, Leo K. Cheng, Jonathan C. Erickson, Peng Du:
Determining the efficient inter-electrode distance for high-resolution mapping using a mathematical model of human gastric dysrhythmias. EMBC 2015: 1448-1451 - [c47]Niranchan Paskaranandavadivel, Peng Du, Jonathan C. Erickson, Gregory O'Grady, Leo K. Cheng:
Extending the automated gastrointestinal analysis pipeline: Removal of invalid slow wave marks in gastric serosal recordings. EMBC 2015: 1938-1941 - [c45]Niranchan Paskaranandavadivel, Xingzheng Pan, Peng Du, Gregory O'Grady, Leo K. Cheng:
Detection of the Recovery Phase of in vivo gastric slow wave recordings. EMBC 2015: 6094-6097 - 2014
- [j21]Simon H. Bull, Gregory O'Grady, Peng Du, Leo K. Cheng:
A System and Method for Online High-Resolution Mapping of Gastric Slow-Wave Activity. IEEE Trans. Biomed. Eng. 61(11): 2679-2687 (2014) - [c42]Stefan Calder, Leo K. Cheng, Peng Du:
A theoretical analysis of the electrogastrogram (EGG). EMBC 2014: 4330-4333 - 2013
- [c40]Jerry Gao, Peng Du, Greg O'Grady, Rosalind Archer, Simon J. Gibbons, Gianrico Farrugia, Leo K. Cheng:
Cellular automaton model for simulating tissue-specific intestinal electrophysiological activity. EMBC 2013: 5537-5540 - [c39]Peng Du, Jerry Gao, Gregory O'Grady, Leo K. Cheng:
A simplified biophysical cell model for gastric slow wave entrainment simulation. EMBC 2013: 6547-6550 - [c38]Niranchan Paskaranandavadivel, Jerry Gao, Peng Du, Gregory O'Grady, Leo K. Cheng:
Automated classification of spatiotemporal characteristics of gastric slow wave propagation. EMBC 2013: 7342-7345 - 2012
- [j12]Niranchan Paskaranandavadivel, Gregory O'Grady, Peng Du, Andrew J. Pullan, Leo K. Cheng:
An Improved Method for the Estimation and Visualization of Velocity Fields from Gastric High-Resolution Electrical Mapping. IEEE Trans. Biomed. Eng. 59(3): 882-889 (2012) - 2011
- [j10]Jerry Gao, Peng Du, Rosalind Archer, Greg O'Grady, Simon J. Gibbons, Gianrico Farrugia, Leo K. Cheng, Andrew J. Pullan:
A Stochastic Multi-Scale Model of Electrical Function in Normal and Depleted ICC Networks. IEEE Trans. Biomed. Eng. 58(12): 3451-3455 (2011) - [j9]Peng Du, Yong Cheng Poh, Jee Lean Lim, Viveka Gajendiran, Greg O'Grady, Martin L. Buist, Andrew J. Pullan, Leo K. Cheng:
A Preliminary Model of Gastrointestinal Electromechanical Coupling. IEEE Trans. Biomed. Eng. 58(12): 3491-3495 (2011) - [c27]Niranchan Paskaranandavadivel, Leo K. Cheng, Peng Du, Gregory O'Grady, Andrew J. Pullan:
Improved signal processing techniques for the analysis of high resolution serosal slow wave activity in the stomach. EMBC 2011: 1737-1740 - [c26]Peng Du, Greg O'Grady, Niranchan Paskaranandavadivel, Timothy R. Angeli, Christopher Lahr, Thomas L. Abell, Leo K. Cheng, Andrew J. Pullan:
Quantification of velocity anisotropy during gastric electrical arrhythmia. EMBC 2011: 4402-4405 - [c25]Timothy R. Angeli, Gregory O'Grady, Jonathan C. Erickson, Peng Du, Niranchan Paskaranandavadivel, Ian P. Bissett, Leo K. Cheng, Andrew J. Pullan:
Mapping small intestine bioelectrical activity using high-resolution printed-circuit-board electrodes. EMBC 2011: 4951-4954 - 2009
- [j3]Peng Du, Greg O'Grady, John A. Windsor, Leo K. Cheng, Andrew J. Pullan:
A Tissue Framework for Simulating the Effects of Gastric Electrical Stimulation and In Vivo Validation. IEEE Trans. Biomed. Eng. 56(12): 2755-2761 (2009)
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