Author Info
Name
Affiliation
Papers
PENG DU
Univ Auckland, Auckland Bioengn Inst, Auckland 1010, New Zealand
30
Collaborators
Citations 
PageRank 
80
10
11.12
Referers 
Referees 
References 
39
64
23
Title
Citations
PageRank
Year
In vivo multi-channel measurement of electrical activity of the non-pregnant rat uterus.00.342022
Effects of Anatomical Variations of the Stomach on Body-Surface Gastric Mapping Investigated Using a Large Population-Based Multiscale Simulation Approach00.342022
Reconstruction of the Gastro-esophageal Junction Based on Ultramill Imaging for Biomechanical Analysis.00.342022
Anatomically Constrained Gastric Slow Wave Localization using Biomagnetic Data.00.342022
Characterizing Spatial Signatures of Gastric Electrical Activity Using Biomagnetic Source Localization00.342022
A Computational Model of Biophysical Properties of the Rat Stomach Informed by Comprehensive Analysis of Muscle Anatomy.00.342022
Mathematical Modeling of Gastric Slow Waves During Electrical Field Stimulation.00.342022
Anatomically-Specific, 3D-Printed Cradles Enable In Vivo Mapping of the Bioelectrical Activation across the Gastroduodenal Junction00.342022
Deciphering Stomach Myoelectrical Slow Wave Conduction Patterns via Confocal Imaging of Gastric Pacemaker Cells and Fractal Geometry.00.342022
Wet-printing of PEDOT: PSS Microelectrodes for Gastric Slow Wave Recording.00.342022
Effects Of Magnetogastrography Sensor Configurations In Tracking Slow Wave Propagation10.402021
Continuum Based Bioelectrical Simulations Using Structurally Realistic Gastrointestinal Pacemaker Cell Networks00.342020
Supervised Machine Learning Segmentation And Quantification Of Gastric Pacemaker Cells00.342020
Simulation-Based Analysis Of Magnetogastrography Sensor Configurations For Characterizing Gastric Slow Wave Dysrhythmias00.342020
A simulated anatomically accurate investigation into the effects of biodiversity on electrogastrography (EGG).00.342020
Effects Of Anatomical Variations On Body Surface Gastric Mapping00.342020
Source Localization For Gastric Electrical Activity Using Simulated Magnetogastrographic Data00.342019
A Method for Multi-day Tracking of Gastrointestinal Smooth Muscle Contractile Patterns in Organotypic Culture.00.342019
A Pipeline For The Registration Of Calcium Transient Data To Structural Networks Of The Interstitial Cells Of Cajal00.342019
A Miniature Configurable Wireless System for Recording Gastric Electrophysiological Activity and Delivering High-Energy Electrical Stimulation.00.342018
A Theoretical Analysis of Electrogastrography (EGG) Signatures Associated With Gastric Dysrhythmias.10.372017
A Mathematical Model Of The Effects Of Anoctamin-1 Loss On Intestinal Slow Wave Entrainment00.342017
Suppression Of Ventilation Artifacts For Gastrointestinal Slow Wave Recordings00.342017
Anatomical Variations Of The Stomach Effects On Electrogastrography00.342017
Detection of the Recovery Phase of in vivo gastric slow wave recordings00.342015
A system and method for online high-resolution mapping of gastric slow-wave activity.40.942014
Cellular automaton model for simulating tissue-specific intestinal electrophysiological activity.00.342013
An improved method for the estimation and visualization of velocity fields from gastric high-resolution electrical mapping.30.482012
A preliminary model of gastrointestinal electromechanical coupling.00.342011
A tissue framework for simulating the effects of gastric electrical stimulation and in vivo validation.10.482009