| Comparison of the Windkessel model and structured-tree model applied to prescribe outflow boundary conditions for a one-dimensional arterial tree model D Guan, F Liang, PA Gremaud Journal of biomechanics 49 (9), 1583-1592, 2016 | 66 | 2016 |
| On the AIC-based model reduction for the general Holzapfel–Ogden myocardial constitutive law D Guan, F Ahmad, P Theobald, S Soe, X Luo, H Gao Biomechanics and Modeling in Mechanobiology 18 (4), 1213-1232, 2019 | 46 | 2019 |
| Effect of myofibre architecture on ventricular pump function by using a neonatal porcine heart model: from DT-MRI to rule-based methods D Guan, J Yao, X Luo, H Gao Royal Society open science 7 (4), 191655, 2020 | 34 | 2020 |
| Determinant factors for arterial hemodynamics in hypertension: theoretical insights from a computational model-based study F Liang, D Guan, J Alastruey Journal of Biomechanical Engineering 140 (3), 031006, 2018 | 25 | 2018 |
| Modelling of fibre dispersion and its effects on cardiac mechanics from diastole to systole D Guan, X Zhuan, W Holmes, X Luo, H Gao Journal of Engineering Mathematics 128 (1), 1-24, 2021 | 24 | 2021 |
| A new active contraction model for the myocardium using a modified hill model D Guan, H Gao, L Cai, X Luo Computers in Biology and Medicine 145, 105417, 2022 | 10 | 2022 |
| An Updated Lagrangian Constrained Mixture Model of Pathological Cardiac Growth and Remodelling D Guan, X Zhuan, X Luo, H Gao Acta Biomaterialia, 2023 | 8 | 2023 |
| Effects of dispersed fibres in myocardial mechanics, Part I: passive response D Guan, Y Mei, L Xu, L Cai, X Luo, H Gao Mathematical Biosciences and Engineering, 2022 | 7 | 2022 |
| Effects of dispersed fibres in myocardial mechanics, Part II: active response D Guan, Y Wang, L Xu, L Cai, X Luo, H Gao Mathematical Biosciences and Engineering, 2022 | 4 | 2022 |
| Association of cerebral infarction with vertebral arterial fenestration using non-Newtonian hemodynamic evaluation Y Mei, D Guan, X Tong, Q Liu, M Hu, G Chen, C Li Mathematical Biosciences and Engineering 19 (7), 7076-7090, 2022 | 4 | 2022 |
| Constitutive modelling of soft biological tissue from ex vivo to in vivo: myocardium as an example D Guan, X Luo, H Gao International Conference by Center for Mathematical Modeling and Data …, 2020 | 4 | 2020 |
| Experimental investigation of wake flow and wave-vortex coupling induced vibration of two tandem and cylinders D GUAN, W HUANG, H SONG Journal of vibration and shock 33 (22), 26-29, 2014 | 3 | 2014 |
| Using LDDMM and a kinematic cardiac growth model to quantify growth and remodelling in rat hearts under PAH D Guan, L Tian, W Li, H Gao Computers in Biology and Medicine 171, 108218, 2024 | 2 | 2024 |
| A Modelling Study of Pulmonary Regurgitation in a Personalized Human Heart D Guan, Y Wang, X Luo, M Danton, H Gao International Conference on Functional Imaging and Modeling of the Heart …, 2023 | | 2023 |
| Effect of Myofibre Dispersion on Ventricular Pump Function D Guan, X Luo, H Gao | | 2022 |
| Growth and Remodelling of Right Ventricle Under Pulmonary Arterial Hypertension D Guan, L Tian, H Gao | | 2022 |
| Mathematical modelling of cardiac function: constitutive law, fibre dispersion, growth and remodelling D Guan University of Glasgow, 2021 | | 2021 |
| Effects of Myofibre Architecture on Biventricular Biomechanics: a Simulation Study D Guan, J Yao, X Luo, H Gao | | 2019 |
| Experimental investigation of wake flow and wave-vortex coupling induced vibration of two tandem and cylinders G Debao, H Weiping, S Hong Journal of vibration and shock 33 (22), 26-29, 2014 | | 2014 |
| Experimental study on coupled vibration of wake and wake vortex of tandem cylinder W Guan, Debao and Song, Hong and Tian, Huiyuan and Geng, Aoxiang and Wei ... Journal of Vibration and Shock 33 (22), 26--29, 2014 | | 2014 |