Cerebral water transport using multiple-network poroelastic theory: application to normal pressure hydrocephalus B Tully, Y Ventikos Journal of Fluid Mechanics 667, 188-215, 2011 | 152 | 2011 |
Strategies to enable large-scale proteomics for reproducible research RC Poulos, PG Hains, R Shah, N Lucas, D Xavier, SS Manda, A Anees, ... Nature communications 11 (1), 3793, 2020 | 94 | 2020 |
Coupling poroelasticity and CFD for cerebrospinal fluid hydrodynamics B Tully, Y Ventikos IEEE Transactions on biomedical engineering 56 (6), 1644-1651, 2009 | 74 | 2009 |
Pan-cancer proteomic map of 949 human cell lines E Gonçalves, RC Poulos, Z Cai, S Barthorpe, SS Manda, N Lucas, A Beck, ... Cancer Cell 40 (8), 835-849. e8, 2022 | 68 | 2022 |
Subject-specific multi-poroelastic model for exploring the risk factors associated with the early stages of Alzheimer's disease L Guo, JC Vardakis, T Lassila, M Mitolo, N Ravikumar, D Chou, M Lange, ... Interface focus 8 (1), 20170019, 2018 | 63 | 2018 |
Investigating cerebral oedema using poroelasticity JC Vardakis, D Chou, BJ Tully, CC Hung, TH Lee, PH Tsui, Y Ventikos Medical engineering & physics 38 (1), 48-57, 2016 | 61 | 2016 |
Computational modelling of the interaction of shock waves with multiple gas-filled bubbles in a liquid MR Betney, B Tully, NA Hawker, Y Ventikos Physics of Fluids 27 (3), 2015 | 53 | 2015 |
A fully dynamic multi-compartmental poroelastic system: Application to aqueductal stenosis D Chou, JC Vardakis, L Guo, BJ Tully, Y Ventikos Journal of Biomechanics 49 (11), 2306-2312, 2016 | 44 | 2016 |
Exploring the efficacy of endoscopic ventriculostomy for hydrocephalus treatment via a multicompartmental poroelastic model of CSF transport: a computational perspective JC Vardakis, BJ Tully, Y Ventikos PloS one 8 (12), e84577, 2013 | 36 | 2013 |
Addressing the challenges of high‐throughput cancer tissue proteomics for clinical application: proCan B Tully, RL Balleine, PG Hains, Q Zhong, RR Reddel, PJ Robinson Proteomics 19 (21-22), 1900109, 2019 | 30 | 2019 |
Multicompartmental poroelasticity as a platform for the integrative modeling of water transport in the brain JC Vardakis, BJ Tully, Y Ventikos Computer Models in Biomechanics: From Nano to Macro, 305-316, 2013 | 20 | 2013 |
A hypervelocity impact facility optimised for the dynamic study of high pressure shock compression TJ Ringrose, HW Doyle, PS Foster, M Betney, JW Skidmore, T Edwards, ... Procedia engineering 204, 344-351, 2017 | 13 | 2017 |
Modeling asymmetric cavity collapse with plasma equations of state B Tully, N Hawker, Y Ventikos Physical Review E 93 (5), 053105, 2016 | 13 | 2016 |
Toffee–a highly efficient, lossless file format for DIA-MS B Tully Scientific Reports 10 (1), 8939, 2020 | 9 | 2020 |
Characterizing shock waves in hydrogel using high speed imaging and a fiber-optic probe hydrophone PA Anderson, MR Betney, HW Doyle, B Tully, Y Ventikos, NA Hawker, ... Physics of Fluids 29 (5), 2017 | 8 | 2017 |
A Case Study and Methodology for OpenSWATH Parameter Optimization Using the ProCan90 Data Set and 45 810 Computational Analysis Runs S Peters, PG Hains, N Lucas, PJ Robinson, B Tully Journal of proteome research 18 (3), 1019-1031, 2019 | 5 | 2019 |
Response to letter to the editor concerning" A fully dynamic multi-compartmental poroelastic system: Application to aqueductal stenosis" JC Vardakis, D Chou, L Guo, BJ Tully, Y Ventikos Journal of Biomechanics 58, 243-246, 2017 | 5 | 2017 |
Pan-cancer proteomic map of 949 human cell lines reveals principles of cancer vulnerabilities E Gonçalves, RC Poulos, Z Cai, S Barthorpe, SS Manda, N Lucas, A Beck, ... bioRxiv, 2022.02. 26.482008, 2022 | 3 | 2022 |
Improved identification and quantification of peptides in mass spectrometry data via chemical and random additive noise elimination (CRANE) AJ Seneviratne, S Peters, D Clarke, M Dausmann, M Hecker, B Tully, ... Bioinformatics 37 (24), 4719-4726, 2021 | 3 | 2021 |
Simulation of warm dense matter in intense bubble collapse B Tully, N Hawker, M Betney, Y Ventikos Proceedings of Meetings on Acoustics 19 (1), 2013 | 3 | 2013 |