公開日期 | 標題 | 作者 | 來源出版物 | scopus | WOS | 全文 |
---|---|---|---|---|---|---|
2020 | The Action Potential | Chappell M.; Payne S.; STEPHEN JOHN PAYNE | Biosystems and Biorobotics | |||
2016 | The action potential | Chappell M.; Payne S.; STEPHEN JOHN PAYNE | Biosystems and Biorobotics | |||
2019 | Application of asymptotic expansion homogenization for vascularized poroelastic brain tissue | Shabudin A.; Mokhtarudin M.J.M.; Payne S.; Mohamed N.A.N.; STEPHEN JOHN PAYNE | 2018 IEEE EMBS Conference on Biomedical Engineering and Sciences, IECBES 2018 - Proceedings | |||
2014 | Between-centre variability in transfer function analysis, a widely used method for linear quantification of the dynamic pressure-flow relation: The CARNet study | Meel-van den Abeelen A.S.S.; Simpson D.M.; Wang L.J.Y.; Slump C.H.; Zhang R.; Tarumi T.; Rickards C.A.; Payne S.; Mitsis G.D.; Kostoglou K.; Marmarelis V.; Shin D.; Tzeng Y.-C.; Ainslie P.N.; Gommer E.; M?ller M.; Dorado A.C.; Smielewski P.; Yelicich B.; Puppo C.; Liu X.; Czosnyka M.; Wang C.-Y.; Novak V.; Panerai R.B.; Claassen J.A.H.R.; STEPHEN JOHN PAYNE | Medical Engineering and Physics | |||
2016 | Cardiovascular system I: The heart | Chappell M.; Payne S.; STEPHEN JOHN PAYNE | Biosystems and Biorobotics | |||
2020 | Cardiovascular System I: The Heart | Chappell M.; Payne S.; STEPHEN JOHN PAYNE | Biosystems and Biorobotics | |||
2020 | Cardiovascular System II: The Vasculature | Chappell M.; Payne S.; STEPHEN JOHN PAYNE | Biosystems and Biorobotics | |||
2016 | Cardiovascular system II: The vasculature | Chappell M.; Payne S.; STEPHEN JOHN PAYNE | Biosystems and Biorobotics | |||
2016 | Cell structure and biochemical reactions | Chappell M.; Payne S.; STEPHEN JOHN PAYNE | Biosystems and Biorobotics | |||
2020 | Cell Structure and Biochemical Reactions | Chappell M.; Payne S.; STEPHEN JOHN PAYNE | Biosystems and Biorobotics | |||
2020 | Cellular Homeostasis and Membrane Potential | Chappell M.; Payne S.; STEPHEN JOHN PAYNE | Biosystems and Biorobotics | |||
2016 | Cellular homeostasis and membrane potential | Chappell M.; Payne S.; STEPHEN JOHN PAYNE | Biosystems and Biorobotics | |||
2020 | Cellular Transport and Communication | Chappell M.; Payne S.; STEPHEN JOHN PAYNE | Biosystems and Biorobotics | |||
2016 | Cellular transport and communication | Chappell M.; Payne S.; STEPHEN JOHN PAYNE | Biosystems and Biorobotics | |||
2016 | The central nervous system | Chappell M.; Payne S.; STEPHEN JOHN PAYNE | Biosystems and Biorobotics | |||
2020 | The Central Nervous System | Chappell M.; Payne S.; STEPHEN JOHN PAYNE | Biosystems and Biorobotics | |||
2015 | Comparison of three artificial models of the magnetohydrodynamic effect on the electrocardiogram | Oster J.; Llinares R.; Payne S.; Tse Z.T.H.; Schmidt E.J.; Clifford G.D.; STEPHEN JOHN PAYNE | Computer Methods in Biomechanics and Biomedical Engineering | 10 | ||
2016 | Continuous positive airway pressure might not solve your cerebral autoregulation problem if you have obstructive sleep apnoea | Payne S.; STEPHEN JOHN PAYNE | Journal of Physiology | |||
2017 | The dual role of cerebral autoregulation and collateral flow in the circle of willis after major vessel occlusion | McConnell F.K.; Payne S.; STEPHEN JOHN PAYNE | IEEE Transactions on Biomedical Engineering | |||
2020 | From Cells to Tissue | Chappell M.; Payne S.; STEPHEN JOHN PAYNE | Biosystems and Biorobotics |