Articles with public access mandates - Charlie MacaskillLearn more
Available somewhere: 14
Simulation of a chain of collapsible contracting lymphangions with progressive valve closure
CD Bertram, C Macaskill, JE Moore Jr
Journal of biomechanical engineering 133, 011008, 2011
Mandates: US National Institutes of Health
Development of a model of a multi-lymphangion lymphatic vessel incorporating realistic and measured parameter values
CD Bertram, C Macaskill, MJ Davis, JE Moore
Biomechanics and modeling in mechanobiology 13, 401-416, 2014
Mandates: US National Institutes of Health
Incorporating measured valve properties into a numerical model of a lymphatic vessel
CD Bertram, C Macaskill, JE Moore Jr
Computer methods in biomechanics and biomedical engineering 17 (14), 1519-1534, 2014
Mandates: US National Institutes of Health
Consequences of intravascular lymphatic valve properties: a study of contraction timing in a multi-lymphangion model
CD Bertram, C Macaskill, MJ Davis, JE Moore Jr
American Journal of Physiology-Heart and Circulatory Physiology 310 (7 …, 2016
Mandates: US National Institutes of Health
A two-phase model of early fibrous cap formation in atherosclerosis
MG Watson, HM Byrne, C Macaskill, MR Myerscough
Journal of Theoretical Biology 456, 123-136, 2018
Mandates: Australian Research Council
Valve-related modes of pump failure in collecting lymphatics: numerical and experimental investigation
CD Bertram, C Macaskill, MJ Davis, JE Moore
Biomechanics and modeling in mechanobiology 16, 1987-2003, 2017
Mandates: US National Institutes of Health
Contraction of collecting lymphatics: organization of pressure-dependent rate for multiple lymphangions
CD Bertram, C Macaskill, MJ Davis, JE Moore
Biomechanics and modeling in mechanobiology 17, 1513-1532, 2018
Mandates: US National Institutes of Health
Pump function curve shape for a model lymphatic vessel
CD Bertram, C Macaskill, JE Moore Jr
Medical engineering & physics 38 (7), 656-663, 2016
Mandates: US National Institutes of Health
Inhibition of contraction strength and frequency by wall shear stress in a single-lymphangion model
CD Bertram, C Macaskill, JE Moore Jr
Journal of biomechanical engineering 141 (11), 111006, 2019
Mandates: US National Institutes of Health
A multiphase model of growth factor-regulated atherosclerotic cap formation
MG Watson, HM Byrne, C Macaskill, MR Myerscough
Journal of Mathematical Biology 81 (2), 725-767, 2020
Mandates: Australian Research Council
A computational model of a network of initial lymphatics and pre-collectors with permeable interstitium
BO Ikhimwin, CD Bertram, S Jamalian, C Macaskill
Biomechanics and modeling in mechanobiology 19, 661-676, 2020
Mandates: US National Institutes of Health
Modelling the coupling of the M-clock and C-clock in lymphatic muscle cells
EJ Hancock, SD Zawieja, C Macaskill, MJ Davis, CD Bertram
Computers in biology and medicine 142, 105189, 2022
Mandates: US National Institutes of Health
Modeling flow in embryonic lymphatic vasculature: what is its role in valve development?1
CD Bertram, BO Ikhimwin, C Macaskill
Mathematical Biosciences and Engineering 18 (2), 1406-1424, 2021
Mandates: US National Institutes of Health
A dual-clock-driven model emulating the effects of either Ano1 or IP3R knock-out on lymphatic muscle cell pace-making
EJ Hancock, SD Zawieja, C Macaskill, MJ Davis, CD Bertram
bioRxiv, 2022.11. 06.515373, 2022
Mandates: US National Institutes of Health
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