A
A. Comerford
Researcher at Imperial College London
Publications - 31
Citations - 1372
A. Comerford is an academic researcher from Imperial College London. The author has contributed to research in topics: Endothelium & Large eddy simulation. The author has an hindex of 15, co-authored 31 publications receiving 1164 citations. Previous affiliations of A. Comerford include University of Canterbury & Technische Universität München.
Papers
More filters
Journal ArticleDOI
Nektar++: An open-source spectral/hp element framework ✩
Chris D. Cantwell,David Moxey,A. Comerford,A. Bolis,G. Rocco,Gianmarco Mengaldo,Daniele De Grazia,Sergey Yakovlev,J.-E. Lombard,Dirk Ekelschot,Bastien E. Jordi,Hui Xu,Yumnah Mohamied,Claes Eskilsson,B. Nelson,Peter Vos,C. Biotto,Robert M. Kirby,Spencer J. Sherwin +18 more
TL;DR: The Nektar++ framework is designed to enable the discretisation and solution of time-independent or time-dependent partial differential equations, and the multi-layered structure of the framework allows the user to embrace as much or as little of the complexity as they need.
Journal ArticleDOI
Tissue-Engineered Tracheal Replacement in a Child: A 4-Year Follow-Up Study
Nicholas Hamilton,Mazyar Kanani,Derek J. Roebuck,Richard Hewitt,Raul Cetto,Emily J. Culme-Seymour,Ed C. Toll,Alister J. Bates,A. Comerford,Clare A. McLaren,Colin R. Butler,C. Crowley,Denise McIntyre,Neil J. Sebire,Sam M. Janes,Christopher O'Callaghan,Christopher E. Mason,P De Coppi,Mark W. Lowdell,Martin J. Elliott,Martin A. Birchall +20 more
TL;DR: The long‐term viability of a decellularized tissue‐engineered trachea within a child is demonstrated and further research is needed to develop bioengineered pediatric tracheal replacements with lower morbidity, better biomechanics and lower costs.
Journal ArticleDOI
Coupling strategies for biomedical fluid–structure interaction problems
TL;DR: A comparison of the most important fluid-structure interaction (FSI) schemes in the context of biomechanical problems is presented in this article, that is a comparison of different fixed-point schemes and a block preconditioned monolithic scheme.
Journal ArticleDOI
Towards a comprehensive computational model for the respiratory system
TL;DR: Novel nested multi-scale procedures are employed to simulate the dynamic behavior of lung parenchyma as a whole and local alveolar ensembles simultaneously without resolving theAlveolar micro-structure completely.
Journal ArticleDOI
Structured tree impedance outflow boundary conditions for 3D lung simulations.
TL;DR: A structured tree outflow boundary conditions for modeling the airflow in patient specific human lungs and demonstrates how different clinical scenarios can be studied without the need to assume the unknown flow distribution into the downstream region.