About this Research Topic
The fluid-structural interactive (FSI) computational model has been well-developed and has played a critical role in biomedical analysis. Specifically tailored for vascular biomechanical analyses with highly flexible walls, FSI models have proven successful in analysing the interaction between the blood fluid dynamics and the vessel walls. The outcomes derived from FSI computational analyses contribute to a broader and deeper understanding of biomechanics and hold immense potential for predicting the progress of cerebrovascular disease from a biomechanical perspective. Despite the current achievements, a pressing need remains for further exploration and refinement of FSI models to elevate their performance, enhance accuracy, and validate their clinical applicability.
This Research Topic is dedicated to delving into the forefront of FSI computational models in cerebrovascular areas. The objective is to spotlight cutting-edge research encompassing the latest advancements in FSI computational methods, theoretical explorations, and the application and validation of clinical data. The research topic welcomes innovative research works pertaining but not limited to the following themes:
• Biomechanics in cerebrovascular diseases
• Formation, progression and rupture of cerebral aneurysm
• Dynamic analysis and motion tracking of aneurysm
• Biomechanical risk factors of stroke
• Computational modelling-assisted medical device design and evaluation
• Computer assists in disease diagnosis and treatment plan
• Clinical studies in cerebrovascular diseases
• Numerical and AI algorithms and methods in vascular imaging processing
• Multi-physics biomechanical analysis and fluid-structural interaction (FSI) modelling methods and technologies
Authors are encouraged to submit a variety of article types, including Original Research, Case Reports, Brief Research Reports, Perspective pieces, Systematic or Mini-Reviews, and Meta-Analyses.
This Research Topic is dedicated to delving into the forefront of FSI computational models in cerebrovascular areas. The objective is to spotlight cutting-edge research encompassing the latest advancements in FSI computational methods, theoretical explorations, and the application and validation of clinical data. The research topic welcomes innovative research works pertaining but not limited to the following themes:
• Biomechanics in cerebrovascular diseases
• Formation, progression and rupture of cerebral aneurysm
• Dynamic analysis and motion tracking of aneurysm
• Biomechanical risk factors of stroke
• Computational modelling-assisted medical device design and evaluation
• Computer assists in disease diagnosis and treatment plan
• Clinical studies in cerebrovascular diseases
• Numerical and AI algorithms and methods in vascular imaging processing
• Multi-physics biomechanical analysis and fluid-structural interaction (FSI) modelling methods and technologies
Authors are encouraged to submit a variety of article types, including Original Research, Case Reports, Brief Research Reports, Perspective pieces, Systematic or Mini-Reviews, and Meta-Analyses.
Keywords: cerebral hemodynamics, vascular mechanics, Fluid-structural interactive, modeling, biomedical analysis
Important Note: All contributions to this Research Topic must be within the scope of the section and journal to which they are submitted, as defined in their mission statements. Frontiers reserves the right to guide an out-of-scope manuscript to a more suitable section or journal at any stage of peer review.
