Additive manufacturing of personalized scaffolds for vascular cell studies in large arteries: A case study on carotid arteries in sickle cell disease patients

Additive manufacturing of personalized scaffolds for vascular cell studies in large arteries: A case study on carotid arteries in sickle cell disease patients

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Patient-specific models have increasingly gained significance in medical and research domains.In the context of hemodynamic studies, computational fluid dynamics emerges as a highly innovative and promising approach.We propose to augment these computational studies with cell-based experiments in individualized artery geometries using personalized scaffolds gallagher fault finder battery and vascular cell experiments.Previous research has demonstrated that the development of Sickle Cell Disease (SCD)-Related Vasculopathy is dependent on personal geometries and flow characteristics of the carotid artery.This fact leaves conventional animal experiments unsuitable for gaining patient-specific insights into cellular signaling, as they cannot replicate the personalized geometry.

These personalized dynamics of cellular signaling may further impact disease progression, yet remains unclear.This paper presents a six-step methodology for creating personalized large artery scaffolds, focusing on high-precision models that yield biologically interpretable patient-specific results.The methodology outlines the creation of personalized large artery models via Additive Manufacturing suitably for supporting cell culture and other cellular experiments.Additionally, it discusses how different Computer-Aided-Design (CAD) construction modes can be used to ceiling fan with 18 inch downrod obtain high-precision personalized models, while simplifying model reconfigurations and facilitating adjustments to general designs such as system connections to bioreactors, fluidic systems and visualization tools.A proposal for quality control measures to ensure geometric congruence for biological relevance of the results is added.

This innovative, interdisciplinary approach appears promising for gaining patient-specific insights into pathophysiology, highlighting the importance of personalized medicine for understanding complex diseases.