In Vitro 3D Cell-Cultured Arterial Models for Studying Vascular Drug Targeting Under Flow

The use of three-dimensional (3D) models of human arteries, which are designed with the correct dimensions and anatomy, enables the proper modeling of various important processes in the cardiovascular system. Recently, although several biological studies have been performed using such 3D models of human arteries, they have not been applied to study vascular targeting. This paper presents a new method to fabricate real-sized, reconstructed human arterial models using a 3D printing technique, line them with human endothelial cells (ECs), and study particle targeting under physiological flow. These models have the advantage of replicating the physiological size and conditions of blood vessels in the human body using low-cost components. This technique may serve as a new platform for studying and understanding drug targeting in the cardiovascular system and may improve the design of new injectable nanomedicines. Moreover, the presented approach may provide significant tools for the study of targeted delivery of different agents for cardiovascular diseases under patient-specific flow and physiological conditions.

Automated summary

This paper introduces a new method of fabricating real-sized, reconstructed human arterial models using 3D printing technology, lining them with human endothelial cells (ECs), and studying particle targeting under physiological flow. The technique may serve as a new platform for studying drug targeting in the cardiovascular system and improving the design of injectable nanomedicines, offering significant tools for studying targeted delivery of different agents for cardiovascular diseases under patient-specific flow and physiological conditions.