Hyaluronic acid (HA) is one of the most widely used extracellular matrix substrate in tissue engineering, drug delivery, and other clinical applications, due to its unique physiochemical properties and ubiquitous biological presence. In the past decade, there has been a surge in research paradigms involving HA products to evaluate their commercial feasibility. Numerous papers and reviews have reported procedures for chemical modifications and cross‐linking of HA, but the intricacies of their scale‐up in the production processes are often not discussed. Protected by confidentiality agreements with industry partners, information on these procedures is exclusive and not accessible within an academic setting. Establishing translatable synthetic protocols of HA would address this significant gap in the field and facilitate their use in other applications. The current method details a reproducible and robust method for producing particles that are composed of high molecular weight hyaluronic acid (cHA) and cross‐linked via a 4‐arm polyethylene glycol amine linker using 4‐(4,6‐dimethoxy‐1,3,5‐triazin‐2‐yl)‐4‐methyl‐morpholinium chloride chemistry. A critical analysis of previously reported procedures for their advantages and limitations (reaction parameters, molar equivalents, and reagents used for cross‐linking), forms the basis for this procedure and its subsequent adaptation to good manufacturing practices requirements. As a component of a Class III medical device, the reported cHA is in the form of non‐sized particles.
The development of functional blood vessels is today a fundamental pillar in the evaluation of new therapies and diagnostic agents. This article describes the manufacture and subsequent functionalization, by means of cell culture, of a microfluidic device with a circular section. Its purpose is to simulate a blood vessel in order to test new treatments for pulmonary arterial hypertension. The manufacture was carried out using a process in which a wire with a circular section determines the dimensions of the channel. To fabricate the blood vessel, cells were seeded under rotary cell culture to obtain a homogeneous cell seeding in the inner wall of the devices. This is a simple and reproducible method that allows the generation of blood vessel models in vitro.
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