AI Article Synopsis
- The advancement of diverse biomaterials has led to innovative biomedical treatments for various conditions, including tissue support, joint replacements, and drug delivery.
- The technique of photo-induced polymerization, which uses electromagnetic radiation to initiate crosslinking in biomaterials, is highlighted for its efficiency and customizable nature to meet clinical requirements.
- The review discusses the photopolymerization process, focusing on commonly used photosensitizers, the reactions they mediate, and potential unwanted oxidation reactions at interfaces, along with suggested solutions.
Article Abstract
The development of diverse types of biomaterials has significantly contributed to bringing new biomedical strategies to treat clinical conditions. Applications of these biomaterials can range from mechanical support and protection of injured tissues to joint replacement, tissue implants, and drug delivery systems. Among the strategies commonly used to prepare biomaterials, the use of electromagnetic radiation to initiate crosslinking stands out. The predominance of photo-induced polymerization methods relies on a fast, efficient, and straightforward process that can be easily adjusted to clinical needs. This strategy consists of irradiating the components that form the material with photons in the near ultraviolet-visible wavelength range (, ∼310 to 750 nm) in the presence of a photoactive molecule. Upon photon absorption, photosensitive molecules can generate excited species that initiate photopolymerization through different reaction mechanisms. However, this process could promote undesired side reactions depending on the target zone or treatment type (, oxidative stress and modification of biomolecules such as proteins and lipids). This review explores the basic concepts behind the photopolymerization process of and biomaterials. Particular emphasis was put on the photosensitization initiated by the most employed photosensitizers and the photoreactions that they mediate in aqueous media. Finally, the undesired oxidation reactions at the bio-interface and potential solutions are presented.
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| http://dx.doi.org/10.1039/d4tb00299g | DOI Listing |
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