Biomedical photopolymers in 3D printing

Author:

Alifui-Segbaya Frank

Abstract

Purpose Three-dimensional printing of acrylic-based medical devices is projected to grow exponentially despite the limitations of photopolymerization and the lack of information on the clinical performance of the materials. The purpose of this paper is to address an issue of critical importance in the translation of the three-dimensionally printed structures to the clinic, which is assessing the toxicity of the polymers and their precursors. Design/methodology/approach This review highlights the different manufacturing processes, challenges and novel experimental work including the zebrafish embryo model, which offers a potential method for toxicity profiling of biomedical photopolymers and their precursors due to its high genetic similarity to humans. Findings Materials information and experimental data available so far suggest that there is a need for regular and rigorous evaluation of new materials to establish their safety and protect users engaging in biomedically-related printing activities. Originality/value The review identifies stringent, contemporary and cost-effective analytical methods for assessing the safety of biomedical photopolymers and their precursors.

Publisher

Emerald

Subject

Industrial and Manufacturing Engineering,Mechanical Engineering

Reference65 articles.

1. 3D Printing and Additive Manufacturing (2017), “Expanding 3D printing technologies to high-volume applications and beyond”, Mary Ann Liebert, Publishers, available at: www.nxtbook.com/nxtbooks/mal/formlabsebook201709/index.php (accessed 6 June 2018).

2. 3D Printing Industry (2015), “3D printing basics: the free beginner’s guide”, available at: http://3dprintingindustry.com/wp-content/uploads/2014/07/3D-Printing-Guide.pdf (accessed 16 January 2016).

3. 3D Systems (2015), “Stereolithography”, available at: www.3dsystems.com/resources/information-guides/stereolithography/sla (accessed 26 November 2015).

4. 3D Systems (2017a), “Our story”, available at: https://au.3dsystems.com/our-story (accessed 25 April 2017).

5. 3D Systems (2017b), “What is MJP (MultiJet printing)?”, available at: https://au.3dsystems.com/resources/information-guides/multi-jet-printing/mjp (accessed 10 March 2017).

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