Litcius/Paper detail

Methods for biomaterials printing: A short review and perspective

Hanieh Shokrani, Amirhossein Shokrani, Mohammad Reza Saeb

2022Methods36 citationsDOIOpen Access PDF

Abstract

Printing technologies have opened larger windows of innovation and creativity to biomaterials engineers by providing them with the ability to fabricate complex shapes in a reasonable time, cost, and weight. However, there has always been a trouble with function adjusting in printing technologies in view of the multiplicity of materials and apparatus parameters. 3D printing, also known as additive manufacturing, revolutionized biomaterials engineering by the conversion of a digital subject into a printed object (implants, scaffolds, or diagnostics and drug delivery devices/systems).Inspired by the lessons learned from 3D printing, the concept of 4D printing (better called shape-morphing fabrication) was conceptualized and put into practice to reply on the need for responsiveness of the printed platforms to a stimulus (light, pH, temperature, voltage, humidity, etc.) in a programmable manner. Later, the next milestone in printing technology was reached by 5D printing, by which the desired objects could be printed from five axes compared to the upward one-point printing by 3D printers. 5D printers use ≈20-30% fewer materials comparatively, enabling the printing of curved surfaces. Nevertheless, all bioprinters need a bio-ink with qualified characteristics for the biomedical applications. Thus, we discussed briefly the cell viability, scaffold biomimicry, scaffold biodegradation and affordability.

Topics & Concepts

Biofabrication3D printingScaffoldNanotechnologyDigital printingThree dimensional printing3d printedTissue engineeringComputer scienceMaterials scienceEngineeringMechanical engineeringEngineering drawingBiomedical engineering3D Printing in Biomedical ResearchAdditive Manufacturing and 3D Printing TechnologiesNeuroscience and Neural Engineering