Litcius/Paper detail

Poly(lactic acid) and its composites as functional materials for 3-D scaffolds in biomedical applications: A mini review of recent trends

S. T. Sikhosana, Thandi Patricia Gumede, Ntsoaki Joyce Malebo, Adepemi O. Ogundeji

2021eXPRESS Polymer Letters41 citationsDOIOpen Access PDF

Abstract

Patients sometimes lose organs and/or organ functions due to disease and injury, which may result in permanent disabilities. Advanced biotechnological practices can now afford victims of these incidences an opportunity to repair some of the damaged tissues or organs without the need for a donor. This can be achieved by reconstruction of the damaged tissue or organ through scaffold and cell technologies. Scaffolds serve as template material for neo-organs to guide and accelerate cell growth. The structure of a scaffold material must meet certain design parameters to achieve optimal functionality in tissue engineering. Pre-requisites include surface compatibility and architectural suitability with the host environment. Polymeric scaffolds derived from polymer blends have the prospects to control the physical and chemical environment of the biological system. In this review, potential roles, general properties, advantages, and disadvantages of poly (lactic acid) and its composites as functional materials for scaffolding will be outlined. PLA and its composites have been subjects of research for some decades due to non-toxicity and the ability to mimic native tissue. Though PLA and composites have demonstrated great potential for various biomedical applications, a lot still needs to be done for them to compete with donor and prosthetic organs.

Topics & Concepts

ScaffoldMaterials scienceTissue engineeringPolymerNanotechnologyBiocompatible materialBiomedical engineeringConstruction engineeringComposite materialEngineeringbiodegradable polymer synthesis and propertiesBone Tissue Engineering MaterialsAdditive Manufacturing and 3D Printing Technologies