Selective Laser Sintering 3D Printing - an Overview of the Technology and Pharmaceutical Applications

Overview

Journal Drug Dev Ind Pharm

Publisher Informa Healthcare

Specialty Pharmacology

Date 2020 May 5

PMID 32364418

Citations 38

Authors

Naseem A Charoo

Sogra F Barakh Ali

Eman M Mohamed

Mathew A Kuttolamadom

Tanil Ozkan

Mansoor A Khan

Ziyaur Rahman

Affiliations

Soon will be listed here.

Abstract

Food and Drug Administration (FDA) has approved a drug product (Spritam®) and many medical devices manufactured by three-dimensional printing (3DP) processes for human use. There is immense potential to print personalized medicines using 3DP. Many 3DP methods have been reported in the literature for pharmaceutical applications. However, selective laser sintering (SLS) printing has remained least explored for pharmaceutical applications. There are many advantages and challenges in adopting a SLS method for fabrication of personalized medicines. Solvent-free nature, availability of FDA approved thermoplastic polymer/excipients (currently used in hot melt-extrusion process), minimal/no post-processing step, etc. are some of the advantages of the SLS printing process. Major challenges of the technology are requirement of at least one thermoplastic component in the formulation and thermal stability of drug and excipients. This review provides an overview of the SLS printing method, excipient requirements, process monitoring, quality defects, regulatory aspects, and potential pharmaceutical applications.

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