Modulating Drug Release from Short Poly(ethylene Glycol) Block Initiated Poly(L-lactide) Di-block Copolymers

Overview

Journal Pharm Res

Specialties Pharmacology
Pharmacy

Date 2022 Apr 27

PMID 35474159

Authors

Zein Azhari

Patricia Smith

Sean McMahon

Wenxin Wang

Ruth E Cameron

Affiliations

Soon will be listed here.

Abstract

This paper investigates drug release from a novel series of mPEG-functionalised PLLA polymers whose individual components (PEG and PLLA) have regulatory FDA approval. Two processing methods were explored to understand their effect on the morphology and drug release profiles of the polymers, with and without mPEG functionalisation. In the first method the polymer and Propranolol.HCl drug powders were mixed together before injection moulding. In the second method, supercritical CO was used to mix the polymer and drug before injection moulding. When non-functionalised PLLA was processed through injection moulding alone, there were no signs of polymer-drug interaction, and the drug was confined to crystals on the surface. This resulted in up to 85 wt% burst release of propranolol.HCl after one day of incubation. By contrast, injection moulding of mPEG-functionalised polymers resulted in the partial dissolution of drug in the polymer matrix and a smaller burst (50 wt% drug) followed by sustained release. This initial burst release was completely eliminated from the profile of mPEG-functionalised polymers processed via supercritical CO. The addition of mPEG facilitated the distribution of the drug into the bulk matrix of the polymer. Paired with supercritical CO processing, the drug release profile showed a slow, sustained release throughout the 4 months of the study.

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