Cross-sectional structure evolution of phase-separated spin-coated ethylcellulose/hydroxypropylcellulose films during solvent quenching
Journal article, 2022

Porous phase-separated ethylcellulose/hydroxypropylcellulose (EC/HPC) films are used to control drug transport out of pharmaceutical pellets. The films are applied on the pellets using fluidized bed spraying. The drug transport rate is determined by the structure of the porous films that are formed as the water-soluble HPC leaches out. However, a detailed understanding of the evolution of the phase-separated structure during production is lacking. Here, we have investigated EC/HPC films produced by spin-coating, which mimics the industrial manufacturing process. This work aimed to understand the structure formation and film shrinkage during solvent evaporation. The cross-sectional structure evolution was characterized using confocal laser scanning microscopy (CLSM), profilometry and image analysis. The effect of the EC/HPC ratio on the cross-sectional structure evolution was investigated. During shrinkage of the film, the phase-separated structure undergoes a transition from 3D to nearly 2D structure evolution along the surface. This transition appears when the typical length scale of the phase-separated structure is on the order of the thickness of the film. This was particularly pronounced for the bicontinuous systems. The shrinkage rate was found to be independent of the EC/HPC ratio, while the initial and final film thickness increased with increasing HPC fraction. A new method to estimate part of the binodal curve in the ternary phase diagram for EC/HPC in ethanol has been developed. The findings of this work provide a good understanding of the mechanisms responsible for the morphology development and allow tailoring of thin EC/HPC films structure for controlled drug release.

Author

Pierre Carmona

Chalmers, Physics, Nano and Biophysics

Christian von Corswant

AstraZeneca AB

Magnus Roding

University of Gothenburg

Aila Särkkä

Chalmers, Mathematical Sciences, Applied Mathematics and Statistics

University of Gothenburg

Eva Olsson

Chalmers, Physics, Nano and Biophysics

Niklas Lorén

Chalmers, Physics, Nano and Biophysics

RSC Advances

20462069 (eISSN)

Vol. 12 40 26078-26089

Subject Categories

Inorganic Chemistry

Polymer Technologies

Materials Chemistry

DOI

10.1039/d2ra04178b

More information

Latest update

10/26/2023