Analysis of 3‐D microstructure of porous poly(lactide‐glycolide) matrices using confocal microscopy

Abstract

Porous matrices of biodegradable polymers are extensively used as scaffolds in tissue engineering and as drug delivery devices. A critical component of the design, processing, and utility of such polymeric systems concerns the local void microarchitecture. In this study, a novel approach based on confocal fluorescence imaging was employed to visualize and quantify in 3 dimensions (3-D) the individual and population-level void morphology within porous polymeric matrices. Poly(lactic acid-glycolic acid) copolymer matrices were cast to yield void configurations of variable void sizes but constant cumulative voidage. Using confocal microscopy, fluorescently saturated polymer matrices were optically sectioned into serial 2-D images, and 3-D void contours were reconstructed via object discrimination and connectivity analysis. The resultant data was used to quantitate the matrix microstructure and map its evolution following polymer degradation. Under conditions of accelerated degradation, matrix erosion was found to cause a significant change in the disposition of voids; this involves two processes (void formation and void enlargement), the extent of which was influenced by the initial void size and the duration of erosion. By virtue of providing both static and dynamic descriptions of the void morphology in poly(lactic acid-glycolic acid) matrices, this is the first spatiotemporal study of the 3-D microarchitecture of porous, bioerodible tissue analog matrices. © 1998 John Wiley & Sons, Inc. J Biomed Mater Res (Appl Biomater) 43: 291–299, 1998