PCL- And Gelatin-based Electrospun Biological Scaffolds For In Vitro Lung Tissue Engineering

ABSTRACT

Purpose/Objectives: Acute and chronic respiratory diseases constitute a substantial socioeconomic burden on a global scale, as made abundantly clear in the last two years with the rampant coronavirus disease 2019 (COVID-19) pandemic. Alas, the development of new therapies for pathological respiratory conditions has been hindered by the inadequacy of current preclinical models, which often fail to provide reliable predictions on drug safety and efficacy in humans. In particular, considerable anatomical and physiological differences between the respiratory systems of commonly used animal models and humans are one of the main issues leading to high drug attrition and clinical failure rates. Accordingly, the generation of physiologically relevant preclinical lung models for early drug development and pharmaceutical research is urgently needed. In this work, poly(ϵ-caprolactone) (PCL) and gelatin were used as raw materials to produce electrospun scaffolds for in vitro lung tissue engineering, in order to generate human biomimetic platforms for preclinical drug safety and efficacy testing. Methodology: PCL and gelatin were mixed at varying volume ratios 10 (PP), 61 (PPG61), 41 (PPG41), and 21 (PPG21), so as to determine the optimal gelatin concentration for cell adhesion and growth. Poly(vinylpyrrolidone) (PVP) was added to every polymer mixture to facilitate the electrospinning process, and electrospun fibrous matrices were fabricated using a needleless electrospinning technique. Scaffold morphology, chemical composition, and wettability were characterized with scanning electron microscopy (SEM), Fourier transform infrared (FTIR) spectroscopy, and water contact angle analysis, respectively. Biocompatibility testing was performed using human bronchial (16HBE) and alveolar (A549) epithelial cell lines, consisting of cell metabolic activity, proliferation, and adhesion evaluation over two weeks of in vitro culture. Results: All polymer blends resulted in the formation of electrospun scaffolds with a nanofibrous structure. The addition of gelatin in PPG61 scaffolds improved fiber morphology compared to PP formulations, but increasing proportions of this polymer in PPG41 and PPG21 mats caused a larger number of defects, such as beading and branching. FTIR analysis confirmed the presence of PCL and PVP in PP scaffolds, as well as the addition of gelatin in all PPG blends. Moreover, as expected, all scaffolds were hydrophilic, with water contact angles below 90°, being suitable for protein adsorption and cell adhesion. Regarding 16HBE and A549 cell viability, surprisingly, no major differences were found between the different formulations over the two-week culture period, showing that all polymer blends were equally capable of promoting cell adhesion and growth. While PP scaffolds significantly outperformed PPG electrospun mats in early timepoints, no such differences were identified at the end of the experimental period. Conclusion/Significance: These results suggested that PCL, PVP, and/or gelatin blend electrospun scaffolds are conducive to lung epithelial cell adhesion and proliferation. Nevertheless, further studies investigating epithelial cell differentiation and function should be conducted to fully assess the suitability of these biomaterials as platforms for in vitro lung tissue engineering.