Respiratory diseases have a major impact on global health. The airway epithelium, which acts as a frontline defence, is one of the most common targets for inhaled allergens, irritants, or micro-organisms to enter the respiratory system. In the tissue engineering field, biomaterials play a crucial role. Due to the continuing high impact of respiratory diseases on society and the emergence of new respiratory viruses, in vitro airway epithelial models with high microphysiological similarities that are also easily adjustable to replicate disease models are urgently needed to better understand those diseases. Thus, the development of biomaterial scaffolds for the airway epithelium is important due to their function as a cell-support device in which cells are seeded in vitro and then are encouraged to lay down a matrix to form the foundations of a tissue for transplantation. Studies conducted in in vitro models are necessary because they accelerate the development of new treatments. Moreover, in comparatively controlled conditions, in vitro models allow for the stimulation of complex interactions between cells, scaffolds, and growth factors. Based on recent studies, the biomaterial scaffolds that have been tested in in vitro models appear to be viable options for repairing the airway epithelium and avoiding any complications. This review discusses the role of biomaterial scaffolds in in vitro airway epithelium models. The effects of scaffold, physicochemical, and mechanical properties in recent studies were also discussed.
Nasal packing is a critical procedure in postoperative care and trauma management aimed at controlling bleeding, providing structural support, and promoting tissue healing. However, conventional nasal packs often lead to discomfort, infection risks, and secondary tissue damage. To address these challenges, this study explores the potential use of biodegradable and biocompatible gelatin-carrageenan composite scaffolds as an alternative nasal packing material. Five compositions of gelatin-carrageenan scaffolds (ratios 10:0, 7:3, 5:5, 3:7, and 0:10) were fabricated and evaluated for physicochemical properties, hemocompatibility, and cytocompatibility. Results suggest that balanced ratios, such as 7:3 and 5:5, may provide a combination of structural integrity, improved biocompatibility, and controlled degradation, making them a potential candidate for nasal packing applications. The scaffolds exhibited low cytotoxicity and reasonable blood compatibility, which could reduce the risks associated with conventional materials. While these findings are promising, further in vivo studies are necessary to validate the efficacy and safety of these scaffolds in clinical settings. If proven effective, gelatin-carrageenan scaffolds may help address some of the limitations of conventional nasal packing materials and improve postoperative care outcomes.