3D Bioplotter Research Papers

Macrophage polarisation is crucial for initiating inflammation in response to biomaterial scaffolds, significantly influencing tissue integration and regeneration in vivo. Modulating macrophage polarisation towards a tissue-regeneration-favouring phenotype through the physical properties of scaffolds offers a promising strategy to enhance tissue regeneration while minimising unfavourable immune responses. However, the critical impact of scaffold physical properties, such as size-scale dimensions, orientation of architectural cues, and local-stiffness of these cues on macrophage polarisation, remains largely unexplored and inadequately understood. This study investigates the combinatorial effects of the physical properties of 3D scaffolds made from poly (-caprolactone) on human macrophage polarisation. Our findings indicate…

Hybrid bioprinting uses sequential printing of melt-extruded biodegradable thermoplastic polymer and cell-encapsulated bioink in a predesigned manner using high- and low-temperature print heads for the fabrication of robust three-dimensional (3D) biological constructs. However, the high-temperature print head and melt-extruded polymer cause irreversible thermal damage to the bioprinted cells, and it affects viability and functionality of 3D bioprinted biological constructs. Thus, there is an urgent need to develop innovative approaches to protect the bioprinted cells, coming into contact or at close proximities to the melt-extruded thermoplastic polymer and the high-temperature print head during hybrid bioprinting. Therefore, this study investigated the potential…