3D Bioplotter Research Papers

In recent years, tissue engineering has experienced significant advancements, mostly driven by the emergence of additive manufacturing technologies and the integration of biomaterials and cells. This advanced technique enables the creation of intricate structures with diverse components and properties, specifically designed for use in biomedical applications. The primary benefit of this technology is its ability to be customised, which helps minimise post-operative difficulties for patients with orthopaedic diseases and those undergoing tissue transplants. For this purpose, the essential components can be synthesised by the patient’s own cells. However, there are still other obstacles that need to be addressed in order…

Bioprinting consists in an innovative approach able to improve the current techniques of bioregeneration in the medical field through the extrusion of cell-loaded bioinks. Its main advantage is the customization to reduce post-operative complications on the patient, as it can be produced from his own cells. The success of bioprinting is determined by the printing parameters but, above all, by the materials. The goal of this work was to define a range of parameters, in order to achieve the highest printing stability, in terms of the quality of the Bioplotter® Silicone TG in relation to process conditions used.

Scaffolds manufacturing for tissue engineering is an elaborate process since to fabricate a functional tissue, the engineered structures have to mimic the extracellular matrix. The key goal is to produce 3D scaffolds composed of macro- and micro- scale structures. The combination of different production technologies, as 3D bioprinting (BP) and electrospinning (ES), enables the fabrication of multiscale structures but, above all, the biomaterial choice is crucial to apply these technologies. Hydrogels based of Polyvinyl alcohol (PVA), a water soluble and biodegradable polymer, are able to create a highly hydrated environment that promotes cell attachment and proliferation, with limited mechanical properties.…

In recent years, a new additive manufacturing (AM) method for three-dimensional (3D) syringe-extrusion (bio)printing of soft hydrogels has been introduced under the name of Freeform Reversible Embedding of Suspended Hydrogels (FRESH). The most common FRESH bath contains gelatin as the main compound and low concentrations of crosslinker(s) (whose nature depends on the hydrogel) for the initiation of an in-situ pre-crosslinking process during printing. In the case of sodium alginate (SA)-based hydrogels ionically crosslinked via calcium chloride (CaCl2), the crosslinker percentage in the gelatin bath is equal to ~10 mM, usually combined with a post-crosslinking at higher concentrations. However, according to the…