Additively manufactured metallic biomaterials.

Metal additive manufacturing (AM) has led to an evolution in the design and fabrication of hard tissue substitutes, enabling personalized implants to address each patient's specific needs. In addition, internal pore architectures integrated within additively manufactured scaffolds, have provided an opportunity to further develop and engineer functional implants for better tissue integration, and long-term durability. In this review, the latest advances in different aspects of the design and manufacturing of additively manufactured metallic biomaterials are highlighted. After introducing metal AM processes, biocompatible metals adapted for integration with AM machines are presented. Then, we elaborate on the tools and approaches undertaken for the design of porous scaffold with engineered internal architecture including, topology optimization techniques, as well as unit cell patterns based on lattice networks, and triply periodic minimal surface. Here, the new possibilities brought by the functionally gradient porous structures to meet the conflicting scaffold design requirements are thoroughly discussed. Subsequently, the design constraints and physical characteristics of the additively manufactured constructs are reviewed in terms of input parameters such as design features and AM processing parameters. We assess the proposed applications of additively manufactured implants for regeneration of different tissue types and the efforts made towards their clinical translation. Finally, we conclude the review with the emerging directions and perspectives for further development of AM in the medical industry.

Recent developments in mussel-inspired materials for biomedical applications.

Over the decades, researchers have strived to synthesize and modify nature-inspired biomaterials, with the primary aim to address the challenges of designing functional biomaterials for regenerative medicine and tissue engineering. Among these challenges, biocompatibility and cellular interactions have been extensively investigated. Some of the most desirable characteristics for biomaterials in these applications are the loading of bioactive molecules, strong adhesion to moist areas, improvement of cellular adhesion, and self-healing properties. Mussel-inspired biomaterials have received growing interest mainly due to the changes in mechanical and biological functions of the scaffold due to catechol modification. Here, we summarize the chemical and biological principles and the latest advancements in production, as well as the use of mussel-inspired biomaterials. Our main focus is the polydopamine coating, the conjugation of catechol with other polymers, and the biomedical applications that polydopamine moieties are used for, such as matrices for drug delivery, tissue regeneration, and hemostatic control. We also present a critical conclusion and an inspired view on the prospects for the development and application of mussel-inspired materials.

Biodegradable microneedle patch for transdermal gene delivery.

The skin houses a developed vascular and lymphatic network with a significant population of immune cells. Because of the properties of the skin, nucleic acid delivery through the tissue has the potential to treat a range of pathologies, including genetic skin conditions, hyperproliferative diseases, cutaneous cancers, wounds, and infections. This work presents a gelatin methacryloyl (GelMA) microneedle (MN)-based platform for local and controlled transdermal delivery of plasmid DNA (pDNA) with high transfection efficiency both in vitro and in vivo. Intracellular delivery of the nucleic acid cargo is enabled by poly(ß-amino ester) (PBAE) nanoparticles (NPs). After being embedded in the GelMA MNs, sustained release of DNA-encapsulated PBAE NPs is achieved and the release profiles can be controlled by adjusting the degree of crosslinking of the GelMA hydrogel. These results highlight the advantages and potential of using PBAE/DNA NP-embedded GelMA MN patches (MN/PBAE/DNA) for successful transdermal delivery of pDNA for tissue regeneration and cancer therapy.