The purpose of this study was to evaluate the scientific literature related to the use of graphene and its derivatives in dentistry. Electronic research was carried out on PubMed, Scopus and Web of Science. The studies found included the following topics: the use of graphene in tissue engineering, implantology, as an antibacterial material and in the manufacture of dental materials.
Scaffolds are three-dimensional porous structures that must have specific requirements to be applied in tissue engineering. Therefore, the study of factors affecting scaffold performance is of great importance. In this work, the optimal conditions for cross-linking preformed chitosan (CS) scaffolds by the tripolyphosphate polyanion (TPP) were investigated. The effect on scaffold physico-chemical properties of different concentrations of chitosan (1 and 2% w/v) and tripolyphosphate (1 and 2% w/v) as well as of cross-linking reaction times (2, 4, or 8 h) were studied.
Tissue engineering is a highly interdisciplinary field of medicine aiming at regenerating damaged tissues by combining cells with porous scaffolds materials. Scaffolds are templates for tissue regeneration and should ensure suitable cell adhesion and mechanical stability throughout the application period. Chitosan (CS) is a biocompatible polymer highly investigated for scaffold preparation but suffers from poor mechanical strength.
The effect of scaffold pore size and interconnectivity as well as porosity are undoubtedly crucial factors for most tissue engineering applications. This premise is the basis of worldwide efforts that have been spent to develop increasingly sophisticate fabrication techniques to control the scaffold microarchitecture and build efficient synthetic analogues of extracellular matrix.
Traumatic amputation of a digital segment with bone loss leaves a patient in severe disability. The degree of disfigurement and
function loss of the hand can be severe and permanent. In general, single-digit replantation is recommended only in selected
circumstances. Reconstructive procedures are restricted by limited shape and have the disadvantage of severe donor site
morbidity. To overcome these limitations, we have developed a tissue engineering approach to create the missing bone phalanx,
Nowadays, 3D bioprinting technologies are rapidly emerging in the field of tissue engineering and regenerative medicine as effective tools enabling the fabrication of advanced tissue constructs that can recapitulate in vitro organ/tissue functions. Selecting the best strategy for bioink deposition is often challenging and time consuming process, as bioink properties-in the first instance, rheological and gelation-strongly influence the suitable paradigms for its deposition.
In tissue engineering practice, a scaffold is often needed to deliver cells to the desired body site needing to be repaired. Scaffolds supporting cells can be either implanted through a surgical operation or injected through a laparoscopic device. The latter option is a first-choice in cases where a small and irregularly shaped defect needs to be regenerated. In such circumstances, the cell carrier has to be miniaturised while maintaining the morphological features that make a scaffold an efficient cell culture support, i.e.
tecnologia che nell’ambito di quella branca della scienza e tecnologia nota come ingegneria tissutale (TE) si sta imponendo in misura crescente grazie alla potenzialità che offre di replicare la complessità isto-morfologica dei tessuti umani. Il bioprinting rappresenta l’aspetto più moderno delle tecnologie di prototipazione rapida (RP) applicate al TE.
Keratins derived from human hair have been widely used for tissue engineering. However, some drawbacks relative to the traditional keratins extracts have been found: (a): difficultly controlling the amino acid composition; (b): batch to batch inconsistent quality; and (c): producing complex keratin and keratin-associated proteins (KAPs), which problems have made some studies concerning human hair keratins stagnant, especially in the mechanism studies related to hemostasis of keratins.
Different approaches have investigated the effects of different extracellular matrices (ECMs) and three-dimensional (3D) culture on islet function, showing encouraging results. Ideally, the proper scaffold should mimic the biochemical composition of the native tissue as it drives numerous signaling pathways involved in tissue homeostasis and functionality. Tissue-derived decellularized biomaterials can preserve the ECM composition of the native tissue making it an ideal scaffold for 3D tissue engineering applications.
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