Soft tissue integration with a hybrid abutment using the "one abutment-one time" therapeutic protocol: case series.

OBJECTIVE: To describe a procedure that uses a definitive BioHPP hybrid abutment (polyether ether ketone [PEEK] reinforced with ceramic nanoparticles), to obtain a hermetic mucous seal with the peri-implant soft tissues. Method and materials: Between July 2017 and December 2019, seven patients aged between 40 and 60 years, who needed prosthetic rehabilitation in the esthetic zone, were treated. Among the various therapeutic solutions offered, patients chose an immediate or conventional implant rehabilitation using the "one abutment-one time" technique with the hybrid SKY elegance implant abutment (bredent medical). Ten implants were placed, five with immediate loading including two postextraction, and five in a conventional/classic loading protocol. The protocol required that the finishing margin of the provisional restoration was positioned approximately 1 to 2 mm from the implant platform, allowing the tissues to heal around the ceramic-reinforced PEEK abutment. After 6 months for the implants with immediate loading, and 3 months for those with conventional loading, the provisional restorations were replaced with definitive zirconia-ceramic prostheses. RESULTS: The clinical evaluation on the 10 implants showed that the reinforced PEEK abutments integrated well with the peri-implant tissues, and were healthy, without plaque, and with no bleeding on probing. An average probing depth of 1.0 mm was observed for nine of the ten placed implants, and for the tenth the implant probing depth was 1.5 mm. CONCLUSIONS: The ceramic-reinforced PEEK abutments BioHPP SKY elegance associated with the one-time therapeutic protocol is a valid alternative to traditional implant loading procedures, leading to an effective peri-implant hermetic mucous seal. (Quintessence Int 2022;53:590-596; doi: 10.3290/j.qi.b3082565; Originally published (in Italian) in Quintenssenza Internationale 2021;35:48-57).

MicroCT X-ray comparison of aligner gap and thickness of six brands of aligners: an in-vitro study.

BACKGROUND: To investigate and compare the gap (i.e. fit) and thickness of six aligner systems (Airnivol, ALL IN, Arc Angel, F22, Invisalign and Nuvola) using industrial computed tomography (CT). The null hypothesis was that there would be no detectable differences in either measurement between the aligners investigated. MATERIALS AND METHODS: Passive aligners of each brand were fitted to one single resin cast prototyped from an STL file from a single patient. The samples obtained were examined under high-resolution micro-CT, and the resulting tomographic microphotographs and volumetric data were compared. 3D analysis investigated the gap volume, the mean gap width and the maximum gap width of each sample. A total of 204 linear 2D measurements were made on 18 microtomographic images to investigate the aligner gap and thickness among different systems. Investigated regions were the central incisor, canine and first molar. The resulting measurements were analysed by ANOVA and compared using Tukey's post hoc analysis (P < 0.05). RESULTS: 3D analysis revealed that the F22 displayed lower gap volume and mean gap width, followed by Airnivol and Invisalign, whereas Airnivol the lowest maximum gap width. 2D analysis showed that F22 had the lowest mean gap and aligner thickness at all teeth investigated. Comparison of the 2D point values revealed statistically significant differences between brands in terms of both measurements (P < 0.05), with the exception of six points in the gap analysis and one in the thickness analysis. CONCLUSIONS: There are differences between the six aligner systems examined in terms of 2D and 3D measurements of aligner thickness and gap.

Scanning Small- and Wide-Angle X-ray Scattering Microscopy Selectively Probes HA Content in Gelatin/Hydroxyapatite Scaffolds for Osteochondral Defect Repair.

This study is aimed at investigating the structure of a scaffold made of bovine gelatin and hydroxyapatite for bone tissue engineering purposes. In particular, the detailed characterization of such a material has a great relevance because of its application in the healing process of the osteochondral defect that consists of a damage of cartilage and injury of the adjacent subchondral bone, significantly compromising millions of patient's quality of life. Two different techniques exploiting X-ray radiation, with table-top setups, are used: microtomography (micro-CT) and microdiffraction. Micro-CT characterizes the microstructure in the three dimensions at the micrometer scale spatial resolution, whereas microdiffraction provides combined structural/morphological information at the atomic and nanoscale, in two dimensional microscopy images with a hundred micrometer spatial resolution. The combination of these two techniques allowed an appropriate structural characterization for the purpose of validating the engineering approach used for the realization of the hydroxyapatite gradient across the scaffold, with properties close to the natural model.