Seong‐Joo Heo scite author profile

Objective: To identify the influence of prosthetic features through a comprehensive analysis with other known risk factors. Materials and methods:A total of 169 patients (n = implants: 349) was retrospectively included in the present study. Peri-implantitis was diagnosed based on periimplant bone loss and probing depth. Using radiographs taken 1 and 5 years following prosthesis insertion, the following features were determined: peri-implant marginal bone loss (MBL), emergence angle (EA), emergence profile (EP) and crown/implant ratio (CIR). The splinted position of prosthesis was also recorded. Multivariable generalized estimating equation was used to analyse the influence of each feature on the prevalence of peri-implantitis. The final prediction model was constructed by Cox proportional hazard regression analysis. Results:The EA showed a significant correlation with MBL. A statistically greater prevalence of peri-implantitis was observed if EA ≥ 30 degrees, when EP is convex and in middle implant splinted with both mesial and distal adjacent implants in bonelevel implant. A similar correlation was not observed in tissue-level implants. CIR had no significant effect on the prevalence of peri-implantitis. Conclusion:Over-contoured implant prosthesis is a critical local confounder for peri-implantitis. The implant splinted to both mesial and distal adjacent implant has a higher risk of peri-implantitis. K E Y W O R D Semergence angle, emergence profile, Peri-implantitis, restoration contour, splinted

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Effects of Printing Parameters on the Fit of Implant-Supported 3D Printing Resin Prosthetics

Park

et al. 2019

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The purpose of the study was to investigate the influence of 3D printing parameters on fit and internal gap of 3D printed resin dental prosthesis. The dental model was simulated and fabricated for three-unit prostheses with two implants. One hundred prostheses were 3D printed with two-layer thicknesses for five build orientations using a resin (NextDent C&B; 3D systems, Soesterberg, The Netherlands) and ten prostheses were manufactured with a milling resin as control. The prostheses were seated and scanned with micro-CT (computerized tomography). Internal gap volume (IGV) was calculated from 3D reconstructed micro-CT data. IGV, marginal fit, and lengths of internal gaps were measured, and the values were analyzed statistically. For the 3D printed prostheses, IGV was smaller at 45°, 60°, and 90° compared to other build orientations. The marginal fit evaluated by absolute marginal discrepancy was smaller than other build orientations at 45° and 60°. IGV was smaller at 50 µm layer thickness than at 100 µm layer thickness, but the marginal fit was smaller at 100 µm layer thickness than at 50 µm layer thickness. The 3D printed prosthesis had smaller internal gap than the milled prosthesis. The marginal fit of the 3D printed resin prosthesis was clinically acceptable, and build orientation of 45° and 60° would be recommended when considering fit and internal gap.

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Microrough titanium surface affects biologic response in MG63 osteoblast‐like cells

Kim¹,

Kim²,

Lim³

et al. 2006

J Biomedical Materials Res

118

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The purpose of this study was to define the surface properties of prepared titanium (Ti) disks, which served as a model system, and to contrast the biologic response of MG63 cells exposed to Ti disks with different levels of surface roughness. The surface properties interact with each other, resulting in a change of other surface qualities in addition to roughness due to the surface roughening procedure. The machined Ti disks were roughened by sandblasting and electric glow discharging. The surface properties of the Ti specimens were inspected through a comprehensive surface analysis. MG63 cell behaviors were compared along with cell number, alkaline phosphatase (ALP) activity, Runx2 gene expression, and type I collagen production. Statistics were evaluated, using analysis of variance (ANOVA). The sandblasted Ti disks demonstrated well-controlled surface roughness features and meaningful average roughness ranges, including the surface roughness of the "modern" microrough implant, used clinically. With increasing Ti surface roughness, the cell number decreased, while the ALP activity, type I collagen production, and Runx2 gene expression increased significantly. The rougher the Ti surface was, the sooner the Runx2 gene was expressed. Based on these results, we suggest that the microrough Ti surfaces of the 1-3 mum range may contribute effectively to osteogenic differentiation and proliferation in MG63 cells.

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Comparison of experience curves between two 3-dimensional intraoral scanners

Kim

Park²,

Kim

et al. 2016

The Journal of Prosthetic Dentistry

139

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Seong‐Joo Heo

Improved biological performance of Ti implants due to surface modification by micro-arc oxidation

Association of prosthetic features and peri‐implantitis: A cross‐sectional study

Effects of Printing Parameters on the Fit of Implant-Supported 3D Printing Resin Prosthetics

Microrough titanium surface affects biologic response in MG63 osteoblast‐like cells

Comparison of experience curves between two 3-dimensional intraoral scanners

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