Effects of Loading Forces, Loading Positions, and Splinting of Two, Three, or Four Ti-Zr (Roxolid ® ) Mini-Implants Supporting the Mandibular Overdentures on Peri-Implant and Posterior Edentulous Area Strains

• Published in: Journal of functional biomaterials Vol. 15; no. 9; p. 260
• Main Authors: Petricevic, Nikola, Celebic, Asja, Puljic, Dario, Milat, Ognjen, Divjak, Alan, Kovacic, Ines
• Format: Journal Article
• Language: English
• Published: Switzerland MDPI AG 09.09.2024; MDPI
• Subjects: Adhesives; Antagonists; Atrophy; Dental implants; Dentures; Dispersion hardening alloys; Edentulous; Gauges; loading forces; Longitudinal studies; Mandible; mandibular overdenture; Mechanical loading; Metal plates; number of implants; Patient satisfaction; Prostheses; Retention; Software; splinting; Strain gauges; Success; Teeth; Ti-Zr mini-implants; Titanium; Titanium base alloys; Vestibular system; Zirconium; Germany; Croatia; Denmark; United States > US; Japan; Liechtenstein; Ti-Zr mini-implants; loading forces; splinting; peri-implant strains; strain gauges; mandibular overdenture; number of implants; edentulous area strains
• ISSN: 2079-4983; 2079-4983
• DOI: 10.3390/jfb15090260

Clinical indications for the Ti-Zr alloy (Roxolid ) mini-implants (MDIs) in subjects with narrow ridges are still under review. The aim was to analyze peri-implant and posterior edentulous area strains dependent on the MDI number, splinting status, loading force, and loading position. Six models were digitally designed and printed. Two, three, or four Ti-Zr MDIs, splinted with a bar or unsplinted (single units), supported mandibular overdentures (ODs), loaded with 50-300 N forces unilaterally, bilaterally, and anteriorly. The artificial mucosa thickness was 2 mm. Strain gauges were bonded on the vestibular and oral peri-implant sides of each MDI, and on the posterior edentulous area under the ODs. Loadings were performed through the metal plate placed on ODs' artificial teeth (15 times repeated). Arithmetic means with standard deviations and the significance of the differences (MANOVA, Sheffe ) were calculated. Different MDI numbers, loading positions, forces, and splinting elicited different peri-implant microstrains. In the two-MDI models, 300 N force during unilateral loading elicited the highest microstrains (almost 3000 εμ on the loaded side), which can jeopardize bone reparation. On the opposite side, >2500 εμ was registered, which represents high strains. During bilateral loadings, microstrains hardly exceeded 2000 εμ, indicating that bilateral chewers or subjects having lower forces can benefit from the two Ti-Zr MDIs, irrespective of splinting. However, in subjects chewing unilaterally, and inducing higher forces (natural teeth antagonists), or bruxers, only two MDIs may not be sufficient to support the OD. By increasing implant numbers, peri-implant strains decrease in both splinted and single-unit MDI models, far beyond values that can interfere with bone reparation, indicating that splinting is not necessary. When the positions of the loading forces are closer to the implant, higher peri-implant strains are induced. Regarding the distal edentulous area, microstrains reached 2000 εμ only during unilateral loadings in the two-MDI models, and all other strains were lower, below 1500 εμ, confirming that implant-supported overdentures do not lead to edentulous ridge atrophy.