Yagci Filiz, Eraslan Ravza, Esim Emir
Department of Prosthodontics, Erciyes University Faculty of Dentistry, Ahmet El Biruni Cad. No:50 Köşk Mah, Melikgazi, Kayseri, Turkey.
Department of Prosthodontics, Erciyes University Faculty of Dentistry, Ahmet El Biruni Cad. No:50 Köşk Mah, Melikgazi, Kayseri, Turkey.
Dent Mater. 2024 Dec;40(12):e113-e120. doi: 10.1016/j.dental.2024.10.011. Epub 2024 Nov 2.
The purpose was to compare the biomechanical behavior of single-piece post-core restorations made from polyaryletherketone materials with fiber post-core restorations when serving as abutments for RPD using finite element analysis (FEA).
Phantom maxillary central incisor and mandibular second premolar were trimmed 1-mm coronally to cemento-enamel junction; root canals were enlarged and the teeth were scanned. Data was transferred to a solid modeling software.Twenty four models, including six post-core restorations:glass-fiber post/composite core (GFH/GFL) and single-piece post-core groups as, PEKK(PKH/PKL);Ti0-reinforced PEEK(TH/TL);ceramic reinforced PEEK(CeH/CeL);carbon fiber reinforced PEEK(CaH/CaL);glass fiber reinforced PEEK(GFPH/GFPL) with hybrid ceramic/lithium disilicate crowns on each tooth were constructed.Loads of 100 N for central incisor, and 300 N for premolar in a 45°oblique direction were applied to simulate masticatory forces. Clasp removal force of a RPD was simulated as 5 N vertically.FEA was employed to evaluate the von Mises stresses.Strain at cement layer was also investigated.
CaH/CaL groups revealed the lowest stress for both teeth at root while TH/TL groups revealed the highest stress. The lowest stress values in the post-core were in GFH/GFL groups while the highest stress occurred in the CaH/CaL groups for both teeth.
Glass-fiber post-cores exhibited the lowest stresses in the post under masticatory and clasp removal forces. It may suggest a potentially lower risk of post fracture compared to polyaryletherketone group materials. TiO-reinforced PEEK post-cores exhibited the lowest stresses among PAEK materials, indicating a potentially high fracture resistance.
采用有限元分析(FEA)比较聚芳醚酮材料制成的一体式桩核修复体与纤维桩核修复体作为可摘局部义齿(RPD)基牙时的生物力学行为。
将上颌中切牙和下颌第二前磨牙模型在冠方距牙骨质-釉质界1mm处截断;扩大根管并对牙齿进行扫描。数据传输至实体建模软件。构建24个模型,包括六种桩核修复体:玻璃纤维桩/复合树脂核(GFH/GFL)以及一体式桩核组,如聚醚醚酮酮(PEKK,PKH/PKL);二氧化钛增强聚醚醚酮(TH/TL);陶瓷增强聚醚醚酮(CeH/CeL);碳纤维增强聚醚醚酮(CaH/CaL);玻璃纤维增强聚醚醚酮(GFPH/GFPL),每颗牙齿上均带有混合陶瓷/二硅酸锂全冠。对中切牙施加100N、对前磨牙沿45°斜向施加300N的载荷以模拟咀嚼力。将RPD卡环的去除力模拟为垂直方向5N。采用有限元分析评估冯·米塞斯应力。同时研究粘结层的应变。
CaH/CaL组在两颗牙齿牙根处均显示出最低应力,而TH/TL组显示出最高应力。桩核中最低应力值出现在GFH/GFL组,而两颗牙齿的CaH/CaL组出现最高应力。
在咀嚼力和卡环去除力作用下,玻璃纤维桩核在桩内表现出最低应力。这可能表明与聚芳醚酮基材料相比,桩折断的风险可能更低。二氧化钛增强聚醚醚酮桩核在聚芳醚酮材料中表现出最低应力,表明其具有潜在的高抗折性。
