骨内种植体的界面剪切强度。

Interfacial shear strength of endosseous implants.

机构信息

The Jane and Jerry Weintraub Center for Reconstructive Biotechnology, Division of Advanced Prosthodontics, Biomaterials and Hospital Dentistry, University of California at Los Angeles School of Dentistry, Los Angeles, California, USA.

出版信息

Int J Oral Maxillofac Implants. 2011 Jul-Aug;26(4):746-51.

PMID:21841983

Abstract

PURPOSE

Surface roughness is known to affect the load-bearing strength of implants. However, the underlying mechanisms are not completely understood. This study sought to investigate the potential effects of bone-to-implant contact (BIC) and mechanical interlocking on the stability of titanium implants using a newly established assessment system that combines nondestructive microcomputed tomography (ΜCT) and the biomechanical push-in test.

MATERIALS AND METHODS

Cylindric implants with a machined or a dual acid-etched (DAE) surface were placed into the distal femurs of Sprague-Dawley rats. At weeks 2 and 4, the femur-implant specimens were harvested and scanned in a desktop ΜCT device, and the BIC was calculated. The implants were then loaded axially using a universal mechanical testing machine and the breakage force was recorded as a push-in value. Machined and DAE implants were also embedded in histology-quality resin to serve as a nonbiologic reference. Two-way analysis of variance and the Mann-Whitney U test were used for statistical analysis.

RESULTS

BIC showed no surface- or time-dependent differences. The mean push-in value of DAE implants was four times greater at week 2 and three times greater at week 4 than that of machined implants. The shear strength at the interface (push-in value/BIC) was greater for DAE surfaces than for machined surfaces in a proportionate manner. When the implants were embedded in the resin with virtually 100% implant-resin contact, DAE implants showed 30% greater push-in values and shear strength than machined implants (P < .05).

CONCLUSIONS

These findings suggest that the percentage of BIC and mechanical interlocking cannot fully explain the surface roughness-related increase in osseointegration, as opposed to the common understanding of osseointegration. Further studies must include more details to discover the precise understanding of the physiology of osseointegration and the potential biologic mechanisms involved.

摘要

目的

众所周知，表面粗糙度会影响种植体的承载强度。然而，其潜在机制尚不完全清楚。本研究旨在使用新建立的评估系统，结合无损微计算机断层扫描（μCT）和生物力学推入试验，研究骨-种植体接触（BIC）和机械互锁对钛种植体稳定性的潜在影响。

材料与方法

将具有机械加工或双重酸蚀（DAE）表面的圆柱形种植体植入 Sprague-Dawley 大鼠的股骨远端。在 2 周和 4 周时，收获股骨-种植体标本并在台式 μCT 设备中进行扫描，并计算 BIC。然后，使用万能材料试验机对种植体进行轴向加载，并记录断裂力作为推入值。还将机械加工和 DAE 种植体嵌入组织学质量树脂中，作为非生物学参考。使用双向方差分析和 Mann-Whitney U 检验进行统计分析。

结果

BIC 没有表现出表面或时间依赖性差异。在第 2 周，DAE 种植体的平均推入值比机械加工种植体高 4 倍，在第 4 周高 3 倍。DAE 表面的界面剪切强度（推入值/BIC）比机械加工表面高，比例适当。当种植体完全嵌入具有 100%种植体-树脂接触的树脂中时，与机械加工种植体相比，DAE 种植体的推入值和剪切强度分别增加了 30%（P<0.05）。