Systematic evaluation of three porcine-derived collagen membranes for guided bone regeneration.

Andrew Tai, Euphemie Landao-Bassonga, Ziming Chen, Minh Tran, Brent Allan, Rui Ruan, Dax Calder, Mithran Goonewardene, Hien Ngo, Ming Hao Zheng
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引用次数: 3

Abstract

Guided bone regeneration is one of the most common surgical treatment modalities performed when an additional alveolar bone is required to stabilize dental implants in partially and fully edentulous patients. The addition of a barrier membrane prevents non-osteogenic tissue invasion into the bone cavity, which is key to the success of guided bone regeneration. Barrier membranes can be broadly classified as non-resorbable or resorbable. In contrast to non-resorbable membranes, resorbable barrier membranes do not require a second surgical procedure for membrane removal. Commercially available resorbable barrier membranes are either synthetically manufactured or derived from xenogeneic collagen. Although collagen barrier membranes have become increasingly popular amongst clinicians, largely due to their superior handling qualities compared to other commercially available barrier membranes, there have been no studies to date that have compared commercially available porcine-derived collagen membranes with respect to surface topography, collagen fibril structure, physical barrier property, and immunogenic composition. This study evaluated three commercially available non-crosslinked porcine-derived collagen membranes (Striate+TM, Bio-Gide® and CreosTM Xenoprotect). Scanning electron microscopy revealed similar collagen fibril distribution on both the rough and smooth sides of the membranes as well as the similar diameters of collagen fibrils. However, D-periodicity of the fibrillar collagen is significantly different among the membranes, with Striate+TM membrane having the closest D-periodicity to native collagen I. This suggests that there is less deformation of collagen during manufacturing process. All collagen membranes showed superior barrier property evidenced by blocking 0.2-16.4 μm beads passing through the membranes. To examine the immunogenic agents in these membranes, we examined the membranes for the presence of DNA and alpha-gal by immunohistochemistry. No alpha-gal or DNA was detected in any membranes. However, using a more sensitive detection method (real-time polymerase chain reaction), a relatively strong DNA signal was detected in Bio-Gide® membrane, but not Striate+TM and CreosTM Xenoprotect membranes. Our study concluded that these membranes are similar but not identical, probably due to the different ages and sources of porcine tissues, as well as different manufacturing processes. We recommend further studies to understand the clinical implications of these findings.

三种猪源性胶原膜诱导骨再生的系统评价。
引导骨再生是最常见的外科治疗方式之一,当需要额外的牙槽骨来稳定种植体的部分和全部无牙患者。添加屏障膜可以防止非成骨组织侵入骨腔,这是引导骨再生成功的关键。屏障膜大致可分为不可吸收膜和可吸收膜。与不可吸收膜相比,可吸收屏障膜不需要第二次手术去除膜。市售的可吸收屏障膜要么是合成制造的,要么是从异种胶原蛋白中提取的。尽管胶原蛋白屏障膜在临床医生中越来越受欢迎,很大程度上是因为与其他市售屏障膜相比,胶原蛋白屏障膜具有优越的处理质量,但迄今为止还没有研究比较市售猪源胶原膜的表面形貌、胶原纤维结构、物理屏障特性和免疫原性组成。本研究评估了三种市售的非交联猪源性胶原膜(Striate+TM、Bio-Gide®和CreosTM Xenoprotect)。扫描电镜显示,在膜的粗糙面和光滑面,胶原原纤维分布相似,胶原原纤维直径相似。然而,纤维胶原蛋白的d -周期性在不同的膜之间存在显著差异,其中Striate+TM膜的d -周期性与天然胶原蛋白i最接近,这表明胶原蛋白在制造过程中变形较少。所有胶原膜均表现出优异的屏障性能,阻断0.2 ~ 16.4 μm微珠通过膜。为了检测这些膜中的免疫原性因子,我们用免疫组织化学方法检测了这些膜中DNA和α -半乳糖的存在。在任何膜中均未检测到α -gal或DNA。然而,使用更灵敏的检测方法(实时聚合酶链反应),在Bio-Gide®膜中检测到相对较强的DNA信号,而在Striate+TM和CreosTM Xenoprotect膜中检测不到。我们的研究得出结论,这些膜相似但不相同,可能是由于猪组织的年龄和来源不同,以及不同的制造工艺。我们建议进一步研究以了解这些发现的临床意义。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
6.70
自引率
0.00%
发文量
9
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