利用轴向血管化组织工程结构重建下颌骨。

Ahmad M Eweida, Ayman S Nabawi, Mona K Marei, Mohamed R Khalil, Habashi A Elhammady
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引用次数: 25

摘要

背景:目前用于下颌骨连续性缺损的重建技术包括使用游离皮瓣、骨移植物和同种异体材料。旨在恢复组织的再生医学新方法主要依赖于所谓的外源性新生血管,其中新生血管床起源于结构的外围。该方法不适用于辐照场中较大的缺陷。方法:我们介绍了一种新的动物模型,通过动-静脉(AV)环进行内源性轴向血管重建。为了验证这一模型,我们对成年公山羊进行了尸体、机械载荷和手术试验研究。尸体研究的目的是确定最佳的血管轴,用于在下颌骨区域创建房室环。进行力学加载研究(3点弯曲试验),以确保下颌骨的力学性能受到设计缺陷的显著影响,并为骨再生后进一步的力学测试提供基线。为了确保手术和术后的顺利进行,我们进行了一项初步的外科研究。结果:修复下颌骨后半部分缺损的最佳血管轴为面动脉(平均长度32.5±1.9 mm,直径2.5 mm)和面静脉(平均长度33.3±1.8 mm,直径2.6 mm)。前半部分的缺损需要额外的静脉移植。缺损对下颌骨的力学性能有显著影响(P值0.0204)。术后第3天起可饲喂软饲,1周内恢复正常饮食。随访2个月,下颌骨未发生断裂。结论:我们的模型引入了下颌构造体轴向血管化的概念。该模型可用于评估辐照场中较大骨缺损的骨再生。这是第一个引入轴向血管形成概念的研究,利用房室袢在下颌骨区域进行血管生成。此外,这是第一个旨在在不需要组织转移的情况下在缺损部位进行合成组织工程结构的轴向血管化的研究(与之前在预制皮瓣中所做的相反)。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Mandibular reconstruction using an axially vascularized tissue-engineered construct.

Mandibular reconstruction using an axially vascularized tissue-engineered construct.

Mandibular reconstruction using an axially vascularized tissue-engineered construct.

Mandibular reconstruction using an axially vascularized tissue-engineered construct.

Background: Current reconstructive techniques for continuity defects of the mandible include the use of free flaps, bone grafts, and alloplastic materials. New methods of regenerative medicine designed to restore tissues depend mainly on the so-called extrinsic neovascularization, where the neovascular bed originates from the periphery of the construct. This method is not applicable for large defects in irradiated fields.

Methods: We are introducing a new animal model for mandibular reconstruction using intrinsic axial vascularization by the Arterio-Venous (AV) loop. In order to test this model, we made cadaveric, mechanical loading, and surgical pilot studies on adult male goats. The cadaveric study aimed at defining the best vascular axis to be used in creating the AV loop in the mandibular region. Mechanical loading studies (3 points bending test) were done to ensure that the mechanical properties of the mandible were significantly affected by the designed defect, and to put a base line for further mechanical testing after bone regeneration. A pilot surgical study was done to ensure smooth operative and post operative procedures.

Results: The best vascular axis to reconstruct defects in the posterior half of the mandible is the facial artery (average length 32.5 ± 1.9 mm, caliber 2.5 mm), and facial vein (average length 33.3 ± 1.8 mm, caliber 2.6 mm). Defects in the anterior half require an additional venous graft. The defect was shown to be significantly affecting the mechanical properties of the mandible (P value 0.0204). The animal was able to feed on soft diet from the 3rd postoperative day and returned to normal diet within a week. The mandible did not break during the period of follow up (2 months).

Conclusions: Our model introduces the concept of axial vascularization of mandibular constructs. This model can be used to assess bone regeneration for large bony defects in irradiated fields. This is the first study to introduce the concept of axial vascularization using the AV loop for angiogenesis in the mandibular region. Moreover, this is the first study aiming at axial vascularization of synthetic tissue engineering constructs at the site of the defect without any need for tissue transfer (in contrast to what was done previously in prefabricated flaps).

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