冲击波疗法下下颌段牙科植入物的应力状态建模

IF 0.4 4区 物理与天体物理 Q4 PHYSICS, MULTIDISCIPLINARY Russian Physics Journal Pub Date : 2024-09-20 DOI:10.1007/s11182-024-03263-5
A. Y. Smolin, G. M. Eremina, I. P. Martyshina
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引用次数: 0

摘要

安装牙齿修复体最重要和最漫长的阶段是金属植入物与骨组织的骨结合。通过使用体外冲击波疗法等方法加速这一过程非常重要。本研究的目的是采用可移动细胞自动机方法中的孔弹性模型,对种植体在牙科区域的骨结合条件进行数值研究。研究对象的下颌部分包括覆盖着 600 μm 厚皮质层的海绵组织和 400 μm 厚牙龈。此外,第二前磨牙和第二臼齿的根部有牙周膜,而第一臼齿的种植体位于软纤维组织的外壳内。根据机械生物学原理,对获得的静水压力和间隙流体压力场进行了分析。研究结果表明,在骨结合的初始阶段,冲击波疗法有利于创造条件,促进骨组织细胞沿着种植体周围纤维组织的主要部分分化和转移。
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Modeling the Stress State of the Mandibular Segment with a Dental Implant Under Shock Wave Therapy

The most significant and protracted phase of the installation of a dental prosthesis is osseointegration of a metal implant with bone tissue. It is important to accelerate this process, for example, by the use of extracorporeal shock wave therapy. The objective of this study is to investigate numerically the conditions for osseointegration of the implant in the dental region employing a poroelastic model implemented in the movable cellular automaton method. The mandibular segment under consideration includes a spongy tissue covered with a cortical layer 600 μm thick and a gum 400 μm thick. Additionally, the second premolar and second molar exhibited periodontal membranes of their roots, while the implant of the first molar was situated within a shell of soft fibrous tissue. The obtained fields of hydrostatic pressure and interstitial fluid pressure were analyzed according to the mechanobiological principles. The results obtained have indicated that shock wave therapy has a beneficial impact on the creation of conditions conducive to the differentiation and transfer of bone tissue cells along the main volume of the fibrous tissue surrounding the implant during the initial osseointegration stage.

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来源期刊
Russian Physics Journal
Russian Physics Journal PHYSICS, MULTIDISCIPLINARY-
CiteScore
1.00
自引率
50.00%
发文量
208
审稿时长
3-6 weeks
期刊介绍: Russian Physics Journal covers the broad spectrum of specialized research in applied physics, with emphasis on work with practical applications in solid-state physics, optics, and magnetism. Particularly interesting results are reported in connection with: electroluminescence and crystal phospors; semiconductors; phase transformations in solids; superconductivity; properties of thin films; and magnetomechanical phenomena.
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