Theoretically proposed optimal frequency for ultrasound induced cartilage restoration.

April D Miller, Anuradha Subramanian, Hendrik J Viljoen
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引用次数: 8

Abstract

Background: Matching the frequency of the driving force to that of the system's natural frequency of vibration results in greater amplitude response. Thus we hypothesize that applying ultrasound at the chondrocyte's resonant frequency will result in greater deformation than applying similar ultrasound power at a frequency outside of the resonant bandwidth. Based on this resonant hypothesis, our group previously confirmed theoretically and experimentally that ultrasound stimulation of suspended chondrocytes at resonance (5 MHz) maximized gene expression of load inducible genes. However, this study was based on suspended chondrocytes. The resonant frequency of a chondrocyte does not only depend on the cell mass and intracellular stiffness, but also on the mechanical properties of the surrounding medium. An in vivo chondrocyte's environment differs whether it be a blood clot (following microfracture), a hydrogel or the pericellular and extracellular matrices of the natural cartilage. All have distinct structures and compositions leading to different resonant frequencies. In this study, we present two theoretical models, the first model to understand the effects of the resonant frequency on the cellular deformation and the second to identify the optimal frequency range for clinical applications of ultrasound to enhance cartilage restoration.

Results: We showed that applying low-intensity ultrasound at the resonant frequency induced deformation equivalent to that experimentally calculated in previous studies at higher intensities and a 1 MHz frequency. Additionally, the resonant frequency of an in vivo chondrocyte in healthy conditions, osteoarthritic conditions, embedded in a blood clot and embedded in fibrin ranges from 3.5 - 4.8 MHz.

Conclusion: The main finding of this study is the theoretically proposed optimal frequency for clinical applications of therapeutic ultrasound induced cartilage restoration is 3.5 - 4.8 MHz (the resonant frequencies of in vivo chondrocytes). Application of ultrasound in this frequency range will maximize desired bioeffects.

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理论上提出超声诱导软骨修复的最佳频率。
背景:将驱动力的频率与系统的固有振动频率相匹配,会产生更大的幅值响应。因此,我们假设在软骨细胞的共振频率上施加超声比在共振带宽以外的频率上施加相似的超声功率会导致更大的变形。基于这一共振假说,课课组前期从理论和实验上证实,超声在共振(5 MHz)下刺激悬浮软骨细胞可使负荷诱导基因的基因表达最大化。然而,这项研究是基于悬浮软骨细胞。软骨细胞的共振频率不仅与细胞质量和细胞内刚度有关,还与周围介质的力学特性有关。体内软骨细胞的环境是不同的,无论是血凝块(微骨折后),水凝胶还是天然软骨的细胞周和细胞外基质。它们都有不同的结构和组成,导致不同的谐振频率。在本研究中,我们提出了两个理论模型,第一个模型用于理解共振频率对细胞变形的影响,第二个模型用于确定临床应用超声增强软骨修复的最佳频率范围。结果:我们发现,在共振频率下应用低强度超声,在更高强度和1 MHz频率下,产生的变形相当于先前研究中实验计算的变形。此外,在健康情况下,骨关节炎情况下,嵌入血凝块和嵌入纤维蛋白的体内软骨细胞的共振频率范围为3.5 - 4.8 MHz。结论:本研究的主要发现是理论上提出的治疗性超声诱导软骨修复临床应用的最佳频率为3.5 ~ 4.8 MHz(体内软骨细胞的共振频率)。在这个频率范围内应用超声波将使期望的生物效应最大化。
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Theoretical Biology and Medical Modelling
Theoretical Biology and Medical Modelling MATHEMATICAL & COMPUTATIONAL BIOLOGY-
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期刊介绍: Theoretical Biology and Medical Modelling is an open access peer-reviewed journal adopting a broad definition of "biology" and focusing on theoretical ideas and models associated with developments in biology and medicine. Mathematicians, biologists and clinicians of various specialisms, philosophers and historians of science are all contributing to the emergence of novel concepts in an age of systems biology, bioinformatics and computer modelling. This is the field in which Theoretical Biology and Medical Modelling operates. We welcome submissions that are technically sound and offering either improved understanding in biology and medicine or progress in theory or method.
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