Multi-parameter viscoelastic material model for denture adhesives based on time-temperature superposition and multiple linear regression analysis.

Anantha Narayanan Ramakrishnan, Josephine Reymann, Christopher Ludtka, Andreas Kiesow, Stefan Schwan
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Abstract

Background: Restorative solutions designed for edentulous patients such as dentures and their accompanying denture adhesives operate in the complex and dynamic environment represented by human oral physiology. Developing material models accounting for the viscoelastic behavior of denture adhesives can facilitate their further optimization within that unique physiological environment. This study aims to statistically quantify the degree of significance of three physiological variables - namely: temperature, adhesive swelling, and pH - on denture adhesive mechanical behavior. Further, based on these statistical significance estimations, a previously-developed viscoelastic material modelling approach for such denture adhesives is further expanded and developed to capture these variables' effects on mechanical behavior.

Methods: In this study a comparable version of Denture adhesive Corega Comfort was analysed rheologically using the steady state frequency sweep tests. The experimentally derived rheological storage and loss modulus values for the selected physiological variables were statistically analyzed using multi parameter linear regression analysis and the Pearson's coefficient technique to understand the significance of each individual parameter on the relaxation spectrum of the denture adhesive. Subsequently, the parameters are incorporated into a viscoelastic material model based on Prony series discretization and time-temperature superposition, and the mathematical relationship for the loss modulus is deduced.

Results: The results of this study clearly indicated that the variation in both the storage and loss modulus values can be accurately predicted using the oral cavity physiological parameters of temperature, swelling ratio, and pH with an adjusted R2 value of 0.85. The R2 value from the multi-parameter regression analysis indicated that the predictor variables can estimate the loss and storage modulus with a reasonable accuracy for at least 85% of the rheologically determined continuous relaxation spectrum with a confidence level of 98%. The Pearson's coefficient for the independent variables indicated that temperature and swelling have a strong influence on the loss modulus, whereas pH had a weak influence. Based on statistical analysis, these mathematical relationships were further developed in this study.

Conclusions: This multi-parameter viscoelastic material model is intended to facilitate future detailed numerical investigations performed with implementation of denture adhesives using the finite element method.

基于时间-温度叠加和多元线性回归分析的义齿粘合剂多参数粘弹性材料模型
背景:为无牙患者设计的修复解决方案,如义齿及其配套的义齿粘合剂,是在人类口腔生理所代表的复杂而动态的环境中运行的。针对义齿粘接剂的粘弹性行为开发材料模型,有助于在这种独特的生理环境中进一步优化义齿粘接剂。本研究旨在统计量化三个生理变量(即温度、粘合剂膨胀和 pH 值)对义齿粘合剂机械行为的重要程度。此外,在这些统计意义估计的基础上,进一步扩展和发展了之前开发的针对此类义齿粘合剂的粘弹性材料建模方法,以捕捉这些变量对机械行为的影响:本研究使用稳态频率扫描试验对同类义齿粘合剂 Corega Comfort 进行了流变学分析。使用多参数线性回归分析和皮尔逊系数技术对实验得出的选定生理变量的流变存储值和损失模量值进行统计分析,以了解每个参数对义齿粘合剂松弛谱的影响。随后,将这些参数纳入基于 Prony 序列离散化和时间-温度叠加的粘弹性材料模型,并推导出损失模量的数学关系:研究结果表明,利用温度、膨胀率和 pH 值等口腔生理参数可以准确预测储存模量和损失模量值的变化,调整后的 R2 值为 0.85。多参数回归分析得出的 R2 值表明,在流变学测定的连续松弛谱中,预测变量至少可以对 85% 的损耗模量和贮存模量进行合理准确的估计,置信度为 98%。自变量的皮尔逊系数表明,温度和膨胀对损耗模量的影响较大,而 pH 值的影响较小。在统计分析的基础上,本研究进一步发展了这些数学关系:该多参数粘弹性材料模型有助于今后使用有限元法对义齿粘合剂进行详细的数值研究。
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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