Effective mechanical properties of frozen hydrogel with ice inclusions

IF 3.3 2区 医学 Q2 ENGINEERING, BIOMEDICAL Journal of the Mechanical Behavior of Biomedical Materials Pub Date : 2023-10-13 DOI:10.1016/j.jmbbm.2023.106190
Qinyun Yang , Moxiao Li , Xuechao Sun , Ming Wang , Shaobao Liu
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Abstract

Hydrogel exhibits attractive mechanical properties that can be regulated to be extremely tough, strong and resilient, adhesive and fatigue-resistant, thus enabling diverse applications ranging from tissue engineering scaffolds, flexible devices, to soft machines. As a liquid-filled porous material composed of polymer networks and water, the hydrogel freezes at subzero temperatures into a new material composed of polymer matrix and ice inclusions: the frozen hydrogel displays dramatically altered mechanical properties, which can significantly affect its safety and reliability in practical applications. In this study, based upon the theory of homogenization, we predicted the effective mechanical properties (e.g., Young's modulus, shear modulus, bulk modulus and Poisson ratio) of a frozen hydrogel with periodically distributed longitudinal ice inclusions. We firstly estimated its longitudinal Young's modulus, longitudinal Poisson ratio and plane strain bulk modulus using the self-consistent method, and then its longitudinal and transverse shear modulus using the generalized self-consistent method; further, the results were employed to calculate its transverse Young's modulus and transverse Poisson ratio. We validated the theoretical predictions against both finite element (FE) simulation and experimental measurement results, with good agreement achieved. We found that the estimated transverse Poisson ratio ranges from 0.3 to 0.53 and, at low volume fraction of ice inclusions, exhibits a value larger than 0.5 that exceeds the Poisson ratios of both the polymer matrix and the ice inclusion (typically 0.33–0.35). Compared with other homogenization methods (e.g., the rule of mixtures, the Halpin-Tsai equations, and the Mori-Tanaka method), the present approach is more accurate in predicting the effective mechanical properties (in particular, the transverse Poisson ratio) of frozen hydrogel. Our study provides theoretical support for the practical applications of frozen liquid-saturated porous materials such as hydrogel.

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含冰块的冷冻水凝胶的有效力学性能。
水凝胶具有吸引人的机械性能,可以调节为极其坚韧、坚固和有弹性、具有粘合性和抗疲劳性,从而实现从组织工程支架、柔性设备到软机器的各种应用。作为一种由聚合物网络和水组成的液体填充多孔材料,水凝胶在零度以下的温度下冻结成由聚合物基质和冰包裹体组成的新材料:冻结的水凝胶表现出显著的机械性能变化,这会显著影响其在实际应用中的安全性和可靠性。在这项研究中,基于均匀化理论,我们预测了具有周期性分布的纵向冰包裹体的冷冻水凝胶的有效力学性能(如杨氏模量、剪切模量、体积模量和泊松比)。我们首先用自洽方法估计了其纵向杨氏模量、纵向泊松比和平面应变体积模量,然后用广义自洽方法估算了其纵向和横向剪切模量;进一步,利用这些结果计算了其横向杨氏模量和横向泊松比。我们根据有限元模拟和实验测量结果验证了理论预测,取得了良好的一致性。我们发现,估计的横向泊松比范围在0.3至0.53之间,在冰包体体积分数较低的情况下,其值大于0.5,超过了聚合物基体和冰包体的泊松比(通常为0.33-0.35)。与其他均匀化方法(如混合物规则、Halpin Tsai方程和Mori-Tanaka方法)相比,本方法在预测冷冻水凝胶的有效力学性能(特别是横向泊松比)方面更准确。我们的研究为水凝胶等冷冻液体饱和多孔材料的实际应用提供了理论支持。
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来源期刊
Journal of the Mechanical Behavior of Biomedical Materials
Journal of the Mechanical Behavior of Biomedical Materials 工程技术-材料科学:生物材料
CiteScore
7.20
自引率
7.70%
发文量
505
审稿时长
46 days
期刊介绍: The Journal of the Mechanical Behavior of Biomedical Materials is concerned with the mechanical deformation, damage and failure under applied forces, of biological material (at the tissue, cellular and molecular levels) and of biomaterials, i.e. those materials which are designed to mimic or replace biological materials. The primary focus of the journal is the synthesis of materials science, biology, and medical and dental science. Reports of fundamental scientific investigations are welcome, as are articles concerned with the practical application of materials in medical devices. Both experimental and theoretical work is of interest; theoretical papers will normally include comparison of predictions with experimental data, though we recognize that this may not always be appropriate. The journal also publishes technical notes concerned with emerging experimental or theoretical techniques, letters to the editor and, by invitation, review articles and papers describing existing techniques for the benefit of an interdisciplinary readership.
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