Research Center for Functional Materials, National Institute for Materials Science (NIMS), 1-1 Namiki, Tsukuba, Ibaraki 305-0044, Japan.
Center for Green Research on Energy and Environmental Materials, National Institute for Materials Science (NIMS), 1-1 Namiki, Tsukuba, Ibaraki 305-0044, Japan.
Acta Biomater. 2021 Sep 15;132:103-113. doi: 10.1016/j.actbio.2021.03.028. Epub 2021 Mar 17.
Mechanics of the extracellular matrix (ECM) exhibit changes during many biological events. During disease progression, such as cancer, matrix stiffening or softening occurs due to crosslinking of the collagen matrix or matrix degradation through cell-secreted enzymes. Engineered hydrogels have emerged as a prime in vitro model to mimic such dynamic mechanics during disease progression. Although there have been a variety of engineered hydrogels, few can offer both stiffening and softening properties under the same working principle. In addition, to model individual disease progression, it is desirable to control the kinetics of mechanical changes. To this end, we describe a photoresponsive hydrogel that undergoes stiffness changes by the photo-induced phase transition. The hydrogel was composed of a copolymer of azobenzene acrylate monomer (AzoAA) and N,N-dimethyl acrylamide (DMA). By tuning the amount of azobenzene, the phase transition behavior of this polymer occurs solely by light irradiation, because of the photoisomerization of azobenzene. This phase behavior was confirmed at 37 C by turbidity measurements. In addition, the crosslinked poly(AzoAA-r-DMA) gel undergoes reversible swelling-deswelling upon photoisomerization by ultraviolet or visible light. Furthermore, the poly(AzoAA-r-DMA) sheet gels exhibited modulus changes at different isomerization states of azobenzene. When MCF-7 cells were cultured on the gels, stiffening at different timepoints induced varied responses in the gene expression levels of E-cadherin. Not only did this suggest an adaptive behavior of the cells against changes in mechanics during disease progression, this also demonstrated our material's potential towards in vitro disease modeling. STATEMENT OF SIGNIFICANCE: During disease progression such as cancer, cellular microenvironment called extracellular matrix (ECM) undergoes stiffness changes. Hydrogels, which are swollen network of crosslinked polymers, have been used to model such dynamic mechanical environment of the ECM. However, few could offer both stiffening and softening properties under the same working principle. Herein, we fabricated a novel photoresponsive hydrogel with switchable mechanics, activated by photo-induced structural change of the polymer chains within the hydrogel. When breast cancer cells were cultured on our dynamic hydrogels, gene expression and morphological observation suggested that cells react to changes in stiffness by a transient response, as opposed to a sustained one. The photoresponsive hydrogel offers possibility for use as a patient-specific model of diseases.
细胞外基质 (ECM) 的力学特性在许多生物事件中发生变化。在疾病进展过程中,如癌症,由于胶原基质的交联或细胞分泌的酶对基质的降解,基质会变硬或变软。工程水凝胶已成为模拟疾病进展过程中这种动态力学特性的主要体外模型。尽管已经有多种工程水凝胶,但很少有能在同一工作原理下同时提供变硬和变软特性的水凝胶。此外,为了模拟个体疾病的进展,控制力学变化的动力学是理想的。为此,我们描述了一种光响应水凝胶,它通过光诱导的相转变来改变其硬度。该水凝胶由偶氮苯丙烯酰胺单体 (AzoAA) 和 N,N-二甲基丙烯酰胺 (DMA) 的共聚物组成。通过调节偶氮苯的含量,由于偶氮苯的光异构化,这种聚合物的相转变行为仅通过光照射即可发生。在 37°C 时,通过浊度测量证实了这种相行为。此外,交联的聚 (AzoAA-r-DMA) 凝胶在紫外光或可见光照射下通过光致异构化发生可逆的溶胀-去溶胀。此外,聚 (AzoAA-r-DMA) 片状凝胶在不同的偶氮苯异构化状态下表现出模量变化。当 MCF-7 细胞在凝胶上培养时,不同时间点的变硬会引起 E-钙粘蛋白基因表达水平的不同反应。这不仅表明细胞对疾病进展过程中力学变化的适应行为,还表明我们的材料在体外疾病建模方面的潜力。
在疾病进展过程中,如癌症,细胞外基质 (ECM) 等细胞微环境会发生硬度变化。水凝胶是交联聚合物的溶胀网络,已被用于模拟 ECM 的这种动态力学环境。然而,很少有能在同一工作原理下同时提供变硬和变软特性的水凝胶。在此,我们制造了一种新型的光响应水凝胶,其力学性能可切换,由水凝胶中聚合物链的光诱导结构变化激活。当乳腺癌细胞在我们的动态水凝胶上培养时,基因表达和形态观察表明,细胞通过瞬态反应而不是持续反应来应对硬度变化。光响应水凝胶为用作特定于患者的疾病模型提供了可能性。
