Le Ngoc Nhi T, Zorn Stefan, Schmitt Samantha K, Gopalan Padma, Murphy William L
Materials Science Program, University of Wisconsin-Madison, Madison, WI, USA.
Department of Biomedical Engineering, University of Wisconsin-Madison, Madison, WI, USA.
Acta Biomater. 2016 Apr 1;34:93-103. doi: 10.1016/j.actbio.2015.09.019. Epub 2015 Sep 16.
Here, we have developed a novel method for forming hydrogel arrays using surfaces patterned with differential wettability. Our method for benchtop array formation is suitable for enhanced-throughput, combinatorial screening of biochemical and biophysical cues from chemically defined cell culture substrates. We demonstrated the ability to generate these arrays without the need for liquid handling systems and screened the combinatorial effects of substrate stiffness and immobilized cell adhesion peptide concentration on human mesenchymal stem cell (hMSC) behavior during short-term 2-dimensional cell culture. Regardless of substrate stiffness, hMSC initial cell attachment, spreading, and proliferation were linearly correlated with immobilized CRGDS peptide concentration. Increasing substrate stiffness also resulted in increased hMSC initial cell attachment, spreading, and proliferation; however, examination of the combinatorial effects of CRGDS peptide concentration and substrate stiffness revealed potential interplay between these distinct substrate signals. Maximal hMSC proliferation seen on substrates with either high stiffness or high CRGDS peptide concentration suggests that some baseline level of cytoskeletal tension was required for hMSC proliferation on hydrogel substrates and that multiple substrate signals could be engineered to work in synergy to promote mechanosensing and regulate cell behavior.
Our novel array formation method using surfaces patterned with differential wettability offers the advantages of benchtop array formation for 2-dimensional cell cultures and enhanced-throughput screening without the need for liquid handling systems. Hydrogel arrays formed via our method are suitable for screening the influence of chemical (e.g. cell adhesive ligands) and physical (stiffness, size, shape, and thickness) substrate properties on stem cell behavior. The arrays are also fully compatible with commercially available micro-array add-on systems, which allows for simultaneous control of the insoluble and soluble cell culture environment. This study used hydrogel arrays to demonstrate that synergy between cell adhesion and mechanosensing can be used to regulate hMSC behavior.
在此,我们开发了一种利用具有不同润湿性的图案化表面形成水凝胶阵列的新方法。我们用于台式阵列形成的方法适用于从化学定义的细胞培养底物中进行高通量、组合式生化和生物物理线索筛选。我们展示了无需液体处理系统即可生成这些阵列的能力,并在短期二维细胞培养过程中筛选了底物硬度和固定化细胞黏附肽浓度对人间充质干细胞(hMSC)行为的组合效应。无论底物硬度如何,hMSC的初始细胞附着、铺展和增殖均与固定化CRGDS肽浓度呈线性相关。增加底物硬度也会导致hMSC初始细胞附着、铺展和增殖增加;然而,对CRGDS肽浓度和底物硬度的组合效应进行研究后发现,这些不同的底物信号之间存在潜在的相互作用。在高硬度或高CRGDS肽浓度的底物上观察到的hMSC最大增殖表明,hMSC在水凝胶底物上增殖需要一定基线水平的细胞骨架张力,并且可以设计多种底物信号协同作用以促进机械传感并调节细胞行为。
我们利用具有不同润湿性的图案化表面的新型阵列形成方法具有用于二维细胞培养的台式阵列形成以及无需液体处理系统即可进行高通量筛选的优点。通过我们的方法形成的水凝胶阵列适用于筛选化学(如细胞黏附配体)和物理(硬度、大小、形状和厚度)底物特性对干细胞行为的影响。这些阵列还与市售的微阵列附加系统完全兼容,这允许同时控制不溶性和可溶性细胞培养环境。本研究使用水凝胶阵列证明细胞黏附和机械传感之间的协同作用可用于调节hMSC行为。