Cavendish Laboratory, University of Cambridge, Cambridge, United Kingdom.
Department of Engineering, University of Cambridge, Cambridge, United Kingdom.
PLoS One. 2014 Apr 11;9(4):e93590. doi: 10.1371/journal.pone.0093590. eCollection 2014.
Cellular behavior is strongly influenced by the architecture and pattern of its interfacing extracellular matrix (ECM). For an artificial culture system which could eventually benefit the translation of scientific findings into therapeutic development, the system should capture the key characteristics of a physiological microenvironment. At the same time, it should also enable standardized, high throughput data acquisition. Since an ECM is composed of different fibrous proteins, studying cellular interaction with individual fibrils will be of physiological relevance. In this study, we employ near-field electrospinning to create ordered patterns of collagenous fibrils of gelatin, based on an acetic acid and ethyl acetate aqueous co-solvent system. Tunable conformations of micro-fibrils were directly deposited onto soft polymeric substrates in a single step. We observe that global topographical features of straight lines, beads-on-strings, and curls are dictated by solution conductivity; whereas the finer details such as the fiber cross-sectional profile are tuned by solution viscosity. Using these fibril constructs as cellular assays, we study EA.hy926 endothelial cells' response to ROCK inhibition, because of ROCK's key role in the regulation of cell shape. The fibril array was shown to modulate the cellular morphology towards a pre-capillary cord-like phenotype, which was otherwise not observed on a flat 2-D substrate. Further facilitated by quantitative analysis of morphological parameters, the fibril platform also provides better dissection in the cells' response to a H1152 ROCK inhibitor. In conclusion, the near-field electrospun fibril constructs provide a more physiologically-relevant platform compared to a featureless 2-D surface, and simultaneously permit statistical single-cell image cytometry using conventional microscopy systems. The patterning approach described here is also expected to form the basics for depositing other protein fibrils, seen among potential applications as culture platforms for drug screening.
细胞行为受到其与细胞外基质(ECM)界面的结构和模式的强烈影响。对于一个最终能够将科学发现转化为治疗开发的人工培养系统,该系统应具有捕获生理微环境的关键特征。同时,它还应能够实现标准化、高通量的数据采集。由于细胞外基质由不同的纤维蛋白组成,因此研究细胞与单个原纤维的相互作用将具有生理相关性。在这项研究中,我们采用近场电纺技术,基于乙酸和乙酯的混合水溶液溶剂系统,制造出明胶胶原纤维的有序图案。微纤维的可调构象可以一步直接沉积在柔软的聚合物基底上。我们观察到,直线、串珠和卷曲等整体形貌特征取决于溶液的电导率;而纤维的横截面轮廓等更精细的细节则由溶液的粘度来调节。我们使用这些纤维结构作为细胞分析物,研究 EA.hy926 内皮细胞对 ROCK 抑制剂的反应,因为 ROCK 在调节细胞形态方面起着关键作用。纤维阵列被证明可以将细胞形态调节为类似前毛细血管的索状表型,而在平坦的 2D 基质上则不会观察到这种表型。通过对形态参数的定量分析进一步促进,纤维平台还可以更好地解析细胞对 H1152 ROCK 抑制剂的反应。总之,与无特征的 2D 表面相比,近场电纺纤维结构提供了更接近生理的平台,同时允许使用传统显微镜系统进行统计的单细胞图像细胞计量学分析。这里描述的图案形成方法也有望成为沉积其他纤维蛋白的基础,在药物筛选等潜在应用中作为培养平台。