Abstract
Microscopic surface architectures that can be easily manufactured have been in demand as mechano-structural cues for tissue engineering. Microscopic surface reliefs synthesized by wrinkling were expected as cell culture scaffolds for cell proliferation, control of cellular alignment and differentiation, and spheroid generation. We previously developed bio-based wrinkled films prepared via lignification-mimetic reactions and drying. Although these films are expected as a candidate for cell culture scaffolds, stability and morphology of the wrinkled surfaces in aqueous buffer solutions were not explored. Here, we investigate the surface morphologies of the wrinkled films in phosphate-buffered saline, and their application to 3T3 cell culture. The wrinkled film prepared with the immersion treatment at 40 °C maintained its wrinkled structure in phosphate-buffered saline even after five days, although the wrinkles were broadened by hydration of the skin layer. Interestingly, higher cell numbers were observed in the 3T3 cell culture using the wrinkled film than using flat film with the same surface composition. In addition, the high biocompatibility of the wrinkled film was confirmed by in vivo experiments. These results strongly encourage application of the wrinkled film as a mechano-structural cue. Studies of the advanced applications for the wrinkled films are now in progress.
Highlights
Tissue engineering has attracted attention as a therapeutic method for replacing damaged tissues and organs [1,2]
In the application for cell culture scaffolds, wrinkled surfaces with unique topographies have been used for cell proliferation [12], control of cellular alignment and differentiation [13,14,16], and spheroid generation [15,17]
We investigate a detailed characterization of the wrinkled surfaces in phosphate-buffered saline (PBS) by atomic force microscopy (AFM) analysis, and the 3T3 cell culture on the wrinkled surfaces, in order to confirm the potential applicability of these synthesized surfaces as mechano-structural cues
Summary
Tissue engineering has attracted attention as a therapeutic method for replacing damaged tissues and organs [1,2]. Development of scaffold materials that can modulate the proliferation, self-renewal, and differentiation of multipotent stem cells into different lineages is a key aspect of tissue engineering [3]. Extensive research has revealed that mechano-structural cues, such as elasticity and topography differentially modulate cell fate in a hierarchical response [4]. Technologies for easy fabrication of microscopic surface architecture would contribute to progress in tissue engineering. Surface wrinkling is a physical process that creates unique topographies in nature [5,6]. In the application for cell culture scaffolds, wrinkled surfaces with unique topographies have been used for cell proliferation [12], control of cellular alignment and differentiation [13,14,16], and spheroid generation [15,17]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
