The growth of stem cells is influenced by both chemical and physical features of the microenvironment, which is also known as “stem cell niche”. These features are dominated by the extra cellular matrix (ECM) and cell-cell interaction. The stem cell niche facilitates the survival, self-renewing and differentiation capabilities of stem cells. Biomaterials with specific structures such as grooves, ridges, pits, or pillars can mimic the topographic landscape of the niche. Cells can “sense” the mechanical properties and surface patterns, ranging from micro- to nano-scale, of the substrate; hence, different sizes of nano-grooves on gelatin surface were designed. The design of grooves or ridges can be systematically modified and those structures can reflect the fibrillar organization of ECM. Most important of all, the orientation of cells along these structures could be observed easily. In previous studies, polystyrene (PS) was often used because it is easy to fabricate topographic structures. However, PS is not biocompatible and biodegradable. For better biocompatibility, gelatin was chose as the material and fabricated into an ideal nano-grooves films by micro-molding method. On the other hand, gelatin can be crosslinked by using several crosslinking agents, which leads to a higher mechanical strength and better flexibility of the material. It was known that stem cells can be served as a source of neurons in transplantation therapies. The differentiation of neurons is associated with directionality of stem cell. To investigate the effect of topographic cues on stem cells, groove pattern arrays, which ridge to groove ratio is 1:1, with two sizes of widths and depths in nano-scale (W/D: 400/100, 400/400, 800/100 and 800/400 nm), were constructed onto gelatin surfaces. Human adipose-derived stem cells (hASCs) were seeded onto the patterned gelatin and cell proliferation and differentiation were observed.