The first part of this thesis is to select a kind of low-toxicity salt, potassium sulfate (K2SO4), as an ingredient to gelatin solution. With over-saturation of weight percentage of potassium sulfate in the gelatin solution the salting reaction occurs while cooling, and the fractal gelatin patterns appear gradually. The author tries many combinations of the K2SO4-gelatin solutions to find out the thickest fractal gelatin pattern of 9.24 μm thick by 20% gelatin and 7.5% K2SO4. The author also cultures living cells above the gelatin samples to investigate the toxicity of the K2SO4-gelatin film by counting the number of cells. The author moreover uses the PDMS molding method to transfer the fractal patterns from the gelatin motherboard to a PDMS flow chip to animate the artificial blood vessel herein. The second part of this thesis is to describe how to use the PDMS flow chip or artificial vessel with fractal patterns to perform the liquid filling experiment. Two kinds of dynamic filling liquids using polystyrene (PS) microbeads of 5 μm size and HepG2 cells are dosed into the PDMS flow chip by a syringe pump for 2 hours with a flow rate of 10 μL/min. The author records the attachment area change of HepG2 cells in the PDMS microchannel for every 10 min. The preliminary result of the dynamic cell filling shows that HepG2 in the fractal microchannel have the similar adhesion behavior as the case using single microchannel with 3 nm surface roughness.