Caffeic acid is a derivative of cinnamic acid, which has good antibacterial properties, but its physicochemical properties need to be improved, including solubility, dissolution rate, stability, and so on. To improve the physicochemical properties and antibacterial activity of caffeic acid, three methods were used in this study to prepare the inclusion complex (IC) of caffeic acid with β-cyclodextrin. Later, some techniques like XRD, DSC, and FT-IR were applied to confirm that the IC could be successfully prepared by solvent evaporation method. Besides, the formation of inclusion complex could effectively improve the solubility and dissolution rate of caffeic acid in pH=7.4 phosphate buffered saline: the solubility increased to 1.5 times and the dissolution rate up to 3 times. In order to apply the antibacterial drug caffeic acid to wound dressings, this study used an electrospun fiber membrane containing natural polymer chitosan with good biocompatibility and synthetic polymer poly(ethylene oxide) with good mechanical properties as the carrier of caffeic acid. Under the same process parameters and environmental conditions, the effects of different concentrations of caffeic acid in the electrospun fiber membrane on the electrospinning process and the properties of the membrane were tested. The experimental results showed that as the concentration of caffeic acid in the fiber membrane increased, the viscosity of the electrospinning solution would drop significantly, making the electrospinning process more difficult. The droplet of the electrospinning solution was obvious and the percentage yield decreased from nearly 90% to less than 30%. Meanwhile, the diameter of the fiber became smaller, the mechanical strength became worse, and the membrane possessed more hydrophobic. Although the high concentration of caffeic acid contributed to the better antibacterial activity of the fiber membrane, where the bacterial survival rate was reduced to almost 0%. However, its low percentage yield made it uneconomical. Therefore, it was later decided to choose chitosan and caffeic acid at a weight ratio of 1:0.001 as the composition ratio of fibers containing caffeic acid-β-cyclodextrin inclusion complex. In the final part of this study, caffeic acid-β-cyclodextrin inclusion complex, chitosan, and poly(ethylene oxide) were co-prepared into an electrospun membrane for the purpose of enhancing the physicochemical properties of caffeic acid. Nonetheless, the acidic electrospinning solution would lead to the hydrolysis of β-cyclodextrin into sugars like oligosaccharides during the preparation process of the electrospinning solution, which would decrease the solvent evaporation rate of the electrospinning solution, resulting in an increase of some defects like beaded structures in the fibers. At the same time, the yield of the fiber was reduced and the mechanical strength turned out to be poor. As for the antibacterial activity, since β-cyclodextrin underwent hydrolysis into sugars required by bacteria, it would actually foster the proliferation of bacteria. In summary, although the inclusion of β-cyclodextrin can effectively improve the solubility and dissolution rate of caffeic acid, it should be able to enhance the antibacterial activity of caffeic acid. However, when the inclusion complex was used in the electrospinning process, the acidic solution would hydrolyze the β-cyclodextrin into sugars, which in turn promoted the reproduction of bacteria. Therefore, if electrospun membranes containing caffeic acid-β-cyclodextrin inclusion complex are to be prepared in the future, neutral solvents can be considered for the preparation of electrospinning solutions. In this way, it may be possible to electrospin the inclusion complex together with the polymer into membrane, and effectively improve the antibacterial effect of the drug, so as to be developed into a wound dressing material with clinical application value.