Electrospinning is a highly effective technology for producing polymer nanofibers. This study utilizes this technology to produce nanofibrous frames to envelop drugs. The surface pores of the nanofibers are used to release the drugs that are contained in the fibers. Compared to traditional drug delivery systems, this method greatly increases the action time. This method also offers the advantages of low mass and high wound closure, effectively facilitating wound recovery. This study utilizes uniaxial and coaxial electrospinning technologies to produce nanofibers containing a number of different drugs, then continuously collects the nanofibers to form non-woven fiber membranes. This study then modifies the environment and manipulates the parameters to produce the most suitable spun fiber frame for drug release. This study utilizes PEO as a spun fiber frame and adds CS+neomycin internally. Various microscopes (OM, SEM, and TEM) are used to examine the external morphology of the spun fibers, including the surface porosity and internal structure. X-ray diffraction is also used to analyze the effect of crystal orientation on drug release variations. Humidity parameters are controlled while producing the fibers, increasing fiber yield rates and drug distribution variance. Finally, EDS is used as a basis for drug release testing. Release volume analysis is used to study variations in the internal to external release of drugs based on changes over a significant length of time. This study reveals that coaxial nanofiber drug release characteristics are significantly more powerful than those of uniaxial nanofibers. Additionally, when the crystal characteristics change, the release effects also change.