Supernovae (SNe) are the spectacularly violent deaths of evolved young massive stars, which expel a shock wave into the intergalactic medium that in turn can spark star formation and disperse heavy elements into the galaxy. While a SN event can be classified by its spectral signature definitively, determining the nature of a SN progenitor depends upon chance photometry taken prior to the event. We circumvent this challenge by turning to the study of SN host environments and their surrounding interstellar medium within the unique and rare population of galaxies that have hosted three or more SN events within the last century. This subpopulation offers the opportunity to study the locations and environmental properties of stellar populations prone to supernovae production. Using moderate-resolution slit spectra spanning 3500-7000 Angstroms taken with the Apache Point Observatory 3.5m telescope DIS spectrograph, our goal is to map the metallicity, ionization parameter, and star formation rates using emission line diagnostic ratios for all of the SN host sites across each SN-rich galaxy. Dubbed the “Fireworks Galaxy” at a distance of 6.9 ± 2.4 Mpc, NGC 6946 has uniquely produced nine core-collapse supernovae (CCSNe) within the last century, which specifically occur when massive stars develop an iron core under gravitational collapse. We present the spatially-resolved metallicity and star formation rates (SFRs) of NGC 6946, tracing nine spectrophotometric slits centered on each CCSN host site across the galaxy. Future work includes stellar population synthesis modelling to determine the host galaxies’ stellar populations, ages, and SFR histories for NGC 6946 and, eventually, the other nine SN-rich host galaxies in our sample.