The biosynthesis of dTDP is unique in conversion of dTMP by thymidylate kinase (TMPK), though other dNDPs are directly produced from their corresponding NDPs by ribonucleotide reductase (RNR). DNA repair requires the coordination between RNR and TMPK to supply dNTPs. Blocking the function of TMPK would cause incorporation of dUTP during DNA repair in tumor cell. Furthermore, inhibition of TMPK is found to enhance tumor lethality on treatment with anticancer drugs. The combination treatment with YMU1 and doxorubicin is effective in chemotherapy against tumor cells. In addition to YMU1, the high-throughput screening in the Genomics Research Center, Academic Sinica revealed several small molecules with high human TMPK inhibition, including TDZD-8. By computer modeling, the designed conjugated molecule containing the moieties of YMU1 and TDZD-8 shows that these two heterocyclic cores can bind to TMPK and ATP active sites, respectively. We thus proceeded with the synthesis and bioassay of the YMU1―TDZD conjugated compound for bioactivity evaluation. First, I synthesized TDZD derivatives from condensation of isocyanate and isothiocyanate and found that they all showed good hTMPK inhibition. However, attempted amide bond coupling of TDZD derivatives and YMU1 derivatives failed because the TDZD ring will decompose to urea under basic conditions. Therefore, another synthetic strategy was designed to construct amide bond first, followed by the formation of TDZD ring to prevent TDZD ring from decomposition into urea. Nevertheless, formation of TDZD ring in the presence of sulfuryl chloride also affected the YMU1 moiety. Even though YMU1–TDZD conjugated compound cannot be synthesized by these two pathways, YMU1–urea conjugated derivatives did show higher inhibition than YMU1.