Breast cancer has been recently revealed as the most deadly cancer to females, hitting an astounding 15-year reduction of life. Although numerous planning treatments have been launched, synergistic interactions of current anti-cancer drugs still stun the target. The Synergistic interactions not only improve breast cancer chemotherapy efficacy, but reduce drug resistance and side-effects as well. However, the shortages of less cell amount from primary tumors and massive drugs needed still remain challenging for high throughput evaluation. In this research, we present a cellular microarray ParaStamp (CMP) chip system, which combines of wax-well-arrayed chips and an automatic liquid dispensing machine, particularly for high throughput drug synergy screening. For the proof-of-conceptual demonstration, we conduct four existent chemotherapeutic drugs (e.g. cisplatin, 5-Fluorouracil, cyclophosphamide, and etoposide) and two breast cancer cell lines (e.g. MCF7 and MDA-MB-231 cells) into the system. A screening strategy based on the combination index (CI) equation is then utilized to identify the optimal drug combinations. In addition, the optimizations are further verified by zebrafish (ZF) tumor xenograft models. Results show that the optimal drug combination screened can cause the dose reduction down to approximately 14.3 folds compared with single drugs conducted. In contrast to standard 96-well plate assay, the study conductor demonstrates that the volume of each tested drug can be retained up to 500 folds. Moreover, a significant 21% inhibition of MCF7 breast tumors engrafted in ZF models is successfully presented by the identified drug combination. Remarkably, the CMP chip could predict the in vivo efficacy more accurately than 96-well plate assays. Taken together, our findings demonstrate the integration of the CMP chip platform and zebrafish tumor xenograft model could improve the outcome for breast cancer chemotherapy. It may further offer new opportunities to enhance personalized medicine and drug discovery.