Part 1. Cisplatin (CIS) is a widely used chemotherapy drug for human cancers, including lung cancer. Despite its significant antitumor activity, the side effects limit its use. Quercetin (Q), a flavonoid present abundantly in plants, has been shown to may increase the antitumor effects of some anti-cancer drugs and to decrease their harmful effects. In this study, we first used a xenograft model to investigate the effects of quercetin on the antitumor and side effects of CIS. Male nude mice were injected with A549 cells (human lung cancer cell line) into the flank. After 4 weeks, the tumor-bearing mice were randomly treated with cisplatin (2 or 5 mg/kg, once a week; CIS2 and CIS5, respectively) alone, or CIS2 in combination with quercetin for 12 weeks. Quercetin was given by a quercetin containing diet (0.1% or 1% quercetin diet; LQ and HQ, respectively) or by intraperitoneal injection (10 mg/kg, 3 times a week; IQ). The results showed that CIS2+HQ and CIS2+IQ rather than CIS2 alone or CIS2+LQ significantly inhibited tumor growth. The effects of CIS2+IQ and CIS2+HQ were similar to that of CIS5. We found that CIS2 in combination a Q containing diet or IQ tended to decrease plasma TBARs levels as well as proinflammatory cytokines in plasma and in tumors, especially IQ. Quercetin containing diets and IQ also significantly increased the total quercetin concentration in tumor tissues in an order HQ>LQ and IQ. In addition, quercetin containing diets and IQ tended to increase gastrocnemius muscle, epididymal fat weight and bone marrow cell number compared to CIS2. Most the efficiencies of IQ were the best. CIS2 decreased the neutrophil count and increased the lymphocyte count. Quercetin tended to suppress these effects of cisplatin. In addition, CIS in combination with quercetin treatment significantly increase the platelet count, while CIS alone had no effect. However, CIS significantly reduced the red blood cell count and quercetin did not recover such an effect of CIS. The results of the present study demonstrated that quercetin not only increase the antitumor effect of cisplatin, but also reduce some of the side effects of cisplatin in vivo. Part 2. We found that the enhancing effect of IQ on the antitumor effect of CIS was better than that of quercetin from diet. We then compared the effect of quercetin and its metabolites, quercetin-3-glucuronide (G), at 2 μM and 5 μM on the anti-growth effect of CIS (1 μM) in A549 cells and explored the possible mechanisms. The results showed that CIS+Q and CIS+G enhanced CIS-induced cells growth arrest in A549 cells in a dose- and time-dependent manner. The combined inhibition efficiency of CIS+Q on cell growth was greater than that of the CIS+G at the same dose. Furthermore, we found that CIS induced cell cycle arrest in G2/M phase, and quercetin-3-glucuronide rather than quercetin significantly increased such an effect of CIS. However, CIS+Q significantly increased the cells in sub-G1 phase, indicating CIS+Q inducing apoptosis. CIS+Q also significantly increase caspase-3 activity, while cisplatin or CIS+G had no significant effect. We determined the expression of p21 and p53, which are associated with cell cycle arrest and apoptosis, in treated cells. The result showed that CIS in combination with Q quercetin or quercetin-3-glucuronide significantly increased p21 and p53 protein expression earlier than CIS alone. The effect of CIS+Q was better than that of CIS+G. In conclusion, quercetin has a better efficiency than quercetin-3-glucuronide to enhance the suppressed effect of CIS on the growth of A549 cells, which is in agreement with our in vivo findings. The results also suggest that quercetin and quercetin-3-glucuronide exert their effect may through increasing the expression of p21 and p53, which in turn inducing cell cycle arrest and apoptosis.