Lung cancer is the leading cause of cancer deaths in Taiwan. In the radiotherapeutic and chemotherapeutic modalities used to treat lung cancer, the great majority of patients will relapse with a tumor that is largely refractory to further treatment. Therefore, the development of methods for predicting resistance of cancer cells is important. In addition, previous research has found that there is a correlation between damage sensitivity and drug resistance of cancer cells, and a correlation between the DNA damage in the patients' blood cells and cancer cells of the tissue. The current investigation optimized the multiplex long quantitative polymerase chain reaction (QPCR) to measure the formation of ultraviolet (UV)-induced DNA lesions in specific genes such as the p53 tumor suppressor gene in the blood lymphocytes from chemotherapeutic patients and analyzed the correlation of damage formation with the therapeutic effectiveness. The average damage incidence was 0.20±0.17 in the 29 non-effective chemotherapeutic lung cancer patients, whereas the average damage incidence was 0.16±0.17 in the 17 effective chemotherapeutic patients. In addition, the proportion of patients with DNA damage was 83% (24/29) and 67% (10/15) for non-effective and effective groups, respectively. Although the preliminary data of multiplex long QPCR showed that the damage formation by UV in the p53 gene of lymphocytes from lung cancer patients with different chemo-effectiveness were not significantly different, there was a tendency of higher damage formation in the non-effective lung cancer patients than the effective patients. Therefore, the present study demonstrates that the measurement of DNA damage sensitivity by the multiplex long QPCR assay in lymphocytes may offer a valid estimate of the therapeutic effectiveness of cancer patients. This rationale, however, needs to be strengthened by further investigations in a larger cohort of patients.