Background Data: Since the marked advance of Human Genome Project, analysis of genetic polymorphism has been popularly used to explain the individual difference in susceptibility to various diseases, such as infection of complicated diseases, sensitivity of medication and environment. However, analysis of gene polymorphisms is sometimes not feasible due to limited DNA available. Objective: A simple and easy method to extract DNA from minimal amount of saliva and blood for PCR amplification of gene is necessary. Some studies indicated the relation between COX-2 expression and cancer. Thus, we try to design an analytical technique to compare the COX-2 promoter region polymorphism in clinical healthy and oral cancer patients. Materials and Methods: This study divided three parts. First, we collected saliva and blood with paper points after full mouth scaling in NTUH. The tips of paper points were used to extract DNA using QIAamp DNA Micro kit. PCR was used to amplified IL-1βgene from isolated DNA, subjected to agarose gel electrophoresis, stained with ethidium bromide. Second, we followed the same method to collect samples and the samples were 201 patients in NTUH, including 187 healthy control subjects and 14 patients who had oral cancer or medical history of oral caner. DNA was isolated and used to amplified the promoter region of COX-2 gene by more sensitive method “nested PCR”. Finally, we utilized the latest analytical technique “high-resolution melting analysis” and nucleotide sequencing to screen some doubtful samples with mutation of COX-2 promoter region. Results: We successfully extracted DNA from all blood and saliva samples by QIAamp DNA isolation kits. After PCR amplification of IL-1β genes (249 b.p), the specific DNA bands were clearly identified on agarose gels after ethidium bromide staining. Moreover, by using Nested PCR, the successful rates to amplify long genetic section of COX-2 promoter region were above 95%. We further utilized high-resolution melting analysis to detect two patterns of the melting curves. According to these two types of curves, we could screen doubtful samples and make further confirmation of gene polymorphism sites by DNA nucleotide sequencing. Conclusion: The results indicate that we can use paper point to substitute the invasive methods for collecting blood and saliva for DNA analysis in the future. The advantage is easy to operate and obtain, not to occupy the space, and the economical cost. Futhermore, people can reduce fear and receive examination by this method. We can amplify long genetic section above 95% by nested PCR which can greatly increase efficiency to amplify tiny amount of DNA. Utilizing high-resolution melting analysis, we can not spend time to sequence all samples, and can not spend money to do real-time PCR. SNP genotyping will be simple, rapid, and inexpensive, requiring only one pair of primers, a little LC Green dye, one PCR machine, and one HR-1 machine. High-resolution melting analysis will be the best methods of SNP genotyping in the future.