418 Background: Accurate and fast screening of mutations is essential for designing individualized therapy necessary and critical for efficient disease management and better patient outcome in mCRC. Detection of hotspots by gold standard direct sequencing (DS) is time consuming and cost ineffective. Pyrosequencing (PS) technique is rapid and precisely committed towards SNP detection. Recent introduction of high throughput multiplex PCR based extension on microarray (Sequenom, SEQ) offers a robust platform capable of detecting multiple SNPs simultaneously in a rapid and cost effective manner. The current study analyzes the concordance and efficacy of the cutting edge SEQ technique to the well established DS and PS methods. Methods: DNA isolated from 122 specimens from 76 mCRC patients were sequenced by all three methods. DS and PS were performed on 4 genes at 10 hotspots. SEQ multiplexing was performed on 31 hotspots in 19 genes by 4 multiplex reactions. Results: We were able to make "calls" for all samples by DS and PS. With the multiplex system, the “calls” rate was 97.8% of successful reactions. Using PS data as our standard in the assay we calculated the percent concordance of DS and SEQ. Futhermore SEQ offered a more accurate identification of the substituted nucleotide in Kras codon 12 as compared to PS. Conclusions: The multiplexing of PCR reactions offers an excellent advantage of high throughput with strong feasibility of analyzing several samples for multiple SNPs simultaneously. The concordance rate of > 90% when compared to PS along with the ability to analyze multiple samples/ hotspots plexed together in a time effective rapid mode provided a trifold advantage of the sequenom technology. It is therefore the next generation technology for rapid genetic evaluation of cancer patients. [Table: see text]
High-Throughput Multiplex Sequencing of miRNA
