Detection of enteric virus contamination of shellfish is limited by current methodology, which is time-consuming, tedious, and lacking in sensitivity due to reliance on cell culture infectivity. Alternative detection methods based on nucleic acid amplification have been hampered by high sample volumes and the presence of enzymatic inhibitors. The goal of this study was to develop methods to purify and concentrate intact virions from oyster extracts to a volume and quality compatible with viral genomic nucleic acid amplification by reverse transcriptase-polymerase chain reaction (RT-PCR). Fifty-gram oyster samples were homogenized and processed by standard adsorption-elution precipitation methodology and then seeded with 105 PFU of poliovirus 1 (PV1) or hepatitis A virus (HAV). Seeded viruses were concentrated by fluorocarbon extraction, polyethylene glycol (PEG) precipitation, chloroform extraction, and cetyltrimethyl ammonium bromide (CTAB) precipitation to a volume of 100 μl with removal of RT-PCR inhibitors. Virus recovery after elution of PEG precipitates was 50% for PVI and IS to 20% for HAV as evaluted by cell culture infectivity. The CTAB precipitation step yielded a concentrated sample which was directly compatible with RT-PCR reactions and capable of detecting about 100 placque=forming units (PFU) of PVl or HAV. When 50-g oyster extracts were seeded and processed by the entire concentration and purification scheme, direct RT-PCR detection of viral genomic RNA was possible at initial inoculum levels of 104 PFU of HAV and 103 PFU of PV1, with recoveries of 1 to 5% of seeded viruses.
