Inactivation of internalized and surface contaminated enteric viruses in green onions

With increasing outbreaks of gastroenteritis associated with produce, it is important to assess interventions to reduce the risk of illness. UV, ozone and high pressure are non-thermal processing technologies that have potential to inactivate human pathogens on produce and allow the retention of fresh-like organoleptic properties. The objective of this study was to determine if UV, ozone, and high pressure are effective technologies compared to traditional chlorine spray on green onions to reduce enteric viral pathogens and to determine the effect of location of the virus (surface or internalized) on the efficacy of these processes. Mature green onion plants were inoculated with murine norovirus (MNV), hepatitis A virus (HAV) and human adenovirus type 41 (Ad41) either on the surface through spot inoculation or through inoculating contaminated hydroponic solution allowing for uptake of the virus into the internal tissues. Inoculated green onions were treated with UV (240 mJ s/cm²), ozone (6.25 ppm for 10 min), pressure (500 MPa, for 5 min at 20 °C), or sprayed with calcium hypochlorite (150 ppm, 4 °C). Viral inactivation was determined by comparing treated and untreated inoculated plants using cell culture infectivity assays. Processing treatments were observed to greatly affect viral inactivation. Viral inactivation for all three viruses was greatest after pressure treatment and the lowest inactivation was observed after chlorine and UV treatment. Both surface inoculated viruses and viruses internalized in green onions were inactivated to some extent by these post-harvest processing treatments. These results suggest that ozone and high pressure processes aimed to reduce the level of microbial contamination of produce have the ability to inactivate viruses if they become localized in the interior portions of produce.     

Depuration and Relaying: A Review on Potential Removal of Norovirus from Oysters

Pollution of coastal waters can result in contamination of bivalve shellfish with human enteric viruses, including norovirus (NoV), and oysters are commonly implicated in outbreaks. Depuration is a postharvest treatment involving placement of shellfish in tanks of clean seawater to reduce contaminant levels; this review focuses on the efficacy of depuration in reducing NoV in oysters. There have been many NoV outbreaks from depurated oysters containing around 10³ genome copies/g oyster tissue, far exceeding the median infectious dose (ID50). Half of the published NoV reduction experiments showed no decrease in NoV during depuration, and in the remaining studies it took between 9 and 45.5 d for a 1‐log reduction—significantly longer than commercial depuration time frames. Surrogate viruses are more rapidly depurated than NoV; the mean number of days to reduce NoV by 1 log is 19, and 7.5 d for surrogates. Thus, surrogates do not appear to be suitable for assessing virological safety of depurated oysters; data on reduction of NoV infectivity during depuration would assist evaluations on surrogate viruses and the impact of methods used. The longer persistence of NoV highlights its special relationship with oysters, which involves the binding of NoV to histo‐blood group‐like ligands in various tissues. Given the persistence of NoV and on‐going outbreaks, depuration as currently performed appears ineffective in guaranteeing virologically safe oysters. Conversely, relaying oysters for 4 wk is more successful, with low NoV concentrations and no illnesses associated with products. The ineffectiveness of depuration emphasizes the need for coastal water quality to be improved to ensure oysters are safe to eat.     

实时荧光RT-PCR检测冷冻草莓中诺如病毒

目的：建立冷冻草莓中的GI、GII型诺如病毒实时荧光RT-PCR检测方法,并应用于实际样品的检测。方法：对草莓样品进行前处理、病毒富集、病毒RNA的提取和纯化,然后采用实时荧光RT-PCR进行检测。结果：核酸提取方法能够有效地去除抑制因子,同时对104份送检样品进行检测,结果均为阴性。结论：所建立的核酸提取与实时荧光RT-PCR结合的检测体系适合于草莓样品中诺如病毒GI、GII型的检测。     

2011—2012年广东省市售牡蛎中诺如病毒污染调查分析

目的 调查2011-2012年广东省市售牡蛎中诺如病毒的污染状况,为采取有效措施减轻牡蛎中诺如病毒污染程度提供建议,达到预防和控制食用牡蛎引起诺如病毒胃肠炎疾病的目的.方法 2011年3月-2012年10月,在广东省部分沿海城市进行市售牡蛎的采样检测,对其诺如病毒污染状况进行连续两年监测,采用荧光RT-PCR检测诺如病毒阳性标本基因分型,并对不同城市、季节及场所牡蛎中诺如病毒的污染情况及基因分型情况进行比较.结果 牡蛎中诺如病毒总检出率为14.9％ (41/275);四个季节牡蛎中诺如病毒检出率依次为4.4％、15.7％、18.2％和36.7％;从基因分型分析,GⅠ型病毒株检出率为4.0％,GⅡ型病毒株检出率为6.2％,GⅠ和GⅡ型病毒株同时检出率为4.7％.结论 2011-2012年广东省市售牡蛎的诺如病毒污染情况在市场、餐饮场所以及不同地区间比较差异无统计学意义,其基因分型间比较差异无统计学意义,但呈现明显季节性特点,以冬季污染最严重.     

The influence of temperature,pH, and water immersion on the high hydrostatic pressure inactivation of GI.1 and GII.4 human noroviruses

Detection of human norovirus (HuNoV) usually relies on molecular biology techniques, such as qRT-PCR. Since histo-blood group antigens (HBGAs) are the functional receptors for HuNoV, HuNoV can bind to porcine gastric mucin (PGM), which contains HBGA-like antigens. In this study, PGM-conjugated magnetic beads were used to collect and quantify potentially infectious HuNoV strains GI.1 and GII.4 treated by high hydrostatic pressure (HHP). Both GI.1 and GII.4 strains used in this study showed increasing pressure sensitivity as judged by loss of PGM binding with decreasing temperature over a range of 1 to 35 °C. Both GI.1 and GII.4 were more resistant to pressure at pH 4 than at neutral pH. Because GI.1 was significantly more resistant to pressure than GII.4, it was used to evaluate HuNoV pressure inactivation in blueberries. GI.1 on dry blueberries was very resistant to pressure while immersion of blueberries in water during pressure treatments substantially enhanced the inactivation. For example, a 2 min-600 MPa treatment of dry blueberries at 1 and 21 °C resulted in < 1-log reductions while a 2.7-log reduction of GI.1 was achieved by a treatment at 500 MPa for 2 min at 1 °C when blueberries were immersed in water. In total, this novel study provides unique information for designing pressure processing parameters (pressure, temperature, and time) and product formulations (such as pH) to inactivate HuNoV in high-risk foods such as berries.     

Antiviral effects of cranberry juice and cranberry proanthocyanidins on foodborne viral surrogates – A time dependence study in vitro

Cranberry juice (CJ) and cranberry proanthocyanidins (PAC) are widely known for their antibacterial, antiviral, and pharmacological activities. The effect of CJ and cranberry PAC on the infectivity of foodborne viral surrogates, murine norovirus (MNV-1), feline calicivirus (FCV-F9), MS2 (ssRNA) bacteriophage, and ?X-174 (ssDNA) bacteriophage after 0 min to 1 h at room temperature was evaluated. Viruses at titers of ∼5 log₁₀PFU/ml were mixed with equal volumes of CJ at pH 2.6, CJ at pH 7.0, 0.30 mg/ml CJ PAC, 0.60 mg/ml PAC, or water and incubated for 0, 10, 20, 30, 40, 50 min, and 1 h at room temperature. Infectivity was determined using standard plaque assays. The viral reduction rates of the four tested viruses were found to vary considerably. Among the tested viruses, FCV-F9 titers were decreased the most by ∼5 log₁₀PFU/ml within 30 min. MS2 titers were decreased the least by only ∼1 log₁₀PFU/ml after 1 h with CJ at pH 2.6 and 0.30 mg/ml PAC, and ∼0.5 log₁₀PFU/ml with CJ at pH 7.0 and 0.15 mg/ml PAC. MNV-1 and ?-X174 showed comparable titer reductions which was between that of FCV-F9 and MS2. In most cases, viral reduction within the first 10 min of treatment accounted for ≥50% of the total reduction. Transmission electron microscopy on FCV-F9 treated with CJ and PAC revealed structural changes. This study shows potential of using natural bioactive compounds for controlling foodborne viral diseases. Further studies are necessary to elucidate the mechanism of action of CJ components and to understand the differences in viral titer reduction profiles.