Department of Food Science and Technology, University of Georgia, Athens, GA 30602, USA.
Department of Food Science and Technology, University of Georgia, Athens, GA 30602, USA.
Food Res Int. 2022 Apr;154:111016. doi: 10.1016/j.foodres.2022.111016. Epub 2022 Feb 17.
Many studies have demonstrated that UV radiation can degrade aflatoxins (AF) in contaminated foods. However, the effective wavelength ranges for AF decomposition and their impacts on the quality of foods have not been elucidated. This study investigated the AF reduction and oil quality change in peanuts subjected to three types of 17 W low-pressure (LP) UV lamps covering UV-A (Max. emission: 365 nm), UV-B (Max. emission: 310 nm), and UV-C (Max. emission: 254 nm) ranges and a 2000 W medium-pressure UV lamp covering from UV-A to UV-C. We used peeled-kernels for this study since the peanut skin represented an ability to protect AF from being degraded by UV. LP UV-A lamp treatment has shown the highest AF reduction in artificially spiked peeled-kernels and no detectable oil deterioration. With the same delivered UV dosage as LP lamp, MP lamp has shown the same level of AF reduction as LP UV-A lamp did, indicating such treatment was energy inefficient. Treating Aspergillus nomius inobulated peeled-kernels by two LP UV-A lamps (2.76 mW/cm) for 1.0 h reduced 40% of AF if the kernels were milled into 1 mm-diameter particle, implying that exposing the interior part of kernels to UV radiation is necessary for an AF decontamination process. In the oil deterioration test, we found that UV-C strongly induced the oil oxidation of peanuts. Accordingly, we concluded that UV-A is the effective wavelength range to degrade AF as well as maintain the oil quality in foods allowing UV radiation to well penetrate the sample, such as liquid foods with low turbidity or solid foods in the particle form. These results also justify the use of solar radiation as an AF decontamination method, rendering this method to be employed in in areas that lack infrastructure.
许多研究表明,紫外线辐射可以降解污染食品中的黄曲霉毒素(AF)。然而,AF 分解的有效波长范围及其对食品质量的影响尚未阐明。本研究调查了三种 17 W 低压(LP)UV 灯(包括 UV-A(最大发射:365nm)、UV-B(最大发射:310nm)和 UV-C(最大发射:254nm))和一种 2000 W 中压 UV 灯对去皮花生中 AF 减少和油质变化的影响,该中压 UV 灯涵盖了从 UV-A 到 UV-C 的范围。由于花生皮具有保护 AF 免受 UV 降解的能力,因此我们在这项研究中使用去皮仁。LP UV-A 灯处理显示出在人工污染的去皮仁中具有最高的 AF 减少率,并且没有检测到油质恶化。在相同的输送 UV 剂量下,MP 灯显示出与 LP UV-A 灯相同的 AF 减少水平,表明这种处理方式效率低下。用两台 LP UV-A 灯(2.76 mW/cm)对感染了 Aspergillus nomius 的去皮仁进行 1.0 h 的照射,如果将仁磨成 1 毫米直径的颗粒,则可以减少 40%的 AF,这表明将仁的内部暴露于 UV 辐射是 AF 脱污染过程所必需的。在油脂劣化试验中,我们发现 UV-C 强烈诱导了花生油脂的氧化。因此,我们得出结论,UV-A 是降解 AF 并保持食品油质的有效波长范围,允许 UV 辐射很好地穿透样品,例如低浊度的液体食品或颗粒状的固体食品。这些结果也证明了利用太阳辐射作为一种 AF 脱污染方法的合理性,使其在缺乏基础设施的地区得到应用。
