Graduate Program of Animal Science, Universidade do Estado de Santa Catarina, Chapecó, Brazil.
Department of Animal Science, Universidade do Estado de Santa Catarina, Chapecó, Brazil.
Microb Pathog. 2020 Dec;149:104517. doi: 10.1016/j.micpath.2020.104517. Epub 2020 Sep 29.
Mycotoxins represent substantial challenges to the farming industry. These include toxins produced by Fusarium fungi, particularly trichothecenes (toxin T-2) and fumonisin (FB). In the present study, we determined the effects of addition on Saccharomyces cerevisiae lysate (SCL) added to feed contaminated with T-2 and FB in terms of health, productive efficiency, and egg laying quality. We used 60 Hy-line Brown laying hens, and divided them into five groups with four repetitions per group and three birds per repetition. There was one group with no contamination with toxin (NoC). The four other groups included combinations of mycotoxin (4 ppm T-2, and 20 ppm FB1): A contamination group was used as control (the C+ group), and another two contained 500 g/ton of SCL (Detoxa Plus®) (the C + D500 group) or 1000 g/ton of SCL (the C + D1000 group). Finally, one group received feed containing 500 g/ton of Detoxa Plus® and 1000 g/ton of Uniwall® MOS 25 (the C + D500 + U1000 group). The experimental period was 84 days, divided into three productive cycles of 28 days each. The NoC hens had greater egg production than the other groups. Hens that consumed feed with SCL had greater egg production than did the C+ group. The NoC hens produced eggs with greater weights than did the C hens; however, C + D1000 and C + D500 + U1000 birds produced greater egg weights than did the C+ group. The C+ group produced lower egg masses than did the NoC and C + D500 + U1000 groups. The feed intake (FI) was lower in hens that ingested mycotoxin. The use of SCL in feed minimized the negative effects of mycotoxin on feed conversion ratio (FI/dozen). Effects of treatment were detected for feed conversion ratio (kg/kg). The hens that consumed mycotoxin had lower shell resistance and thickness compared to those in the NoC group. The red color of egg yolk was greater in the control groups. There were fluctuations in levels of liver enzymes when birds consumed mycotoxin (sometimes reduced and sometimes increased); nevertheless, the cumulative effect increased the activity of alanine aminotransferase. The serum concentration of reactive oxygen species was greater in hens that ingested mycotoxin only on d 84 compared to the NoC group. Serum glutathione S-transferase activity was greater on d 56 in C + D500 and C + D1000 hens than in the others. We conclude that, in general, the consumption of mycotoxin impaired the performance and quality of the eggs of the hens; the addition of the S. cerevisiae lysate and the addition organic acids, yeast cell wall and mineral carrier minimized some of the negative effects caused by T-2 and FB1.
真菌毒素对农业产业构成了重大挑战。这些毒素包括镰刀菌产生的毒素,特别是单端孢霉烯族化合物(毒素 T-2)和伏马菌素(FB)。在本研究中,我们根据健康、生产效率和产蛋质量,确定了添加到被 T-2 和 FB 污染的饲料中的酿酒酵母裂解物(SCL)的效果。我们使用了 60 只海兰褐蛋鸡,将它们分为五组,每组四个重复,每个重复三只鸡。有一组没有接触毒素(NoC)。其他四组包括组合霉菌毒素(4 ppm T-2 和 20 ppm FB1):A 污染组作为对照(C+组),另外两组含有 500 g/吨的 SCL(Detoxa Plus®)(C+D500 组)或 1000 g/吨的 SCL(C+D1000 组)。最后,一组鸡食用含有 500 g/吨 Detoxa Plus®和 1000 g/吨 Uniwall® MOS 25 的饲料(C+D500+U1000 组)。实验期为 84 天,分为三个 28 天的生产周期。NoC 母鸡的产蛋量高于其他组。食用 SCL 的母鸡比 C+组的母鸡产蛋更多。NoC 母鸡产的蛋比 C 母鸡重;然而,C+D1000 和 C+D500+U1000 组的母鸡产蛋比 C+组重。C+组的产蛋量低于 NoC 和 C+D500+U1000 组。摄入霉菌毒素的母鸡饲料摄入量(FI)较低。SCL 在饲料中的使用将霉菌毒素对饲料转化率(FI/dozen)的负面影响降到最低。在饲料转化率(kg/kg)方面检测到了处理效果。摄入霉菌毒素的母鸡蛋壳强度和厚度均低于 NoC 组。对照组蛋黄颜色较深。当鸟类摄入霉菌毒素时,肝脏酶的水平会波动(有时减少,有时增加);然而,累积效应会增加丙氨酸氨基转移酶的活性。与 NoC 组相比,仅在第 84 天摄入霉菌毒素的母鸡血清中活性氧的浓度更高。C+D500 和 C+D1000 母鸡在第 56 天的血清谷胱甘肽 S-转移酶活性高于其他母鸡。我们得出结论,一般来说,摄入霉菌毒素会损害母鸡的产蛋性能和质量;添加酿酒酵母裂解物以及添加有机酸、酵母细胞壁和矿物质载体可最大限度地减少 T-2 和 FB1 造成的一些负面影响。
