Woo Seungmin, Kim Sooah, Ye Suji, Kim Soo Rin, Seol Jeongman, Dooyum Uyeh Daniel, Kim Junhee, Hong Dong Hyuck, Kim Jong Nam, Ha Yushin
Department of Bio Industrial Machinery Engineering, Kyungpook National University, Daegu 41566, Korea.
Department of Environment Science & Biotechnology, Jeonju University, Jeonju 55069, Korea.
J Anim Sci Technol. 2020 Mar;62(2):227-238. doi: 10.5187/jast.2020.62.2.227. Epub 2020 Mar 31.
Use of raw feedstuffs for livestock is limited by low digestibility. Recently, fermentation of feedstuffs has been highlighted as a new way to improve nutrient absorption through the production of organic acids using inoculated microorganisms, which can also play a probiotic role. However, standard procedures for feedstuff fermentation have not been clearly defined because the process is influenced by climatic variation, and an analytical standard for fermented feedstuffs is lacking. This study aimed to evaluate the microbiological and biochemical changes of feedstuffs during fermentation at temperatures corresponding to different seasons (10°C, 20°C, 30°C, and 40°C). We also investigated the effects of yeast, lactic acid bacteria (LAB), and spp. on fermentation and determined the results of their interactions during fermentation. The viable cells were observed within 8 days in single-strain fermentation. However, when feedstuffs were inoculated with a culture of mixed strains, LAB were predominant at low temperatures (10°C and 20°C), while spp. was predominant at high temperatures (30°C and 40°C). A significant drop in pH from 6.5 to 4.3 was observed when LAB was the dominant strain in the culture, which correlated with the concentrations of lactic acid. Slight ethanol production was detected above 20°C regardless of the incubation temperature, suggesting active metabolism of yeast, despite this organism making up a marginal portion of the microbes in the mixed culture. These results suggested that fermentation temperature significantly affects microbiological profiles and biochemical parameters, such as pH and the lactic acid concentration, of fermented feedstuffs. Our data provide valuable information for the determination of industrial standards for fermented feedstuffs.
用于牲畜的原料饲料由于消化率低而受到限制。最近,饲料发酵作为一种新方法受到关注,即通过接种微生物产生有机酸来提高养分吸收,这些微生物还可发挥益生菌的作用。然而,由于饲料发酵过程受气候变化影响,尚未明确界定饲料发酵的标准程序,并且缺乏发酵饲料的分析标准。本研究旨在评估饲料在对应不同季节的温度(10°C、20°C、30°C和40°C)下发酵过程中的微生物学和生化变化。我们还研究了酵母、乳酸菌(LAB)和 spp. 对发酵的影响,并确定了它们在发酵过程中的相互作用结果。在单菌株发酵中,8天内可观察到活细胞。然而,当饲料接种混合菌株培养物时,乳酸菌在低温(10°C和20°C)下占主导地位,而 spp. 在高温(30°C和40°C)下占主导地位。当乳酸菌是培养物中的优势菌株时,观察到pH从6.5显著下降至4.3,这与乳酸浓度相关。无论培养温度如何,在20°C以上均检测到少量乙醇产生,这表明酵母具有活跃的代谢,尽管该微生物在混合培养物中占微生物的比例很小。这些结果表明,发酵温度显著影响发酵饲料的微生物学特征和生化参数,如pH和乳酸浓度。我们的数据为确定发酵饲料的工业标准提供了有价值的信息。
