利用黑曲霉通过微生物发酵法从南瓜皮中生产香兰素

IF 0.8 Q3 MULTIDISCIPLINARY SCIENCES Malaysian Journal of Fundamental and Applied Sciences Pub Date : 2023-12-04 DOI:10.11113/mjfas.v19n6.3193
Raisatul Mirza Mohd Rifaie, Latiffah Karim
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引用次数: 0

摘要

香草是用于制药、食品、调味和香料等行业的主要天然调味剂,其中香草醛是主要成分。香兰素(4-羟基-3-甲氧基苯甲醛)是植物的次生代谢产物,是天然香草的主要感官香气成分。香草素化合物可以通过以下途径生产:直接香草豆提取、化学合成和生物技术过程(生物香草生产)。目前,化学合成法生产香兰素已被美国和欧洲立法所拒绝,而植物源性香兰素价格昂贵。目前的研究表明,黑曲霉通过一步发酵的方法从南瓜皮(Cucurbita moschata)生产香草素。本研究采用不同浓度的氢氧化钠(1.0 M和2.0 M)进行碱性水解预处理,并在阿威酸转化为香兰素的生物转化过程中采用不同的水解液进料量,分为小进料量(SFV)和大进料量(LFV)。采用高效液相色谱(HPLC)进行检测和定量分析,得到香兰素产率分别为0.49 mg/L (1.0 M SFV)、0.5 mg/L (1.0 M LFV)、0.33 mg/L (2.0 M SFV)、0.59 mg/L (2.0 M LFV)。以硫代巴比妥酸为试剂进行紫外-可见分光光度法分析,香兰素得率分别为2.76µg/ml (1.0 M SFV)、3.78µg/ml (1.0 M LFV)、2.68µg/ml (2.0 M SFV)、3.05µg/ml (2.0 M LFV)。总之,南瓜皮可以被认为是阿魏酸的重要来源,黑曲霉是一种将阿魏酸转化为香草酸的有效真菌,然后将香草酸转化为香兰素。
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Production of Vanillin from Pumpkin Peels via Microbiological Fermentation using Aspergillus niger
Vanilla is the main natural flavouring agent used in industries such as pharmaceuticals, food, flavouring, and fragrance, in which vanillin is the major component. Vanillin (4-hydroxy-3-methoxybenzaldehyde) is a secondary metabolite of plants and the major organoleptic aroma component of natural vanilla. The vanillin compound can be produced using the following routes: direct vanilla bean extraction, chemical synthesis, and biotechnological processes (bio-vanilla production). Nowadays, the chemical synthesis method used for vanillin production has been rejected by the United States and European legislation, while plant-derived vanillin is expensive. The current study demonstrates vanillin production from pumpkin peels (Cucurbita moschata) by Aspergillus niger via one-step fermentation approach. This study implements different concentrations of sodium hydroxide (1.0 M and 2.0 M) during alkaline hydrolysis pretreatment and different feeding volumes of hydrolysates during the biotransformation processes of ferulic acid into vanillin, classified as small feeding volumes (SFV) and large feeding volumes (LFV). Detection and quantification analysis were carried out using high performance liquid chromatography (HPLC), resulting in vanillin yield of 0.49 mg/L (1.0 M SFV), 0.5 mg/L (1.0 M LFV), 0.33 mg/L (2.0 M SFV), 0.59 mg/L (2.0 M LFV). Analysis with ultraviolet-visible (UV-VIS) spectrophotometry using thiobarbituric acid as reagent was carried out as well, resulting in vanillin yield of 2.76 µg/ml (1.0 M SFV), 3.78 µg/ml (1.0 M LFV), 2.68 µg/ml (2.0 M SFV), 3.05 µg/ml (2.0 M LFV). In conclusion, pumpkin peels can be considered a great source of ferulic acid and Aspergillus niger was reported as an efficient fungus in converting ferulic acid to vanillic acid, which will then be transformed into vanillin.
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