传统与未来的碰撞：食品发酵工程技术与应用进展

随着生物技术的飞速发展,作为食品生物工程的主要组成部分,食品发酵工程技术不断升级,在传统发酵食品的菌种、发酵过程、产品品质得到改善的同时,生物制造的功能食品组分、未来食品等新型产品也应运而生。首先概述了由生物技术和信息技术的进步带来的食品发酵研究手段与生产方式的多层面变革,并重点阐释了利用食品合成生物学设计构建细胞工厂的思路和方法,以及食品生物工程在微生物分析、过程工程和分离工程方面的智能化进程。其次,介绍了现代食品生物工程技术在改善传统发酵食品品质及安全性、生产功能食品组分、添加剂和酶制剂、创制未来食品和开发新型益生食品方面的应用进展。最后,对全球和我国食品发酵产业面临的挑战和未来发展趋势进行了总结和展望,以期为食品发酵的技术革新和工业化应用提供参考。     

生物胺降解酶研究进展及其应用

生物胺是存在于发酵食品和酒精饮料中的潜在胺类危害物。如果人体摄入过量的生物胺,则会引起呼吸困难、呕吐和发烧等过敏反应。生物胺降解酶是通过将生物胺氧化成醛类物质来实现降解生物胺的一类酶。目前发现的具有降解生物胺能力的酶主要包括胺氧化酶、胺脱氢酶和多铜氧化酶。本文详细阐述了这3类主要生物胺降解酶的催化机理、底物特异性、酶学性质、应用特性和它们对生物胺的降解效果,归纳和总结了生物胺降解酶的异源表达和分子改造的研究进展,并对生物胺降解酶在基因挖掘、分子改造和表达等方面的研究趋势进行了展望,以期为研究和开发食品中生物胺的酶法降解策略提供参考。     

Production of pectolytic enzymes – a review

Pectolytic enzymes play an important role in food processing industries and alcoholic beverage industries. These enzymes degrade pectin and reduce the viscosity of the solution so that it can be handled easily. These enzymes are mainly synthesized by plants and microorganisms. Aspergillus niger is used for industrial production of pectolytic enzymes. This fungus produces polygalacturonase, polymethylgalacturonase and pectinlyase. This review mainly concerns with the production of pectolytic enzymes using different carbon sources. It also deals with the effect of operating parameters such as temperature, aeration rate, agitation and type of fermentation on the production of these enzymes.     

Phage lytic proteins: biotechnological applications beyond clinical antimicrobials

Most bacteriophages encode two types of cell wall lytic proteins: endolysins (lysins) and virion-associated peptidoglycan hydrolases. Both enzymes have the ability to degrade the peptidoglycan of Gram-positive bacteria resulting in cell lysis when they are applied externally. Bacteriophage lytic proteins have a demonstrated potential in treating animal models of infectious diseases. There has also been an increase in the study of these lytic proteins for their application in areas such as food safety, pathogen detection/diagnosis, surfaces disinfection, vaccine development and nanotechnology. This review summarizes the more recent developments, outlines the full potential of these proteins to develop new biotechnological tools and discusses the feasibility of these proposals.     

Potentialities of fluorescent carbon nanomaterials as sensor for food analysis

Food safety and quality are among the most significant and prevalent research areas worldwide. The fabrication of appropriate technical procedures or devices for the recognition of hazardous features in foods is essential to safeguard food materials. In the recent era, developing high-performance sensors based on carbon nanomaterial for food safety investigation has made noteworthy progress. Hence this review briefly highlights the different detection approaches (colorimetric sensor, fluorescence sensor, surface-enhanced Raman scattering, surface plasmon resonance, chemiluminescence, and electroluminescence), functional carbon nanomaterials with various dimensions (quantum dots, graphene quantum dots) and detection mechanisms. Further, this review emphasizes the assimilation of carbon nanomaterials with optical sensors to identify multiple contaminants in food products. The insights of carbon-based nanomaterials optical sensors for pesticides and insecticides, toxic metals, antibiotics, microorganisms, and mycotoxins detection are described in detail. Finally, the opportunities and future perspectives of nanomaterials-based optical analytical approaches for detecting various food contaminants are discussed.     

High pressure application for food biopolymers

High hydrostatic pressure constitutes an efficient physical tool to modify food biopolymers, such as proteins or starches. This review presents data on the effects of high hydrostatic pressure in combination with temperature on protein stability, enzymatic activity and starch gelatinization. Attention is given to the protein thermodynamics in response to combined pressure and temperature treatments specifically on the pressure-temperature-isokineticity phase diagrams of selected enzymes, prions and starches relevant in food processing and biotechnology.     

Molecular and cellular studies on the absorption,function, and safety of food components in intestinal epithelial cells

The intestinal tract comes into direct contact with the external environment despite being inside the body. Intestinal epithelial cells, which line the inner face of the intestinal tract, have various important functions, including absorption of food substances, immune functions such as cytokine secretion, and barrier function against xenobiotics by means of detoxification enzymes. It is likely that the functions of intestinal epithelial cells are regulated or modulated by these components because they are frequently exposed to food components at high concentrations. This review summarizes our research on the interaction between intestinal epithelial cells and food components at cellular and molecular levels. The influence of xenobiotic contamination in foods on the cellular function of intestinal epithelial cells is also described in this review.     

乳酸菌对重金属吸附作用的研究进展

重金属污染是人们关注的食品安全问题热点之一,使用食品安全级乳酸菌吸附重金属成为了新的研究方向。本文在分析环境和食品中汞、镉、铅污染的来源及对人类危害的基础上,对微生物与重金属的相互作用进行介绍,重点归纳了乳酸菌作为重金属吸附剂的潜能,以及吸附重金属的作用机制和研究现状,为研发高效吸附重金属的乳酸菌吸附剂提供了可行性的思路。     

枯草杆菌脂肪水解酶LipA和LipB

源自枯草杆菌的分泌型脂肪水解酶LipA及LipB已经被克隆、表达并表征. 它们的分子结构特点、催化机理也已经被深入研究. 枯草杆菌脂肪水解酶因为具有较好的食品工业及化学工业等方面的应用潜力,已经吸引了越来越多的关注. 通过定向进化及高通量筛选的方法对酶分子进行改造,提高其热稳定性及立体选择性是近年的研究热点. 结合国外及本研究组的工作,本文对LipA和LipB的生化性质、结构特点以及采用基因工程突变的方法进行分子改造等方面的研究进展做一简要综述. 另外,对其中一些研究论文做了简要的评价,并提出对未来工作的展望.     

Food packaging’s materials: A food safety perspective

Food packaging serves purposes of food product safety and easy handling and transport by preventing chemical contamination and enhancing shelf life, which provides convenience for consumers. Various types of materials, including plastics, glass, metals, and papers and their composites, have been used for food packaging. However, owing to consumers’ increased health awareness, the significance of transferring harmful materials from packaging materials into foods is of greater concern. This review highlights the interactions of food with packaging materials and elaborates the mechanism, types, and contributing factors of migration of chemical substances from the packaging to foods. Also, various types of chemical migrants from different packaging materials with their possible impacts on food safety and human health are discussed. We conclude with a future outlook based on legislative considerations and ongoing technical contributions to optimization of food–package interactions.     

Processing of Apple Pomace for Bioactive Molecules

The growth of horticulture industries worldwide has generated huge quantities of fruit wastes (25%–40% of the total fruits processed). These residues are generally a good source of carbohydrates, especially cell wall polysaccharides and other functionally important bioactive molecules such as proteins, vitamins, minerals and natural antioxidants. “Apple pomace” is a left-over solid biomass with a high moisture content, obtained as a by-product during the processing of apple fruits for juice, cider or wine preparation. Owing to the high carbohydrate content, apple pomace is used as a substrate in a number of microbial processes for the production of organic acids, enzymes, single cell protein, ethanol, low alcoholic drinks and pigments. Recent research trends reveal that there is an increase in the utilization of apple pomace as a food processing residue for the extraction of value added products such as dietary fibre, protein, natural antioxidants, biopolymers, pigments and compounds with unique properties. However, the central dogma is still the stability, safety and economic feasibility of the process(s)/product(s) developed. This review is mainly focused on assessing recent research developments in extraction, isolation and characterization of bioactive molecules from apple pomace, along with their commercial utilization, in food fortification.     

We are what we eat: food safety and proteomics

In this review, we lead the reader through the evolution of proteomics application to the study of quality control in production processes of foods (including food of plant origin and transgenic plants in particular, but also meat, wine and beer, and milk) and food safety (screening for foodborne pathogens). These topics are attracting a great deal of attention, especially in recent years, when the international community has become increasingly aware of the central role of food quality and safety and their influence on the health of end-consumers. Early proteomics studies in the field of food research were mainly aimed at performing exploratory analyses of food (bovine, swine, chicken, or lamb meat, but also transgenic food such as genetically modified maize, for example) and beverages (wine), with the goal of improving the quality of the end-products. Recently, developments in the field of proteomics have also allowed the study of safety issues, as the technical advantages of sensitive techniques such as mass spectrometry have guaranteed a faster and improved individuation of food contaminating pathogens with unprecedented sensitivity and specificity.     

细菌群体感应及其在食品变质中的作用

食品相关细菌引起的生物被膜形成和食品变质是食品工业中的重大问题。研究表明细菌群体感应(Quorum sensing,QS)与被膜形成、食品腐败变质密切相关。重点对细菌产生的各种QS信号分子及其在被膜形成的作用和被膜在食品工业中的重要性做了介绍。QS信号分子与食品变质密切相关,故对QS抑制剂作为新型食品防腐剂以延长储存期限及加强食品安全的前景进行了概述。     

Cleaning and disinfection programmes in food establishments: a literature review on verification procedures

In food establishments, cleaning and disinfection programmes contribute to provide the environmental conditions that are necessary for the production of safe and healthy food. Compliance with validated programmes is evaluated through verification activities, in order to establish, through objective evidence, if they are implemented as they were written and if they are effective, achieving continuous improvement of the sanitation programmes. In accordance with the specific guidelines of each country, food companies set up their technical specifications and develop their own cleaning and disinfection programmes. Depending on the analytical method used, one of the main challenges was to establish a reasonable limit of acceptability according to the impact that each surface has on the safety and hygiene of the food that is prepared. This review was focused on the procedures implemented to verify the cleaning and disinfection programmes in food establishments. In particular, this study examines the methodologies used (audits and analytical methods), sites for the collection of samples, acceptance criteria and main findings. The results of the analysed studies constitute a scientific basis for designing or improving sanitation procedures and their verification in food companies, and also provide relevant information for food safety authorities.     

食品微生物生长预测模型研究新进展

为了更好的了解食品微生物学预测模型的基本内容, 探讨数学模型在预测微生物学中的作用, 达到提高食品卫生检测效率, 保证食品质量安全的目的, 本文以文献综述形式, 简要概述了预测微生物学一级、二级和三级模型的含义与内容。并在此基础上, 着重介绍了全球范围内已经成功推广使用的多种三级模型, 阐述了它们的研究背景、研究进展、使用方法, 分析了各种模型存在的优缺点, 可为实际应用中选择合适的模型提供参考。在比较使用不同种类模型后, 发现Baranyi & Roberts、响应面和ComBase模型在各级模型中具有更好的使用价值。     

风险矩阵分级模型在哈尔滨市食品安全风险评估中的建立与应用

目的:建立哈尔滨市风险矩阵分级模型,并应用该模型探索食品污染的风险。方法:采用风险矩阵、文献综述及专家判断法对某年食品安全风险监测中位列化学污染物及微生物污染超标率首位的食品-项目组合,即动物肝脏-克伦特罗组合、水产品-副溶血性弧菌组合进行模型评估。结果:参照风险矩阵,动物肝脏-克伦特罗组合的健康风险分值为6,可以判断哈尔滨市人群由于食用动物肝脏而导致克伦特罗膳食暴露的健康风险等级为"中风险",水产品-副溶血性弧菌组合的健康风险分值为2,可以判断哈尔滨市人群每餐由于食用水产品而导致副溶血性弧菌膳食暴露的健康风险等级为"极低风险"。结论:哈尔滨市该年食品安全总体情况较好,风险等级较低,但部分监测项目存在食品安全风险隐患,应予以关注。     

食品微生物生长预测模型研究新进展

为了更好的了解食品微生物学预测模型的基本内容,探讨数学模型在预测微生物学中的作用,达到提高食品卫生检测效率,保证食品质量安全的目的,本文以文献综述形式,简要概述了预测微生物学一级、二级和三级模型的含义与内容。并在此基础上,着重介绍了全球范围内已经成功推广使用的多种三级模型,阐述了它们的研究背景、研究进展、使用方法,分析了各种模型存在的优缺点,可为实际应用中选择合适的模型提供参考。在比较使用不同种类模型后,发现Baranyi＆Roberts、响应面和ComBase模型在各级模型中具有更好的使用价值。     

香兰素抗菌机制研究进展

食品安全问题在中国范围内频发,严重威胁民众的健康和安全。为防止此类问题发生,对于由微生物污染食品所产生的危害,可通过添加抗菌剂有效降低安全隐患,随着食品安全法的不断完善,抗菌剂的添加量也愈加严格和规范。香兰素是一种具有抗菌性的传统食品添加剂,但是目前缺乏对其抗菌机制的全面理解,因此,限制了香兰素在抗菌特性方面的广泛应用。有鉴于此,现对香兰素的结构、功能与抗菌活性的相关性及其抗菌机制研究进展予以综述,并对具有抗菌特性的香兰素衍生物进行探讨。     

Biotechnological potential of pectinolytic complexes of fungi

Plant cell wall-degrading enzymes, such as cellulases, hemicellulases and pectinases, have been extensively studied because of their well documented biotechnological potential, mainly in the food industry. In particular, lytic enzymes from filamentous fungi have been the subject of a vast number of studies due both to their advantages as models for enzyme production and their characteristics. The demand for such enzymes is rapidly increasing, as are the efforts to improve their production and to implement their use in several industrial processes, with the goal of making them more efficient and environment-friendly. The present review focuses mainly on pectinolytic enzymes of filamentous fungi, which are responsible for degradation of pectin, one of the major components of the plant cell wall. Also discussed are the past and current strategies for the production of cell wall-degrading enzymes and their present applications in a number of biotechnological areas.