蛋白质组学技术在不同物种乳掺假检测中的应用

乳品是人类重要的营养源，然而乳品掺假现象时常发生，近年来尤以向乳品中掺假动、植物蛋白，向特色畜乳中掺假牛乳等方式为主，这不仅损害了消费者的利益，甚至会危害消费者的健康。该研究总结了目前常见的掺假行为及相关检测方法，并介绍了蛋白质组学技术——一种通过确立特定生物标记物来区别不同物种乳的技术。作者查询了国内外近十年来牛乳和特色乳掺假方面的研究报道，关键词设置为“蛋白质组学”、“乳品”、“真实性”、“生物标记物”等，按照奶畜乳类别将所得文献进行分类。分别对奶牛乳、羊乳、驼乳、水牛乳、牦牛乳、驴乳的掺假物、潜在标记物和检出限等方面进行了总结和分析，以期为乳品真实性鉴定和保障乳品质量安全提供有效的工作思路。     

乳及乳制品蛋白质掺假检测研究进展

阐述两类方法、一个原则：乳及乳制品蛋白质掺假特异性检测方法和乳及乳制品蛋白质掺假非特异性检测方法;任何一种乳品蛋白质掺假检测方法的建立都要以某一特定蛋白质差异性为依据的原则。     

指纹图谱技术在生鲜乳掺假检测中的研究进展

生鲜乳是乳制品行业发展的主要原料,是决定乳制品质量的关键因素。然而近年来国内外在乳制品方面的食品安全事件频发,不法分子通过在生鲜乳中掺入虚假物质以获取经济利益的行为已经成为严重的安全问题,对人们健康以及整个乳制品行业造成不良影响。指纹图谱技术是对通过一定的分析工具产生的图像进行判别的一种检测技术,可以对生鲜乳的掺假进行更灵敏、准确和快速的检测。本文通过对生鲜乳的安全现状进行剖析,总结了电泳法、光谱法、色谱法和电子感官技术法4种指纹图谱技术在牛乳掺假检测中的应用,比较了4种技术的优点和局限性,并对未来的研究方向进行了展望,为提高生鲜乳的品质与安全以及保证消费者健康提供理论依据与参考。     

激光诱导击穿光谱在乳制品质量检测中的应用

乳制品是人体健康必需营养的重要来源之一,因此保证乳制品的质量和安全至关重要。作为一种新型的激光烧蚀原子发射光谱技术,激光诱导击穿光谱已经在乳制品的定性和定量分析方面展现出了巨大的应用潜力。本文简要介绍了激光诱导击穿光谱的检测原理,综述了激光诱导击穿光谱在乳制品中矿物质元素、重金属元素、脂肪和蛋白质含量,以及牛奶掺假物检测方面的最新研究进展。最后,探讨了激光诱导击穿光谱在乳制品质量检测方面存在的问题并对其发展趋势进行了展望。     

Milk Preservatives and Adulterants: Processing,Regulatory and Safety Issues

Liquid milk has been an important human nutrient source for a thousand years. However, the safety of milk has always been challenged due to illegal use of preservatives and adulterants such as hydrogen peroxide, salicylic acid, benzoic acid, water, neutralizers, melamine, and so on. Addition of these two types of substances in milk has become a common feature for fulfilling the milk demands of overpopulated countries. Now, for the dairy industry, it seems to be difficult to run the plant without the use of preservatives and or adulterants, especially under Indian conditions. In addition to their potential toxic effects on human health, they also undermine the economy of a country. The lack of timely action against the unscrupulous traders by the public health departments and other law enforcement groups and lack of simple and rapid methods for detection of adulteration further encourage this menace. This overview attempts to address the key features of these two types of harmful substances in milk, their effect on milk composition and constituents, along with their regulatory and safety aspects.     

原料乳中药物残留和掺假物质检测方法的研究进展

原料乳中药物残留或掺假物质的存在造成的安全事件屡屡发生,这使我国乳品行业面临着巨大的挑战。本文主要综述了常规检测法、免疫分析法、仪器检测分析法、生物传感器和蛋白质芯片技术等对原料乳中常见聚醚类抗生素、类固醇激素、苯二氮卓类药物、苯基脲类除草剂、四环素类抗生素和青霉素类抗生素等药物残留、物理性质与原料乳相近的物质、常见电解质、非电解质、防腐剂等掺假物质的检测方法,以及对单一成分掺假物和多种成分掺假物的检测方法,并比较了不同检测方法的准确度、灵敏度、成本等优缺点,以期为相关检测部门进行质量监测或生产厂家牛乳收购提供技术参考。     

Application of immunological methods for the detection of species adulteration in dairy products

A number of enzyme‐linked immunosorbent assays (ELISAs) have been developed for the detection of milk adulteration in dairy products. Target antigens have been caseins, lactoglobulins, immunoglobulins and other whey proteins. Polyclonal and monoclonal antibodies have been used in a variety of formats including direct, indirect, competitive and sandwich ELISAs. ELISAs have been successfully applied to the detection of cows' milk adulteration of sheep, goat and buffalo milk. Goat milk adulteration of sheep milk has also been detected. A number of ELISAs have also been applied to cheese. It is recommended that ELISA should be used in combination with PCR to ensure compliance with current legislation.     

Applications of Raman spectroscopic techniques for quality and safety evaluation of milk: A review of recent developments

Milk is a complete nutrient source for humans. The quality and safety of milk are critical for both producers and consumers, thereby the dairy industry requires rapid and nondestructive methods to ensure milk quality and safety. However, conventional methods are time-consuming and laborious, and require complicated preparation procedures. Therefore, the exploration of new milk analytical methods is essential. This current review introduces the principles of Raman spectroscopy and presents recent advances since 2012 of Raman spectroscopic techniques mainly involving surface-enhanced Raman spectroscopy (SERS), fourier-transform (FT) Raman spectroscopy, near-infrared (NIR) Raman spectroscopy, and micro-Raman spectroscopy for milk analysis including milk compositions, microorganisms and antibiotic residues in milk, as well as milk adulterants. Additionally, some challenges and future outlooks are proposed. The current review shows that Raman spectroscopic techniques have the promising potential for providing rapid and nondestructive detection of milk parameters. However, the application of Raman spectroscopy on milk analysis is not common yet since some limitations of Raman spectroscopy need to be overcome before making it a routine tool for the dairy industry.     

Detection of Adulterants and Contaminants in Liquid Foods—A Review

Milk and fruit juices have paramount importance in human diet. Increasing demand of these liquid foods has made them vulnerable to economic adulteration during processing and in supply chain. Adulterants are difficult to detect by consumers and thus necessitating the requirement of rapid, accurate and sensitive detection. The potential adulterants in milk and fruit juices and their limits set by different regulatory bodies have been briefly described in this review. Potential advantages and limitations of various techniques such as physicochemical methods, chromatography, immunoassays, molecular, electrical, spectroscopy with chemometrics, electronic nose, and biosensors have been described. Spectroscopy in combination with chemometrics has shown potential for rapid, precise, and sensitive detection of potential adulterants in these liquid foods.     

Adverse child health impacts resulting from food adulterations in the Greater China Region

Food adulteration has a long history in human society, and it still occurs in modern times. Because children are relatively vulnerable to food adulterants, studying the health impacts of food adulteration on children is important. This article provides an overview of the child health impacts of food adulterants in two recent food adulteration incidents in the Greater China Region: (1) a plasticizer incident in Taiwan and (2) a 2,4,6‐triamino‐1,3,5‐triazine (melamine)‐tainted milk incident in China. The involved food adulterants, di‐(2‐ethylhexyl) phthalate (DEHP), diisononyl phthalate (DiNP) and melamine, are harmful to the hippocampus, kidneys, reproductive organs and immune system of children, and they also increase the risk of cancer. To detect food adulteration and to avoid further harm caused by food adulteration, simple screening methods have been developed, and they have recently emerged as a new focus area for research. This article also summarizes the simple screening methods used to analyse the aforementioned food adulterants and reports how governments reacted to the recent food incidents. © 2017 Society of Chemical Industry     

乳制品质量快速检测原理与技术研究进展

乳制品是鲜奶以及所有以奶为主要原料加工制成的产品的总称,乳制品的安全问题是全球关注的热点。为了对乳制品质量进行监控,目前已有的检测标准和方法需要在实验室进行,检测环境条件要求较高,周期较长。研究并开发灵敏、准确、便捷的检测方法十分必要。近年来,一系列新的乳制品质量快速检测技术已经被广泛应用,本文主要介绍了电子学、光谱学和生物学检测技术的原理及其在乳制品质量检测应用中的优缺点,同时展望了乳制品质量检测技术的发展方向,旨在为乳制品质量检测技术的进一步发展提供资料参考和思路。     

检测牛奶中杂质的表面增强拉曼光谱基底研究进展

牛奶安全问题时有发生,为了保证食品安全,避免给消费者带来健康风险,乳制品行业亟需开发快速和无损的检测方法。表面增强拉曼光谱法（Surface-Enhanced Raman Spectroscopy,SERS）作为一种分子指纹技术,具有操作简便、无损、快速和受水干扰小等优点,因而被广泛应用于奶制品的快速、灵敏检测。SERS信号的稳定性和重现性主要取决于表面增强基底的制备,本文综述了近年来用于牛奶检测的SERS增强基底的制备方法,目前研究比较多的SERS基底材料是成本较高的贵金属材料,导致贵金属基底的应用受到一些局限,因此新型材料的SERS基底是表面增强拉曼光谱研究的新热点。此外,目前所报道的应用于牛奶检测的SERS基底中,所检测的物质只是牛奶中众多杂质的一部分,甲醛、过氧化氢、重铬酸和水杨酸等掺假物质还未见报道。     

表面增强拉曼光谱在乳和乳品有害物质检测中的研究进展

乳和乳制品作为人类必不可少的食品之一,其中的有害物质,如农兽药残留、真菌毒素、非法添加物质以及其他污染物对消费者的健康安全构成了严重威胁,同时也阻碍了乳制品行业的发展。表面增强拉曼光谱法（Surface Enhanced Raman Spectroscopy,SERS）作为一种新兴的检测方法,有望能够满足目前乳和乳制品高通量,高灵敏度的检测需求。本文总结了SERS方法在牛奶检测中的研究进展,包括金属纳米检测探针和SERS固相平台的制备、抗体和适配体等分子识别技术的应用、核酸扩增技术以及微流控技术等与SERS的结合。最后,对SERS在乳制品的研究发展方向和应用前景做了总结和展望。     

近红外光谱技术在食品掺伪检测应用中的研究进展

近年来,我国食品掺伪现象严重。目前一些常用的食品掺伪检测方法费时费力,需要消耗大量的化学试剂。近红外光谱技术能够实现快速、无损、在线的食品掺伪检测。本文综述近红外光谱技术在食用油、牛奶、蜂蜜、饮料等液态食品和肉制品、奶粉、茶叶、小麦粉等固态食品掺伪检测应用中的研究进展,同时分析近红外光谱技术在掺伪检测中的局限性以及存在问题,并对今后的进一步研究提出展望。     

Culture‐Dependent and Culture‐Independent Nucleic‐Acid‐Based Methods Used in the Microbial Safety Assessment of Milk and Dairy Products

Despite great advances in the diagnostics and better awareness for food safety and security worldwide, significant numbers of foodborne outbreaks have been traced back to the consumption of milk and dairy products contaminated with pathogenic bacteria, such as Listeria monocytogenes, Staphylococcus aureus, Salmonella spp., Campylobacter spp., and pathogenic Escherichia coli. Several culture‐dependent and culture‐independent nucleic acid‐based methods have been proposed to identify, detect, and type milk‐ and dairyborne pathogenic bacteria. In our review, we will provide an overview on why it is of utmost importance to ascertain the presence of pathogenic microorganisms in milk and milk products; thereafter, we will describe the most commonly used culture‐dependent and culture‐independent methods, as well as the most attractive ones with regard to their future exploitation, providing the reader with new insights into how and when they can be exploited to ensure the enumeration, and accurate detection at both species and strain level of the most important milk‐ and dairyborne pathogenic bacteria, even if in a viable but nonculturable state.     

Current Immunoassay Methods for the Rapid Detection of Aflatoxin in Milk and Dairy Products

The presence of mycotoxins in foodstuff causes serious health problems to consumers and economically affects the food industry. Among the mycotoxins, aflatoxins are very toxic and highly carcinogenic contaminants which affect the safety of many foods, and therefore endanger human health. Aflatoxin M₁ (AFM₁) found in milk results from the biotransformation of aflatoxin B₁. Many efforts have been made to control the source of AFM₁ from farmers to dairy product companies. However, AFM₁ escapes ordinary methods of food treatment such as cooking, sterilization, and freezing, hence it appears in milk and dairy products. The presence of high levels of AFM₁ constitutes an alarming threat as milk and dairy products contain essential nutrients for human health, especially for infants and children. For this reason, there is a pressing need for developing a fast and reliable screening method for detecting trace aflatoxins in food. Several analytical methods based on high‐performance liquid chromatography (HPLC) and mass spectroscopy have been used for aflatoxin detection; however, they are expensive, time‐consuming, and require many skills. Recently, immunoassay methods, including enzyme‐linked immunosorbent assay (ELISA), immunosensors, and lateral flow immunoassay (LFIA), have been preferred for food analysis because of their improved qualities such as high sensitivity, simplicity, and capability of onsite monitoring. This paper reviews the new developments and applications of immunoassays for the rapid detection of AFM₁ in milk.     

Melamine detection in milk using vibrational spectroscopy and chemometrics analysis: A review

Major advances in the field of chemometrics combined with the use of vibrational spectroscopy have proven essential for the identification and quantification of food contaminants. These techniques, which have guided the work of regulatory agencies overlooking the food industry, can be readily applied to monitor food processing, quality control, and quality assurance. These processes can ensure product authenticity with respect to variety, geographical origin, and presence or absence of contaminants. Food analysis by vibrational spectroscopy provides overall chemical composition of the tested food sample; therefore, it is widely considered to be a highly reliable and empirical fingerprints of that samples. In 2008, melamine adulteration of milk powder in China resulted in devastatingly adverse effects for both consumers and the overall Chinese economy at large. As a result, regulatory agencies have markedly increased their interest in using fast, reliable, and accurate methods for identifying food contaminants. In this article, we provide a detailed overview of the uses of vibrational spectroscopy methods and chemometrics for the detection and quantification of melamine in dairy products.     

Fourier transform infrared spectroscopy and multivariate analysis for the detection and quantification of different milk species

The authenticity of milk and milk products is important and has extended health, cultural, and financial implications. Current analytical methods for the detection of milk adulteration are slow, laborious, and therefore impractical for use in routine milk screening by the dairy industry. Fourier transform infrared (FT-IR) spectroscopy is a rapid biochemical fingerprinting technique that could be used to reduce this sample analysis period significantly. To test this hypothesis we investigated 3 types of milk: cow, goat, and sheep milk. From these, 4 mixtures were prepared. The first 3 were binary mixtures of sheep and cow milk, goat and cow milk, or sheep and goat milk; in all mixtures the mixtures contained between 0 and 100% of each milk in increments of 5%. The fourth combination was a tertiary mixture containing sheep, cow, and goat milk also in increments of 5%. Analysis by FT-IR spectroscopy in combination with multivariate statistical methods, including partial least squares (PLS) regression and nonlinear kernel partial least squares (KPLS) regression, were used for multivariate calibration to quantify the different levels of adulterated milk. The FT-IR spectra showed a reasonably good predictive value for the binary mixtures, with an error level of 6.5 to 8% when analyzed using PLS. The results improved and excellent predictions were achieved (only 4-6% error) when KPLS was employed. Excellent predictions were achieved by both PLS and KPLS with errors of 3.4 to 4.9% and 3.9 to 6.4%, respectively, when the tertiary mixtures were analyzed. We believe that these results show that FT-IR spectroscopy has excellent potential for use in the dairy industry as a rapid method of detection and quantification in milk adulteration.     

Influence of skimmed milk concentrate replacement by dry dairy products in a low‐fat set‐type yoghurt model system. Use of caseinates,co‐precipitate and blended dairy powders

Yoghurt fortification with caseinates, co‐precipitate and blended dairy powders in a low‐fat yoghurt model system was studied. These dairy products were characterised for pH, moisture, lactose, mineral and protein fractions. Milk proteins were characterised by polyacrylamide gel electrophoresis (SDS‐PAGE) and isoelectric focusing (IEF). Minerals such as Na, Ca, K and Mg were analysed by atomic absorption spectroscopy. Yoghurts were formulated using a skimmed milk concentrate as a milk base enriched with different dry dairy products up to 43 g kg⁻¹ protein content. The percentage of skimmed milk concentrate replaced with dry dairy products in the mix was between 1.37 and 6.35%. Yoghurts enriched with caseinates had higher viscosity and syneresis index (56.81 Pa s and 548.8 g kg⁻¹ respectively) than yoghurts based on concentrated skimmed milk fortified with co‐precipitate (39.00 Pa s and 392.9 g kg⁻¹) or blended dairy products (33.25 Pa s and 431.8 g kg⁻¹). One blended dairy product was tested to manufacture low‐fat yoghurt on an industrial scale, yielding good rheological properties (high viscosity‐consistence, 37.77 Pa s, and low syneresis index, 450 g kg⁻¹) and lower cost than traditional enrichment with skimmed milk powder. © 2000 Society of Chemical Industry     

蛋白质组学技术及其在乳及乳制品中的应用研究进展

蛋白质组学技术是近年来生命科学研究的重要工具,在食品、医学及动植物研究领域具有独特优势。利用蛋白质组学技术研究乳及乳制品,深入阐明其中蛋白质的表达及动态变化已成为当前的研究热点。该文主要综述了蛋白质组学的概念、常用技术及应用领域,重点介绍蛋白质组学在乳及乳制品领域,特别是在乳脂肪球膜蛋白、乳清蛋白、乳及乳制品加工过程以及干酪制品中的研究应用,探讨了目前乳及乳制品蛋白质组学研究中存在的问题与局限,并对蛋白质组学及其在乳及乳制品中的应用前景进行了总结与展望,为应用蛋白质组学技术深入研究乳及乳制品提供了理论依据。