纸基食品接触材料中4-肉桂苯酚和水杨酸对叔丁基苯酯向干性食品模拟物TenaxTA的迁移

以纸基食品接触材料中的4-肉桂苯酚(CP)和水杨酸对叔丁基苯酯(TBS)为模拟迁移物,对其向干性食品模拟物Tenax TA中的迁移规律采用超高效液相色谱结合荧光检测(UPLC-FLR)方法进行了研究。在不同温度下对CP和TBS的迁移动力学进行了考察,并对其在封闭环境和敞开环境下的迁移率进行对比研究。通过设计不同质量的Tenax TA接触直径为3.5 cm圆片样品的迁移试验,探索了迁移试验中合适的模拟物质量/接触材料面积比条件。系列试验结果表明,迁移物迁移时间越长,迁移温度越高,相应的迁移率就越高;在高的迁移温度下,迁移物在Tenax TA上的解吸会导致迁移率的下降;在封闭条件下CP和TBS的迁移率要高于敞开条件下的迁移率;迁移试验中,4.16 g/dm²的模拟物质量/接触材料面积比是利用干性食品模拟物进行食品接触材料暴露评估的合适的迁移试验条件。密闭条件下市售的8种食品接触材料干性食品模拟物迁移实验研究表明,TBS存在于用于包装坚果类食品的包装纸中,含量为15.54 mg/kg。     

聚乙烯塑料包装材料中4种抗氧化剂向脂肪食品模拟物迁移的研究

本文基于超高效液相色谱建立了一种脂肪食品模拟物异辛烷中抗氧化剂叔丁基对羟基茴香醚(BHA)、2,6-二叔丁基对甲酚(BHT)、四[甲基-β-(3,5-二叔丁基-4-羟基苯基)丙酸酯]季戊四醇酯(Irganox1010)以及β-(4-羟基-3,5-二叔丁基苯基)丙酸正十八酯(Irganox1076)的提取检测方法,加标回收率在78.0%～108.7%之间,相对标准偏差(RSD)在4.0%～13.7%之间。研究了聚乙烯(PE)膜中抗氧化剂向异辛烷的迁移,讨论了温度及时间对迁移的影响,并根据迁移数据进行了初步的数学模型的建立,对实验值与数值模拟结果计算值作了对比分析。     

PVC塑料包装中化学物总迁移的研究

食品包装安全是食品安全的一个重要环节.食品容器、包装等接触材料与食品长期接触会发生"迁移",分为总迁移(overall migration)和特定迁移(specific migration)[1].其中,特定迁移是指某一特定物质在食品包装或容器与食品接触过程中发生的迁移;总迁移是从塑料材料或制品样品到试验媒介的组分总体迁移量.就物质而言,有可知物与未知物,就过程而言,有包装向食品的迁移,也有食品向包装的渗透、吸收等.进行总迁移实验有助于更全面了解一种材料与食品接触会发生的总体变化,对特定迁移的研究起有辅助与补充作用.欧盟对于食品模拟物、样品及前处理[2]、迁移测试方法[3]都有相应规定[4],本实验采用整体浸泡法,研究了PVC材料中化学物在不同食品模拟物中的总迁移.1 实验部分1.1 实验试剂和器材     

高效液相色谱法测定食品接触材料中苯酚和4-叔丁基苯酚迁移量

提出了食品接触材料在水、3％(质量分数)乙酸溶液、乙醇(1+9)溶液、异辛烷4种食品模拟物中苯酚、4-叔丁基苯酚迁移量的高效液相色谱测定方法.不同种类的食品模拟物采用不同的样品前处理方法提取后,用Diamonsil C18色谱柱为固定相,甲醇-水为流动相梯度洗脱,以激发波长220 nm、发射波长312nm的荧光检测器进...     

气相色谱-质谱法同时测定塑料食品接触材料中25种芳香族伯胺的迁移量

采用固相萃取前处理技术,结合气相色谱-质谱法对食品接触材料中25种芳香族伯胺的迁移量进行了同时测定。样品中25种目标物分别用蒸馏水和30 g/L醋酸浸出后,用氨水调节浸泡液至pH 8～10,经固相萃取小柱富集净化,再用体积比为1:1的叔丁基甲醚和乙醇混合液洗脱定容后用气相色谱-质谱仪测定。不同芳香族伯胺的检出限略有差异,在0.4～2.0 μg/kg的范围内。加标水平在10 μg/kg时,除2,4-二氨基苯甲醚在酸性模拟物中的回收率较低外,其他芳香族伯胺的回收率均在51.6%～118.4%之间,相对标准偏差(n=7)为0.5%～9.8%。同时探讨了不同实验条件如叔丁基甲醚和乙醇的体积比、pH值等条件对25种芳香族伯胺回收率的影响。结果表明,该方法准确、稳定,完全满足欧盟指令No 10/2011对食品接触塑料材料及制品中芳香族伯胺特定迁移量的限量要求,可用于食品接触材料中芳香族伯胺的实际检验。     

热脱附-气相色谱-质谱法测定聚氨酯发泡床垫中12种挥发性有机化合物北大核心CSCD

采用热脱附-气相色谱-质谱法测定聚氨酯发泡床垫中12种挥发性有机化合物的含量。采用挥发性有机化合物的环境气候箱模拟室内环境,用含有Tenax TA的吸附管收集释放出的挥发性有机化合物。在气相色谱分离中采用DB-5MS毛细管色谱柱,在质谱分析中采用全扫描模式。12种挥发性有机化合物的质量在一定范围内与其对应的峰面积呈线性关系,方法的检出限(3S/N)为1.0μg·m^(-3)。加标回收率为84.3%～106%,测定值的相对标准偏差(n=6)为8.0%～9.8%。     

固相萃取/气相色谱-质谱法对接触食品的塑料制品中24种芳香族伯胺迁移量的同时测定

建立了固相萃取/气相色谱-质谱同时测定接触食品的塑料材料和制品中24种受限的芳香族伯胺特定迁移量的分析方法.样品中24种目标物用蒸馏水浸出后,经固相萃取小柱富集净化,再用叔丁基甲醚洗脱,洗脱液氮吹浓缩定容后用气相色谱-质谱法测定.不同的芳香族伯胺,方法的检出限略有差异,为0.01 ～1 μg/kg;各种芳香族伯胺的含量在10 μg/kg时获得的相对标准偏差(n=6)为3.8% ～14.7%.方法完全满足欧盟指令2007/19/EC对接触食品的塑料制品中芳香族伯胺特定迁移量的限量要求.利用该法检测了43批近期经宁波口岸出口的接触食品的塑料制品,仅有2批次分别检出了2-氯苯胺和二甲基苯胺.     

食品包装材料中双酚A在食品模拟物中迁移规律的研究

食品塑料包装材料的安全是保障食品安全的重要一环,包装材料中的双酚A潜在迁移性对人体健康的危害已引起社会的关注. 分别选取蒸馏水、3%乙酸(体积分数)和10%乙醇(体积分数)3种食品模拟物,浸泡已知双酚A含量的食品包装材料,在一定的时间点测试浸泡液中双酚A含量,研究迁移量与模拟物之间的关系. 结果表明,在不同食品模拟物下包装材料中双酚A的迁移量不同,其特定迁移量顺序为10%乙醇溶液>3 %乙酸溶液>蒸馏水. 并研究了温度、时间及微波作用影响食品包装材料中双酚A向食品中的迁移量,结果表明,双酚A向食品中迁移量随接触时间的延长、温度的升高而增加,微波作用能显著提高包装材料中双酚A向食品中的迁移量.     

多壁碳纳米管固相萃取-高效液相色谱-串联质谱法测定食品接触材料中双酚-二环氧甘油醚的迁移量

建立了测定食品接触材料中6种双酚-二环氧甘油醚(双酚A二缩水甘油醚(BADGE)及其衍生物双酚A(2,3-二羟丙基)甘油醚(BADGE•H2O)、双酚A(3-氯-2-羟丙基)甘油醚(BADGE•HCl)、双酚A(3-氯-2-羟丙基)(2,3-二羟丙基)醚(BADGE•H2O•HCl)和双酚F二缩水甘油醚(BFDGE)及其衍生物双酚F双(3-氯-2-羟丙基)甘油醚(BFDGE•2HCl))迁移到食品中的迁移量的高效液相色谱-串联质谱法(HPLC-MS/MS)。样品以叔丁基甲醚(MTBE)为提取溶剂,超声提取,提取液经多壁碳纳米管(MWCNTs)固相萃取(SPE)柱富集、净化。以COSMOSIL C18为分析柱,流动相为0.1%甲酸的5 mmol/L醋酸铵溶液和甲醇。6种双酚-二环氧甘油醚在1.0～100 μg/L范围内线性关系良好(r2＞0.9991)。在3个添加水平下,6种目标化合物的回收率范围为78.6%～89.9%,相对标准偏差小于10%。方法检出限范围为0.5～1.5 μg/L。该方法操作简单,灵敏度高,可应用于食品接触材料中双酚-二环氧甘油醚迁移量的快速检测。     

非苯乙烯骨架极性吸附树脂的合成及结构表征

首次通过在DP-CMB和BE-XDC非苯乙烯型树脂骨架上的附加交联或功能基引入反应制得系列含亚砜基、硝基与乙酰基的极性超高交联吸附树脂新材料.利用IR、低温氮吸附-脱附、元素分析等物理化学手段对上述材料的化学结构及微观形貌进行了表征,为离子交换与吸附树脂的性能改善及应用领域拓宽提供一类具有很好应用前景的多孔聚合物骨架新材料.     

Application of differential scanning calorimetry in food research and food quality assurance

Differential scanning calorimetry (DSC) is the most widely used thermal analytical technique in food research and it has a great utility in quality assurance of food. Proteins are the most studied food components by thermal analysis including studies on conformation changes of food proteins as affected by various environmental factors, thermal denaturation of tissue proteins, food enzymes and enzyme preparations for the food industry, as well as effects of various additives on their thermal properties. Freezing-induced denaturation of food proteins and the effect of cryoprotectants are also monitored by DSC. Polymer characterization based on DSC of polysaccharides, gelatinization behaviour of starches and interaction of starch with other food components can be determined, and phase transitions during baking processes can be studied by DSC. Studies on crystallization and melting behaviour of fats observed by DSC indicate changes in lipid composition or help characterizing products. Thermal oxidative decomposition of edible oils examined by DSC can be used for predicting oil stability. Using DSC in the freezing range has a great potential for measuring and modelling frozen food thermal properties, and to estimate the state of water in foods and food ingredients. Research in food microbiology utilizes DSC in better understanding thermoadaptive mechanisms or heat killing of food-borne microorganisms. Isothermic microcalorimetric techniques provide informative data regarding microbial growth and microbial metabolism.     

食物的色、香、味与食品添加剂

食品添加剂可以改善食品的品质,延长食品的保存期,增加食品的营养成分。本文介绍了生活中常见的食品添加剂：食品色素、食用香料、甜味剂、鲜味剂、防腐剂和抗氧化剂的性能、使用范围和化学结构。以便于在化学教学中开阔学生的知识视野,提高学生的学习兴趣,全面培养学生的科学素质。     

食品色素和人体健康

食品的色泽是评价食品的指标之一。随着食品工业的发展和人们食用加工食品的增多,了解有关食品色素的知识显得非常必要。本文介绍了一些有关食品色素及对人体健康利与弊的知识。     

NMR-Based Approaches in the Study of Foods

In this review, the three different NMR-based approaches usually used to study foodstuffs are described, reporting specific examples. The first approach starts with the food of interest that can be investigated using different complementary NMR methodologies to obtain a comprehensive picture of food composition and structure; another approach starts with the specific problem related to a given food (frauds, safety, traceability, geographical and botanical origin, farming methods, food processing, maturation and ageing, etc.) that can be addressed by choosing the most suitable NMR methodology; finally, it is possible to start from a single NMR methodology, developing a broad range of applications to tackle common food-related challenges and different aspects related to foods.     

固相微萃取技术的进展及其在食品分析中应用的现状

固相微萃取(SPME)是当今色谱分析中使用极为广泛的样品前处理方法,这一技术将萃取、浓缩、解吸、进样等功能集于一体,灵敏度高且操作简便。该文简要介绍了近年来SPME涂层、装置及相应技术的演变,综述了SPME在国内外食品分析中的应用现状,并讨论了国内部分研究者在采用这一技术进行定量分析时存在的一些共性问题。     

聚苯乙烯提取物的检测与评价

随着材料科学的迅速发展,聚合物材料以不同的形态越来越广泛地应用于食品包装中。但是由于聚合物材料自身的特性及其改性加工,导致了很多低分子量化合物的形成,因而给食品安全性带来很大隐患,也危害着人们的身体健康。为了解决这一问题,在选用材料前,必须分析聚合物材料中低分子化合物的迁移情况,考虑迁移过程对包材使用的影响。实验中选用正庚烷、8%乙醇、50%乙醇和蒸馏水作为食品模拟液,用气相色谱测定聚苯乙烯提取物的迁移量,进而将实验数据分析比较。结果显示,迁移量随着温度的升高和时间的延长而不断增加,溶剂种类的影响为:正庚烷>50%乙醇>8%乙醇>蒸馏水。     

反相高效液相色谱法同时快速测定食品中常见的8种食品添加剂

 采用反相高效液相色谱法测定食品中常见的 8种食品添加剂 :糖精、甜味素、苯甲酸、山梨酸、香兰素、咖啡因、胭脂红和日落黄。实验采用Shim packCLC ODS分析柱 ,以甲醇 乙酸铵 (pH 7 0 ) (体积比为 44∶5 6 )为流动相 ,在UV 2 2 0nm处检测。样品经Carrez试剂处理去除杂质后直接进样 ,一次进样分析仅需 8min。平均回收率为 91 9%～ 10 8 5 % ,相对标准偏差小于 4% (n =5 )。     

Evaluation of Innovative Dried Purée from Jerusalem Artichoke—In Vitro Studies of Its Physicochemical and Health-Promoting Properties

The present study aimed to evaluate the effect of Jerusalem artichoke processing methods and drying methods (freeze drying, sublimation drying, vacuum drying) on the basic physicochemical parameters, profiles and contents of sugars and polyphenolic compounds, and health-promoting properties (antioxidant activity, inhibition of the activities of α-amylase, α-glucosidase, and pancreatic lipase) of the produced purée. A total of 25 polyphenolic compounds belonging to hydroxycinnamic phenolic acids (LC-PDA-MS-QTof) were detected in Jerusalem artichoke purée. Their average content in the raw material was at 820 mg/100 g dm (UPLC-PDA-FL) and was 2.7 times higher than in the cooked material. The chemical composition and the health-promoting value of the purées were affected by the drying method, with the most beneficial values of the evaluated parameters obtained upon freeze drying. Vacuum drying could offer an alternative to freeze drying, as both methods ensured relatively comparable values of the assessed parameters.     

Surfactants Used in Food Industry: A Review

The understanding of the formation, structures, and properties of emulsions is essential to the creation and stabilization of structures in food. The increasing use of surfactants, the identification of compounds with low toxicity and good surface activity properties is of great interest. The relevance of the major end points specified in the Organisation for Economic Co-operation and Development (OECD) guidelines for the hazard assessment of food chemicals is critically analyzed and main parameters are acute toxicity, subacute repeated studies, allergy, reproductive toxicity, long-term studies, and mutagenicity tests. We focus this article on surfactant association structures and food colloids. There is almost infinite number of combinations are organized and arranged in very complex internal microstructures with various types of assemblies such as dispersions, emulsions, foams, gels, etc. Low-mass surfactants are very mobile at the interface and they are particularly efficient reducing the interfacial tension. As a result, they rapidly coat the freshly created oil-water interface during emulsification. In this category, we mainly mentioned monoglycerides, lecithins, glycolipids, fatty alcohols and fatty acids. High-mass surfactants cover protein and polysacharide groups. The protein molecule may interpenetrate in the lipid phase to various degrees. The specific binding is predominantly electrostatic: The headgroups of the surfactants bind to groups of opposite charge on the protein. The saturation binding for anionic surfactants is pH-independent and seems to be controlled by the cooperative hydrophobic interactions. Polysaccharides and smallmolecule surfactants are two of the predominant groups of amphiphilic materials that have been explored for the stabilization of emulsions. One of the most important aspects of polymer-surfactant systems is their ability to control stability and rheology over a wide range of composition. Biocompatible, biodegradable, and/or nontoxic emulsion-based formulations have great potential for applications in the food. The combination of particular characteristics such as emulsifying, anti-adhesive and antimicrobial activities presented by biosurfactants suggests potential application as multipurpose ingredients or additives.     

Time Evolution of Microbial Composition and Metabolic Profile for Biogenic Amines and Free Amino Acids in a Model Cucumber Fermentation System Brined with 0.5% to 5.0% Sodium Chloride

Salt concentrations in brine and temperature are the major environmental factors that affect activity of microorganisms and, thus may affect formation of biogenic amines (BAs) during the fermentation process. A model system to ferment cucumbers with low salt (0.5%, 1.5% or 5.0% NaCl) at two temperatures (11 or 23 °C) was used to study the ability of indigenous microbiota to produce biogenic amines and metabolize amino acid precursors. Colony counts for presumptive Enterococcus and Enterobacteriaceae increased by 4 and up to 2 log of CFU∙mL⁻¹, respectively, and remained viable for more than 10 days. 16S rRNA sequencing showed that Lactobacillus and Enterobacter were dominant in fermented cucumbers with 0.5% and 1.5% salt concentrations after storage. The initial content of BAs in raw material of 25.44 ± 4.03 mg∙kg⁻¹ fluctuated throughout experiment, but after 6 months there were no significant differences between tested variants. The most abundant BA was putrescine, that reached a maximum concentration of 158.02 ± 25.11 mg∙kg⁻¹. The Biogenic Amines Index (BAI) calculated for all samples was significantly below that needed to induce undesirable effects upon consumption. The highest value was calculated for the 23 °C/5.0% NaCl brine variant after 192 h of fermentation (223.93 ± 54.40). Results presented in this work indicate that possibilities to control spontaneous fermentation by changing salt concentration and temperature to inhibit the formation of BAs are very limited.