电子束辐照对美国红鱼肉挥发性风味成分的影响

为了分析电子束辐照剂量对美国红鱼肉挥发性风味物质的影响。本文采用固相微萃取-气质联用技术,分离鉴定不同剂量电子束辐照后红鱼肉的挥发性风味成分。结果表明:(1)辐照后红鱼肉风味有一定变化,感官评分随辐照剂量的增加而有所降低;(2)红鱼肉经1、3、5、7、9kGy剂量处理,检出的挥发性风味成分由36种分别增加到52、46、65、55、55种;挥发性成分中羰基化合物及醇类物质的相对含量最高;辐照后挥发性醇类、酯类、芳香类物质相对含量降低,高剂量辐照后醛酮类、含硫含氮类化合物相对含量普遍增加,是导致气味改变的主要因素。总之,美国红鱼肉经低于5kGy剂量辐照后能较好的保持其原有风味,高剂量电子束辐照会导致异味的产生。     

辐照对低脂Mozzarella干酪成熟过程中挥发性风味物质的影响

采取0、1、3、5 kGy不同剂量辐照低脂Mozzarella干酪,研究不同剂量辐照对其成熟过程中的理化指标和挥发性风味化合物的影响。结果表明:辐照对低脂Mozzarella干酪成熟过程中脂肪的含量、pH值4.6 SN、12%TCA SN有显著的影响(P0.05),对其它理化指标的影响均不显著(P0.05)。不同成熟期内,不同剂量辐照处理后对低脂Mozzarella干酪中挥发性风味化合物的影响不同,辐照对低脂Mozzarella干酪中的酮类、酸类、醇类、酚类、酯类的种类和含量影响较大,5kGy辐照后的影响大于其它辐照剂量处理的,对其它挥发性化合物的影响较小,不同辐照剂量与挥发性化合物形成之间没有特定的影响规律。     

电子鼻结合HS-SPME-GC-MS分析辐照对甲鱼预制菜挥发性风味成分的影响

为了探究辐照对甲鱼预制菜挥发性风味成分的影响,采用0、4.7、7.1、9.9 kGy剂量⁶⁰Co-γ射线辐照处理甲鱼预制菜,通过感官评定并利用电子鼻结合顶空固相微萃取-气相色谱-质谱联用技术(HS-SPME-GC-MS)分析辐照前后挥发性风味成分的变化。结果表明,5 kGy以内剂量辐照对甲鱼预制菜的感官品质无明显影响,高于5 kGy会影响其气味和滋味,进而可能产生异味。辐照对甲鱼预制菜特征气味引起的差异主要表现在传感器响应值较高的芳香成分和有机硫化物、氮氧化合物、甲烷、醇类和醛酮类物质,利用主成分分析(PCA)和线性判别分析(LDA)能够有效区分经不同剂量辐照处理的甲鱼预制菜。4.7 kGy组与对照组气味差异较小,7.1、9.9 kGy组与对照组差异相对较大。不同剂量辐照后甲鱼预制菜挥发性成分的种类增加,醛类、酸类相对含量降低,烃类、芳香族类、酮类、酯类相对含量升高,醇类、含氮含硫及杂环类相对含量先降低后升高。相对气味活度值(ROAV)分析结果表明,壬醛、癸醛、辛醛、己醛、庚醛、1-辛烯-3-醇和2-戊基呋喃是甲鱼预制菜的关键风味成分,苯甲醛、苯乙醛、(E,E)-2, 4-癸二烯醛对其风味具有重要修饰作用。辐照后辛醛、己醛、1-辛烯-3-醇对甲鱼预制菜总体风味的贡献率降低,庚醛、2-戊基呋喃的贡献率先降低后增加,苯乙醛的贡献率增加并成为关键风味成分。因此,建议采用不超过5 kGy剂量的⁶⁰Co-γ射线辐照处理甲鱼预制菜,在杀菌的同时最大限度保持其原有风味。本研究结果为辐照技术在甲鱼预制菜杀菌保鲜中的应用提供了科学依据。     

竹叶黄酮联合电子束对鳗鱼鲞风味物质产生的影响研究

为探究竹叶黄酮联合电子束辐照处理对鳗鱼鲞挥发性风味物质形成的作用,本试验对比了传统道地工艺鳗鱼鲞、工厂工艺鳗鱼鲞和竹叶黄酮联合电子束辐照处理工艺鳗鱼鲞的感官品质和挥发性风味物质。结果表明,0.25%竹叶黄酮联合6 kGy电子束辐照处理后鳗鱼鲞的感官评价在气味、滋味、组织状态、色泽及质地方面与传统加工方式较为接近;鳗鱼鲞的挥发性化合物以烃类、醛类和醇类为主,1-戊烯-3-醇、2,7-辛二烯-1-醇、壬醛、戊醛、癸醛等化合物对鳗鱼鲞总体风味形成有重要贡献;添加低剂量的竹叶黄酮在抑制鳗鱼鲞脂肪氧化的同时基本不会对鳗鱼鲞的风味造成影响,而电子束辐照在一定程度上会促进鳗鱼鲞风味物质的增加,且辐照剂量越大,化合物含量越高。综合考虑,采取0.25%竹叶黄酮联合6 kGy电子束辐照处理鳗鱼鲞较合适,可使鳗鱼鲞的风味接近传统加工方式。本研究结果为鳗鱼鲞的新型工艺研发提供了参考。     

辐照对发酵香肠品质特性的影响

本文以0、2、4、6kGy剂量60Co γ射线辐照发酵香肠,以水分活度、水分含量、pH值、含盐量、氨基酸总量、非蛋白氮、总氮、硫代巴比妥酸值、挥发性风味物质、肌浆蛋白与肌原纤维蛋白降解情况为指标,研究辐照对香肠品质的影响。结果表明：发酵香肠经不同剂量辐照后水分含量差异显著(P<0.05),氯化钠含量差异并不显著,而0、2kGy辐照后发酵香肠的pH值显著高于4、6kGy辐照,4kGy剂量辐照的发酵香肠中氨基酸总量显著高于2、6kGy处理的样品(P<0.05),4kGy剂量辐照香肠烯烃、酸和酮类物质含量最多,6kGy辐照组中醇类物质含量最多。辐照处理的发酵香肠中肌浆蛋白和肌原蛋白的降解情况低于对照。     

应用HS-SPME和GC/MS技术检测舍饲合作猪肌肉中的风味物质

用顶空固相微萃取和气-质联用技术分析检测了舍饲合作猪背最长肌的挥发性风味物质。结果表明:在60℃样品前处理条件下,共鉴定出50种风味化合物,其中有效成分43种;80℃时共鉴定出168种风味化合物,其中有效成分98种。检测结果还表明,醛类物质、含硫含氮化合物以及呋喃类物质可能是影响合作猪肉风味的重要挥发性物质。     

基于判别分析法的金华火腿挥发性风味物质的形成过程分析

为了弄清金华火腿风味物质的形成过程,以60只杂交猪后腿为原料,按照传统工艺加工金华火腿,用气质联用仪(GC-MS)分析了6个工艺点的肌肉中挥发性风味物质的出峰面积,并用判别分析法分别研究了用挥发性风味物质的出峰面积和出峰面积占总出峰面积的百分率建立的判别函数判断金华火腿加工程度的可能性.研究结果表明,用金华火腿挥发性风味化合物的峰面积进行逐步判别分析,有20种挥发性化合物进入判别函数,而用峰面积占总出峰面积的百分率进行逐步判别分析,有17种挥发性化合物进入判别函数,建立的两套判别函数都能准确判别火腿的加工程度.结果提示:金华火腿风味化合物是在加工过程中逐步形成的,在不同加工阶段,火腿特征风味化合物的含量及其比例各具特征,可以用以辨别火腿的加工时间.     

北京地区酱卤牛肉中挥发性风味物质剖面分析

为研究酱卤牛肉中挥发性风味物质的贡献程度,以北京地区老字号酱卤牛肉(稻香村、天福号、月盛斋、东来顺)为研究对象,探究各酱卤牛肉产品中风味物质的组成、质量浓度及整体贡献,并采用顶空固相微萃取-气相色谱-质谱联用技术对北京地区老字号酱卤牛肉中的挥发性风味成分进行定性定量分析。结果表明,4种酱卤牛肉产品中共鉴定出78种挥发性风味物质,其中气味活性物质(OAV ≥1)12种,分别为庚醛、壬醛、肉豆蔻醛、桉叶油醇、芳樟醇、(-)-4-萜品醇、L-α-松油醇、α-松油醇、草蒿脑、茴香脑、1-甲基萘、2-戊基呋喃,被确定为主体风味物质。因具有相对较高的OAV和特殊风味,壬醛、桉叶油醇、芳樟醇、草蒿脑、茴香脑被认定为北京地区老字号酱卤牛肉的特征风味物质,酮类、酯类和部分醇类为修饰风味物质。对12种气味活性物质进行主成分分析和聚类分析,发现不同酱卤牛肉的风味轮廓差异显著,可明确区分其整体风味情况;气味活性物质可聚为4类,其分别来源于原料肉中脂肪的氧化降解、美拉德反应,以及香辛料的添加等。本研究结果为酱卤牛肉产品的风味调控提供了理论参考。     

香菇生长过程中挥发性风味成分组成及其风味评价

为了明确影响香菇风味的特征性挥发性风味成分,本研究采用固相微萃取(SPME)和气相色谱-质谱联用(GC-MS)技术分析鉴定了不同生长阶段香菇子实体中挥发性风味成分的组成,结合电子鼻系统对不同生长阶段香菇子实体的风味进行差异区分,利用相对风味活度值(ROAV)分析挥发性风味成分对香菇子实体风味的贡献率,运用主成分分析(PCA)明确香菇生长过程中的特征性风味成分,并对不同生长阶段香菇子实体进行风味评价。结果表明,在香菇子实体的6个生长阶段中,共检测出134种挥发性风味成分,主要包括含硫化合物、醛类化合物和八碳化合物。电子鼻系统可以对不同生长阶段的香菇子实体风味进行差异区分。挥发性成分二甲基三硫、1,2,4-三硫杂环戊烷、二甲基二硫、3-甲基丁醛、E-2-壬烯醛和2,4-癸二烯醛是香菇子实体生长过程中关键风味物质,对香菇子实体风味贡献较大。PCA分析发现,二甲基三硫、二甲基二硫、1-辛烯-3-醇、3-甲基丁醛、己醛、2-甲基丁醛、1-庚烯-3-酮、E-2-壬烯醛、(E,E)-2,4-壬二烯醛和2-十一酮10种挥发性成分为香菇的特征性风味成分;成熟期、未开伞生长阶段采收的香菇子实体风味品质较优,菌盖完全开伞后,香菇子实体风味品质较差。本研究结果为香菇栽培和挥发性风味成分的开发利用提供了一定的理论指导。     

加热温度对牡蛎挥发性风味成分的影响

为探讨牡蛎挥发性风味与加工温度的关系,运用电子鼻和顶空固相微萃取气质联用技术（HS-SPME-GC-MS）对不同温度加热牡蛎的挥发性成分进行分析。结果表明,电子鼻能够灵敏地检测到牡蛎在加热过程中气味的变化,新鲜牡蛎在加热到1000C和1500C时气味发生明显变化。通过GC-MS从新鲜牡蛎、100℃加热牡蛎和150℃加热牡蛎中分别检出47、59和56种挥发性物质,己醛、反-2-,顺-6-壬二烯醛、庚醛、辛醛等醛类物质对新鲜牡蛎的风味影响较大,使其具有腥味、蘑菇及黄瓜的风味;经过100℃加热后,牡蛎的腥味减弱,肉香浓郁,醛类和杂环化合物是其主要的挥发性风味物质;150℃加热牡蛎的主要挥发性物质是烃类,杂环化合物对其烘烤风味的形成具有重要作用。     

Investigation of the reaction between 4-hydroxy-5-methyl-3(2H)-furanone and cysteine or hydrogen sulfide at pH 4.5

Reaction of 4-hydroxy-5-methyl-3(2H)-furanone (HMF) with cysteine or hydrogen sulfide at pH 4.5 for 60 min at 140 degrees C produced complex mixtures of volatile compounds, the majority of which contained sulfur. Sixty-nine compounds were identified, some tentatively, by GC/MS. These included disulfides (26), thiols (7), dithiolanones (6), thiophenones (4), dithianones (3), and thienothiophenes (6). The main non-sulfur compounds were 2, 3-pentanedione, 2,4-pentanedione, and 3,4-hexanedione. Both systems produced approximately the same total quantity of volatile compounds, but the reaction containing cysteine gave the larger number of individual compounds, with thiols quantitatively the dominant components. By comparison, the major products formed in the reaction with hydrogen sulfide were the dithiolanones. Reaction pathways are presented for the major products and, where applicable, possible reasons for the differences in composition of the two systems are discussed. The contribution of these reactions, and their products, to the flavor of roasted foods is considered.     

Volatiles from roasted byproducts of the poultry-processing industry

Volatiles of roasted chicken breast muscle and byproducts, such as backbones, breastbones, spent bones, and skin, were investigated. Total volatile concentrations ranged from 2030 ppb in the roasted backbones to 4049 ppb in the roasted skin. The major classes of volatile compounds detected in roasted samples were aldehydes (648-1532 ppb) and alcohols (336-1006 ppb). Nitrogen- and/or sulfur-containing compounds were also detected in appreciable quantities (161-706 ppb) in all samples. For all samples, hexanal and 2-methyl-2-buten-1-ol were dominant among the aldehydes and alcohols, respectively. Among the nitrogen- and sulfur-containing compounds, Maillard reaction products, such as tetrahydropyridazines, piperidines, and thiazoles, were the major contributors to the total volatile content in all samples. The composition of volatiles observed in roasted byproducts was markedly different from that of the roasted breast muscle. Therefore, the blending of the byproducts in appropriate proportions or blending of volatile flavor extracts from different byproducts may be necessary to obtain an aroma that mimics roasted chicken aroma.     

Effect of Drying Treatment Conditions on Sensory Profile of Germinated Oat

Germination and subsequent drying of oat produced significantly different sensory profiles depending on processing parameters such as drying speed and temperature profile. The most salient sensory attributes for processed oat were roasted odor and flavor, sweet taste, intense odor, intense aftertaste, and hard, crisp, brittle texture (P < 0.05). High temperatures (>85°C) were necessary to produce these sensory attributes, and quick drying after germination resulted in higher levels of intensity of favorable sensory attributes. The total amount of volatile compounds was higher in native (ungerminated) oat than in processed oat. During germination, and particularly during the drying treatment, the profile of volatile compounds changed. The most abundant volatile compounds responsible for odor were dimethyl sulfide, hexanal, pentanal, and iso butanal. The relative amount of dimethyl sulfide increased as a function of temperature in drying, whereas hexanal, pentanal, and isobutanal disappeared during heating, as did several other small ketones, alcohols, and esters. The germinated oat dried at high temperatures (65–93°C and 65–85°C) was perceived as being roasted, sweet, and nutty. Sensory and instrumental profile analyses of selected volatile compounds using partial least squares (PLS) regression techniques showed that these sensory attributes were clearly related to dimethyl sulfides and isobutanol. A moist and earthy odor was related to cymene, limonene, and isobutanal. Phenolic compounds significantly influenced oat flavor, whereas lipids had a negligible effect.     

Volatile sulfur compounds in irradiated precooked turkey breast analyzed with pulsed flame photometric detection

Ionizing radiation is an effective processing technology for pathogen inactivation on various foods. However, the generation of off-odor is a concern for some irradiated meats. This study was conducted to investigate volatile sulfur compounds of precooked ready-to-eat turkey breast as functions of radiation dose and subsequent storage. Precooked turkey breast was exposed to 0, 1, 2, 3, 4, and 5 kGy of gamma radiation and stored for 14 days at 5 degrees C. Volatile sulfur compounds were extracted using solid phase microextraction (SPME), followed by gas chromatographic separation and pulsed flame photometric detection. Irradiation dramatically increased concentrations of hydrogen sulfide, sulfur dioxide, methanethiol, and dimethyl disulfide. The rate of increase was higher at low doses (0-2 kGy) than at higher doses of 3-5 kGy. Carbon disulfide was the only volatile sulfur compound that was reduced by irradiation. Concentrations of all volatile sulfur compounds decreased in both irradiated and nonirradiated samples stored at 5 degrees C.     

Differences Between Sensory Profiles and Development of Rancidity During Long‐Term Storage of Native and Processed Oat

Changes in the sensory attributes, lipid composition, and amounts of volatile and phenolic compounds of native and processed (germinated and dried) crushed oat were followed during a 12‐month storage period. The influence of the chemical attributes on the sensory profiles of oats was analyzed by statistical multivariate techniques (PLS regression). During the storage period, significant changes in the sensory profiles of the native and processed oat groats were observed. The stability of oat groats was significantly increased through germination and subsequent drying because the chemical changes causing rancidity and bitterness developed more slowly in the processed oat when compared with the native oat. In native oat, the most intensive changes due to deteriorat ion had already occurred after one month of storage, whereas in processed oat, these changes were perceived considerably later. Stored oat that had deteriorated was evaluated as being musty and earthy in odor and bitter and rancid in flavor. The accumulation of free fatty acids and volatile compounds related to lipid oxidation were closely correlated with the development of the undesired sensory attributes described above. The total amount of phenolic compounds, as well as the volatile aromatic and branched chain compounds derived mainly from protein degradation, showed a significant relationship with favorable sensory attributes such as roasted odor and flavor. Lipid oxidation occurred during the storage and was observed both in the polar and in the nonpolar lipid classes of native oat, whereas in the processed oat, these changes were nonsignificant. Photo‐oxidation of acylated fatty acids may significantly contribute to the development of volatile lipid oxidation products during storage.     

低温风干工艺下酱鸭加工过程中品质特性变化规律研究

为改善酱鸭的质地、色泽和风味,本试验在传统酱鸭加工工艺的基础上,引入低温风干工艺制备酱鸭,并研究其加工过程中理化特性(水分含量、色泽、剪切力值、质构特性)和挥发性风味成分的变化。结果表明,在加工过程中,酱鸭水分含量从76.55%降至58.27%(P0.05);与原料肉相比,L~*值在风干6 h显著降低,a~*值在腌制和风干结束下降,b~*值和咀嚼性在酱制阶段增加,杀菌阶段下降,硬度在酱制阶段升高,而弹性和内聚性均在杀菌阶段降低;与风干24 h相比,胶着性在杀菌阶段降低(P0.05),剪切力值先升高后下降。酱鸭挥发性风味成分分析显示,酱鸭成品有70种挥发性风味成分,主要为萜烯类、醛类、呋喃类、酮类、烃类和醇类;其中,莰烯、己醛和2-戊基呋喃是酱鸭成品主要的特征风味成分,分别占总相对含量的16.51%、10.44%和11.88%。本试验结果为低温风干工艺下酱鸭品质变化特征的研究提供了一定的理论依据。     

Detection of gamma-irradiated sesame seeds before and after roasting by analyzing photostimulated luminescence, thermoluminescence, and electron spin resonance

Sesame seeds were irradiated using a (60)Co irradiator (0-4 kGy) and then roasted (220 degrees C for 10 min). To identify the irradiation treatment, physical detection methods like photostimulated luminescence (PSL), thermoluminescence (TL), and electron spin resonance (ESR) have been investigated before and after roasting. The photon counts of the irradiated samples (nonroasted and roasted) were higher than those of nonirradiated ones, making it possible to distinguish the two samples. The threshold values of nonroasted and roasted samples increased linearly with the irradiation dose, respectively. The TL for the nonirradiated nonroasted and roasted samples presented a lower peak at about 300 degrees C, but irradiated samples showed a higher peak at around 150 degrees C. The areas of TL glow curves were 15 times higher in nonroasted as compared with roasted samples. TL ratio [integrated area of TL 1 (the first glow)/TL 2 (the second glow)] obtained by the reirradiation step was 0 in nonirradiated samples and more than 0.15 in irradiated samples. The radiation-induced ESR signals originating from cellulose were determined in irradiated samples before and after roasting.