秘鲁鱿鱼内源性甲醛生成机理及其控制技术研究
|
摘要
我国已成为水产品生产大国,产量连续18年居世界第一位,国内外市场对水产品的质量与安全提出了更高的要求。但近年来,我国水产品安全事件层出不穷,其中鱿鱼等水产品中甲醛含量超标问题尤为突出,关系到鱿鱼产业乃至全国水产加工产业的发展,亟待解决。因此,探明鱿鱼及制品加工过程中甲醛产生机理,研发鱿鱼及制品中甲醛的控制技术,已成为迫切之需。
鉴于此,本课题以资源丰富、开发潜力巨大的秘鲁鱿鱼为研究对象,跟踪鱿鱼加工和储藏过程甲醛的消长规律,研究鱿鱼甲醛生成的酶学途径和高温化学分解途径,探索添加剂控制鱿鱼冷冻和高温过程内源性甲醛的生成,初步闸明了鱿鱼甲醛抑制剂的作用机制。
本论文主要围绕以上几个方面开展工作,获得结果如下:
1.鱿鱼及其制品储藏加工过程甲醛消长规律的研究显示,鱿鱼原料中FRB-FA含量为5.33-20.13 mg/kg,鱿鱼品种影响甲醛本底含量,鱿鱼制品甲醛含量明显高于鱿鱼原料,FRB-FA含量为17.03-126.23 mg/kg,F-FA含量为1.09-7.09 mg/kg。肝脏甲醛含量明显高于其他组织,胴体靠近内脏和软骨部分较高。鱿鱼肌肉25℃和4℃储存过程随着鱼肉品质的变质,两种甲醛含量逐步下降,高温促进FRB-FA和F-FA的生成,特别是80-100℃。鱿鱼丝加工过程蒸煮和焙烤工序甲醛含量明显上升。秘鲁和北太鱿鱼丝在25℃、4℃和-20℃储存条件下两种甲醛表现相同的变化趋势,25℃储存的鱿鱼丝FRB-FA呈现上升的趋势,低温储藏减少甲醛生成,鱿鱼丝F-FA均呈现下降-再上升的变化趋势,低温储藏,甲醛下降越低,回升越慢。结果表明,鱿鱼加工热处理促进甲醛生成,使鱿鱼制品甲醛含量显著高于原料,鱿鱼和鱿鱼丝储存过程甲醛含量有显著的变化,随着鱼肉变质甲醛含量逐步下降,低温减少鱿鱼丝甲醛的生成。
2.秘鲁鱿鱼甲醛生成TMAOase性质及酶活抑制的研究显示,秘鲁鱿鱼TMAOase活性较低,肝脏酶活相对较高。鱿鱼肝脏和肌肉粗酶最佳作用温度为40℃和50℃,表现不耐热性,最佳作用pH分别为4.5和7.0,Na_2SO_3和CA能明显促进酶活,而TP和Na_2S对酶活有较强的抑制作用。肝脏TMAOase经过酸化、DE52和Sephacryl S-300层析,获得较纯化的酶。纯化酶与肝脏粗酶性质相似,分子量为27.0kDa,纯化酶最佳pH为7.0,最佳作用温度为40℃,表现热不稳定性,Km为20.35 mM。EDTA,Na_2SO_3和CA促进酶活,而TP和Na_2S抑制酶活。鱿鱼肝脏.肌肉和TMAOase-肌肉体外重组体甲醛和DMA明显生成,高含量甲醛能促进鱼肉蛋白质交联,使空间结构变得致密。TP、蔗糖和乙酸3种添加剂能显著减少酶-肌肉重组体中甲醛和DMA含量,其中TP抑制甲醛效果最好,蔗糖还有微弱抑制TMA的生成,3种添加剂能延缓TMAO分解和蛋白可溶性的下降,但是对蛋白分布无影响。结果表明,秘鲁鱿鱼存在TMAOase酶催化生成甲醛的途径,该途径对鱿鱼内源性甲醛的贡献不大,TP、蔗糖和乙酸能有效减少冷冻过程鱿鱼的甲醛含量。
3.秘鲁鱿鱼高温过程甲醛生成特性和控制的研究显示,鱿鱼和鳕鱼高温具有不同的甲醛生成特点,5种鱿鱼经100℃处理甲醛、DMA和TMA含量显著上升,相应的TMAO含量下降,而4种鳕鱼相同处理后甲醛显著下降,DMA含量无明显变化,TMA含量下升,相应的TMAO含量下降。鱿鱼肌肉和上清高温甲醛生成规律相似,上清pH 7.0时甲醛和DMA生成最高,添加物Na_2SO_3、Fe~(2+)+Asc、Fe~(2+)+Cys强烈促进鱿鱼体系甲醛的生成,而TP、MF、CA、CaCl_2、MgCl_2显著降低甲醛含量。TMAO标准体系在辅助因子作用下高温分解生成甲醛、DMA和TMA,温度越高,生成量越多;pH 5.0时甲醛和DMA生成最高;添加剂H_2O_2和碘乙酸促进甲醛生成,而CA和Na_2S减少甲醛含量。TMAO-Fe~(2+)体系和鱿鱼体系高温均检测到了相似的自由基六重峰,a_N和g相似,a_N分别为6.07G和6.05G,g为2.009G。高温甲醛抑制剂最佳作用浓度CA和CaCl_2为10mM,MgCl_2为50mM、TP为0.1%,MF为0.05%。CA、TP和CaCl_2正交组均能显著降低鱿鱼上清中的甲醛和DMA含量,将0.04%TP和10mM CaCl_2作为最佳的复合甲醛抑制剂。复合甲醛抑制剂能有效降低鱿鱼片甲醛和DMA含量,不影响蛋白含量,但鱿鱼硬度、明度L~*水值和红度a~*略有增加。结果表明,鱿鱼高温具有TMAO热分解生成高含量的甲醛、DMA和TMA的(CH_3)_3N·自由基反应,该途径-高温化学分解是鱿鱼内源性甲醛的主要来源,复合甲醛抑制剂能显著降低高温过程鱿鱼的甲醛含量。
4.秘鲁鱿鱼甲醛抑制剂作用机制的初步研究显示,甲醛抑制剂具有两种不同的作用方式,CA、CaCl_2、MgCl_2通过抑制鱿鱼TMAO的热分解,减少甲醛的生成。TP和MF主要捕获鱿鱼中生成的甲醛。5种几茶素类单体中ECg、EGCg结合甲醛能力较高,甲醛捕获率为21-22%,6种简单酚类中间苯三酚结合甲醛能力最高,甲醛捕获率为34%。CA等有机酸明显抑制鱿鱼和TMAO体系高温甲醛和DMA的生成,鱿鱼体系中草酸、CA和柠檬酸三钠效果最好,而TMAO体系酒石酸效果最好。CaCl_2和乳酸钙能显著减少鱿鱼上清甲醛和DMA含量,Ca~(2+)能抑制Fe~(2+)对甲醛生成的促进作用。CA和Ca~(2+)降低鱿鱼高温TMAO分解的自由基信号强度,CA效果更佳。结果表明,TP捕获甲醛主要与几茶素单体A环的间苯三酚型结构有关,CA通过鳌合体系中的Fe~(2+),Ca~(2+)通过抑制Fe~(2+)参与TMAO脱甲基作用,从而降低自由基的信号,实现抑制鱿鱼高温甲醛生成。
China has become the largest producer of aquatic products,and the output has been the first place in the world for 18 years.So,the higher demand for satety and quality of quactic products were proposed.Recently,among the emergences of food safety endless,the great attention has been paid to the problem of formaldehyde(FA) in squid.It had badly affected the development of squid industry,even the whole aquatic product processing industry in China. Therefore,the study has become an urgent task,that found out the formation mechanism of FA in the process of squid and the effective techniques to control the amount of FA in squid products.
In view of these situations,Dosidicus gigas having the largest shape and most abundant resource was aimed in the study.The production trend of FA was decteted during the process and storage stage of squid.Furthernmore,the enzyme pathway and chemical decompositon pathway of FA formation was analyzed.The amount of FA in squid was controlled by the inhibitors during the frozen and thermal stage.And the reactivity mechanism of FA inhibitors were evaluated primarily.
The main results obtained in this study were as follows.
1.The amounts of FA in tour species of squid mantle were from 5.33 to 20.13 mg/kg, different from species.The content of FRB-FA was higher in squid products than mantle,from 17.03 to 126.23 mg/kg,and F-FA was from 1.09 to 7.09 mg/kg.It was found that the liver tissue and the muscle located near the viscera and gristle produced more FA than the other parts of squid.As the quality of squid muscle deteriorated,the amount of F-FA and FBR-FA reduced gradually in muscle stored at 25℃and 4℃.FA formation increased markedly at high temperature,especially from 80 to 100℃.The cooking and baking processes promoted significantly FA formation during the production of dried squid thread.The change of F-FA and FBR-FA showed the similar trend in dried squid thread of Dosidicus gigas and T pacificus stored at 25℃,4℃and -20℃.The content of FRB-FA increased at 25℃,and restrained at low temperature.Then,the content of F-FA showed the trend of droping and rising again,more significantly dropped,more slowly rising at low temperature.The results indicated that the thermal treatment in squid promoted the formation of FA,causing a higher greatly content of FA in squid products than muscle.In the storge,FA content droped gradually with the muscle deterioration for squid muscle,and FA formation was inhibited at the low temperature for squid thread.
2.TMAOase activity in Dosidicus gigas was low among the different tissues,found the highest activity in the liver.The crude TMAOase activity in liver and muscle of squid was optimal at temperature 40℃and 50℃,and was optimal at pH 4.5 and 7.0,respectively.Na_2SO_3 and CA promoted the enzyme activity,whereas enzyme activity was inhibited by TP and Na_2S. TMAOase in the liver was purified by deithylaminoethyl-cellulose and sephacryl S-300 chromatography.The molecular mass of the purified TMAOase was defined to be 27.0 kDa by SDS-PAGE.The optimal pH and temperature of the TMAOase was 7.0 and 40℃,respectively. The enzyme was stable to heat treatment up to 50℃.And the TMAOase converted TMAO to DMA and FA soichiometrically with a Km of 20.35 mM.Na_2SO_3 and CA was effective at activating TMAOase,whereas the TMAOase could be significantly inhibited by TP and Na_2S. The FA and DMA were produced significantly in the recombiner with liver or crude TMAOase from liver and muscle stored at -20℃.The more FA caused the protein aggregation and denser spatical structure of protein.The results indicated that the TMAOase catalyzed the conversion of TMAO to FA and DMA in squid,however,the enzymatic pathway was unimportant for the total amount of FA.The additives of TP,saccharose and acetic acid could effectively reduced the FA content in the frozen squid muscle.
3.The mode of FA formation was different between squids and cods at high temperature. After five species of squid treated at 100℃,the amount of FA,DMA and TMA increased. Whereas,in the four species of cod treated similarly,the amount of FA reduced,and TMA increased.Corresponding,the amount of TMAO both in squids and cods dropped significantly. The FA formation was silimlar in both muscle and supernatant of squid at high temperature. The most amount of FA and DMA was produced at pH 7.0 in the squid supernatant.Additives of Na_2SO_3,Fe~(2+) in presence of the reductants of Asc and Cys,exhibed stimulating greatly effect, whereas,TP,ME CA,CaCl_(2,) MgCl_(2) decreased markedly the content of FA in squid.The TMAO solutions decomposed FA,DMA and TMA in presence of Cys,Asc and FeCl_2, especially higher than 60℃.The most amount of FA and DMA was produced at pH 5.0. Additives of H_2O_2 and iodoacetic acid promoted the formation of FA,whereas CA and Na_2S had reduced the content of FA.The free radical signal was detected in thermal processing of TMAO-Fe~(2+) system and squid system.The a_N and g value of free radical signal in the two system were resembled,a_N value about 6.07G and 6.05G,respectively,and g value about 2.009G.The optimal inhibiting concentrations were 10mM,10mM,50mM,0.1%and 0.05%for CA,CaCl_(2,) MgCl_(2,) TP and MF,respectively.Three-level,three variable orthogonal experiment of CA,CaCl_2 and TP showed that all of groups could reduce the formation of FA and DMA in squid supernatant,0.04%TP and 10mM CaCl_2 as the optimal group of compound inhibitors. The amount of FA and DMA dropped significantly in squid slice immersed in the compound inhibitor,and the content of protein had no effect.However,the hardness,L~* and a~* increased. The results indicated that the(CH_3)_3N·radical existed in the thermal conversion of TMAO to FA,DMA and TMA in squid.This pathway was important for the total amount of FA in squid products.And the compound inhibitors of TP and CaCl_2 could effectively reduced the FA content in the squid treated at high temperature.
4.FA inhibitors had two different mode to reduce the content of FA of squid at high temperature,which CA,CaCl_(2(?)) MgCl_2 restained the thermal decomposition of TMAO in contrast,TP and MF captured the growed FA.The ECG,EGCg and phloroglucinol had a strong ability of capture FA,which reached 21%,22%,24%,respectively.The production of FA and DMA was inhibited greatly by oganic acid on behalf of CA both in the squid and TMAO system. The inhibiting action of oxalic acid,CA and sodium citrate was most effective in the squid system,whereas,tartaric acid were most effective in the TMAO system.CaCl_2 and calcium lactate could reduce significantly the content of FA and DMA.Futhermore,reaction of Fe~(2+) accelerating the formation of FA was inhibited by Ca~(2+) in squid supernatant.CA and Ca~(2+) could reduce the free radical signal strength produced thermal decompostion of TMAO in squid,the better for CA.The results indicated that the capture ability for TP may due to the presence of a phloroglucinolic A-ring structure.It was mechanism of inhibitors that the Fe~(2+) in the squid was chelated by CA,and function group of Fe~(2+) in the TMAO decomposing reaction was combined competively by Ca~(2+),causing the drop of free radical signal to lesser FA formation.
鉴于此,本课题以资源丰富、开发潜力巨大的秘鲁鱿鱼为研究对象,跟踪鱿鱼加工和储藏过程甲醛的消长规律,研究鱿鱼甲醛生成的酶学途径和高温化学分解途径,探索添加剂控制鱿鱼冷冻和高温过程内源性甲醛的生成,初步闸明了鱿鱼甲醛抑制剂的作用机制。
本论文主要围绕以上几个方面开展工作,获得结果如下:
1.鱿鱼及其制品储藏加工过程甲醛消长规律的研究显示,鱿鱼原料中FRB-FA含量为5.33-20.13 mg/kg,鱿鱼品种影响甲醛本底含量,鱿鱼制品甲醛含量明显高于鱿鱼原料,FRB-FA含量为17.03-126.23 mg/kg,F-FA含量为1.09-7.09 mg/kg。肝脏甲醛含量明显高于其他组织,胴体靠近内脏和软骨部分较高。鱿鱼肌肉25℃和4℃储存过程随着鱼肉品质的变质,两种甲醛含量逐步下降,高温促进FRB-FA和F-FA的生成,特别是80-100℃。鱿鱼丝加工过程蒸煮和焙烤工序甲醛含量明显上升。秘鲁和北太鱿鱼丝在25℃、4℃和-20℃储存条件下两种甲醛表现相同的变化趋势,25℃储存的鱿鱼丝FRB-FA呈现上升的趋势,低温储藏减少甲醛生成,鱿鱼丝F-FA均呈现下降-再上升的变化趋势,低温储藏,甲醛下降越低,回升越慢。结果表明,鱿鱼加工热处理促进甲醛生成,使鱿鱼制品甲醛含量显著高于原料,鱿鱼和鱿鱼丝储存过程甲醛含量有显著的变化,随着鱼肉变质甲醛含量逐步下降,低温减少鱿鱼丝甲醛的生成。
2.秘鲁鱿鱼甲醛生成TMAOase性质及酶活抑制的研究显示,秘鲁鱿鱼TMAOase活性较低,肝脏酶活相对较高。鱿鱼肝脏和肌肉粗酶最佳作用温度为40℃和50℃,表现不耐热性,最佳作用pH分别为4.5和7.0,Na_2SO_3和CA能明显促进酶活,而TP和Na_2S对酶活有较强的抑制作用。肝脏TMAOase经过酸化、DE52和Sephacryl S-300层析,获得较纯化的酶。纯化酶与肝脏粗酶性质相似,分子量为27.0kDa,纯化酶最佳pH为7.0,最佳作用温度为40℃,表现热不稳定性,Km为20.35 mM。EDTA,Na_2SO_3和CA促进酶活,而TP和Na_2S抑制酶活。鱿鱼肝脏.肌肉和TMAOase-肌肉体外重组体甲醛和DMA明显生成,高含量甲醛能促进鱼肉蛋白质交联,使空间结构变得致密。TP、蔗糖和乙酸3种添加剂能显著减少酶-肌肉重组体中甲醛和DMA含量,其中TP抑制甲醛效果最好,蔗糖还有微弱抑制TMA的生成,3种添加剂能延缓TMAO分解和蛋白可溶性的下降,但是对蛋白分布无影响。结果表明,秘鲁鱿鱼存在TMAOase酶催化生成甲醛的途径,该途径对鱿鱼内源性甲醛的贡献不大,TP、蔗糖和乙酸能有效减少冷冻过程鱿鱼的甲醛含量。
3.秘鲁鱿鱼高温过程甲醛生成特性和控制的研究显示,鱿鱼和鳕鱼高温具有不同的甲醛生成特点,5种鱿鱼经100℃处理甲醛、DMA和TMA含量显著上升,相应的TMAO含量下降,而4种鳕鱼相同处理后甲醛显著下降,DMA含量无明显变化,TMA含量下升,相应的TMAO含量下降。鱿鱼肌肉和上清高温甲醛生成规律相似,上清pH 7.0时甲醛和DMA生成最高,添加物Na_2SO_3、Fe~(2+)+Asc、Fe~(2+)+Cys强烈促进鱿鱼体系甲醛的生成,而TP、MF、CA、CaCl_2、MgCl_2显著降低甲醛含量。TMAO标准体系在辅助因子作用下高温分解生成甲醛、DMA和TMA,温度越高,生成量越多;pH 5.0时甲醛和DMA生成最高;添加剂H_2O_2和碘乙酸促进甲醛生成,而CA和Na_2S减少甲醛含量。TMAO-Fe~(2+)体系和鱿鱼体系高温均检测到了相似的自由基六重峰,a_N和g相似,a_N分别为6.07G和6.05G,g为2.009G。高温甲醛抑制剂最佳作用浓度CA和CaCl_2为10mM,MgCl_2为50mM、TP为0.1%,MF为0.05%。CA、TP和CaCl_2正交组均能显著降低鱿鱼上清中的甲醛和DMA含量,将0.04%TP和10mM CaCl_2作为最佳的复合甲醛抑制剂。复合甲醛抑制剂能有效降低鱿鱼片甲醛和DMA含量,不影响蛋白含量,但鱿鱼硬度、明度L~*水值和红度a~*略有增加。结果表明,鱿鱼高温具有TMAO热分解生成高含量的甲醛、DMA和TMA的(CH_3)_3N·自由基反应,该途径-高温化学分解是鱿鱼内源性甲醛的主要来源,复合甲醛抑制剂能显著降低高温过程鱿鱼的甲醛含量。
4.秘鲁鱿鱼甲醛抑制剂作用机制的初步研究显示,甲醛抑制剂具有两种不同的作用方式,CA、CaCl_2、MgCl_2通过抑制鱿鱼TMAO的热分解,减少甲醛的生成。TP和MF主要捕获鱿鱼中生成的甲醛。5种几茶素类单体中ECg、EGCg结合甲醛能力较高,甲醛捕获率为21-22%,6种简单酚类中间苯三酚结合甲醛能力最高,甲醛捕获率为34%。CA等有机酸明显抑制鱿鱼和TMAO体系高温甲醛和DMA的生成,鱿鱼体系中草酸、CA和柠檬酸三钠效果最好,而TMAO体系酒石酸效果最好。CaCl_2和乳酸钙能显著减少鱿鱼上清甲醛和DMA含量,Ca~(2+)能抑制Fe~(2+)对甲醛生成的促进作用。CA和Ca~(2+)降低鱿鱼高温TMAO分解的自由基信号强度,CA效果更佳。结果表明,TP捕获甲醛主要与几茶素单体A环的间苯三酚型结构有关,CA通过鳌合体系中的Fe~(2+),Ca~(2+)通过抑制Fe~(2+)参与TMAO脱甲基作用,从而降低自由基的信号,实现抑制鱿鱼高温甲醛生成。
China has become the largest producer of aquatic products,and the output has been the first place in the world for 18 years.So,the higher demand for satety and quality of quactic products were proposed.Recently,among the emergences of food safety endless,the great attention has been paid to the problem of formaldehyde(FA) in squid.It had badly affected the development of squid industry,even the whole aquatic product processing industry in China. Therefore,the study has become an urgent task,that found out the formation mechanism of FA in the process of squid and the effective techniques to control the amount of FA in squid products.
In view of these situations,Dosidicus gigas having the largest shape and most abundant resource was aimed in the study.The production trend of FA was decteted during the process and storage stage of squid.Furthernmore,the enzyme pathway and chemical decompositon pathway of FA formation was analyzed.The amount of FA in squid was controlled by the inhibitors during the frozen and thermal stage.And the reactivity mechanism of FA inhibitors were evaluated primarily.
The main results obtained in this study were as follows.
1.The amounts of FA in tour species of squid mantle were from 5.33 to 20.13 mg/kg, different from species.The content of FRB-FA was higher in squid products than mantle,from 17.03 to 126.23 mg/kg,and F-FA was from 1.09 to 7.09 mg/kg.It was found that the liver tissue and the muscle located near the viscera and gristle produced more FA than the other parts of squid.As the quality of squid muscle deteriorated,the amount of F-FA and FBR-FA reduced gradually in muscle stored at 25℃and 4℃.FA formation increased markedly at high temperature,especially from 80 to 100℃.The cooking and baking processes promoted significantly FA formation during the production of dried squid thread.The change of F-FA and FBR-FA showed the similar trend in dried squid thread of Dosidicus gigas and T pacificus stored at 25℃,4℃and -20℃.The content of FRB-FA increased at 25℃,and restrained at low temperature.Then,the content of F-FA showed the trend of droping and rising again,more significantly dropped,more slowly rising at low temperature.The results indicated that the thermal treatment in squid promoted the formation of FA,causing a higher greatly content of FA in squid products than muscle.In the storge,FA content droped gradually with the muscle deterioration for squid muscle,and FA formation was inhibited at the low temperature for squid thread.
2.TMAOase activity in Dosidicus gigas was low among the different tissues,found the highest activity in the liver.The crude TMAOase activity in liver and muscle of squid was optimal at temperature 40℃and 50℃,and was optimal at pH 4.5 and 7.0,respectively.Na_2SO_3 and CA promoted the enzyme activity,whereas enzyme activity was inhibited by TP and Na_2S. TMAOase in the liver was purified by deithylaminoethyl-cellulose and sephacryl S-300 chromatography.The molecular mass of the purified TMAOase was defined to be 27.0 kDa by SDS-PAGE.The optimal pH and temperature of the TMAOase was 7.0 and 40℃,respectively. The enzyme was stable to heat treatment up to 50℃.And the TMAOase converted TMAO to DMA and FA soichiometrically with a Km of 20.35 mM.Na_2SO_3 and CA was effective at activating TMAOase,whereas the TMAOase could be significantly inhibited by TP and Na_2S. The FA and DMA were produced significantly in the recombiner with liver or crude TMAOase from liver and muscle stored at -20℃.The more FA caused the protein aggregation and denser spatical structure of protein.The results indicated that the TMAOase catalyzed the conversion of TMAO to FA and DMA in squid,however,the enzymatic pathway was unimportant for the total amount of FA.The additives of TP,saccharose and acetic acid could effectively reduced the FA content in the frozen squid muscle.
3.The mode of FA formation was different between squids and cods at high temperature. After five species of squid treated at 100℃,the amount of FA,DMA and TMA increased. Whereas,in the four species of cod treated similarly,the amount of FA reduced,and TMA increased.Corresponding,the amount of TMAO both in squids and cods dropped significantly. The FA formation was silimlar in both muscle and supernatant of squid at high temperature. The most amount of FA and DMA was produced at pH 7.0 in the squid supernatant.Additives of Na_2SO_3,Fe~(2+) in presence of the reductants of Asc and Cys,exhibed stimulating greatly effect, whereas,TP,ME CA,CaCl_(2,) MgCl_(2) decreased markedly the content of FA in squid.The TMAO solutions decomposed FA,DMA and TMA in presence of Cys,Asc and FeCl_2, especially higher than 60℃.The most amount of FA and DMA was produced at pH 5.0. Additives of H_2O_2 and iodoacetic acid promoted the formation of FA,whereas CA and Na_2S had reduced the content of FA.The free radical signal was detected in thermal processing of TMAO-Fe~(2+) system and squid system.The a_N and g value of free radical signal in the two system were resembled,a_N value about 6.07G and 6.05G,respectively,and g value about 2.009G.The optimal inhibiting concentrations were 10mM,10mM,50mM,0.1%and 0.05%for CA,CaCl_(2,) MgCl_(2,) TP and MF,respectively.Three-level,three variable orthogonal experiment of CA,CaCl_2 and TP showed that all of groups could reduce the formation of FA and DMA in squid supernatant,0.04%TP and 10mM CaCl_2 as the optimal group of compound inhibitors. The amount of FA and DMA dropped significantly in squid slice immersed in the compound inhibitor,and the content of protein had no effect.However,the hardness,L~* and a~* increased. The results indicated that the(CH_3)_3N·radical existed in the thermal conversion of TMAO to FA,DMA and TMA in squid.This pathway was important for the total amount of FA in squid products.And the compound inhibitors of TP and CaCl_2 could effectively reduced the FA content in the squid treated at high temperature.
4.FA inhibitors had two different mode to reduce the content of FA of squid at high temperature,which CA,CaCl_(2(?)) MgCl_2 restained the thermal decomposition of TMAO in contrast,TP and MF captured the growed FA.The ECG,EGCg and phloroglucinol had a strong ability of capture FA,which reached 21%,22%,24%,respectively.The production of FA and DMA was inhibited greatly by oganic acid on behalf of CA both in the squid and TMAO system. The inhibiting action of oxalic acid,CA and sodium citrate was most effective in the squid system,whereas,tartaric acid were most effective in the TMAO system.CaCl_2 and calcium lactate could reduce significantly the content of FA and DMA.Futhermore,reaction of Fe~(2+) accelerating the formation of FA was inhibited by Ca~(2+) in squid supernatant.CA and Ca~(2+) could reduce the free radical signal strength produced thermal decompostion of TMAO in squid,the better for CA.The results indicated that the capture ability for TP may due to the presence of a phloroglucinolic A-ring structure.It was mechanism of inhibitors that the Fe~(2+) in the squid was chelated by CA,and function group of Fe~(2+) in the TMAO decomposing reaction was combined competively by Ca~(2+),causing the drop of free radical signal to lesser FA formation.
引文
Agustsson I,Strom A R.Biosynthesis and turnover of trimethylamine oxide in the teleost Cod,Gadus morhua[J].J Bio Chem,1981,256(15):8045-8049.
Ang,J F,Hultin H O.Denaturation of cod myosin during freezing after modification with formaldehyde [J].J Food Sci,1989,54:814-818.
Anthoni U,Borresen T,Christophersen C,Gram L,Nielsen P H.Is trimethylamine oxide a reliable indicator for the marine origin of fish?[J].Comp Biochem Physiol,1990,97:569-572.
Babbitt J K,Crawford D L,Law D K.Decomposition of trimethylamine oxide and changes in protein extractability during frozen storage of minced and intact hake muscle[J].J Agri Food Chem,1972,20(5):1052-1054.
Banda M C M,Hultin H O.Role of cofactors in breakdown of TMAO in frozen red Hake muscle[J].J Food Proc Preserv,1983,7:221-236.
Bechmann I E.Comparison of the formaldehyde content found in boiled and raw mince of frozen saithe using different analytical methods[J].Lebensm-Wiss u-Technol,1998,31:449-453.
Benjakul S,Visessangaun W,Tanaka M.Partial purification and characterization of trimethyl-N-oxide demethylase from lizardfish kidney[J].Comp Biochem Physiol,Part B,2003,135:359-371.
Benjakul S,Visessanguan W,Tanaka M.Induced formation of dimethylamine and formaldehyde by lizardfish (Saurida micropectoralis) kidmey trimethylamine-N-oxide demethylase[J].Food Chem,2004,84:297-305.
Bianchi F,Careri M,Mangia A.Fish and food safety:Determination of formaldehyde in 12 fish species by SPME extraction and GC-MS analysis[J].Food Chem.2007,100:1049-1053.
Bordi C,lobbi-nivol C,MejeanV,Parte J C.Effects of ISSo2 Insertions in Structural and Regulatory Genes of the Trimethylamine Oxide Reductase of Shewanella oneidensis[J].J Bacteriol,2003,185(6):2042-2045.
Boulton C A,Crabbe M J C,Large P L.Microbial oxidation of amines.Partial purification of a trimethylamine mono-oxygenase from Pseudomonas aminovorans and its role in growth on trimethylamine[J].Biochem J,1974,140:253-263.
Castell C H,Neal W E,Dale J.Comparison of changes in trimethylamine,dimethylamine,and extractable protein in iced and frozen gadoid fillets[J].J Fish Res Bd of Can,1973,30:1246-1248.
Dingle J R,Keith R A,Lall B.Protein instability in frozen storage induced in minced muscle of flatfishes by mixture with muscle of red hake[J].Can Inst Food Sci Tech J,1977,10:143-146.
Dos Santos J P,lobbi-nivol C,Couillault C,Giordano G,Mejean V.Molecular analysis of the trimethylamine N-oxide (TMAO) reductase respiratory system from a Shewanella species[J].J Mol Biol,1998,284:421-433.
Ferris J P,Gerwe R D,Gapsi G R.Detoxication Mechanisms.Ⅱ.The Iron-Catalyzed Dealkylation of Trimethylamine Oxide[J].J Amer Chem Soci,1967,89(20):5270-5275.
Fu X Y,Xu C H,Miao B C,Liang J N,Li Z J,Cui F X.Purification and characterization of trimethylamine- N-Oxide demethylase from Jumbo Squid (Dosidicus gigas)[i].J Agric Food Chem,2006,54:968-972.
Fu X Y,Xu C H,Miao B C,Liang J N,Li Z J,Zhang Y Q,Wang Q.Effect of processing steps on the physico-chemical properties of dried-seasoned squid[J].Food Chem,2007,103:287-294.
Gill T A,Paulson A T.Localization and characterization and partial purification of TMAase[J].Camp Biochem Physiol,1982,7 lb:49-56.
Harada K,Yamada K.Some properties of a formaldehyde and dimethylamine forming enzyme obtained form Barbatia virescens[J].J Shimonoseki Univ Fish,1971,19:95-103.
Harada K.Studies on enzymes forming formaldehyde and demethylamine in fish and shellfish.[J].J Shimonoseki Univ Fish,1975,23:161-241.
Hashida K,Ohara S,Makino R.Improvement of formaldehyde-scavenging ability of condensed tannins by ammonia treatment[J].Holzforschung,2006,60:178-183.
Havemeister W,Rehbein H,Steinhart H,Gonzales-Sotelo C,Krogsgaard-Nielsen M,Jorgensen B.Visualization of the enzyme trimethylamine oxide demthylase in isoelectric focusing gels by an enzyme-specific staining method[J].Electrophoresis,1999,20:1934-1938.
Herrera J R,Pastoriza L,Sampedro G.Inhibition of formaldehyde production in frozen-stored minced blue whiting (Micromesistius poutassou) muscle by cryostabilizers:an approach from the glassy state theory[J].Agric Food Chem,2000,48(11):5256-5262.
Hills W E,Urbach G.The reaction of (+)-catechin with formaldehyde[J].J appl Chem,1959,9:474-482.
Hultin H O.Trimethylamine-N-oxide (TMAO) demethylation and protein denaturation in fish muscle[M].Advan Seafood Biochem,1992:25-42.
Joly A,Cottin P,Hanching L,Ducastaing A.Trimethylamine N-oxide Demethylase (TMAO-ase) of saithe (Pollachius-virens) kidney:a study of some physicochemical and enzymic properties[J].Sci Food Agric,1992,59(2):261-267.
Kalasz H.Biological Role of Formaldehyde,and Cycles Related to Methylation,Demethylation,and Formaldehyde Production[J].Mini Rev Medic Chem,2003,3(3):175-192.
Kijowski J M,Mast M G.Effect of sodium chloride and phosphates on the thermal properties of chicken meat proteins[J].Food Sci,1988,53:367-370.
Kimura M,Kimura I,Seki N.TMAOase,trimethylamine-N-oxide demethylase,is a thermostable and active enzyme at 80℃[J].Fish Sci,2003,69:414-420.
Kimura M,Seki N,Kimura I.Occurrence and some properties of trimethylamine-N-oxide demethylase in myofibrillar fraction from walleye pollack muscle[J].Fish Sci,2000a,66:725-729.
Kimura M,Seki N,Kimura I.Purification and characterization of trimethylamine-N-oxide demethylase from walleye pollack muscle[J].Fish Sci,2000b,66:967-973.
Landolt L A,Hultin H O.Removal of trimethylamine oxide and soluble protein from intact red hake muscle by washing[J].J Food Process Preserv,1981,5:227-242.
Li J L,Zhu J L,Ye L F.Determination of Formaldehyde in Squid Products by HPLC[J].Asia Pac J Clin Nutr,2007,16(Suppl 1):127-130.
Lin J K,Chang H W,Lin-Shiau S Y.Abundance of dimethylamine in seafoods:possible implication in the incidence of human cancer[J].Nutr Cancer,1984,6(3):148-159.
Lin J K,Hurng D C.Thermal conversion of trimethylamine-N-oxide to trimethylamine and dimethylamine in squids[J].Food Chem Toxic,1985,23:579-583.
Lundstrom R C,Correia F F,Wilhelm K A.Enzymatic dimethylamine and formaldehyde production in minced American plaice and blackback flounder mixed with a red Hake TMAO-ase active fraction[J].J FoodSci,1982,47:1305-1310.
Lunstrom R C,Correia F F,Wilhelm K A.Dimethylamine and formaldehyde production in fresh red hake (Urophycis chuss):the effect of packing material oxygen permeability and cellular damage[J].Refig Sci Technol,1981,4:457-464.
Mansilla M R,Sotelo C G,Moran R M.Partial purificationand biochemical characterization of TMAOase from kidney of European hake (Merluccins merluccius)[J].Eur Food Technol,2004,218:262-268.
Nielsen M K,Jorgensen B M.Quantitative relationship between trimethylamine oxide aldolase activity and formaldehyde accumulation in white muscle from gadiform fish during frozen storage[J].J Agric Food Chem,2004,16,52(12):3814-3822.
Niizeki N,Daikoku T,Hirata T,Shourbagy I E,Song X,Sakaguchi M.Mechanism of biosynthesis of trimethylamine oxide from choline in the teleost tilapia,Oreochromis niloticus,under freshwater conditions[J].Comp Biochem Physiol B Biochem Mol Biol,2002,131(3):371-386.
Nitisewojo P,Hultin H O.Charatristics of TMAO degrading systems in Atlantic short finned squid[J].J Food Biochem,1986,10:93-106.
Odziejska I K,Niecikowska C,Sikorski Z E.Dimethylamine and formaldehyde in cooked squid (Illex argentinus) muscle extract and mantle[J].Food Chem,1994,50(3):281-283.
Okunaga T.Studies on the development of dimethylamine and formaldehyde in Alaska Pollack muscle during frozen storage[J].Bull Hokkaido Reg Fish Res Lab,1964,29:108-122.
Parkin K L,Hultin H O.A membrane fraction from red hake muscle catalyzing the conversion of TMAO to dimethylamine and formaldehyde.In advances in technology in the chilling,freezing,processing,storage and transport of fish,especially underutilized species[J].Internat Inst Refrig,1981:475-782.
Parkin K L,Hultin H O.Characterization of trimethylamine-n-oxide(TMAO) demethylase activity from fish muscle microsomes[J].J Biochem,1986,100:77-86.
Parkin K L,Hultin H O.Fish muscle microsome catalyze the conversion of trimethylamine oxide to dimethylamine and formaldehyde[J].FEBS Letts,1982,139:61-64.
Parkin K L,Hultin H O.Partial purification of trimethylamine N-oxide(TMAO) demethylase from crude fish muscle microsomes by detergents[J].J Biochem,1986,100:87-97.
Parkin K L,Hultin H O.Some factors influencing the production of dimethylamine and formaldehyde in minced and intact red hake muscle[J].J Food Proc Preserv,1982,6:73-97.
Phillippy B Q,Hultin H O.Distribution and some characteristics of trimethylamine -n-oxide(TMAO) demethylase activity of red hake muscle[J].J Food Biochem,1993a,17:235-250.
Phillippy B Q,Hultin H O.Some factors involved in trimethylamine N-oxide (TMAO) demethylation in post mortem red hake muscle[J].J Food Biochem,1993b,17:251-266.
Racicot L D,Lundatrom R C,Wilhelm K A,Ravesi E M,Licciardello J J.Effect of oxidizing and reducing agents on trimethylamine N-oxide demethylase activity in red Hake muscle[J].J Agric Food Chem,1984,32:459-464.
Ragnarsson K,Regenstein J M.Changes in ecectrophoretic patterns of gadoid and non-gadoid fish muscle during frozen storage[J].J Food Sci,1989,54:819-823.
Reece P.The role of oxygen in the production of formadehyde in frozen minced Cod muscle[J].J Sci Food Agric,1983,34:1108-1112.
Rehbein H,Schreiber W.TMAO-ase activity in tissues offish species from the Northeast Atlantic[J].J Comp Biochem Physiol,1984,79B:447-452.
Rehbein H.Relevance of trimethylamine oxide demethylase activity and haemoglobin content to formaldehyde production and texture deterioration in frozen stored minced fish muscle[J].J Sci Food Agric,1988,43:261-276.
Rey-Mansilla M,Sotelo C G,Aubourg S P,Rehbein H,Bo Jorgensen W H,Nielsen M K.Localization of formaldehyde production during frozen storage of European hake (Merluccius merluccius)[i].Eur Food Res Technol.2001,231:43-47.
Rey-Mansilla M,Sotelo C G,Perez-Martin R I.TMAOase Activity of European Hake (Merluccius merluccius) Organs:Influence of Biological Condition and Season[J].J Food Sci,2002,67(9):3242-3251.
Rey-Mansilla M,Sotelo CG,Moran R M.Partial purification and biochemical haracterization of TMAOase from kidney of European hake (Merluccius merluccius) [J].Eur Food Technol,2004,218:262-268.
Sartora L,Pezzatoa E,Dell Aicaa I,Caniatob R,Bigginc S,Garbisa S.Inhibition of matrix-proteases by polyphenols:chemical insights for antiinflammatory and anti-invasion drug design[J].Biochem Pharm,2002,64:229-237.
Sotelo C,Gallardo M J,Pineiro C,Perez-Martin R.Trimethylamine oxide and derived compounds' changes during frozen storage of hake (Merluccius merluccius)[i].J Food Chem,1995,53:61-65.
Sotelo C,Pineiro C,Perez-martin R.Denaturation of fish proteins during frozen storage:role of formaldehyde[J].Z Lebensm Unters Forsch,1995,200(1):14-23.
Spinelli J,Koury B J.Nonenzymic formation of Dimethylamine in Dried Fishery Products[J].J Agric Food Chem,1979.27(5):1104-1108.
Spinelli J,Koury B J.Some new observations on the pathways of formation of dimethylamine in fish muscle and liver[J].J Agric Food Chem,1981,29(2):327-331.
Stanley D W,Hultin H O.Quality factors in cooked North Atlantic squid[J].Can Inst Food Sci Technol J,1982,15:277-282.
Strom A R.Biosynthesis of trimethylamine oxide in calanoid.Seasonal changes in trimethylamine mono-oxygenase[J].Mar Biol,1979,51:33-40.
Surrey.Stable Micro Systems[M].User Manual of TA-XT2i.England,2000.
Synowiecki J,Sikorski Z E.Heat induced changes in thiol groups in squid proteins[J].J Food Biochem,1988,12:127-135.
Takagaki A,Katsuhiko F,Fumic N.Application of green tea catechins as formaldehyde scavengers[J].Mokuzai Gakkaishi,2000,46 (3):231-237.
Takeuchi K,Hatanaka A,Kimura M,Seki N,Kimura I,Yamada S,Yamashita S.Aspolin,a novel extremely aspartic acid-rich protein in fish muscle,promotes iron-mediated demethylation of trimethylamine-N-oxide[J].J Biol Chem,2003,278(48):47416-47422.
Tokunaga T.Biochemical and food science study of trimethylamine oxide and its relatedsubstances in marine fish[J].Bull Tokai Reg Fish Res Lab,1980,101:121-129.
Tokunaga T.Studies on the development of dimethylamine an FA in Alaska pollack muscle during frozen storage[J].Bull Hokkkaido Reg Fish Lab,1964,29:108-122.
Tomioka K,Ogushi J,Endo K.Studies on dimethylamine in foods-Ⅱ Enzymic formation of dimethylamine from trimethylamine oxide[J].Bull Jap Soc Sci Fish,1974,40:1021-1026.
Tyihak E,Albert L,Nemeth Z I,Katay G,Kiraly Veghely Z,Szende,B.Formaldehyde cycle and the natural formaldehyde generators and capturers[J].Acta Biol Hung.1998;49(2-4):225-238.
Vaisey E B.The Non-Enzymatic Reduction of Trimethylamine Oxide to Trimethylamine,Dimethylamine,and Formaldehyde[J].Can J Biochem Physiol,1956,34(6):1085-1090.
Werringloer J.Assay of formaldehyde generated during microsomal oxidation reactions[J].Methods Enzymol,1978,52:297-302.
Yamada K,Amano K.Studies on the biological formation of formaldehyde and dimethylamine in fish and shellfish-Ⅴ.On the enzymatic formation in the pyloric caeca of Alaska Pollock.[J].Bull Jap Soc Scient Fish,1965a,31:60-64.
Yamada K,Amano K.Studies on the biological formation of formaldehyde and dimethylamine in fish and shellfish-Ⅶ.Effect of methylene blue on the enzymatic formation of formaldehyde and dimethylamine from trimethylamine oxide[J].Bull Jap Soc Scient Fish,1965b,31:1030-1037.
Yamada K,Harada K,Amano K.Biological formation of formaldehyde and dimethylamine in fish and shellfish-Ⅶ.Requriement of cofactor in the enzyme system[J].Bull Jap Soc Scient Fish,1969,35:227-231.
Yukiko K,Mitsuhiro T,Takashi S.Marked Formation of Thiazolidine-4-carboxylic Acid,an Effective Nitrite Trapping Agent in Vivo,on Boiling of Dried Shiitake Mushroom[J].Agric.Food Chem.1990,38:1945-1949.
Zdzislaw S,Kostuch S.Trimethylamine N-oxide demethylase:Its occurrence,properties,and role in technological changes in frozen fish[J].Food Chem,1982,9:213-222.
安利华,孙群,郑万源.东海地区常见水产品甲醛本底值调查及含量分析[J].中国食品卫生杂志,2005,17(6):524-527.
毕彩虹,杨坚茶.茶多酚的保健作用研究进展[J].西南园艺,2006,34(2):37-39.
陈效兰,雷钢铁.柠檬酸在食品工业中的应用[J].食品研究与开发,2000,21(3):6-7.
刁恩杰.香菇中甲醛影响因素及在加工中控制措施研究[D].硕士学位论文,2005.
杜永芳,周德庆,王智.不同贮存温度下龙头鱼和蓝鳕中甲醛含量的变化[J].食品科技,2006,7:107-109.
庚晋,周洁.甲醉污染的危害[J].建材产品与应用,2002,(5):49-51.
黄茂福.鳌合剂及其在印染工业中的应用[J].印染,2001,1:37-40.
李里特.食品物性学[M].北京:中国农业出版社,2001.
励建荣,孙群.水产品中甲醛本底值、产生机理及检测方法研究进展(二)[J].中国水产,2005,(9):65-66.
励建荣,孙群.水产品中甲醛本底值、产生机理及检测方法研究进展(一)[J].中国水产,2005,(8):64-65.
励建荣,俞其林,胡子豪,朱军莉,贾佳.茶多酚与甲醛的反应特性研究[J].中国食品学报,2008,8(2):52-57.
励建荣,朱军莉.秘鲁鱿鱼丝加工过程甲醛产生控制的研究[J].中国食品学报,2006,6(1):200-203.
柳淑芳,杜永芳,朱文慧,马敬军,周德庆.食用鱼类甲醛本底含量研究初报[J].海洋水产研究,2005,26(6):77-82.
马敬军,周德庆,柳淑芳,马洪明.二硝基苯肼衍生-高效液相色谱法测定水产品中甲醛含量的研究[J].海洋水产研究,2005,26(1):28-31.
马敬军,周德庆,张双灵.水产品中甲醛本底含量与产生机理的研究进展[J].海洋水产研究,2004,25(4):85-88.
茅林春,吴涛,方雪花.氯化钙和热处理对斜切南瓜的保鲜作用[J].中国食品学报,2007,7(1):115-118.
莫文敏,曾庆孝.蛋白质改性研究进展[J].食品科学,2000,21(6):6-9.
王金权,罗建中,张明,宋光敏,朱又春 茶叶在甲醛污染治理中的试验性研究[J].环境工程,2005,23(4):47-49.
王阳光,李碧清,高华明.在室温下存放的鱿鱼甲醛含量的变化[J].贮运保鲜,2005,26(7):171-172.
王尧耕,陈新军.世界大样性经济柔鱼类资源及其渔业[M].北京:海洋出版社,2004.
吴富忠,黄丽君.鱿鱼及制品中甲醛来源与产生规律探索[J].中国公共卫生管理,2006,22(3):256-258.
杨贤强,王岳飞,陈留记.茶多酚化学[M].上海:上海科学技术出版社,2003:373-383.
叶丽芳.鱿鱼及制品甲醛测定方法、本底含量和甲醛生成控制的初步研究[D].硕士学位论文,2007.
于立群.何风生.甲醛的健康效应[J].国外医学卫生学分册,2004,31(2):84-87.
俞其林,励建荣.食品中甲醛的来源与控制[J].现代食品科技,2007,10(23):76-78.
俞其林.茶多酚作为甲醛捕获剂的反应特性及在鱿鱼制品中的应用研究[D].硕士学位论文,2008.
Ang,J F,Hultin H O.Denaturation of cod myosin during freezing after modification with formaldehyde [J].J Food Sci,1989,54:814-818.
Anthoni U,Borresen T,Christophersen C,Gram L,Nielsen P H.Is trimethylamine oxide a reliable indicator for the marine origin of fish?[J].Comp Biochem Physiol,1990,97:569-572.
Babbitt J K,Crawford D L,Law D K.Decomposition of trimethylamine oxide and changes in protein extractability during frozen storage of minced and intact hake muscle[J].J Agri Food Chem,1972,20(5):1052-1054.
Banda M C M,Hultin H O.Role of cofactors in breakdown of TMAO in frozen red Hake muscle[J].J Food Proc Preserv,1983,7:221-236.
Bechmann I E.Comparison of the formaldehyde content found in boiled and raw mince of frozen saithe using different analytical methods[J].Lebensm-Wiss u-Technol,1998,31:449-453.
Benjakul S,Visessangaun W,Tanaka M.Partial purification and characterization of trimethyl-N-oxide demethylase from lizardfish kidney[J].Comp Biochem Physiol,Part B,2003,135:359-371.
Benjakul S,Visessanguan W,Tanaka M.Induced formation of dimethylamine and formaldehyde by lizardfish (Saurida micropectoralis) kidmey trimethylamine-N-oxide demethylase[J].Food Chem,2004,84:297-305.
Bianchi F,Careri M,Mangia A.Fish and food safety:Determination of formaldehyde in 12 fish species by SPME extraction and GC-MS analysis[J].Food Chem.2007,100:1049-1053.
Bordi C,lobbi-nivol C,MejeanV,Parte J C.Effects of ISSo2 Insertions in Structural and Regulatory Genes of the Trimethylamine Oxide Reductase of Shewanella oneidensis[J].J Bacteriol,2003,185(6):2042-2045.
Boulton C A,Crabbe M J C,Large P L.Microbial oxidation of amines.Partial purification of a trimethylamine mono-oxygenase from Pseudomonas aminovorans and its role in growth on trimethylamine[J].Biochem J,1974,140:253-263.
Castell C H,Neal W E,Dale J.Comparison of changes in trimethylamine,dimethylamine,and extractable protein in iced and frozen gadoid fillets[J].J Fish Res Bd of Can,1973,30:1246-1248.
Dingle J R,Keith R A,Lall B.Protein instability in frozen storage induced in minced muscle of flatfishes by mixture with muscle of red hake[J].Can Inst Food Sci Tech J,1977,10:143-146.
Dos Santos J P,lobbi-nivol C,Couillault C,Giordano G,Mejean V.Molecular analysis of the trimethylamine N-oxide (TMAO) reductase respiratory system from a Shewanella species[J].J Mol Biol,1998,284:421-433.
Ferris J P,Gerwe R D,Gapsi G R.Detoxication Mechanisms.Ⅱ.The Iron-Catalyzed Dealkylation of Trimethylamine Oxide[J].J Amer Chem Soci,1967,89(20):5270-5275.
Fu X Y,Xu C H,Miao B C,Liang J N,Li Z J,Cui F X.Purification and characterization of trimethylamine- N-Oxide demethylase from Jumbo Squid (Dosidicus gigas)[i].J Agric Food Chem,2006,54:968-972.
Fu X Y,Xu C H,Miao B C,Liang J N,Li Z J,Zhang Y Q,Wang Q.Effect of processing steps on the physico-chemical properties of dried-seasoned squid[J].Food Chem,2007,103:287-294.
Gill T A,Paulson A T.Localization and characterization and partial purification of TMAase[J].Camp Biochem Physiol,1982,7 lb:49-56.
Harada K,Yamada K.Some properties of a formaldehyde and dimethylamine forming enzyme obtained form Barbatia virescens[J].J Shimonoseki Univ Fish,1971,19:95-103.
Harada K.Studies on enzymes forming formaldehyde and demethylamine in fish and shellfish.[J].J Shimonoseki Univ Fish,1975,23:161-241.
Hashida K,Ohara S,Makino R.Improvement of formaldehyde-scavenging ability of condensed tannins by ammonia treatment[J].Holzforschung,2006,60:178-183.
Havemeister W,Rehbein H,Steinhart H,Gonzales-Sotelo C,Krogsgaard-Nielsen M,Jorgensen B.Visualization of the enzyme trimethylamine oxide demthylase in isoelectric focusing gels by an enzyme-specific staining method[J].Electrophoresis,1999,20:1934-1938.
Herrera J R,Pastoriza L,Sampedro G.Inhibition of formaldehyde production in frozen-stored minced blue whiting (Micromesistius poutassou) muscle by cryostabilizers:an approach from the glassy state theory[J].Agric Food Chem,2000,48(11):5256-5262.
Hills W E,Urbach G.The reaction of (+)-catechin with formaldehyde[J].J appl Chem,1959,9:474-482.
Hultin H O.Trimethylamine-N-oxide (TMAO) demethylation and protein denaturation in fish muscle[M].Advan Seafood Biochem,1992:25-42.
Joly A,Cottin P,Hanching L,Ducastaing A.Trimethylamine N-oxide Demethylase (TMAO-ase) of saithe (Pollachius-virens) kidney:a study of some physicochemical and enzymic properties[J].Sci Food Agric,1992,59(2):261-267.
Kalasz H.Biological Role of Formaldehyde,and Cycles Related to Methylation,Demethylation,and Formaldehyde Production[J].Mini Rev Medic Chem,2003,3(3):175-192.
Kijowski J M,Mast M G.Effect of sodium chloride and phosphates on the thermal properties of chicken meat proteins[J].Food Sci,1988,53:367-370.
Kimura M,Kimura I,Seki N.TMAOase,trimethylamine-N-oxide demethylase,is a thermostable and active enzyme at 80℃[J].Fish Sci,2003,69:414-420.
Kimura M,Seki N,Kimura I.Occurrence and some properties of trimethylamine-N-oxide demethylase in myofibrillar fraction from walleye pollack muscle[J].Fish Sci,2000a,66:725-729.
Kimura M,Seki N,Kimura I.Purification and characterization of trimethylamine-N-oxide demethylase from walleye pollack muscle[J].Fish Sci,2000b,66:967-973.
Landolt L A,Hultin H O.Removal of trimethylamine oxide and soluble protein from intact red hake muscle by washing[J].J Food Process Preserv,1981,5:227-242.
Li J L,Zhu J L,Ye L F.Determination of Formaldehyde in Squid Products by HPLC[J].Asia Pac J Clin Nutr,2007,16(Suppl 1):127-130.
Lin J K,Chang H W,Lin-Shiau S Y.Abundance of dimethylamine in seafoods:possible implication in the incidence of human cancer[J].Nutr Cancer,1984,6(3):148-159.
Lin J K,Hurng D C.Thermal conversion of trimethylamine-N-oxide to trimethylamine and dimethylamine in squids[J].Food Chem Toxic,1985,23:579-583.
Lundstrom R C,Correia F F,Wilhelm K A.Enzymatic dimethylamine and formaldehyde production in minced American plaice and blackback flounder mixed with a red Hake TMAO-ase active fraction[J].J FoodSci,1982,47:1305-1310.
Lunstrom R C,Correia F F,Wilhelm K A.Dimethylamine and formaldehyde production in fresh red hake (Urophycis chuss):the effect of packing material oxygen permeability and cellular damage[J].Refig Sci Technol,1981,4:457-464.
Mansilla M R,Sotelo C G,Moran R M.Partial purificationand biochemical characterization of TMAOase from kidney of European hake (Merluccins merluccius)[J].Eur Food Technol,2004,218:262-268.
Nielsen M K,Jorgensen B M.Quantitative relationship between trimethylamine oxide aldolase activity and formaldehyde accumulation in white muscle from gadiform fish during frozen storage[J].J Agric Food Chem,2004,16,52(12):3814-3822.
Niizeki N,Daikoku T,Hirata T,Shourbagy I E,Song X,Sakaguchi M.Mechanism of biosynthesis of trimethylamine oxide from choline in the teleost tilapia,Oreochromis niloticus,under freshwater conditions[J].Comp Biochem Physiol B Biochem Mol Biol,2002,131(3):371-386.
Nitisewojo P,Hultin H O.Charatristics of TMAO degrading systems in Atlantic short finned squid[J].J Food Biochem,1986,10:93-106.
Odziejska I K,Niecikowska C,Sikorski Z E.Dimethylamine and formaldehyde in cooked squid (Illex argentinus) muscle extract and mantle[J].Food Chem,1994,50(3):281-283.
Okunaga T.Studies on the development of dimethylamine and formaldehyde in Alaska Pollack muscle during frozen storage[J].Bull Hokkaido Reg Fish Res Lab,1964,29:108-122.
Parkin K L,Hultin H O.A membrane fraction from red hake muscle catalyzing the conversion of TMAO to dimethylamine and formaldehyde.In advances in technology in the chilling,freezing,processing,storage and transport of fish,especially underutilized species[J].Internat Inst Refrig,1981:475-782.
Parkin K L,Hultin H O.Characterization of trimethylamine-n-oxide(TMAO) demethylase activity from fish muscle microsomes[J].J Biochem,1986,100:77-86.
Parkin K L,Hultin H O.Fish muscle microsome catalyze the conversion of trimethylamine oxide to dimethylamine and formaldehyde[J].FEBS Letts,1982,139:61-64.
Parkin K L,Hultin H O.Partial purification of trimethylamine N-oxide(TMAO) demethylase from crude fish muscle microsomes by detergents[J].J Biochem,1986,100:87-97.
Parkin K L,Hultin H O.Some factors influencing the production of dimethylamine and formaldehyde in minced and intact red hake muscle[J].J Food Proc Preserv,1982,6:73-97.
Phillippy B Q,Hultin H O.Distribution and some characteristics of trimethylamine -n-oxide(TMAO) demethylase activity of red hake muscle[J].J Food Biochem,1993a,17:235-250.
Phillippy B Q,Hultin H O.Some factors involved in trimethylamine N-oxide (TMAO) demethylation in post mortem red hake muscle[J].J Food Biochem,1993b,17:251-266.
Racicot L D,Lundatrom R C,Wilhelm K A,Ravesi E M,Licciardello J J.Effect of oxidizing and reducing agents on trimethylamine N-oxide demethylase activity in red Hake muscle[J].J Agric Food Chem,1984,32:459-464.
Ragnarsson K,Regenstein J M.Changes in ecectrophoretic patterns of gadoid and non-gadoid fish muscle during frozen storage[J].J Food Sci,1989,54:819-823.
Reece P.The role of oxygen in the production of formadehyde in frozen minced Cod muscle[J].J Sci Food Agric,1983,34:1108-1112.
Rehbein H,Schreiber W.TMAO-ase activity in tissues offish species from the Northeast Atlantic[J].J Comp Biochem Physiol,1984,79B:447-452.
Rehbein H.Relevance of trimethylamine oxide demethylase activity and haemoglobin content to formaldehyde production and texture deterioration in frozen stored minced fish muscle[J].J Sci Food Agric,1988,43:261-276.
Rey-Mansilla M,Sotelo C G,Aubourg S P,Rehbein H,Bo Jorgensen W H,Nielsen M K.Localization of formaldehyde production during frozen storage of European hake (Merluccius merluccius)[i].Eur Food Res Technol.2001,231:43-47.
Rey-Mansilla M,Sotelo C G,Perez-Martin R I.TMAOase Activity of European Hake (Merluccius merluccius) Organs:Influence of Biological Condition and Season[J].J Food Sci,2002,67(9):3242-3251.
Rey-Mansilla M,Sotelo CG,Moran R M.Partial purification and biochemical haracterization of TMAOase from kidney of European hake (Merluccius merluccius) [J].Eur Food Technol,2004,218:262-268.
Sartora L,Pezzatoa E,Dell Aicaa I,Caniatob R,Bigginc S,Garbisa S.Inhibition of matrix-proteases by polyphenols:chemical insights for antiinflammatory and anti-invasion drug design[J].Biochem Pharm,2002,64:229-237.
Sotelo C,Gallardo M J,Pineiro C,Perez-Martin R.Trimethylamine oxide and derived compounds' changes during frozen storage of hake (Merluccius merluccius)[i].J Food Chem,1995,53:61-65.
Sotelo C,Pineiro C,Perez-martin R.Denaturation of fish proteins during frozen storage:role of formaldehyde[J].Z Lebensm Unters Forsch,1995,200(1):14-23.
Spinelli J,Koury B J.Nonenzymic formation of Dimethylamine in Dried Fishery Products[J].J Agric Food Chem,1979.27(5):1104-1108.
Spinelli J,Koury B J.Some new observations on the pathways of formation of dimethylamine in fish muscle and liver[J].J Agric Food Chem,1981,29(2):327-331.
Stanley D W,Hultin H O.Quality factors in cooked North Atlantic squid[J].Can Inst Food Sci Technol J,1982,15:277-282.
Strom A R.Biosynthesis of trimethylamine oxide in calanoid.Seasonal changes in trimethylamine mono-oxygenase[J].Mar Biol,1979,51:33-40.
Surrey.Stable Micro Systems[M].User Manual of TA-XT2i.England,2000.
Synowiecki J,Sikorski Z E.Heat induced changes in thiol groups in squid proteins[J].J Food Biochem,1988,12:127-135.
Takagaki A,Katsuhiko F,Fumic N.Application of green tea catechins as formaldehyde scavengers[J].Mokuzai Gakkaishi,2000,46 (3):231-237.
Takeuchi K,Hatanaka A,Kimura M,Seki N,Kimura I,Yamada S,Yamashita S.Aspolin,a novel extremely aspartic acid-rich protein in fish muscle,promotes iron-mediated demethylation of trimethylamine-N-oxide[J].J Biol Chem,2003,278(48):47416-47422.
Tokunaga T.Biochemical and food science study of trimethylamine oxide and its relatedsubstances in marine fish[J].Bull Tokai Reg Fish Res Lab,1980,101:121-129.
Tokunaga T.Studies on the development of dimethylamine an FA in Alaska pollack muscle during frozen storage[J].Bull Hokkkaido Reg Fish Lab,1964,29:108-122.
Tomioka K,Ogushi J,Endo K.Studies on dimethylamine in foods-Ⅱ Enzymic formation of dimethylamine from trimethylamine oxide[J].Bull Jap Soc Sci Fish,1974,40:1021-1026.
Tyihak E,Albert L,Nemeth Z I,Katay G,Kiraly Veghely Z,Szende,B.Formaldehyde cycle and the natural formaldehyde generators and capturers[J].Acta Biol Hung.1998;49(2-4):225-238.
Vaisey E B.The Non-Enzymatic Reduction of Trimethylamine Oxide to Trimethylamine,Dimethylamine,and Formaldehyde[J].Can J Biochem Physiol,1956,34(6):1085-1090.
Werringloer J.Assay of formaldehyde generated during microsomal oxidation reactions[J].Methods Enzymol,1978,52:297-302.
Yamada K,Amano K.Studies on the biological formation of formaldehyde and dimethylamine in fish and shellfish-Ⅴ.On the enzymatic formation in the pyloric caeca of Alaska Pollock.[J].Bull Jap Soc Scient Fish,1965a,31:60-64.
Yamada K,Amano K.Studies on the biological formation of formaldehyde and dimethylamine in fish and shellfish-Ⅶ.Effect of methylene blue on the enzymatic formation of formaldehyde and dimethylamine from trimethylamine oxide[J].Bull Jap Soc Scient Fish,1965b,31:1030-1037.
Yamada K,Harada K,Amano K.Biological formation of formaldehyde and dimethylamine in fish and shellfish-Ⅶ.Requriement of cofactor in the enzyme system[J].Bull Jap Soc Scient Fish,1969,35:227-231.
Yukiko K,Mitsuhiro T,Takashi S.Marked Formation of Thiazolidine-4-carboxylic Acid,an Effective Nitrite Trapping Agent in Vivo,on Boiling of Dried Shiitake Mushroom[J].Agric.Food Chem.1990,38:1945-1949.
Zdzislaw S,Kostuch S.Trimethylamine N-oxide demethylase:Its occurrence,properties,and role in technological changes in frozen fish[J].Food Chem,1982,9:213-222.
安利华,孙群,郑万源.东海地区常见水产品甲醛本底值调查及含量分析[J].中国食品卫生杂志,2005,17(6):524-527.
毕彩虹,杨坚茶.茶多酚的保健作用研究进展[J].西南园艺,2006,34(2):37-39.
陈效兰,雷钢铁.柠檬酸在食品工业中的应用[J].食品研究与开发,2000,21(3):6-7.
刁恩杰.香菇中甲醛影响因素及在加工中控制措施研究[D].硕士学位论文,2005.
杜永芳,周德庆,王智.不同贮存温度下龙头鱼和蓝鳕中甲醛含量的变化[J].食品科技,2006,7:107-109.
庚晋,周洁.甲醉污染的危害[J].建材产品与应用,2002,(5):49-51.
黄茂福.鳌合剂及其在印染工业中的应用[J].印染,2001,1:37-40.
李里特.食品物性学[M].北京:中国农业出版社,2001.
励建荣,孙群.水产品中甲醛本底值、产生机理及检测方法研究进展(二)[J].中国水产,2005,(9):65-66.
励建荣,孙群.水产品中甲醛本底值、产生机理及检测方法研究进展(一)[J].中国水产,2005,(8):64-65.
励建荣,俞其林,胡子豪,朱军莉,贾佳.茶多酚与甲醛的反应特性研究[J].中国食品学报,2008,8(2):52-57.
励建荣,朱军莉.秘鲁鱿鱼丝加工过程甲醛产生控制的研究[J].中国食品学报,2006,6(1):200-203.
柳淑芳,杜永芳,朱文慧,马敬军,周德庆.食用鱼类甲醛本底含量研究初报[J].海洋水产研究,2005,26(6):77-82.
马敬军,周德庆,柳淑芳,马洪明.二硝基苯肼衍生-高效液相色谱法测定水产品中甲醛含量的研究[J].海洋水产研究,2005,26(1):28-31.
马敬军,周德庆,张双灵.水产品中甲醛本底含量与产生机理的研究进展[J].海洋水产研究,2004,25(4):85-88.
茅林春,吴涛,方雪花.氯化钙和热处理对斜切南瓜的保鲜作用[J].中国食品学报,2007,7(1):115-118.
莫文敏,曾庆孝.蛋白质改性研究进展[J].食品科学,2000,21(6):6-9.
王金权,罗建中,张明,宋光敏,朱又春 茶叶在甲醛污染治理中的试验性研究[J].环境工程,2005,23(4):47-49.
王阳光,李碧清,高华明.在室温下存放的鱿鱼甲醛含量的变化[J].贮运保鲜,2005,26(7):171-172.
王尧耕,陈新军.世界大样性经济柔鱼类资源及其渔业[M].北京:海洋出版社,2004.
吴富忠,黄丽君.鱿鱼及制品中甲醛来源与产生规律探索[J].中国公共卫生管理,2006,22(3):256-258.
杨贤强,王岳飞,陈留记.茶多酚化学[M].上海:上海科学技术出版社,2003:373-383.
叶丽芳.鱿鱼及制品甲醛测定方法、本底含量和甲醛生成控制的初步研究[D].硕士学位论文,2007.
于立群.何风生.甲醛的健康效应[J].国外医学卫生学分册,2004,31(2):84-87.
俞其林,励建荣.食品中甲醛的来源与控制[J].现代食品科技,2007,10(23):76-78.
俞其林.茶多酚作为甲醛捕获剂的反应特性及在鱿鱼制品中的应用研究[D].硕士学位论文,2008.
© 2004-2018 中国地质图书馆版权所有 京ICP备05064691号 京公网安备11010802017129号 地址:北京市海淀区学院路29号 邮编:100083 电话:办公室:(+86 10)66554848;文献借阅、咨询服务、科技查新:66554700 |