日本鬼鲉胚胎及卵黄囊仔鱼发育过程中脂肪及脂肪酸特性变化

以野生日本鬼鲉人工催产获得的受精卵为实验材料,定量检测了日本鬼鲉胚胎及卵黄囊仔鱼发育过程中脂肪组成及脂肪酸含量.结果表明:日本鬼鲉胚胎及卵黄囊仔鱼的总脂肪含量为13.85％～ 11.66％,极性脂肪占总脂肪含量为75.39％～ 72.20％.总脂肪及极性脂肪含量在胚胎发育阶段无显著变化,在卵黄囊仔鱼阶段随发育而显著下降.中性脂肪含量在胚胎发育阶段有显著变化,在卵黄囊仔鱼阶段其含量相对稳定.野生日本鬼鲉胚胎及卵黄囊仔鱼总脂肪的主要脂肪酸为DHA(22∶6n-3),16∶0,ARA(20∶4n-6),EPA(20∶5n-3),18∶0和18∶1n-9.总脂肪及极性脂肪的DHA,ARA,EPA含量(mg/gDW)均随胚胎和卵黄囊仔鱼的发育而显著下降,且DHA和ARA含量均在胚胎囊胚期至尾芽期大幅降低.中性脂EPA和DHA含量随发育呈先升后降,其峰值分别出现在初孵仔鱼和2日龄(2DPH)卵黄囊仔鱼.中性脂ARA含量随发育逐步升高,峰值出现在3日龄(3DPH)卵黄囊仔鱼.在胚胎发育前期,总脂肪DHA和ARA相对EPA被选择性消耗,饱和脂肪酸(SFAs)和多不饱和脂肪酸(PUFAs)相对单不饱和脂肪酸(MUFAs)被机体选择性消耗,N-6PUFA相对N-3 PUFA被选择性消耗;在胚胎发育后期及卵黄囊仔鱼阶段,总脂肪EPA相对DHA和ARA被选择性消耗.在胚胎和卵黄囊仔鱼发育过程中,SFAs中16∶0相对18∶0被选择性消耗.胚胎发育后期阶段和卵黄囊仔鱼阶段,总脂肪MUFAs中16∶1相对18∶1被选择性消耗.实验表明日本鬼鲉胚胎及卵黄囊仔鱼发育阶段极性脂肪中DHA、ARA和EPA可以向中性脂肪中转移,胚胎和卵黄囊仔鱼对不同类别脂肪中的重要脂肪酸的消耗具有选择性,且其选择性与发育阶段相关.     

黄颡鱼早期发育阶段受精卵和鱼体脂肪酸组成变化

研究了黄颡鱼受精卵孵化期间和仔鱼发育阶段脂肪含量和脂肪酸的组成变化规律.采用常规化学分析方法和气相色谱法对黄颡鱼从鱼卵受精开始至仔鱼孵化后未投饵的7 d内的脂肪含量和脂肪酸组成进行测定.结果表明,受精卵在整个孵化期间脂肪含量有下降趋势.受精卵中不饱和脂肪酸含量大于饱和脂肪酸含量.受精卵在整个孵化期间各种脂肪酸含量无明显变化.仔鱼孵化后,鱼体总脂肪含量急剧下降,总脂含量从0日龄的4.57%降低到7日龄的0.75%.仔鱼在饥饿期间鱼体脂肪酸组成发生明显变化,单不饱和脂肪酸含量下降最为明显,尤其是C18:1.仔鱼在饥饿期间,脂肪酸按n-9>n-6>n-3顺序被先后利用,黄颡鱼仔鱼发育阶段主要以单不饱和脂肪酸作为能量代谢基质,而C20:4n6(AA)和C22:6n3(DHA)优先于C20:5n3(EPA)被保存下来.     

大黄鱼仔、稚、幼鱼发育阶段的脂肪酸组成及其变化

研究了大黄鱼早期主要发育阶段（前仔鱼期、后仔鱼期、稚鱼、幼鱼）体内脂肪酸的组成及含量的变化规律,并重点比较了发病稚鱼与正常稚鱼的脂肪酸组成。用GC／MS法共检测到24种脂肪酸,且种类随发育而递增,其中饱和脂肪酸（SFA）12种,单不饱和脂肪酸（MUFA）6种,多不饱和脂肪酸（PUFA）6种。分析结果表明：大黄鱼鱼苗内源性营养阶段以饱和脂肪酸C14：0、C16：0及单不饱和脂肪酸C16：1、C18：1作为能量代谢的主要来源;必需脂肪酸C20：4（n-6）（AA）在鱼苗开口前就已存在,而DHA和EPA摄食后才被检测到,其含量受饵料种类的影响,DHA含量变化范围为7．26％～25．36％,EPA为3．41％～8．40％。与同期正常鱼苗相比,病鱼苗的主要脂肪酸DHA、EPA含量显著降低,DHA不足前者的1／3,而AA、C18：1、C18：2、C18：3含量和EPA／DHA的比值显著增加,分别是前者的1．5—3倍。导致稚鱼阶段“胀鳔病”发生的内在原因可能是DHA和EPA的缺乏以及AA偏高。研究结果为预防“胀鳔”鱼苗的发生提供了理论依据。     

菊黄东方鲀发育早期的脂肪酸组成变化

采用生化分析手段对菊黄东方鲀的未受精卵、胚胎(出膜前,受精后80~85 h)、初孵仔鱼(0日龄)、开口前仔鱼(3日龄)的脂肪酸组成和含量进行了检测和分析。结果显示,菊黄东方鲀卵和鱼苗的水分含量随着个体发育出现升高趋势,而鱼苗总脂含量随着个体发育显著下降。各发育阶段的干样中检出8种饱和脂肪酸(SFA)、7种单不饱和脂肪酸(MUFA)和12种多不饱和脂肪酸(PUFA)。菊黄东方鲀未受精卵脂肪酸组成与其亲本卵巢非常相似;胚胎期的脂肪酸利用率高低顺序为SFA(15.08%)、MUFA(14.46%)、n6PUFA(10.20%)和n3PUFA(0.19%),以C16:0、C16:1、C18:1n9c和C18:2n6c为主要能量来源,n3PUFA被优先保存,特别是DHA得到完全保留;孵化后,在内源性营养阶段,仔鱼对n3PUFA利用迅速上升,仔鱼开口前的脂肪酸利用率高低顺序与胚胎期正好相反:n3PUFA(19.60%)、n6PUFA(16.98%)、SFA(13.50%)和MUFA(13.01%),以C18:2n6c、C22:5n3(DPA)、C20:5n3(EPA)、C22:6n3(DHA)、C18:1n9c和C16:0为主要能量来源,其中仔鱼对DHA实际利用量为最高(14.44 mg/g),仔鱼在开口前期n3PUFA(特别是DHA)被大量利用消耗。研究表明,菊黄东方鲀仔鱼发育需要消耗大量的n3PUFA(特别是DHA和EPA),并建议在菊黄东方鲀苗种培育开口阶段及时增加富含EPA和DHA饵料的投喂量,如海水的轮虫、藻类强化过的卤虫幼体,缓解苗种开口阶段成活率低下的问题。     

花鳗鲡成鱼肌肉脂肪酸组成分析

为给花鳗鲡肉质营养评价及饲料研制提供基础数据和理论分析依据,对花鳗鲡肌肉粗营养成分与脂肪酸组成进行了测定。测定结果:花鳗鲡肌肉的水分含量为68.79%,蛋白质含量为17.58%,脂肪含量为10.86%,其中C14∶0、C15∶0、C16∶0、C18∶0,C16∶0等饱和脂肪酸(SFA)的相对含量为27.6%,C16∶1、C18∶1、C20∶1、C18∶1等单不饱和脂肪酸(MUFA)的相对含量为47.04%,C16∶3n-3、C18∶3n-3、C20∶5n-3、C22∶6n-3等n-3多不饱和脂肪酸(n-3PUFA)的相对含量为9.4%,C18∶2n-6、C20∶4n-6、C18∶2n-6等n-6多不饱和脂肪酸(n-6PUFA)的相对含量为6.66%,多不饱和脂肪酸中DHA的相对含量为2.29%,EPA的相对含量为5.30%。分析结果显示,花鳗鲡肌肉中蛋白质和多不饱和脂肪酸含量非常高,属于优质的蛋白和脂肪源。     

延迟首次投喂对胭脂鱼仔鱼氨基酸和脂肪酸的影响

为考察饥饿及恢复摄食对胭脂鱼仔鱼氨基酸和脂肪酸的影响.在水温(19±0.5)℃下,对胭脂鱼仔鱼实施延迟首次投喂0、1、3、5、7、9和11d共7个处理,随后进行饱食投喂,分别在延迟处理结束时以及摄食后(19日龄和29日龄)取材对鱼体的含脂量、脂肪酸和氨基酸含量进行检测.结果如下:(1)随延迟首次投喂时间的增加,胭脂鱼仔鱼鱼体的脂肪含量呈显著下降趋势.在实验结束时(29日龄),各处理组仔鱼的脂肪含量均与对照组无显著性差异,表现出完全补偿效应.(2)胭脂鱼仔鱼在饥饿期间,主要以单不饱和脂肪酸作为能量代谢基质,按n-6＞n-9＞n-3顺序被先后利用,且C22∶6n-3 (DHA)优先于C20∶5n-3(EPA)被保存下来.同时,鱼体中DHA和ARA的百分含量与仔鱼体质量和含水率存在极显著相关关系.(3)随延迟首次投喂时间的增加,胭脂鱼仔鱼的丙氨酸、异亮氨酸、亮氨酸和组氨酸显著下降;天冬氨酸和谷氨酸显著上升;而甘氨酸、赖氨酸和精氨酸则呈先上升后下降的趋势.结果表明:胭脂鱼仔鱼对饥饿有较强的适应性,在饥饿初期以消耗脂类物质为主,当脂类物质趋于阈值,氨基酸开始被大量消耗;胭脂鱼仔鱼在饥饿后恢复摄食时,鱼体氨基酸的恢复比脂肪酸更慢.     

多个条斑紫菜品系采收期内脂肪酸组成、含量的变化分析

为探讨条斑紫菜不同栽培品系、不同采收期脂肪酸组成及含量的变化,本实验对10个栽培品系进行了跟踪测定分析,结果显示:条斑紫菜的脂肪酸组成稳定,与品系、采收期内季节性变化无关,但含量存在明显的差异。各品系的3个采收期的饱和脂肪酸(16∶0为主,包括13∶0、16∶0、18∶0)的相对含量约为20%;不饱和脂肪酸(以EPA为主,包括18∶1 n-9、18∶2 n-6、18∶3 n-3、20∶1 n-9、20∶2 n-7、20∶3 n-7、20∶4 n-6(AA)、20∶5 n-3(EPA))的相对含量为70%左右。在温度最低2月份的采收样品中,总脂肪酸和EPA含量最高,显示低温有利于条斑紫菜脂肪酸尤其是EPA的积累。另外,条斑紫菜富含以EPA为主的不饱和脂肪酸,在整个采收期内,样品中的n-6/n-3比值为4.9～7.7,符合WHO/FAO膳食推荐值。     

闽东海域繁殖期雌性棘头梅童鱼亲鱼不同组织的脂肪酸组成分析

为获知棘头梅童鱼亲鱼性腺发育后期脂类及脂肪酸蓄积特点,采用内标定量法,对性腺发育至Ⅳ期的雌性棘头梅童鱼亲鱼肌肉、肝脏和卵巢组织中的脂肪及脂肪酸含量进行了测定,并比较分析了3种组织中的脂肪酸组成。结果表明:雌性棘头梅童鱼亲鱼卵巢、肝脏和肌肉中脂肪的质量分数分别为(4.84±0.05)%、(2.66±0.05)%和(0.56±0.05)%,不同组织间具有显著性差异(P<0.05)。雌性棘头梅童鱼亲鱼的卵巢、肌肉和肝脏中分别检出29种脂肪酸,含量最高的饱和脂肪酸依次为C16∶0、C18∶0和C14∶0;含量最高的单不饱和脂肪酸依次为C16∶1、C18∶1n9c和C20∶1;含量最高的多不饱和脂肪酸依次为C22∶6n3(DHA)、C20∶5n3(EPA)和C20∶4n6(ARA)。从相对含量来看,肌肉中饱和脂肪酸的质量分数为(58.22±0.24)%,显著高于肝脏(52.71±0.24)%和卵巢(36.42±0.24)%(P<0.05);卵巢中单不饱和脂肪酸的质量分数为(23.78±0.09)%,显著高于肌肉(16.15±0.07)%和肝脏(10.79±0.05)%(P<0.05);卵巢中多不饱和脂肪酸质量分数为(39.79±0.19)%,显著高于肝脏(36.49±0.21) %和肌肉(25.63±0.19)%(P<0.05)。肌肉、肝脏和卵巢中EPA和DHA的总量依次升高,质量分数分别为(19.34±0.15)%、(26.59±0.16)%和(27.78±0.13)%。卵巢、肝脏和肌肉组织中的DHA/EPA分别为1.95、2.28和1.89,n-3系和n-6系多不饱和脂肪酸的比值分别为3.29、3.81和6.25。     

大鳍鳠产卵前后肌肉脂肪酸组成变化的研究

采用毛细管气相色谱法,对产卵前后大鳍鳠肌肉中的脂肪酸组成进行了测定。结果表明,大鳍鳠肌肉中脂肪酸种类丰富,含有22种脂肪酸,油酸(C18:1n-9)所占比例最高,其次为软脂酸(C16:0)、棕榈酸(C16:1n-7)、亚油酸(C18:2n-6),所占比例分别为22.38%~37.57%、18.86%~23.95%、7.00%~11.52%、7.46%~9.97%。EPA和DHA在大鳍鳠肌肉中占有较高的比例,EPA占总脂肪酸的5.39%,DHA占5.44%。在野生大鳍鳠产卵前后的22种脂肪酸中有8种饱和脂肪酸(SFA),6种单不饱和脂肪酸(MUFA)和8种多饱和脂肪酸(PUFA),大鳍鳠肌肉中脂肪酸在产卵前后表现出差异。     

野生与人工养殖牙鲆亲鱼不同组织脂肪酸的比较

为研究脂肪酸对牙鲆繁育性能的影响, 采用生物化学方法, 对野生和养殖牙鲆亲鱼肌肉、肝脏及卵中脂肪酸组成分别进行测定。结果表明: (1) 牙鲆肌肉、肝脏和卵中脂肪含量大小关系为肝脏>卵>肌肉。野生亲鱼肌肉和卵中脂肪含量显著低于养殖亲鱼(P<0.05), 肝脏脂肪含量与养殖亲鱼无显著差异; (2) 牙鲆亲鱼3种组织中均检测出21种脂肪酸。野生亲鱼肌肉中饱和脂肪酸(SFA)与养殖亲鱼无显著差异, 单不饱和脂肪酸(MUFA)显著低于养殖亲鱼(P<0.05)。肝脏和卵中SFA显著高于养殖亲鱼(P<0.05), MUFA与养殖亲鱼无显著差异; (3) 野生亲鱼肌肉、肝脏和卵中高不饱和脂肪酸(PUFA)的含量, 尤其是肝脏和卵中C20:5n-3(EPA)、C22:6n-3(DHA)的含量均显著低于养殖亲鱼(P<0.05), 但肌肉和卵中的C20:4n-6(ARA)含量明显高于养殖亲鱼(P<0.05); (4) 野生牙鲆亲鱼肌肉、肝脏和卵中n-3/n-6 PUFA及EPA/ARA显著低于养殖亲鱼(P<0.05), 肝脏中DHA/EPA显著高于养殖亲鱼(P<0.05), 但野生亲鱼肌肉和卵中的DHA/EPA与养殖亲鱼无显著差异。比较结果说明, DHA、EPA和ARA等PUFA是与牙鲆繁殖性能密切相关的重要脂肪酸。在牙鲆亲鱼养殖过程中, 除了提供牙鲆亲鱼足够的脂肪酸营养外, 也应注意各种脂肪酸, 尤其是PUFA中各种脂肪酸之间的添加比例, 从而保证亲鱼的繁殖性能及卵和仔鱼的质量。     

兴凯湖翘嘴鲌野生和养殖群体脂肪酸及相关血液指标的比较

对3龄、4龄和5龄兴凯湖翘嘴鲌(Culter alburnus)野生和养殖群体肌肉脂肪含量、脂肪酸含量以及部分血液生化指标进行了分析比较.结果表明:在兴凯湖翘嘴鲌野生与养殖群体肌肉中均检测到18种脂肪酸,以油酸、亚油酸和棕榈酸为主.野生群体肌肉饱和脂肪酸(SFA)、多不饱和脂肪酸(PUFA)、二十碳五烯酸(EPA)和二...     

黄颡鱼胚胎发育早期脂肪酸变化的研究

采用生物化学方法测定了黄颡鱼成熟卵及早期胚胎的脂肪酸组成.试验结果表明,在成熟卵和早期胚胎中占主要比例的脂肪酸为:软脂酸(C_(16∶0))、硬脂酸(C_(18∶0))、棕榈油酸(C_(16∶1n-7))、油酸(C_(18∶1n-9))、亚油酸(C_(18∶2n-6)),此外,成熟卵中还含有较高比例的亚麻酸(C_(18∶3n-3)).胚胎对不同脂肪酸的利用因胚胎发育时期的不同而有差异,多不饱和脂肪酸(PUFA)在囊胚期、原肠期和器官形成期占有较高的比例;单不饱和脂肪酸(MUFA)在卵裂期和囊胚期所占比例升高较快;饱和脂肪酸(SFA)是胚胎发育过程中能量的主要提供者,在原肠期、神经胚期和器官形成期存在着活跃的代谢,为这些时期的发育提供能量.与成熟卵相比,黄颡鱼的受精卵在脂肪酸组成上显示了不同.PUFA比例明显减少,而SFA的比例迅速增加,表明在卵粒受精后,胚胎内开始了活跃的代谢过程.     

罗非鱼不同组织脂肪酸含量的分析

分别取罗非鱼(Oreochromis niloticus)的肉、脂肪、肝、眼和皮等组织,用氯仿-甲醇(2∶1,v/v)提取,以C17∶0为内标物,利用气相色谱-质谱法(GC/MS)分析了各组织脂肪酸种类及含量。结果显示:罗非鱼各种组织中含有16种脂肪酸,富含多不饱和脂肪酸。脂肪组织中的脂肪酸含量最高,其次是眼睛、肝脏、鱼肉和鱼皮;各组织中饱和脂肪酸(SFA)含量为202~8869 mg/kg,主要为棕榈酸(C16∶0)和硬脂酸(C18∶0);单不饱和脂肪酸(MUFA)含量为293~11219 mg/kg,主要为棕榈油酸(C16∶1)和油酸(C18∶1);多不饱和脂肪酸(PUFA)含量为362~8293 mg/kg,主要是亚油酸(C18∶2)、亚麻酸(C18∶3)和二十二碳六烯酸(DHA,C22∶6);n-6/n-3为1.20~2.46。     

Dynamics of total lipids and fatty acids during embryogenesis and larval development of Eurasian perch (Perca fluviatilis)

Total lipid and fatty acid compositions were determined during embryogenesis and larval development in Eurasian perch (Perca fluviatilis). During embryonic development, perch did not catabolize lipids and fatty acids as an energy source. However, during larval development, there was an exponential relationship between the decrease in total lipids and the duration of starving (r ²=0.9957) and feeding (r ²=1). The duration of the starving period (10 days post hatching) was shorter than the feeding period (35 days post hatching). In both starved and fed larvae, there is an apparent preference in utilization of polyunsaturated fatty acids followed by monounsaturated fatty acids. Saturated fatty acids were utilized by neither fed perch larvae nor by starved perch larvae. In starved larvae, palmitoleic 16:1(n-7) and oleic 18:1(n-9) acids were the preferentially monounsaturated fatty acids catabolized and their contribution as energy source from total fatty acids catabolized over the first week was 37.6%. In fed larvae, these 2 nutrients were also the most monounsaturated fatty acids utilized as energy source and possibly also as precursors for others monounsaturated fatty acids biosynthesis. During the same period and among (n-6) polyunsaturated fatty acids, starved perch utilized less linoleic 18:2(n-6) and arachidonic 20:4(n-6) acids than fed larvae despite the fact that the starved perch were in more unfavorable nutritional conditions. In the case of (n-3) fatty acids, starved larvae utilized more linolenic acid 18:3(n-3) and less eicosapentaenoic 20:5(n-3) acid and docosahexaenoic 22:6(n-3) acid than fed perch. Starved larvae probably spared 20:5(n-3) and 22:6(n-3) for physiological functions.     

An Invasive Shrimp Species,Machrobrachium nipponense,in Anzali Wetland Demonstrated a Potential Source for Commercial Fishing

ABSTRACT

The proximate content, fatty acids composition, and nutritional quality index (NQI) of Macrobrachium nipponense at three habitats in the Anzali wetland in Iran were investigated as a potential source for human consumption. The highest amounts of protein, lipid, ash, and energy contents in muscle of M. nipponense were showed in autumn (non-reproductive season) (p < 0.05). The main monounsaturated fatty acids (MUFA) were oleic acid (C18:1 n9 C, C18:1 ω9 T) and palmitoleic acid (C16:1). Moreover, the main polyunsaturated fatty acids (PUFA) were docosahexaenoic acid (DHA, C22:6 n3), eicosapentaenoic acid (EPA, C20:5n3), arachidonic acid (ARA, C20:4 n6), linoleic acid (LA, C18:2 ω6), and α-linolenic acid (ALA, C18:3 n3). The predominant individual saturated fatty acid (SFA) was palmitic acid (0.07–13.4%), while oleic acid (14.7–26.3%), EPA (3.5–12.7%) and linoleic acid (0.04–14.9%) represented the most abundant individual MUFA and PUFA in M. nipponense. The highest mean value of EPA+DHA (14.0), n3/n6 (1.02), ΣMUFA/ΣSFA (1.05), ΣPUFA/ΣSFA (1.04), and EPA/DHA (3.8) ratios in M. nipponense was in autumn. The range of atherogenicity index (AI) and thrombogenicity index (TI) was much lower, from 0.42 to 0.6 and from 0.33 to 0.57, respectively, in terms of season. The results obtained in the present study show that M. nipponense is an excellent nutritional food source in the Anzali wetland.     

Influence of egg lipids and fatty acids on egg viability, and their utilization during embryonic development of spotted wolf-fish, Anarhichas minor Olafsen

The changes in egg lipids and fatty acid compositions that occur during embryonic development of spotted wolf‐fish, Anarhichas minor, were examined by monitoring individual egg batches from the time of spawning (egg stripping) until hatching. The lipids, present as 3.7±0.1% of the wet mass of the freshly stripped eggs, contained high percentages of monoenes (monounsaturated fatty acids (MUFAs), ca. 33%) and polyenes (ca. 43%) and approximately 20% saturated fatty acids (SFAs). The fatty acid profiles were dominated by a small number of fatty acids. The major SFA was 16:0 (ca. 14%), the dominant MUFA was 18:1 n‐9 (ca. 21%), and among the polyenes, the n‐3 highly unsaturated fatty acids (HUFAs) 22:6 n‐3 docosahexaenoic acid (DHA) and 20:5 n‐3 eicosapentaenoic acid (EPA) were present in the highest concentrations (EPA, ca. 16%; DHA, ca. 19%). The n‐6 HUFA 20:4 n‐6 arachidonic acid (AA) was present as ca. 1% of the total fatty acids in the freshly stripped eggs. This resulted in an AA:EPA of ca. 0.07, which is lower than reported for eggs of many other fish species. As embryonic development progressed, the percentage contribution of AA to the total fatty acids almost doubled. There were also increases in the relative proportions of SFAs (due mainly to an increase in the percentage of 16:0 to ca. 16% at hatch) and DHA (to ca. 23%), and there was a corresponding decrease in the percentage of MUFAs (mostly brought about by a decrease in the percentage of 18:1 n‐9 to ca. 18% at hatch). The most marked changes occurred towards the end of incubation. The percentage of EPA changed little during incubation. This implies that there was selective retention of DHA, 16:0 and AA, and these fatty acids were probably incorporated into cell membranes. MUFAs, particularly 18:1 n‐9, seem to have been catabolized to provide energy for the developing embryo, and some EPA also seems to have been utilized as an energy source. Survival of eggs to the eyed stage (range ca. 10–80%) and to hatch (ca. 5–75%) was negatively correlated with the %AA, %EPA and AA:DHA of the freshly stripped eggs. There was also a negative correlation between AA:EPA and egg survival, which implies that there is not a universal requirement for a high AA:EPA to ensure high rates of survival of fish eggs.     

俄罗斯鲟鱼卵与西伯利亚鲟鱼卵的营养成分比较

采用生化方法分析了俄罗斯鲟(Acipenser gueldenstaedti)和西伯利亚鲟(Acipenser baerii)鱼卵的营养成分,并对两者的营养品质进行了比较。结果表明:这两种鱼卵的水分含量平均值为62.83%～64.88%,粗蛋白平均含量为20.38%～20.77%,粗脂平均含量为10.41%～13.58%。统计分析表明,俄罗斯鲟鱼卵的粗脂肪含量显著低于西伯利亚鲟鱼卵,而粗蛋白、水分和灰分含量略高于西伯利亚鲟鱼卵。俄罗斯鲟鱼卵和西伯利亚鲟鱼卵的氨基酸组成一致,均含有17种氨基酸,必需氨基酸指数(EAAI)分别为50.66和44.43。两种鲟鱼卵的脂肪酸中,均以C16∶0、C18∶2n6c和DHA为主要脂肪酸,三者总的质量分数达50%左右;而二十碳五烯酸(EPA)与二十二碳六烯酸(DHA)的总量俄罗斯鲟鱼卵高于西伯利亚鲟鱼卵,在两种鱼卵中含量分别为19.47%和16.83%。分析结果表明,两种鲟鱼卵均含有丰富的各种营养成分,但从粗蛋白、必需氨基酸(EAA)、DHA和n3PUFA含量来看,俄罗斯鲟鱼卵的营养价值优于西伯利亚鲟鱼卵。