72 resultados para DMSO
Resumo:
A simple and convenient protocol for the cryopreservation of the flounder (Paralichthys olivaceus) sperm was established for "on the spot" cryopreservation of large quantities of semen. The use of three cryoprotectants, dimethyl sulphoxide (DMSO), glycerol (Gly) and methanol was tested in the method. The percentage of motile sperm present in semen after it had been frozen and thawed in the presence of DMSO, Gly or methanol was 60.5 +/- 3.6, 79.17 +/- 4.5 and 13.25 +/- 4.7%, respectively. The fertilization rates of this sperm were 67.06 +/- 15.1, 76.20 +/- 10.0 and 44.93 +/- 22.6%, while the hatching rates of eggs fertilized with this sperm were 37.40 +/- 8.3, 48.18 +/- 25.7 and 23.35 +/- 10.8%, respectively. It was found that Gly and DMSO were better cryoprotectants than methanol, with Gly giving the best overall results. Under scanning electron microscopy, it could be seen that while the majority of the frozen-thawed sperm remained morphologically normal, some exhibited lost or dilated mitochondria, swollen mid-pieces, broken tails, or damaged cell membrane, which probably caused the decrease in motility and fertility of the frozen-thawed sperm. (C) 2003 Elsevier Science Inc. All rights reserved.
Resumo:
In this study several parameters critical to the success of cryopreserving Sydney rock oyster (Saccostrea glomerata) larvae were investigated. They were: (1) cryoprotectants (10% dimethyl sulfoxide and 10% propylene glycol). (2) freezing protocols (with or without the seeding step). (3) larval concentrations (1,000, 3,000, 5,000, 10,000, 30,000 individuals mL(-1)). and (4) larval ages (6, 12, 24, 48 and 96 h old). The survival rates were determined as percentages of postthaw larvae performing active movements for the 6 and 12 h larvae or active cilia movement for the 24, 48 and 96 h larvae. Analyses showed that the difference in survival rates between different age classses was significant in all the experiments conducted, with the maximum survival rate being achieved in the 24-h-old larvae the postthaw survival rates of larvae cryopreserved with 10% dimethyl sulfoxide (93.1 +/- 0.2%) were significantly higher (P < 0.001) that those with 10% propylene glycol (81.5 +/- 0.4%). Differences in postthaw survival rates between different concentrations (1,000 30,000 individuals mL(-1)) were not significant within each of the three larval age classes (6-, 12-, and 24-h-old ) used.
Resumo:
鱼类胚胎由于其自身结构特征:体积大、含水量高、多室结构等,迄今超低温保存尚未成功。超低温保存过程中所造成的冷冻损伤是制约鱼类胚胎超低温保存成功与否的关键,具体表现为渗透压影响、抗冻剂毒性、冰晶损伤等。系统研究并阐明鱼类胚胎冷冻损伤机理,是成功建立鱼类胚胎超低温保存技术的基础。本论文主要针对胚胎对渗透压的耐受性、抗冻剂对胚胎的渗透性、降温速率对胚胎内外冰晶形成温度的影响等冷冻损伤机理进行了系统研究,主要研究结果如下: 1.通过检测胚胎在不同浓度人工海水(0%、25%、50%、75%、1×、2×、3×、4×,渗透压范围0~3740 mOsm/kg)中的孵化率,确定了真鲷不同发育时期胚胎对渗透压的耐受范围,以及心跳期胚胎浸泡不同时间对渗透压的耐受范围。结果显示:①真鲷2-4细胞期、原肠期、10-14体节期胚胎、心跳期和出膜前期胚胎孵化率>50%时渗透压的范围依次为:919~1391 mOsm/kg、919~1391 mOsm/kg、462 ~1391 mOsm/kg、232~1878 mOsm/kg和692~1391 mOsm/kg,表明心跳期胚胎对渗透压变化的耐受范围最广;②在不同浓度人工海水中分别浸泡10 min、30 min、1 h、5 h和10 h后,真鲷胚胎孵化率无显著变化的渗透压范围分别为0~2804 mOsm/kg、0~1878 mOsm/kg、232~1391 mOsm/kg、232~1391 mOsm/kg和919~1391 mOsm/kg;结果表明心跳期胚胎对渗透压的耐受范围随浸泡时间的延长而减小。 2.采用毛细管电泳技术检测胚胎内部DMSO的浓度,并且分析了胚胎孵化率和胚胎内部DMSO的浓度随浸泡时间变化与外部抗冻剂的关系。结果表明胚胎孵化率随胚胎外部抗冻剂溶液浓度和浸泡时间的增加而降低;胚胎内部DMSO浓度随胚胎外部抗冻剂溶液浓度和浸泡时间的增加而增加。对胚胎孵化率(y1)随抗冻剂溶液浓度(x)的变化进行一元三次多项式回归,当浸泡时间分别为10 min、30 min和60 min时,回归方程依次为:y1 = -2832.7x3 + 575.01x2 - 37.011x + 99.641(R2 = 0.9722);y1 = 30288x3 - 16322x2 + 2077.3x + 27.603(R2 = 0.9876);y1 = 16052x3 - 5985.2x2 - 32.696x + 119.6(R2 = 0.9124)。对胚胎内部DMSO浓度(y2)随抗冻剂溶液浓度(x)的变化进行回归,当浸泡时间分别为10 min、30 min和60 min时,回归方程依次为:y2 = 0.2584e6.7294x(R2 = 0.9876);y2 = 0.2521e10.964x(R2 = 0.9644);y2 = 0.4054e10.95x(R2 = 0.8954)。 3. 利用低温显微镜观察了不同降温速率(20、40、60、80、100、120℃/min)对胚胎内外冰晶形成温度的影响。胚胎外部冰晶形成温度(TEIF)随降温速率的增加显著下降,在降温速率大于80℃/min之后,TEIF随降温速率增加而降低的幅度减小;胚胎内部冰晶形成温度(TIIF)在降温速率小于80℃/min 时随降温速率的升高而降低,在降温速率大于80℃/min 时随降温速率的升高而升高;胚胎内外冰晶形成温度差值(TEIF - TIIF)在降温速率小于80℃/min时随降温速率的升高而增大,在降温速率大于80℃/min时随降温速率的升高而减小。 4. 在低温显微镜下观察了真鲷胚胎低温保存中有复活胚胎记录的保存方法在冷冻解冻过程中的冰晶形成过程,结果表明:①在冷冻过程中,玻璃化法冷冻的胚胎的内部冰晶形成温度(-53.70,-64.33℃)显著低于程序降温法(-17.51,-21.40℃);而且在玻璃化法冷冻的胚胎内部冰晶形成温度高于外部冰晶后形成(-70.30℃),程序降温法中则相反,胚胎内部冰晶形成温度显著低于外部冰晶形成温度(-4.93,-5.00℃);玻璃化法中,40%PG冷冻的胚胎外部溶液出现玻璃化现象,其他组均未出现;②在解冻过程中,各组均出现重结晶现象;解冻后,玻璃化法的胚胎完整率(62.82%)远高于程序降温法(9.21%)。
Resumo:
种质问题是养殖健康发展的基础。在鱼类养殖中,卵子和精子的质量直接关系到受精、胚胎发育,仔稚鱼发育以及幼鱼生长等一系列过程。本论文针对大西洋庸鲽和大西洋鲑的配子质量进行研究。研究内容涉及大西洋庸鲽精子冷冻保存方法;促性腺激素释放激素类似物(GnRHa)使用对其精子冷冻保存效果、以及脂肪酸组成的影响;野生和驯养大西洋鲑卵子在脂肪酸、类胡萝卜素、矿物盐方面的差异比较。 精子冷冻保存通过提高对精子的利用效率,进而对于种质改良,推进鱼类养殖科研和生产具有重要意义。本实验建立了大西洋庸鲽精子大容量冷冻保存方法。八种抗冻剂冷冻保存实验结果表明:10% 及15% DMSO配以 HBSS 或KS 的抗冻剂组合冷冻保存效果最佳,4 mL体积冷冻保存可获得与1.6 mL同样的保存效果。 在繁殖季节后期注射GnRHa激素缓释剂,可获得质量稳定的大西洋庸鲽精液,将激素注射方法与精子冷冻保存方法相结合对于提高雄鱼利用率,扩大生产规模具有重要实用价值。本项研究分三个时间采集注射GnRHa激素后的雄鱼精子以及同期未注射激素的雄鱼精子,对所有精子样品使用同样的方法进行冷冻保存,检测冷冻保存后解冻精子的受精率与活力。结果表明,激素注射与否对于冷冻保存后精子的受精率和活力无显著影响,两类冷冻精液均达到鲜精水平。实验结果还表明,注射激素14天后的精子的密度显著的降低。说明GnRHa激素的使用可以显著降低精子密度,但不会影响精子的冷冻保存效果。 本相研究同时对注射GnRHa 缓释激素和未注射GnRHa 缓释激素的大西洋庸鲽精液脂肪酸成分进行分析,以检测该激素使用对精子生化组分的影响。结果表明激素的使用对在DHA (22:6n-3,二十二碳六烯酸)、EPA(20:5n-3,二十碳五烯酸)、AA(20:4n-6,花生四烯酸)等重要脂肪酸,不饱和脂肪酸、饱和脂肪酸以及n-3、n-6等重要种类的脂肪酸总量及其比例没有显著影响。精液脂肪酸中DHA含量最高,约占25%;PUFA约为44%。 作为世界性的重要养殖品种,野生和驯养大西洋鲑在形态、生化组成以及遗传 等方面表现出的差异被广泛关注。本论文,对野生和驯养大西洋鲑受精卵关键生化成分进行分析,通过与野生受精卵比较阐明驯养受精卵的质量状况,为亲鱼营养需求提供指导依据。本实验中野生配子和驯养配子的受精率没有显著差异,但重要脂肪酸组成、类胡萝卜素以及矿物盐含量都存在多方面显著差异。两类受精卵脂肪酸中含量最高的依次为18:1n-9(油酸)、DHA(二十二碳六烯酸)、16:0(棕榈酸)、EPA(二十碳五烯酸)。野生受精卵的单不饱和脂肪酸总量显著高于驯养受精卵,而多不饱和脂肪酸(PUFA)比例显著低于驯养的受精卵。在主要必需不饱和脂肪酸(EFA)中,DHA和EPA在野生受精卵中的比例高于驯养受精卵,AA(花生四烯酸)低于驯养受精卵。野生受精卵虾青素(Ax)的含量低于驯养受精卵而鸡油菌素(Cx)含量高于驯养受精卵。野生受精卵中多种矿物盐的含量(铝、铜、铁、硒和锌)含量显著高于驯养的受精卵。差别最大的为铜。诸多方面的差异表明,野生亲鱼与驯养亲鱼产出的卵子确实存在显著差异,因此关注亲鱼的营养极为重要。
Resumo:
从1949年以来经过近五十年的发展,超低温保存种质细胞技术已经趋于成熟,特别是在家畜推广良种化的过程中发挥重要作用。对海洋动物种质细胞保存研究的范围主要集中在鲑鳟鱼类和牡蛎等少数几种海洋生物上。本研究结合“国家自然科学基金”研究项目,进行了三种贝类和两种鱼类精子的超低温保存实验,得到了它们在液氮(-196 ℃)条件下的适宜保存条件。栉孔扇贝(Chlamys farreri)冻精解冻后复苏比例、受精率和孵化率最高可达到49.39%、42.06%和12.15睦栉孔扇贝精子超低温保存时发生冷冻伤害的温度范围在-30 ℃~-60 ℃;其低温保存的最适降温速率为20 ℃/min;使用抗冻剂二甲基亚砜(DMSO)的最适浓度为5 ℃,其保存效果优于甘油;样品保存的最佳体积为0.6ml~1ml;解冻精子的最适水温为35 ℃,50 ℃次之,20 ℃最差;用自然海水激活解冻后精子的效果好于低盐度溶液;在0 ℃进行预处理平衡时间不宜太长;在抗冻液中加入蛋黄对保存效果没有改善,并且会对冻精的孵化率有抑制作用;用20 ℃/min和5%DMSO冷冻精子,液氮中保存栉孔扇贝精子55天后其复苏比例达到42.17%。超低温保存紫贻贝(Mytilus galloprovincialis Lamarck)精子,解冻后其复苏比例、受精率和孵化率最高可达到41.63%、69.52%和54.74%。保存紫贻贝精子最适降温速率为5 ℃/min,发生冻伤的温度范围是-20 ℃~-60 ℃;使用抗冻剂DMSO的保存效果好于甘油,且使用抗冻剂DMSO的最适浓度为15%;利用自然海水激活冻精效果好于低盐度或高pH值的溶液;样品体积(在0.2~1ml之间)对保存效果没有影响;采用15%DMSO和5 ℃/min的降温速率处理精子,液氮中保存90天后复苏比例仍达到41.8%。保存菲律宾蛤仔(Ruditapes philippinarum (Adams and Reeve))精子的最适降温速率为5 ℃/min,发生冻伤的温度范围是-30 ℃~-60 ℃;抗冻剂DMSO的保存效果好于甘油,也用DMSO与甘油混合使用,使用抗冻剂DMSO的最适浓度为10%;利用自然海水激活冻精效果好于低盐度或高pH的溶液;样品体积(在0.2%~1.6ml之间)对保存效果有显著影响。冷冻保存后精子复苏比例、受精率和孵化率最高达到40.84%、68.87%和47.17%;以最适降温速率和抗冻剂浓度处理精子,并在液氮中保存36天后冻精复苏比例仍可以达到38.54%。黑鲷(Sparus macrocephalus)精子经过超低温保存后复苏率、存活率最高可以达到61.37%和61.4。保存黑鲷精子时发生冷冻伤害的温度范围是-20 ℃~-60 ℃,适宜的降温速率为20 ℃/min;使用抗冻剂DMSO的适宜浓度为20%;样品体积对保存效果有相关性;利用自然海水激活冻精效果好于低盐度或高pH值的溶液;使用20%DMSO和20 ℃/min降温速率处理,在液氮中保存黑鲷精子66天后解冻,其复苏率和存活率分别为59.81%和58.45%。在液氮中保存真鲷(Pagrosomus major)精子时发生冷冻伤害的温域为-30 ℃~-60 ℃,适宜的降温速率为20 ℃/min;使用抗冻剂DMSO的适宜浓度为20%;采用低盐度或高pH值的溶液激活冻精的效果不如自然海水。真鲷冻精的复苏率和存活率最高可达到50.73%和62.5;以20 ℃/min和20%DMSO处理真鲷精子,保存在液氮中46天后冻精复苏率和存活率为50.63%和61.02%。通过对多种贝类和鱼类精子的超低温保存实验,不仅获得超低温保存基本条件,并且通过显微镜观察结合前人的研究,对产生冻伤的原因和保护的机理提出了一个模式。
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本文对真鲷心跳期胚胎对5种常用渗透性抗冻剂(DMSO、甘油、甲醇、丙二醇、乙二醇)和3种非渗透性抗冻剂(PVP、PEG-8000、蔗糖)的耐受性进行了研究。渗透性抗冻剂分6个浓度梯度(5%;10%;15%;20%;25%;30%)和3个时间组(10min;30min;1h)。非渗透性抗冻剂中,PVP、PEG-8000分3个浓度梯度(5%、10%、15%)和2个时间组(10min、30min),蔗糖为4个浓度梯度(5%、10%、15%、20%)和2个时间组(10min、30min)。实验结果表明,在渗透性抗冻剂组中,浓度为5%的处理组的孵化率(>90%)与对照组差异均不显著,随着抗冻剂浓度增大及处理时间的延长,真鲷心跳期胚胎的孵化率显著下降(P<0.05),在最高浓度的最长处理时间中胚胎孵化率均降到了0。总体上,真鲷心跳期胚胎对五种渗透性抗冻剂的耐受性从小到大依次为:甲醇 < 甘油 < 乙二醇 < DMSO < 丙二醇。对影响胚胎孵化率的三个因素(抗冻剂、浓度、时间)进行的因素效应分析结果表明,三种因素对孵化率的影响显著(P<0.05),并且浓度效应 > 时间效应 > 抗冻剂效应。在非渗透性抗冻剂组中,蔗糖组胚胎孵化率未呈显著变化;PVP组随着浓度及时间的增大,孵化率显著下降(P<0.05);PEG-8000组随着浓度增大孵化率显著下降(P<0.05),但在两个时间组间差异不显著。相同处理情况下PEG-8000对真鲷心跳期胚胎的毒性要小于PVP。因素效应分析比较结果表明仅时间效应不显著,且抗冻剂效应 > 浓度效应 > 时间效应。 对所用各种抗冻剂进行了渗透压测量,实验中使用的渗透性抗冻剂(5%-30%)的渗透压值在959-7980mOsm/kg之间,均高于使用海水的渗透压值(919mOsm/kg);使用的非渗透性抗冻剂的渗透压值在316-1040mOsm/kg之间,除20%蔗糖渗透压值(1040mOsm/kg)高于海水外,其他非渗透性抗冻剂的渗透压值均要低于海水。对孵化率与相应的溶液渗透压值进行相关回归分析结果表明,渗透性抗冻剂的渗透压与孵化率呈显著的负相关(P<0.05),而非渗透性抗冻剂的渗透压与孵化率相关不显著。渗透性抗冻剂组的回归分析结果表明,二次方程的曲线拟合度最高,得到的回归方程分别为:Y10min = -2×10-8X2 10min - 6×10-5 X 10min + 1.5635 (R2 = 0.713),Y30min= 5×10-8X2 30min-0.0007 X 30min + 2.097(R2 = 0.681),Y1h = 7×10-8X2 1h-0.0008 X 1h+ 2.0397(R2= 0.725)。 在真鲷胚胎对抗冻剂耐受性实验的基础上,挑选五种抗冻剂--10%DMSO、5%甘油、10%甲醇、20%丙二醇、10%乙二醇,浸泡真鲷心跳期胚胎30min后,分别以超速(130℃/min)、快速(20℃/min)、慢速(3℃/min)的速度降温并使用低温显微镜进行观察,依次记录Toif(油球结冰)、Teif(胚胎外部结冰)、Tiif(胚胎内部结冰)等结冰点,Toif值在-9~-23℃之间;Teif值在-21~-35℃之间;Tiif值在-21~-52℃之间。结冰顺序为先油球结冰,然后胚胎外部结冰随之内部马上瞬间变黑形成内部冰晶。随着降温速度的提高,各结冰温度值显著下降。各抗冻剂之间的Teif及Tiif值不同,Toif值之间没有显著差异。对两种玻璃化冷冻方法进行模拟观察,发现胚胎冰晶形成的顺序与非玻璃化过程不同--先内部结冰然后逐渐蔓延至外部形成外部冰晶,而且模拟玻璃化的内部结冰温度Tiif值(-52.56℃)显著(P<0.05)低于使用低浓度的同种抗冻剂超速降温组的Tiif值(-40.11℃)。在快速及慢速降温组中,20%丙二醇组的Tiif要显著的低于其他组(P<0.05);在超速降温中,甲醇组的Tiif值要显著的低于其他组(P<0.05)。在Tiif小于30℃的实验组中获得形态完整胚胎的比例平均仅有30.77%;在Tiif大于30℃的实验组中获得形态完整胚胎的平均比例高达70.37%,模拟玻璃化组达到100%。各抗冻剂之间,复温后胚胎形态完整率10%甲醇组最高(77.78%);其次依次为10%乙二醇(66.67%)、20%丙二醇(55.56%)和10%DMSO(55.56%);5%甘油组最低(11.11%);推测甲醇的对胚胎的渗透效果要好于其他组。综上推测:使用丙二醇、甲醇作为抗冻剂以及玻璃化冷冻保存方法对真鲷心跳期胚胎超低温保存也许较为合适。 我们对低温保存的真鲷精子核DNA损伤进行了研究以期为下一步胚胎遗传物质稳定性研究提供参考依据。研究方法为单细胞凝胶电泳(SCGE),针对研究对象,在实验过程中对传统的碱性单细胞凝胶电泳在铺胶方法、电泳条件等进行了改进。对精子细胞进行预处理,在碱性电泳液中使核DNA双链解链变性后电泳,EB染色lOmin后,在荧光显微镜下观察,每次随机观察50个左右的核DNA。结果表明,对荧光显微镜下观察到的精子核按彗尾长度及荧光强度划分等级,出现损伤的精子核DNA的损伤程度主要为轻度损伤和中度损伤,很少见有完全损伤的真鲷精子核。经5%、10%、18%、20%、25%、30%DMSO冷冻保存后的精子彗星率分别为33.47% ± 8.95%; 35.91% ± 19.44%; 48.95% ± 8.90%; 43.33% ± 11.19%; 55.80% ± 38.94%。鲜精彗星率为31.43 % ± 2.68%。对比真鲷冷冻精液与新鲜精液的精子DNA的损伤状况,表明仅用30% DMSO冷冻精子DNA损伤状况与鲜精差异显著(P<0.05)。 综上所述,渗透性抗冻剂对胚胎的毒性与其渗透压值呈显著的负相关关系。丙二醇对真鲷心跳期胚胎毒性最小,甲醇较其他抗冻剂能更好的渗透入胚胎;玻璃化方法能显著降低Tiif值并能更好的保持超低温保存后胚胎的形态完整性,因此,使用丙二醇、甲醇作为抗冻剂以及玻璃化冷冻保存方法对真鲷心跳期胚胎超低温保存也许较为合适。常规使用的用于超低温保存真鲷精子的DMSO(浓度<15%)不会对精子核物质稳定性造成明显影响。由于胚胎较精子结构要复杂许多,对于真鲷胚胎损伤机理的研究还有大量工作可以开展。
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The objectives were to assess motility, fertilizing capacity, structural integrity, and mitochondrial function in fresh versus frozen-thawed (15% DMSO was used as a cryoprotectant) sperm from red seabrearn (Pagrus major). Mean (+/- S.D.) rates of motility, fertilization and hatching of frozen-thawed sperm were 81.0 +/- 5.4, 92.8 +/- 1.9, and 91.8 +/- 5.2%, respectively; for fresh sperm, they were 87.5 +/- 7.7, 95.8 +/- 2.4, and 93.8 +/- 4.2%. Although motility was lower in frozen-thawed versus fresh sperm (P < 0.05), there was no effect (P > 0.05) of cryopreservation on fertilization or hatching. Based on scanning and transmission electron microscopy, 77.8 +/- 5.6% of fresh sperm had normal morphology, whereas for frozen-thawed sperm, 63.0 +/- 7.2% had normal morphology, 20.6 +/- 3.1% were slightly damaged (e.g. swelling or rupture of head, mid-piece and tail region as well as mitochondria), and 16.4 +/- 4.2% were severely damaged. Sperm were stained with propidium iodide and Rhodamine 123 to assess plasma membrane integrity and mitochondrial function, respectively, and examined with flow cytometry. For fresh sperm, 83.9% had an intact membrane and functional mitochondria, whereas for frozen-thawed sperm, 74.8% had an intact membrane and functional mitochondria, 12.7% had a damaged membrane, 9.9% had nonfunctional mitochondria, and 2.6% had both a damaged membrane and nonfunctional mitochondria. In conclusion, ultrastructure and flow cytometry were valuable for assessment of frozen-thawed sperm quality; cryopreservation damaged the sperm but fertilizing ability was not significantly decreased. (c) 2007 Elsevier Inc. All rights reserved.
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In the present study, the quality of post-thaw sperm of red seabream Pagrus major frozen with 6-24% DMSO was investigated. The motility, average path velocity and fertilizing capacity of fresh and their corresponding post-thaw sperm were examined for evaluation of the post-thaw sperm motion characteristics and its association with fertilizing capacity. An analysis of sperm motility before and after cryopreservation has been performed using computer-assisted sperm analysis (CASA). For post-thaw sperm frozen with 12-21% DMSO, the percentages of motile sperm were not significantly (P > 0.05) changed 10 s after activation. Moreover, the main motility pattern and swimming velocity of the motile post-thaw sperm were not significantly (P > 0.05) changed and the progressive linear motion was still the dominant pattern. However, the total motility of post-thaw sperm (72.3 +/- 6.3%) 30 s after activation was (P < 0.05) lower than the corresponding fresh sperm (82.7 +/- 7.2%). Additionally, the fertilizing capacity of post-thaw sperm was investigated with a standardized sperm to egg ratio 500:1. There is a linear regression relationship between the percentage of motile post-thaw sperm and fertilizing capability. These data demonstrate that 12-21% DMSO can provide good protection to the sperm during the freezing-thawing process. (c) 2006 Elsevier B.V. All rights reserved.
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The objectives were to investigate the effect of cryoprotectants on the hatching rate of red seabream embryos. Heart-beat embryos were immersed in: five permeable cryoprotectants, dimethyl sulfoxide (DMSO), glycerol (Gly), methanol (MeOH), 1,2-propylene glycol (PG), and ethylene glycol (EG). in concentrations of 5-30% for 10, 30, or 60 min; and two non-permeable cryoprotectants: polyvinylpyrrolidone (PVP), and sucrose (in concentrations of 5-20% for 10 or 30 min). The embryos were then washed and incubated in filtered seawater until hatching occurred. The hatching rate of the embryos treated with permeable cryoprotectants decreased (P < 0.05) with increased concentration and duration of exposure. In addition, PG was the least toxic permeable cryoprotectant, followed by DMSO and EG, whereas Gly and MeOH were the most toxic. At a concentration of 15% and 30 min exposure, the hatching rate of the embryos immersed in PG was 93.3 +/- 7.0% (mean +/- S.D.), however. in DMSO. EG, Gly. and MeOH, it was 82.7 +/- 10.4, 22.0 +/- 5.7, 0.0 +/- 0.0, and 0.0 +/- 0.0%, respectively. Hatching rate of embryos treated with PVP decreased (P < 0.05) with the increase of concentration and exposure time, whereas for embryos treated with sucrose, there was no significant decrease in comparison with the control at the concentrations used. (C) 2008 Elsevier Inc. All rights reserved.
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The objective was to identify an appropriate cryoprotectant and protocol for vitrification of red sea bream (Pagrus major) embryos. The toxicity of five single-agent cryoprotectants, dimethyl sulfoxide (DMSO), propylene glycol (PG), ethylene glycol (EG), glycerol (GLY), and methyl alcohol (MeOH), as well as nine cryoprotectant mixtures, were investigated by comparing post-thaw hatching rates. Two vitrifying protocols, a straw method and a solid surface vitrification method (copper floating over liquid nitrogen), were evaluated on the basis of post-thaw embryo morphology. Exposure to single-agent cryoprotectants (10% concentration for 15 min) was not toxic to embryos, whereas for higher concentrations (20 and 30%) and a longer duration of exposure (30 min), DMSO and PG were better tolerated than the other cryoprotectants. Among nine cryoprotectant mixtures, the combination of 20% DMSO + 10% PG + 10% MeOH had the lowest toxicity after exposure for 10 min or 15 min. High percentages of morphologically intact embryos, 50.6 +/- 16.7% (mean +/- S.D.) and 77.8 +/- 15.5%, were achieved by the straw vitrifying method (20.5% DMSO + 15.5% acetamide + 10% PG, thawing at 43 degrees C and washing in 0.5 M sucrose solution for 5 min) and by the solid surface vitrification method (40% GLY, thawing at 22 degrees C and washing in 0.5 M sucrose solution for 5 min). After thawing, morphological changes in the degenerated embryos included shrunken yolks and ruptured chorions. Furthermore, thawed embryos that were morphologically intact did not consistently survive incubation. (C) 2007 Elsevier Inc. All rights reserved.
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本发明涉及一种鉴定正品藏茵陈川西獐牙菜的分子试剂盒及其应用。该试剂盒反应液主要由DNA片段引物IDl:GGCTTGCCTCTCGACGCTC,ID2:GCAAGCGTCACGAAGACGCG,和DMSO试剂等组成。该试剂盒的应用包括以下步骤:1、对药材进行总DNA提取;2、利用引物对提取的DNA进行PCR扩增,若得到约500bp片段的扩增产物,则为川西獐牙菜;无此扩增片段,则是伪品种类。
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本文在Bruker AM-400 NMR谱仪上,在不同温度下研究了线形脑啡肽(N-Tyr~1-Gly~2-Gly~3-Phe~4-Leu~5)在DMSO中的NMR溶液构象。由NMR测试结果,得到了NH化学位移温度梯度系数、扭转角φ、χ'约束和~1H-~1H NOE距离约束,用目标函数法计算了脑啡肽的溶液构象,分析了优势边链构象。研究结果指明了多肽骨架的柔变性且处于构象平衡中。
