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| Current Status and Thinking on Green Feed Additives in Aquaculture of Sea Cucumber Apostichopus japonicus |
| ZHAO Zhenjun, YE Bo, DONG Ying, WANG Xuda, WANG Xiaoyue, LIU Danni, LIU Guilin, ZHANG Qian, CAO Chen, GAO Xuewen, LI Mengyao, LI Shilei |
| Key Laboratory of Protection and Utilization of Aquatic Germplasm Resource, Ministry of Agriculture and Rural Affairs, Key Laboratory of Germplasm Improvement and Fine Seed Breeding for Marine Aquatic Animals, Liaoning Province, Liaoning Ocean and Fisheries Science Research Institute, Dalian 116023, China |
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[1] MOON J, RYU H, SUH J. Antitumor effects of glycoprotein extracted from sea cucumber (Stichopus japonicus)[J]. Journal of Food Science and Nutrition,1999,4:117-121.
[2] 赵红霞,王国霞,孙育平,等.水产新型饲料添加剂的研发与应用[J].广东农业科学,2020,47(11):135-143.
[3] 王熙涛,徐永平,金礼吉,等.仿刺参绿色饲料添加剂研究的进展[J].水产科学,2014,33(6):393-397.
[4] 黄沧海.环保型水产饲料添加剂的研究与应用[J].饲料广角,2015(7):38-41.
[5] 尚卫敏,王朝明,张桂众.水产饲料添加剂研究概况[J].江西饲料,2011(3):16-20.
[6] 陈勇.中药饲料添加剂及其在水产养殖中的应用[J].现代农业科技,2012(17):264-265.
[7] 沈朕,王晓兰,韩雅萌,等.3种复方中药饲料添加剂对刺参生长及免疫力的影响[J].贵州农业科学,2016,44(4):103-105.
[8] 吴亚楠,柳鹏,李强,等.复方中草药对仿刺参免疫力和抗病力的影响[J].大连海洋大学学报,2011,26(4):338-343.
[9] 翟奥博.复合微生态制剂对刺参幼参生长、水质及免疫相关酶的影响[D].大连:大连海洋大学,2017.
[10] 王印庚,冷敏,陈霞,等.中草药对刺参腐皮综合征病原菌的体外抑菌试验[J].渔业科学进展,2009,30(2):1-7.
[11] 陈效儒,张文兵,麦康森,等.饲料中添加甘草酸对刺参生长、免疫及抗病力的影响[J].水生生物学报,2010,34(4):731-738.
[12] CHANG J, ZHANG W B, MAI K S, et al. Effects of dietary β-glucan and glycyrrhizin on non-specific immunity and disease resistance of the sea cucumber (Apostichopus japonicus Selenka) challenged with Vibrio splendidus[J]. Journal of Ocean University of China,2010,9(4):389-394.
[13] 张元发,盖春蕾,叶海斌,等.大黄对仿刺参体腔液中非特异性免疫的影响[J].安徽农业科学,2018,46(23):57-60.
[14] 孙永欣,李亚洁,温志新,等.饲喂黄芪和黄芪多糖对刺参生长性能的影响[J].中国饲料,2009(4):31-36.
[15] ZHU F. A review on the application of herbal medicines in the disease control of aquatic animals[J]. Aquaculture,2020,526:735422.
[16] 姚刚,李强,付雷,等.几种中草药对刺参幼参的急性毒性试验[J].大连海洋大学学报,2017,32(2):161-166.
[17] 张琴.刺参(Apostichopus japonicus Selenka)高效免疫增强剂的筛选与应用[D].青岛:中国海洋大学,2010.
[18] 韩丽蓉.壳寡糖、稀土及壳寡糖稀土配合物对刺参生长、免疫反应和抗病力的影响[D].青岛:中国海洋大学,2014.
[19] GU M, MA H M, MAI K S, et al. Effects of dietary β-glucan, mannan oligosaccharide and their combinations on growth performance, immunity and resistance against Vibrio splendidus of sea cucumber, Apostichopus japonicus[J]. Fish & Shellfish Immunology,2011,31(2):303-309.
[20] ZHANG Q, MA H M, MAI K S, et al. Interaction of dietary Bacillus subtilis and fructooligosaccharide on the growth performance, non-specific immunity of sea cucumber, Apostichopus japonicus[J]. Fish & Shellfish Immunology,2010,29(2):204-211.
[21] WANG X T, WANG L L, CHE J, et al. In vitro non-specific immunostimulatory effect of alginate oligosaccharides with different molecular weights and compositions on sea cucumber (Apostichopus japonicus) coelomocytes[J]. Aquaculture,2014,434:434-441.
[22] 王际英,宋志东,李培玉,等.饲料添加半乳甘露寡糖对刺参幼参生长、体壁营养组成及免疫力的影响[J].中国水产科学,2014,21(2):310-319.
[23] 郭娜,姚子昂,于国友,等.海带酶解产物对海参生长及其免疫相关因子的影响[J].中国酿造,2019,38(4):160-164.
[24] WANG T T, SUN Y X, JIN L J, et al. Enhancement of non-specific immune response in sea cucumber (Apostichopus japonicus) by Astragalus membranaceus and its polysaccharides[J]. Fish & Shellfish Immunology,2009,27(6):757-762.
[25] SUN Y X, JIN L J, WANG T T, et al. Polysaccharides from Astragalus membranaceus promote phagocytosis and superoxide anion (O-2) production by coelomocytes from sea cucumber Apostichopus japonicus in vitro[J]. Comparative Biochemistry and Physiology Part C:Toxicology & Pharmacology,2008,147(3):293-298.
[26] 孙永欣,徐永平,汪婷婷,等.黄芪多糖对仿刺参体腔细胞中溶菌酶基因表达量的影响[J].水产科学,2009,28(10):572-574.
[27] 朱晓振,孟现尧,贾晨晨,等.菊芋全粉对高温胁迫下仿刺参免疫及消化功能的影响[J].中国饲料,2020(11):77-83.
[28] 梁超.饲料中添加二甲酸钾、低聚木糖和菊粉对刺参的生长、免疫和抗灿烂弧菌感染能力的影响[D].青岛:中国海洋大学,2011.
[29] 白阳.壳聚糖和壳寡糖及其配合物对刺参生长和品质相关指标的影响[D].青岛:中国海洋大学,2015.
[30] 李君华,刘佳亮,曹学彬,等.饲料中添加低聚木糖对仿刺参幼参生长性能、肠道消化酶活力和免疫力的影响[J].动物营养学报,2016,28(8):2534-2541.
[31] 王淑娴,李天保,樊英,等.茯苓多糖对刺参体腔液中免疫因子活性的影响[J].饲料研究,2010(1):59-61.
[32] ZHAO W, LIANG M, ZHANG P. Effect of yeast polysaccharide on the immune function of juvenile sea cucumber, Apostichopus japonicus Selenka under pH stress[J]. Aquaculture International,2010,18(5):777-786.
[33] 李宝山,王际英,王成强,等.仿刺参幼参对饲料中维生素B6需求量的研究[J].水产学报,2019,43(12):2545-2553.
[34] OKORIE O E, KO S H, GO S, et al. Preliminary study of the optimum dietary riboflavin level in sea cucumber, Apostichopus japonicus (Selenka)[J]. Journal of the World Aquaculture Society,2011,42(5):657-666.
[35] 王丽丽,李宝山,王际英,等.维生素D3对仿刺参幼参生长、体组成及抗氧化能力的影响[J].渔业科学进展,2019,40(1):110-118.
[36] OKORIE O E, KO S H, GO S, et al. Preliminary study of the optimum dietary ascorbic acid level in sea cucumber, Apostichopus japonicus (Selenka)[J]. Journal of the World Aquaculture Society,2008,39(6):758-765.
[37] 王开来.维生素C对刺参生长和非特异性免疫的影响[D].大连:大连理工大学,2009:82.
[38] LUO Z Y, WANG B J, LIU M, et al. Effect of dietary supplementation of vitamin C on growth, reactive oxygen species, and antioxidant enzyme activity of Apostichopus japonicus (Selenka) juveniles exposed to nitrite[J]. Chinese Journal of Oceanology and Limnology,2014,32(4):749-763.
[39] 张琴,麦康森,张文兵,等.饲料中添加硒酵母和维生素E对刺参生长、免疫力及抗病力的影响[J].动物营养学报,2011,23(10):1745-1755.
[40] KO S H, GO S, OKORIE O E, et al. Preliminary study of the dietary α-tocopherol requirement in sea cucumber, Apostichopus japonicus[J]. Journal of the World Aquaculture Society,2009,40(5):659-666.
[41] 赵琳.饲料中添加维生素E、双齿围沙蚕对刺参性腺发育的影响[D].大连:大连海洋大学,2020.
[42] 王吉桥,王志香,于红艳,等.饲料中不同类型的硒对仿刺参幼参生长和免疫指标的影响[J].大连海洋大学学报,2011,26(4):306-311.
[43] 吴香莹,盛伟博,聂琴,等.饲料中添加酵母硒对刺参生长、抗氧化能力及夏眠前后硒含量的影响[J].动物营养学报,2020,32(6):2791-2798.
[44] 刘洪展,郑风荣,孙修勤,等.亚硒酸钠对刺参免疫反应中体腔液酶活力的影响[J].水产学报,2012,36(1):98-105.
[45] PARK S C, SHIMAMURA I, FUKUNAGA M, et al. Isolation of bacteriophages specific to a fish pathogen, Pseudomonas plecoglossicida, as a candidate for disease control[J]. Applied and Environmental Microbiology,2000,66(4):1416-1422.
[46] WALAKIRA J K, CARRIAS A A, HOSSAIN M J, et al. Identification and characterization of bacteriophages specific to the catfish pathogen, Edwardsiella ictaluri[J]. Journal of Applied Microbiology,2008,105(6):2133-2142.
[47] 杨扬.应用噬菌体防治弧菌引发的刺参腐皮综合征[D].大连:大连理工大学,2013.
[48] 李振.噬菌体防控苗期刺参弧菌感染的研究[D].大连:大连理工大学,2018.
[49] ZHANG J C, CAO Z H, LI Z, et al. Effect of bacteriophages on Vibrio alginolyticus infection in the sea cucumber, Apostichopus japonicus (Selenka)[J]. Journal of the World Aquaculture Society,2015,46(2):149-158.
[50] 秦搏,陈四清,常青,等.饲料中添加纤维素酶对幼刺参生长性能、消化能力和非特异性免疫力的影响[J].动物营养学报,2014,26(9):2698-2705.
[51] 徐彬.刺参幼参预消化配合饲料的研究[D].北京:中国农业科学院,2009:84.
[52] 武明欣,王际英,李宝山,等.酶制剂对刺参生长、体成分、免疫能力及氨氮胁迫下免疫酶活力和热休克蛋白70含量的影响[J].动物营养学报,2015,27(4):1293-1301.
[53] 武明欣.酶制剂对刺参生长、消化及免疫能力的影响[D].上海:上海海洋大学,2015:36.
[54] 戚传利,王福强,钱淑媛,等.复合酶对刺参生长、免疫酶活性和消化酶活性的影响[J].中国饲料,2014(19):33-36.
[55] 李向阳.固定化酶的制备及其在海参饲料中的应用研究[D].烟台:烟台大学,2011:62.
[56] 包鹏云,李璐瑶,徐哲,等.海洋红酵母H26对刺参幼参生长、免疫指标和肠道菌群的影响[J].大连海洋大学学报,2019,34(5):615-622.
[57] 王晓飞,史翠娟,阚光锋,等.南极红酵母AN5的发酵及对海参体成分的影响[J].极地研究,2018,30(1):50-56.
[58] YANG Z P, SUN J M, XU Z, et al. Beneficial effects of Metschnikowia sp. C14 on growth and intestinal digestive enzymes of juvenile sea cucumber Apostichopus japonicus[J]. Animal Feed Science and Technology,2014,197:142-147.
[59] LIU Z M, MA Y X, YANG Z P, et al. Immune responses and disease resistance of the juvenile sea cucumber Apostichopus japonicus induced by Metschnikowia sp. C14[J]. Aquaculture,2012,368/369:10-18.
[60] YANG Z P, SUN J M, XU Z. Beneficial effects of Rhodotorula sp. C11 on growth and disease resistance of juvenile Japanese spiky sea cucumber Apostichopus japonicus[J].Journal of Aquatic Animal Health,2015,27:2,71-76.
[61] WANG J H, ZHAO L Q, LIU J F, et al. Effect of potential probiotic Rhodotorula benthica D30 on the growth performance, digestive enzyme activity and immunity in juvenile sea cucumber Apostichopus japonicus[J]. Fish & Shellfish Immunology,2015,43(2):330-336.
[62] MA Y X, LIU Z M, YANG Z P, et al. Effects of dietary live yeast Hanseniaspora opuntiae C21 on the immune and disease resistance against Vibrio splendidus infection in juvenile sea cucumber Apostichopus japonicus[J]. Fish & Shellfish Immunology,2013,34(1):66-73.
[63] ZHAO Y C, ZHANG W B, XU W, et al. Effects of potential probiotic Bacillus subtilis T13 on growth, immunity and disease resistance against Vibrio splendidus infection in juvenile sea cucumber Apostichopus japonicus[J]. Fish & Shellfish Immunology,2012,32(5):750-755.
[64] LI J G, XU Y P, JIN L J, et al. Effects of a probiotic mixture (Bacillus subtilis YB-1 and Bacillus cereus YB-2) on disease resistance and non-specific immunity of sea cucumber, Apostichopus japonicus (Selenka)[J]. Aquaculture Research,2015,46:3008-3019.
[65] 王旭达,关晓燕,王鉴,等.地衣芽孢杆菌对仿刺参生长、消化和免疫功能的影响[J].水产科学,2021,40(2):151-158.
[66] ZHAO Y C, YUAN L, WAN J L, et al. Effects of potential probiotic Bacillus cereus EN25 on growth, immunity and disease resistance of juvenile sea cucumber Apostichopus japonicus[J]. Fish & Shellfish Immunology,2016,49:237-242.
[67] 田良,陈政强.饲料中添加微生物制剂对仿刺参生长与免疫的影响[J].集美大学学报(自然科学版),2017,22(2):1-10.
[68] 周文铭,李俐颖,孙欣宇,等.复合微生物净水剂在仿刺参养殖中的应用[J].水产科学,2021,40(5):686-692.
[69] 韩莎,曲洪霞,李成林,等.微生态制剂及其使用策略对刺参生长与养殖水质的影响[J].中国农学通报,2020,36(2):144-148.
[70] 王宇翕,芦士杰,肖珊,等.一种复合微生态制剂发酵条件优化及其对刺参养殖水体水质的影响[J].大连工业大学学报,2020,39(1):6-11.
[71] 李建光.刺参菌群结构的分析及益生菌对刺参的影响[D].大连:大连理工大学,2014.
[72] 孙蕾.海洋益生菌对养殖水体的影响[D].大连:大连工业大学,2015.
[73] YAN F J, TIAN X L, DONG S L, et al. Growth performance, immune response, and disease resistance against Vibrio splendidus infection in juvenile sea cucumber Apostichopus japonicus fed a supplementary diet of the potential probiotic Paracoccus marcusii DB11[J]. Aquaculture,2014,420/421:105-111.
[74] LIU N N, ZHANG S S, ZHANG W W, et al. Vibrio sp. 33 a potential bacterial antagonist of Vibrio splendidus pathogenic to sea cucumber (Apostichopus japonicus)[J]. Aquaculture,2017,470:68-73.
[75] 王宜磊,于夫俊.功能性蛋白举例[J].生物学通报,1998,33(6):16-17.
[76] 熊川男,李伟,白雪芳,等.凝集素作为海参免疫增强剂在人工养殖海参中的应用[J].饲料工业,2005,26(18):30-32.
[77] 黄自然,王少颐.注射大肠杆菌诱导柞蚕蛹血淋巴产生抗菌物质(简报)[J].华南农学院学报,1981,2(1):65-68.
[78] MA S H, SUN Y X, WANG F Q, et al. Effects of tussah immunoreactive substances on growth, immunity, disease resistance against Vibrio splendidus and gut microbiota profile of Apostichopus japonicus[J]. Fish & Shellfish Immunology,2017,63:471-479.
[79] 李树英.柞蚕抗病活性物质的提取及应用[J].中国蚕业,2015,36(1):20-24.
[80] 孙永欣,温志新,米锐,等.柞蚕免疫蛹粉在刺参健康养殖中的应用研究[J].中国饲料,2016(15):19-23.
[81] WANG X D, ZHOU Z C, GUAN X Y, et al. Effects of dietary Lactobacillus acidophilus and tussah immunoreactive substances supplementation on physiological and immune characteristics of sea cucumber (Apostichopus japonicus)[J]. Aquaculture,2021,542:736897.
[82] WANG X D, JIANG J W, GUAN X Y, et al. Effects of Lactobacillus acidophilus and tussah immunoreactive substances on disease resistance of sea cucumber (Apostichopus japonicus) against Vibrio splendidus[J]. Aquaculture Research,2021,52(10):4601-4612.
[83] 杜正江.抗刺参腐皮综合征特异性卵黄抗体新制剂的研究[D].大连:大连理工大学,2017.
[84] 靖凯霖.特异性卵黄抗体对灿烂弧菌感染仿刺参的保护作用研究[D].大连:大连理工大学,2016.
[85] 冯丽娟.致刺参腐皮综合征溶藻弧菌卵黄抗体的制备及活性研究[D].大连:大连理工大学,2021.
[86] TSAI H J, KUO J C, LOU S W, et al. Articles:growth enhancement of juvenile striped mullet by feeding recombinant yeasts containing fish growth hormone[J]. The Progressive Fish-Culturist,1994,56(1):7-12.
[87] ANTORO S, ZAIRIN M Jr, ALIMUDDIN A, et al. Growth, biochemical composition, innate immunity and histological performance of the juvenile humpback grouper (Cromileptes altivelis) after treatment with recombinant fish growth hormone[J]. Aquaculture Research,2016,47(4):1238-1250.
[88] XUE Z, LI H, WANG X L, et al. A review of the immune molecules in the sea cucumber[J]. Fish & Shellfish Immunology,2015,44(1):1-11.
[89] KJUUL A K, BÜLLESBACH E E, ESPELID S, et al. Effects of cecropin peptides on bacteria pathogenic to fish[J]. Journal of Fish Diseases,1999,22(5):387-394.
[90] 毕楠.海参i-型溶菌酶和抗菌肽饲喂海参和肉鸡的试验研究[D].大连:大连工业大学,2018.
[91] 姜兰,白俊杰,邓国成,等.重组抗菌肽的制备及其对水产养殖中常见病原菌的抑菌效果[J].中国水产科学,2002,9(2):152-156.
[92] VIJAYARAM S, SUN Y Z, ZUORRO A, et al. Bioactive immunostimulants as health-promoting feed additives in aquaculture:a review[J]. Fish & Shellfish Immunology,2022,130:294-308.
[93] RICO A, PHU T M, SATAPORNVANIT K, et al. Use of veterinary medicines, feed additives and probiotics in four major internationally traded aquaculture species farmed in Asia[J]. Aquaculture,2013,412/413:231-243.
[94] DAWOOD M A O, KOSHIO S, ESTEBAN M Á. Beneficial roles of feed additives as immunostimulants in aquaculture:a review[J]. Reviews in Aquaculture,2018,10(4):950-974.
[95] 程纯明.年使用量将近30万吨!国内水产微生态制剂前景广阔,宝来利来将如何布局[J].当代水产,2018,43(5):40-41.
[96] 吴鹏,徐二华,赵威,等.饲料添加剂包被产品的制备和检测方法研究进展[J].中国畜牧杂志,2022,58(10):37-43.
[97] 周德刚.包被可保护饲料添加剂的有效性[J].中国畜牧杂志,2011,47(12):45-46.
[98] 吴小嫚,胡乐琴.复合法制备嗜酸乳杆菌-双歧杆菌益生菌微胶囊饲料工艺及体外消化特性研究[J].动物营养学报,2020,32(1):372-381.
[99] 杨正坤,郑云峰,高潮,等.包被技术对饲料添加剂重要性的研究[J].广东饲料,2014,23(3):36-37.
[100] 李芳,游斌杰,郑萍,等.国内包被技术在畜牧业的应用研究进展[J].饲料研究,2019,42(5):100-105.
[101] 冯莉萍.微囊技术在水产饲料上的应用[J].浙江海洋学院学报(自然科学版),2001,20(增刊):88-93.
[102] 牛化欣.微胶囊氨基酸制备及其在饲料加工和虾养殖中的效果研究[D].无锡:江南大学,2011.
[103] 杨正坤,郑云峰,高潮,等.包被技术在饲料添加剂中的应用[J].饲料广角,2014(4):33-34. |
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