商品分类

浏览历史

B21485	叶黄素
源叶	分析标准品,HPLC≥90%，鉴别

英文名：
Lutein

别名：
二羟基-d-胡萝卜素，9-胡萝烯-3-3'-二醇

CAS号：
127-40-2

分子式：
C₄₀H₅₆O₂

分子量：
568.881

MDL：
MFCD00017353

品牌	货号	产品规格	市场价(RMB)	您的折扣价(RMB)	库存（上海）	北京	武汉	南京	数量	计量单位	加入购物车...
源叶	B21485-20mg	分析标准品,HPLC≥90%，鉴别	￥200.00元	￥180.00元	>10	1	0	0		EA	加入购物车
源叶	B21485-100mg	分析标准品,HPLC≥90%，鉴别	￥600.00元	￥600.00元	>10	0	0	0		EA	加入购物车

大包装询价

提交您的电话号码并同意《个人信息授权与保护申明》，到货后将短信提示。
提交

产品介绍

参考文献(99篇)

质检证书(COA)

摩尔浓度计算器

相关产品

熔点： 183°C

沸点： 702.3°C at 760mmHg

比旋光度： 18Cd +165° (c = 0.7 in benzene)

外观：金属光泽的结晶 Coppery powder

溶解性：不溶于水。溶于油性溶剂。

敏感性：对空气敏感

储存条件： -20℃

注意：部分产品我司仅能提供部分信息，我司不保证所提供信息的权威性，仅供客户参考交流研究之用。

99. [IF=6.1] Yanhua Liu et al."Structure–property relationship of pea protein fibrils in stabilization of HIPEs and the encapsulation, protection, controlled release and oral delivery of carotenoids for alleviating intestinal inflammation."Food & Function.2024 Jan;:

98. [IF=6.1] Xinyu Du et al."Salt-Promoted Fibrillation of Legume Proteins Enhanced Interfacial Modulus for Stabilization of HIPEs Encapsulating Carotenoids with Improved Nutritional Performance."JOURNAL OF AGRICULTURAL AND FOOD CHEMISTRY.2024;72(1):690–703

97. [IF=8.2] Shuwei Luo et al."Solubility-permeability interplay of a supersaturated lutein delivery system constructed by glycosylated stevioside and hydroxypropyl-methylcellulose."INTERNATIONAL JOURNAL OF BIOLOGICAL MACROMOLECULES.2024 Feb;258:128791

96. [IF=9.5] Jin-Bo Li et al."Ultrahigh-permeance polyamide thin-film composite membranes enabled by interfacial polymerization on a macro-porous substrate toward organic solvent nanofiltration."JOURNAL OF MEMBRANE SCIENCE.2024 Feb;693:122342

95. [IF=10.7] Shi Liu et al."Utilization of self-assembled soy protein nanoparticles as carriers for natural pigments: Examining non-interaction mechanisms and stability."FOOD HYDROCOLLOIDS.2024 Mar;148:109491

94. [IF=8.1] Li Ma et al."Stability protection of lutein emulsions by utilizing a functional conjugate of collagen and Lycium barbarum L. leaf flavonoid."FOOD RESEARCH INTERNATIONAL.2023 Nov;:113775

93. [IF=6.1] Hongtao Wang et al."Analysis of Carotenoids and Gene Expression in Apple Germplasm Resources Reveals the Role of MdCRTISO and MdLCYE in the Accumulation of Carotenoids."JOURNAL OF AGRICULTURAL AND FOOD CHEMISTRY.2023;71(41):15121–15131

92. [IF=6] Yan Jiao et al."Lutein-loaded glycosylated zein nanoparticles-Preparation, characterization, and stability in functional drink."LWT-FOOD SCIENCE AND TECHNOLOGY.10.1016/j.lwt.2023.115308

91. [IF=6.1] Huili Jing et al."Protective mechanism of lutein combined with EGCG against N-methyl-N nitrosourea-induced retinitis pigmentosa."Food & Function.10.1039/D3FO02716C

90. [IF=0] Huang Danqiong et al."Enhancement of β-carotene content in Chlamydomonas reinhardtii by expressing bacterium-driven lycopene β-cyclase."Biotechnology for Biofuels and Bioproducts.2023 Dec;16(1):1-8

89. [IF=6.9] Zhao Weihua et al."The Transcript Factor EMB1444-like Affects Tomato Fruit Ripening by Regulating YELLOW-FRUITED TOMATO 1, a Core Component of Ethylene Signaling Transduction."JOURNAL OF EXPERIMENTAL BOTANY.2023 Aug;:

88. [IF=10.7] Xiaojing Du et al."Preparation, characterization and functional properties of ternary composite nanoparticles for enhanced water solubility and bioaccessibility of lutein."FOOD HYDROCOLLOIDS.2023 Jul;:109039

87. [IF=7.091] Ya-Hui Wang et al."Lycopene ε-cyclase mediated transition of α-carotene and β-carotene metabolic flow in carrot fleshy root."PLANT JOURNAL.2023 May;:

86. [IF=9.231] Rui Wang et al."Enhanced encapsulation of lutein using soy protein isolate nanoparticles prepared by pulsed electric field and pH shifting treatment."FOOD CHEMISTRY.2023 Oct;424:136386

85. [IF=8.022] Pengxiang Xu et al."Effect of sodium alginate-based hydrogel loaded with lutein on gut microbiota and inflammatory response in DSS-induced colitis mice."Food Science and Human Wellness.2023 Nov;12:2428

84. [4.927] Jiayue Xu et al."Development of an HPLC-PDA Method for the Determination of Capsanthin, Zeaxanthin, Lutein, β-Cryptoxanthin and β-Carotene Simultaneously in Chili Peppers and Products."MOLECULES.2023 Jan;28(5):2362

83. [5.363] Yaxian Zhuge et al."Grape phytochrome-interacting factor VvPIF1 negatively regulates carotenoid biosynthesis by repressing VvPSY expression."PLANT SCIENCE.2023 Jun;331:111693

82. [6.449] Qingsong Liu et al."Microemulsion-based lutein extraction from marigold petals: Process optimization and stabilization evaluation."INDUSTRIAL CROPS AND PRODUCTS.2023 May;195:116454

81. [11.504] Yayuan Xu et al."Study on the relationship between lutein bioaccessibility and in vitro lipid digestion of nanostructured lipid carriers with different interface structures."FOOD HYDROCOLLOIDS.2023 May;139:108569

80. [4.132] Liping Lu et al."Excitation-Dependence of Excited-State Dynamics and Vibrational Relaxation of Lutein Explored by Multiplex Transient Grating."ACS Omega.2022;XXXX(XXX):XXX-XXX

79. [IF=5.895] Zhuqing Dai et al."Study on the Interaction between Four Typical Carotenoids and Human Gut Microflora Using an in Vitro Fermentation Model."JOURNAL OF AGRICULTURAL AND FOOD CHEMISTRY.2022;XXXX(XXX):XXX-XXX

78. [IF=5.363] Yushun Li et al."A mutation in SlCHLH encoding a magnesium chelatase H subunit is involved in the formation of yellow stigma in tomato (Solanum lycopersicum L.)."PLANT SCIENCE.2022 Dec;325:111466

77. [IF=3.612] Shuwei Luo et al."Release characteristics and bioaccessibility of lutein from calcium alginate hydrogels during simulated digestion in vitro."INTERNATIONAL JOURNAL OF FOOD SCIENCE AND TECHNOLOGY.2022 Jul;:

76. [IF=7.425] Yanan He et al."Effect of germination on the main chemical compounds and 5-methyltetrahydrofolate metabolism of different quinoa varieties."FOOD RESEARCH INTERNATIONAL.2022 Sep;159:111601

75. [IF=5.999] Yan Li et al."Improvement of solubility, stability and antioxidant activity of carotenoids using deep eutectic solvent-based microemulsions."COLLOIDS AND SURFACES B-BIOINTERFACES.2022 Sep;217:112591

74. [IF=6.706] Yebing Zhang et al."Lutein Can Alleviate Oxidative Stress, Inflammation, and Apoptosis Induced by Excessive Alcohol to Ameliorate Reproductive Damage in Male Rats."Nutrients.2022 Jan;14(12):2385

73. [IF=9.231] Shuwei Luo et al."Hybridization of glucosyl stevioside and hydroxypropyl methylcellulose to improve the solubility of lutein."FOOD CHEMISTRY.2022 Nov;394:133490

72. [IF=7.514] Ningxiang Yu et al."Preparation of novel self-assembled albumin nanoparticles from Camellia seed cake waste for lutein delivery."FOOD CHEMISTRY. 2022 Sep;389:133032

71. [IF=4.451] Huaqian Wu et al."Formation of pea protein amyloid fibrils to stabilize high internal phase emulsions for encapsulation of lutein."Journal of Functional Foods. 2022 Jul;94:105110

70. [IF=7.514] Ying Chang et al."Glycosylated zein as a novel nanodelivery vehicle for lutein."Food Chem. 2022 May;376:131927

69. [IF=4.952] Chengbin Zhao et al."Ultrasound-induced red bean protein–lutein interactions and their effects on physicochemical properties, antioxidant activities and digestion behaviors of complexes."Lwt Food Sci Technol. 2022 Apr;160:113322

68. [IF=3.356] Wang Ya-Hui et al."Transcript profiling of genes involved in carotenoid biosynthesis among three carrot cultivars with various taproot colors."Protoplasma. 2020 May;257(3):949-963

67. [IF=3.463] Ya-Zhuo Yang et al."Low temperature effects on carotenoids biosynthesis in the leaves of green and albino tea plant (Camellia sinensis (L.) O. Kuntze)."Sci Hortic-Amsterdam. 2021 Jul;285:110164

66. [IF=3.599] Liping Lu et al."Structures and exciton dynamics of aggregated lutein and zeaxanthin in aqueous media."J Lumin. 2020 Jun;222:117099

65. [IF=4.24] Xiao-Yu Ma et al."Lutein transport systems loaded with rice protein-based self-assembled nanoparticles."Food Biosci. 2021 Aug;42:101061

64. [IF=4.379] Song Hongxia et al."The genes crucial to carotenoid metabolism under elevated CO2 levels in carrot (Daucus carota L.)."Sci Rep-Uk. 2021 Jun;11(1):1-13

63. [IF=4.411] Litao Wang et al."Optimization of Ultrasonic-Assisted Extraction and Purification of Zeaxanthin and Lutein in Corn Gluten Meal."Molecules. 2019 Jan;24(16):2994

62. [IF=4.729] Weihua Zhao et al."Yellow-fruited phenotype is caused by 573 bp insertion at 5' UTR of YFT1 allele in yft1 mutant tomato."Plant Sci. 2020 Nov;300:110637

61. [IF=4.952] Zhongbo Liu et al."Fabrication and characterization of food-grade Pickering high internal emulsions stabilized with β-cyclodextrin."Lwt Food Sci Technol. 2020 Dec;134:110134

60. [IF=4.952] Mengjie Ma et al."Fabrication and characterization of zein/tea saponin composite nanoparticles as delivery vehicles of lutein."Lwt Food Sci Technol. 2020 May;125:109270

59. [IF=5.396] Yu Xu et al."Nanoparticles based on carboxymethylcellulose-modified rice protein for efficient delivery of lutein."Food Funct. 2020 Mar;11(3):2380-2394

58. [IF=5.753] Junwen Wang et al."Exogenous Application of 5-Aminolevulinic Acid Promotes Coloration and Improves the Quality of Tomato Fruit by Regulating Carotenoid Metabolism."Front Plant Sci. 2021; 12: 683868

57. [IF=6.992] Zhao Weihua et al."The transcription factor WRKY32 affects tomato fruit colour by regulating YELLOW FRUITED-TOMATO 1, a core component of ethylene signal transduction."J Exp Bot. 2021 May;72(12):4269-4282

56. [IF=7.514] Zhuqing Dai et al."Study on the bioavailability of stevioside-encapsulized lutein and its mechanism."Food Chem. 2021 Aug;354:129528

55. [IF=7.514] Zhaojing Jiang et al."Structuring of sunflower oil by stearic acid derivatives: Experimental and molecular modelling studies."Food Chem. 2020 Sep;324:126801

54. [IF=7.514] Ningxiang Yu et al."Development of composite nanoparticles from gum Arabic and carboxymethylcellulose-modified Stauntonia brachyanthera seed albumin for lutein delivery."Food Chem. 2022 Mar;372:131269

53. [IF=7.514] Xuehua Wang et al."Non-volatile and volatile metabolic profiling of tomato juice processed by high-hydrostatic-pressure and high-temperature short-time."Food Chem. 2022 Mar;371:131161

52. [IF=9.147] Hao Li et al."Zein/soluble soybean polysaccharide composite nanoparticles for encapsulation and oral delivery of lutein."Food Hydrocolloid. 2020 Jun;103:105715

51. [IF=9.229] Linlin Deng et al."Highly Crystalline Covalent Organic Frameworks Act as a Dual-Functional Fluorescent-Sensing Platform for Myricetin and Water, and Adsorbents for Myricetin."Acs Appl Mater Inter. 2021;13(28):33449–33463

50. [IF=0.691] Lu Liping et al."Spectral analysis of interaction between carotenoid and tyrosine in ethanol-water solution."Russ J Phys Chem A+. 2015 Mar;89(3):417-422

49. [IF=0.741] Lu L. et al."Influence of Phenylalanine on Carotenoid Aggregation."J Appl Spectrosc+. 2015 Jan;81(6):1068-1072

48. [IF=1.595] Li Jing-Wen et al."Carotenoid Accumulation and Distinct Transcript Profiling of Structural Genes Involved in Carotenoid Biosynthesis in Celery."Plant Mol Biol Rep. 2018 Aug;36(4):663-674

47. [IF=2.475] Tingting Wang et al."Combined process of reaction, extraction, and purification of lutein in marigold flower by isopropanol–KOH aqueous two-phase system."Sep Sci Technol. 2016;51(9):1490-1498

46. [IF=2.848] Bao-xing XIE et al."Supplemental blue and red light promote lycopene synthesis in tomato fruits."J Integr Agr. 2019 Mar;18:590

45. [IF=2.896] Lu Wang et al."Rapid assay for testing superoxide anion radical scavenging activities to natural pigments by ultra-high performance liquid chromatography-diode-array detection method."Anal Methods-Uk. 2015 Feb;7(4):1535-1542

44. [IF=3.246] Chittasupho Chuda et al."Stability, Cytotoxicity, and Retinal Pigment Epithelial Cell Binding of Hyaluronic Acid-Coated PLGA Nanoparticles Encapsulating Lutein."Aaps Pharmscitech. 2019 Jan;20(1):1-13

43. [IF=3.361] Yan Jiao et al."Polypeptide – decorated nanoliposomes as novel delivery systems for lutein."Rsc Adv. 2018 Sep;8(55):31372-31381

42. [IF=3.848] Ma Jing et al."Distinct transcription profile of genes involved in carotenoid biosynthesis among six different color carrot (Daucus carota L.) cultivars."Acta Bioch Bioph Sin. 2017 Sep;49(9):817-826

41. [IF=4.411] Ai-Li Guo et al."Influence of Sulfur Fumigation on the Chemical Constituents and Antioxidant Activity of Buds of Lonicera japonica."Molecules. 2014 Oct;19(10):16640-16655

40. [IF=4.499] Feng Xue et al."Encapsulation of tomato oleoresin with zein prepared from corn gluten meal."J Food Eng. 2013 Dec;119:439

39. [IF=4.5] Yanfei Liu et al."Biochemical and functional characterization of AcUFGT3a, a galactosyltransferase involved in anthocyanin biosynthesis in the red-fleshed kiwifruit (Actinidia chinensis)."Physiol Plantarum. 2018 Apr;162(4):409-426

38. [IF=4.952] Yong-Hui Wang et al."Amphiphilic zein hydrolysate as a delivery vehicle: The role of xanthophylls."Lwt Food Sci Technol. 2017 Jun;79:463

37. [IF=5.309] Wanqiang Wu et al."Lutein suppresses inflammatory responses through Nrf2 activation and NF‐κB inactivation in lipopolysaccharide‐stimulated BV‐2 microglia."Mol Nutr Food Res. 2015 Sep;59(9):1663-1673

36. [IF=5.396] Yan Jiao et al."Zein-derived peptides as nanocarriers to increase the water solubility and stability of lutein."Food Funct. 2018 Jan;9(1):117-123

35. [IF=5.396] Feng Xue et al."In vivo antioxidant activity of carotenoid powder from tomato byproduct and its use as a source of carotenoids for egg-laying hens."Food Funct. 2013 Mar;4(4):610-617

34. [IF=7.514] Liangxiao Zhang et al."Simultaneous determination of tocopherols, carotenoids and phytosterols in edible vegetable oil by ultrasound-assisted saponification, LLE and LC-MS/MS."Food Chem. 2019 Aug;289:313

33. Li, Jing-Wen, et al. "Carotenoid accumulation and distinct transcript profiling of structural genes involved in carotenoid biosynthesis in celery." Plant Molecular Biology Reporter 36.4 (2018): 663-674.https://doi.org/10.1007/s11105-018-1112-0

32. Wang, Tingting, et al. "Combined process of reaction, extraction, and purification of lutein in marigold flower by isopropanol–KOH aqueous two-phase system." Separation Science and Technology 51.9 (2016): 1490-1498.https://doi.org/10.1080/01496395.2016.116

31. Ma, Jing, et al. "Distinct transcription profile of genes involved in carotenoid biosynthesis among six different color carrot (Daucus carota L.) cultivars." Acta biochimica et biophysica Sinica 49.9 (2017): 817-826.https://doi.org/10.1093/abbs/gmx081

30. Lu, L., X. Ni, and X. Luo. "Influence of phenylalanine on carotenoid aggregation." Journal of Applied Spectroscopy 81.6 (2015): 1068-1072.

29. Liu, Zhongbo, et al. "Fabrication and characterization of food-grade Pickering high internal emulsions stabilized with β-cyclodextrin." LWT 134 (2020): 110134.https://doi.org/10.1016/j.lwt.2020.110134

28. 侯惠静,张晓燕,陈建波,柳昊杰,孟令莉,石振鹏,吴子健,赵伟.BSA-葡聚糖-叶黄素纳米颗粒的制备及其抗氧化活性[J].食品研究与开发,2020,41(20):137-145.

27. 常影,焦岩,刘庆松,刘庆明,孙晓宏,韩赫.玉米肽负载叶黄素纳米粒的结构表征及释放性能研究[J].食品科技,2021,46(02):238-243.

26. 李秀鑫,吴红艳,于晓丹,翟丽萍.影响叶黄素稳定性的因素[J].食品工业,2020,41(10):71-74.

25. 焦岩,高嘉宁,常影,佟佳路,韩赫,景文娟.叶黄素纳米脂质体的多聚赖氨酸修饰及其体外释放性能[J].中国油脂,2021,46(03):62-67.

24. 虞昕磊. 鲜叶摊放方式对绿茶色、香、味品质成分代谢的影响研究[D].华中农业大学,2020.

23. 孟繁玲,张宇,徐少博,赵宏,王宇亮,赵芷萌,张曼.南瓜中游离叶黄素的制备及抗氧化活性[J].食品与生物技术学报,2020,39(08):81-88.

22. 穆青陈亚淑谢笔钧杨季芳陈吉刚孙智达.北极海洋红球菌B7740(Rhodococcus sp.)产类胡萝卜素和类异戊二烯醌的抗氧化、抗增殖活性[J].食品科学 2018 39(11):159-164.

21. 刘跃芹, 赵雪松, 吴杰,等. 高效液相色谱法测定玉米浆干粉中维生素B6的含量[J]. 食品工业科技, 2013(24):61-63.

20. 钟碧萍, 黄宏南. 高效液相内标法同时测定保健食品中叶黄素和β-胡萝卜素的含量[J]. 海峡药学, 2013, 25(009):101-103.

19. 赵永平, 钟娇娇, 朱亚,等. 超临界CO2法萃取万寿菊中叶黄素的工艺优化研究[J]. 陕西农业科学, 2016, 62(012):70-72.

18. 李静文, 马静, 却枫,等. 芹菜中类胡萝卜素合成相关番茄红素ε–环化酶基因AgLCYE的克隆与表达分析[J]. 园艺学报, 2018.

17. 陈叶, 戴竹青, 宋江峰,等. 胶束化对Caco-2上皮细胞叶黄素吸收和转运的影响[J]. 食品工业科技, 2019, v.40;No.436(20):310-315.

16. 焦岩, 李大婧, 刘春泉,等. 纳米脂质体提高叶黄素的稳定性[J]. 食品工业, 2019, 040(004):24-27.

15. 张颖,陈华翰,李春美.番茄中类胡萝卜素及其顺式异构体的HPLC分析[J].分析测试学报,2016,35(04):448-453.

14. 李季楠, 胡浩, 吴雪娇,等. 环境因素对叶黄素纳米乳液稳定性及其抗氧化活性的影响[J]. 食品科学, 2019, 40(19).

13. 焦岩, 韩赫, 常影,等. 玉米醇溶蛋白负载叶黄素纳米粒的制备与表征[J]. 食品与机械, 2019(7):7-12.

12. 李小丽, 梁远学, 郜凌超,等. 油棕果实不同发育时期类胡萝卜素的含量变化[J]. 华中农业大学学报, 2015, 34(1):23-27.

11. 樊金玲, 杨睿, 孙晓菲,等. 榆树叶中类胡萝卜素的组成和含量[J]. 食品科学, 36(2).

10. 于奉生, 孙志高, 方明,等. 杀菌对柑橘汁中类胡萝卜素及色泽的影响[J]. 食品与发酵工业, 2019, 45(07):225-232+238.

9. 方明, 孙志高, 于奉生,等. 微波皂化法提取桔皮中类胡萝卜素及其组分分析[J]. 食品与发酵工业, 2019, 45(08):119-126.

8. 魏良淑, 吴芳, 蒋夕平,等. 基于紫外-可见光谱法研究叶黄素聚集体结构及其动力学[J]. 光谱学与光谱分析, 2018, 38(12):150-154.

7. 陈东洋, 张昊, 冯家力,等. 固相萃取-高效液相色谱法测定禽蛋中斑蝥黄和叶黄素[J]. 中国食品卫生杂志, 2020, v.32(01):51-55.

6. 卢礼萍李明刘桂玲等. 叶黄素聚集体吸收光谱的实验分析与理论模拟[J]. 光谱学与光谱分析 2016(36):3291.

5. 焦岩李大婧刘春泉等. 叶黄素纳米脂质体的制备工艺优化及其氧化稳定性[J]. 食品科学 2017 38(018):259-265.

4. 高蓓蓓金立李悦等. 不同储藏条件下铁皮石斛花中色素类成分的变化规律研究[J]. 中国中药杂志 2020 v.45(04):127-135.

3. 焦岩常影林巍景文娟李大婧.三聚磷酸钠修饰叶黄素纳米脂质体及释放性能研究[J].食品工业 2017 38(12):63-67.

2. 吕美孙一甲徐一楠等. HPLC法测定禽蛋蛋黄中玉米黄质和叶黄素[J]. 食品工业 2019(6).

1. 黄昕蕾王雁张辉.3种石斛属植物类胡萝卜素成分及代谢途径分析[J].林业科学研究 2019 32(05):107-113.