翅果油纳米乳的制备及抗氧化性能的研究

doi:10.3969/j.issn.1001-1803.2022.07.007

摘要/Abstract

摘要：

采用自乳化成型技术制备翅果油纳米乳,考察其理化特性,并对其抗氧化性能进行评价。纳米乳外观均匀,粒径大小分布均一,分散指数（PDI）、pH值、电导率等均表明其理化特性良好。纳米乳稳定性测试分别在4 ℃冰箱和25 ℃常温存储、转速3 000和6 000 r/min离心、稀释10倍和100倍条件下进行,粒径均未有明显改变,且未发生分层、浑浊及沉淀析出的现象,表明其稳定性良好。通过DPPH自由基清除实验和羟基自由基清除实验验证纳米乳的抗氧化性能,显示翅果油纳米乳及翅果油对DPPH自由基和羟基自由基的清除能力均呈现随着质量浓度增加而逐渐增强的趋势,且纳米乳的DPPH自由基清除能力和羟基自由基的清除能力均优于同质量浓度的翅果油,表明翅果油纳米乳具有更优的抗氧化能力。本研究的纳米乳可以作为一种稳定和潜在的载体形式,提高药物或活性成分的抗氧化性能,也可以为翅果油的开发应用提供研究基础。

关键词: 翅果油, 纳米乳, 抗氧化性

Abstract:

Nanotechnology has practical and potential application value in various fields. Recently, the nanoemulsion, a spontaneous emulsification delivery system has attracted increasing attention, which is composed of oil phase, surfactant, cosurfactant and water phase. An Elaeagnus mollis Diels seed oil nanoemulsion was constructed by self-nanoemulsifying method and its characterization and antioxidant activity were evaluated. The appearance, particle size, particle size distribution and pH value of the nanoemulsion were all showed that the nanoemulsion was qualified. The stability determination of nanoemulsion was tested under different conditions respectively, and the change in particle size was not obvious, and no delamination, turbidity and precipitation occurred, which suggested that the nanoemulsion possessed a good stability. DPPH radical scavenging experiment and hydroxyl radical scavenging experiment were conducted to verify the antioxidant activity of the nanoemulsion. The scavenging ability of Elaeagnus mollis Diels seed oil nanoemulsion and Elaeagnus mollis Diels seed oil to DPPH free radical was increased with the concentration increasing, and the scavenging ability of the nanoemulsion was better than that of the oil. At the same time, the scavenging ability of the nanoemulsion to hydroxyl radicals was significantly stronger than that of Elaeagnus mollis Diels seed oil. Nanoemulsion has smaller particle size, larger specific surface area, which is beneficial to the improvement of drug solubility, stability and antioxidant activity. Nanoemulsion is a promising delivery system, which can provide experimental basis for the application of Elaeagnus mollis Diels seed oil.

Key words: Elaeagnus mollis Diels seed oil, nanoemulsion, antioxidant activity

中图分类号:

TQ658

赵志娟,公培龙,王霞辉,于佳卉,刘晓妹. 翅果油纳米乳的制备及抗氧化性能的研究[J]. 日用化学工业, 2022, 52(7): 731-736.

Zhao Zhijuan,Gong Peilong,Wang Xiahui,Yu Jiahui,Liu Xiaomei. Preparation and antioxidant properties of Elaeagnus mollis Diels seed oil nanoemulsions[J]. China Surfactant Detergent & Cosmetics, 2022, 52(7): 731-736.

图/表 8

图1

图2

图3

表1

图4

表2

图5

图6

参考文献 17

[1]	Quan Hongfeng, Yang Ting, Peng Xiaodong. Preliminary study on anti-inflammatory and neuroprotective activity of the SCF-CO₂ extract from Elaeagnus mollis seeds[J]. Ningxia Medical Journal, 2017, 39 (11) : 980-982.
[2]	Wang X M, Bai B, Li J, et al. Development of the Elaeagnus mollis oil submicron-emulsion of its anti-fatigue activity[J]. Food Research and Development, 2018, 39 (8) : 159-165.
[3]	Feng X X, Li J, Chen Q Q, et al. Amino acid composition and nutritional evaluation of proteins extracted from Elaeagnus mollis Diels seed kernels[J]. Food Science, 2016, 37 (22) : 160-165. doi: 10.1111/j.1365-2621.1972.tb03409.x
[4]	Singh Y, Meher J G, Raval K, et al. Nanoemulsion: concepts, development and applications in drug delivery[J]. Journal of Controlled Release, 2017, 252: 28-49. doi: 10.1016/j.jconrel.2017.03.008
[5]	Rehman F U, Shah K U, Shah S U, et al. From nanoemulsions to self nanoemulsions, with recent advances in self-nanoemulsifying drug delivery systems (SNEDDS)[J]. Expert Opinion on Drug Delivery, 2017, 14 (11) : 1325-1340. doi: 10.1080/17425247.2016.1218462
[6]	Zhao Z J, Cui X D, Ma X L, et al. Preparation, characterization, and evaluation of antioxidant activity and bioavailability of a self-nanoemulsifying drug delivery system(SNEDDS) for buckwheat flavonoids[J]. Acta. Biochim. Biophys. Sin., 2020, 52 (11) : 1265-1273. doi: 10.1093/abbs/gmaa124
[7]	Dey T K, Koley H, Ghosh M, et al. Effects of nano-sizing on lipid bioaccessibility and ex vivo bioavailability from EPA-DHA rich oil in water nanoemulsion[J]. Food Chemistry, 2019, 275: 135-142. doi: 10.1016/j.foodchem.2018.09.084
[8]	Kumar M, Bishnoi R S, Shukla A K, et al. Techniques for formulation of nanoemulsion drug delivery system: a review[J]. Preventive Nutrition and Food Science, 2019, 24 (3) : 225-234. doi: 10.3746/pnf.2019.24.3.225
[9]	Huang X L, Dai Y Q, Cai J X, et al. Resveratrol encapsulation in core-shell biopolymer nanoparticles: impact on antioxidant and anticancer activities[J]. Food Hydrocolloids, 2017, 64: 157-165. doi: 10.1016/j.foodhyd.2016.10.029
[10]	Zeng F Y, Wang D D, Tian Y, et al. Nanoemulsion for improving the oral bioavailability of hesperetin: formulation optimization and absorption mechanism[J]. Journal of Pharmaceutical Sciences, 2021, 110 (6) : 2555-2561. doi: 10.1016/j.xphs.2021.02.030
[11]	Zhong W M, Tang P Y, Liu T, et al. Linalool nanoemulsion preparation, characterization and antimicrobial activity against aeromonas hydrophila[J]. International Journal of Molecular Sciences, 2021, 22 (20) : 11003. doi: 10.3390/ijms222011003
[12]	Pathania R, Najda A, Chawla P, et al. Low-energy assisted sodium alginate stabilized Phyllanthus niruri extract nanoemulsion: Characterization, in vitro antioxidant and antimicrobial application[J]. Biotechnology Reports, 2022, 33 (3) : e00711. doi: 10.1016/j.btre.2022.e00711
[13]	Liu M, Cao S Y, He Y, et al. Preparation of citral nanoemulsion and its effect on the preservation of Shatangju[J]. Food and Fermentation Industries, 2022: 1-11. DOI: 10.13995/j.cnki.11-1802/ts.029569. doi: 10.13995/j.cnki.11-1802/ts.029569
[14]	He W, Wu W Y. Preparation and quality evaluation of O/W-type nifedipine transdermal nanoemulsion[J]. China Pharmacist, 2017, 20 (4) : 668-673.
[15]	Davidov-Pardo G, McClements D J. Nutraceutical delivery systems: resveratrol encapsulation in grape seed oil nanoemulsions formed by spontaneous emulsification[J]. Food Chemistry, 2015, 167: 205-212. doi: 10.1016/j.foodchem.2014.06.082 pmid: 25148980
[16]	Sabeena F K H, Andersen L L, Otte J, et al. Antioxidant activity of cod (Gadus morhua) protein hydrolysates: fractionation and characterisation of peptide fractions[J]. Food Chemistry, 2016, 204: 409-419. doi: S0308-8146(16)30322-3 pmid: 26988519
[17]	Brizzolari A, Campisi G M, Santaniello E, et al. Effect of organic co-solvents in the evaluation of the hydroxyl radical scavenging activity by the 2-deoxyribose degradation assay: the paradigmatic case of alpha-lipoic acid[J]. Biophysical Chemistry, 2017, 220: 1-6. doi: S0301-4622(16)30385-4 pmid: 27825024

测试条件	外观变化	粒径/nm
4 ℃冰箱	无明显变化,无分层絮凝等	163.8±1.2
25 ℃常温	无明显变化,无分层絮凝等	161.0±1.4
3 000 r/min	无明显变化,无分层絮凝等	161.3±2.1
6 000 r/min	无明显变化,无分层絮凝等	162.1±0.9
10倍稀释	无明显变化,无分层絮凝等	162.6±1.4
100倍稀释	无明显变化,无分层絮凝等	163.9±1.5