不同烟草品种烟籽油理化性质及脂肪酸和挥发性成分评价

doi:10.3969/j.issn.1004-1524.2022.06.06

浙江农业学报 ›› 2022, Vol. 34 ›› Issue (6): 1152-1161.DOI: 10.3969/j.issn.1004-1524.2022.06.06

不同烟草品种烟籽油理化性质及脂肪酸和挥发性成分评价

宋碧清¹(), 杨晓东¹, 郑昀晔¹, 王国平¹, 徐盛春², 赵燕³, 赵珊珊³, 马宇轩³^,^*(), 李素娟²^,^*()

1.玉溪中烟种子有限责任公司,云南玉溪 653100
2.浙江省农业科学院农产品质量安全危害因子与风险防控国家重点实验室公共实验室,浙江杭州 310021
3.中国农业科学院农业质量标准与检测技术研究所,北京 100081

收稿日期:2021-09-23 出版日期:2022-06-25 发布日期:2022-06-30
通讯作者: 马宇轩,李素娟
作者简介:李素娟,E-mail： sujuanli2001@163.com
*马宇轩,E-mail: 184175624@qq.com;
宋碧清（1982—）,女,福建莆田人,硕士,主要从事烟草种子及育种研究。E-mail： 10540258@qq.com
基金资助:
中国烟草总公司云南省公司科技计划项目(2019530000241048)

Evaluation of physicochemical properties, fatty acids and volatile components of different tobacco seed oils

SONG Biqing¹(), YANG Xiaodong¹, ZHENG Yunye¹, WANG Guoping¹, XU Shengchun², ZHAO Yan³, ZHAO Shanshan³, MA Yuxuan³^,^*(), LI Sujuan²^,^*()

1. Yuxi Zhongyan Tobacco Seed Co., Ltd., Yuxi 653100, Yunnan, China
2. Central Laboratory, State Key Laboratory for Managing Biotic and Chemical Threats to the Quality and Safety of Agro-Products, Zhejiang Academy of Agricultural Sciences, Hangzhou 310021, China
3. Institute of Quality Standard & Testing Technology for Agro-Products, Chinese Academy of Agricultural Sciences, Beijing 100081, China

Received:2021-09-23 Online:2022-06-25 Published:2022-06-30
Contact: MA Yuxuan,LI Sujuan

摘要/Abstract

摘要：

本研究采用索氏提取法提取8个烟草品种的烟籽油,进行理化性质分析,并用气相色谱（GC）、气相色谱-质谱联用技术（GC-MS）分别测定烟籽油的脂肪酸组成和挥发性成分。结果表明,除皂化值和折光率外,8种烟籽油在酸价、比重、过氧化值及碘值中均差异显著,红大和NC89两个品种的酸价最低,保山4号的过氧化值最低,NC89的碘值最高,大竖把直把品种的比重最大,8个品种烟籽油的皂化值范围为176.13~190.81 mg·g^-1、折光率约为1.470,综合理化性质数据,品质较好的是Burley21,它的酸价、皂化值、比重、过氧化值、碘值及折光率分别是0.75 mg·g^-1、185.04 mg·g^-1、0.84 g·cm^-3、1.17%、1520.5 g·kg^-1及1.467 81。8个烟籽油品种的多不饱和脂肪酸含量均较高（785.99~965.99 mg·g^-1）,多不饱和脂肪酸/饱和脂肪酸（PUFA/SFA）值在5.61~6.60,亚油酸在8个品种测得的所有脂肪酸中均含量最高（772.41~944.20 mg·g^-1）。在8个品种的烟籽油中检测出棕榈酸甲酯、棕榈酸、亚油酸甲酯、油酸甲酯、亚油酸、己内酰胺和2,2'-亚甲基双-(4-甲基-6-叔丁基苯酚)7种挥发性物质,其中亚油酸含量最高,与脂肪酸含量测定结果具有一致性。比较脂肪酸及挥发性物质结果,云雪2号及Burley21两个品种较好。综合理化性质、脂肪酸与挥发性物质结果,Burley21是较为理想的烟籽油原料。

关键词: 烟籽, 油脂, 理化性质, 脂肪酸, 挥发性物质

Abstract:

In this study, the Soxhlet extraction method was used for extracting tobacco accessions. The physicochemical properties were measured, and the fatty acid composition and volatile components of tobacco seed oil were determined by gas chromatography (GC) and gas chromatography-mass spectrometry (GC-MS) for quality evalution. The results showed that there were significant differences in acid value, specific gravity, peroxide value and iodine value among eight tobacco seed oils, except saponification value and refractive index. Hongda and NC89 had the lowest acid value, Baoshan 4 showed the lowest peroxide value, the highest iodine value is NC89, and Dashubazhiba was with the highest specific gravity. Based on the performance of physical and chemical properties, the Burley21 has a better quality, whose acid value, saponification value, specific gravity, peroxide value, iodine value and refractive index were 0.75 mg·g^-1, 185.04 mg·g^-1, 0.84 g·cm^-3, 1.17%, 1 520.5 g·kg^-1 and 1.467 81, respectively. All the seed oil of eight different tobacco accessions were showed a high level of polyunsaturated fatty acids contents (785.99-965.99 mg·g^-1), and the polyunsaturated fatty acids/saturated fatty acids(PUFA/SFA) value ranged from 5.61 to 6.60. The linoleic acid content was the highest (772.41-944.20 mg·g^-1) among all the measured fatty acids. On the other hand, in total, we detected seven kinds of volatile substances, including palmitic acid methyl ester, methyl palmitic acid, linoleic acid, oleic acid, linoleic acid, methyl caprolactam, and 2, 2'-methylene double-(4-methyl-6-tertiary butyl phenol) from the seed oil. The composition and the content of volatile substances were highly consistent with the polyunsaturated fatty acids. In summary, considering the results of fatty acids and volatile substances, we found that Yunxue 2 and Burley21 showed better quality. Taken together, we concluded that the Burley21 is an ideal raw material for tobacco seed oil.

Key words: tobacco seed, oil, the physicochemical properties, fatty acid, volatile components

中图分类号:

S572

宋碧清, 杨晓东, 郑昀晔, 王国平, 徐盛春, 赵燕, 赵珊珊, 马宇轩, 李素娟. 不同烟草品种烟籽油理化性质及脂肪酸和挥发性成分评价[J]. 浙江农业学报, 2022, 34(6): 1152-1161.

SONG Biqing, YANG Xiaodong, ZHENG Yunye, WANG Guoping, XU Shengchun, ZHAO Yan, ZHAO Shanshan, MA Yuxuan, LI Sujuan. Evaluation of physicochemical properties, fatty acids and volatile components of different tobacco seed oils[J]. Acta Agriculturae Zhejiangensis, 2022, 34(6): 1152-1161.

图/表 5

参考文献 34

[1]	左青, 李国卫. 加工过程对油脂食用安全的影响[J]. 中国油脂, 2009, 34(1): 13-15.
[2]	刘玉兰. 油脂制取与加工工艺学[M]. 2版. 北京: 科学出版社, 2009.
[3]	左青, 章家新. 大豆色拉油返色原因初探及对策[J]. 中国油脂, 2000, 25(6): 79-81.
	ZUO Q, ZHANG J X. Reasons and treatment of soybean salad oil color reversion[J]. China Oils and Fats, 2000, 25(6): 79-81. (in Chinese with English abstract)
[4]	左青, 高轶群. 油脂返色机理分析和防止对策[J]. 中国油脂, 2003, 28(11): 26-29.
	ZUO Q, GAO Y Q. Reasons analysis and treatment of oil color reversion[J]. China Oils and Fats, 2003, 28(11): 26-29. (in Chinese with English abstract)
[5]	梁少华, 董彩文, 赵西周, 等. 脱臭工艺条件对棉籽油中反式脂肪酸含量的影响[J]. 中国油脂, 2010, 35(3): 54-58.
	LIANG S H, DONG C W, ZHAO X Z, et al. Effect of deodorizing conditions on trans-fatty acids content in cottonseed oil[J]. China Oils and Fats, 2010, 35(3): 54-58. (in Chinese with English abstract)
[6]	狄强, 刘渝阳. 食物安全观视角下的我国食用植物油安全保障体系构建[J]. 农村经济, 2021(10): 27-34.
	DI Q, LIU Y Y. Construction of edible vegetable oil safety guarantee system in China from the perspective of food safety[J]. Rural Economy, 2021(10): 27-34. (in Chinese)
[7]	张立伟. 上半年食用植物油市场运行状况及下半年展望[J]. 黑龙江粮食, 2021(8): 20-22.
	ZHANG L W. Operation status of edible vegetable oil market in the first half of the year and prospect in the second half of the year[J]. Journal of Heilongjiang Grain, 2021(8): 20-22. (in Chinese)
[8]	孟桂元, 涂洲溢, 詹兴国, 等. 我国植物油料油脂生产、消费需求分析及发展对策[J]. 中国油脂, 2020, 45(10): 1-4.
	MENG G Y, TU Z Y, ZHAN X G, et al. Development strategy and analysis of production and consumption demand of plant oilseeds and oils in China[J]. China Oils and Fats, 2020, 45(10): 1-4. (in Chinese with English abstract)
[9]	RAO P U. Nutrient composition of some less-familiar oil seeds[J]. Food Chemistry, 1994, 50(4): 379-382. DOI URL
[10]	邵岩, 马文广, 胡晋,编著. 烟草种子生产加工[M]. 北京: 科学出版社, 2017.
[11]	MUKHTAR A, ULLAH H, MUKHTAR H. Extraction and characterization of tobacco seed oil[J]. Asian Journal of Chemistry, 2006, 18: 20-24.
[12]	李晓辉. 残次烟叶与烟籽的开发利用[J]. 科技情报开发与经济, 1994(6): 10.
	LI X H. Development and utilization of defective tobacco leaves and tobacco seeds[J]. Sci/Tech Information Development & Economy, 1994(6): 10. (in Chinese)
[13]	RIEMENSCHNEIDER R W, SPECK R M, BEINHART E G. Analysis and fatty acid composition of tobacco seed oils[J]. Oil & Soap, 1945, 22(5): 120-122.
[14]	FREGA N, BOCCI F, CONTE L S, et al. Chemical composition of tobacco seeds (Nicotiana tabacum L.)[J]. Journal of the American Oil Chemists' Society, 1991, 68(1): 29-33.
[15]	KOIWAI A, SUZUKI F, MATSUZAKI T, et al. The fatty acid composition of seeds and leaves of Nicotiana species[J]. Phytochemistry, 1983, 22(6): 1409-1412. DOI URL
[16]	李斌, 米树华. ω-3和ω-6多不饱和脂肪酸对血脂代谢影响及相关机制[J]. 中国医药, 2013, 8(5): 710-712.
	LI B, MI S H. ω- 3 and ω- Effects of polyunsaturated fatty acids on blood lipid metabolism and related mechanism[J]. China Medicine, 2013, 8(5): 710-712. (in Chinese)
[17]	MATTIL K F, NORRIS F A, SWERN D. Bailey’s industrial oil and fat products[M]. 3rd ed. New York: Interscience Publishers, 1964: 213.
[18]	卢亭, 何计龙. 水浴静置皂化法测定食用植物油中皂化值[J]. 粮食与油脂, 2017, 30(6): 87-88.
19	LU T, HE J L. Water bath static saponification method for detecting saponification value in edible vegetable oils[J]. Cereals & Oils, 2017, 30(6): 87-88. (in Chinese with English abstract)
[19]	陆维锦. 可见分光光度法在食用油过氧化值测定中的应用[J]. 现代食品, 2017(10): 111-112.
	LU W J. The application of visible spectrophotometry in determination of peroxide value of edible oil[J]. Modern Food, 2017(10): 111-112. (in Chinese with English abstract)
[20]	江秀明, 周长智, 李建伟,等. 可见分光光度法测定食用油过氧化值[J]. 郑州粮食学院学报, 1999, 20(2):55-57.
	JIANG X M, ZHOU C Z, LI J W, et al. Determination of provinedible oil by visual spectrophotometer[J]. Journal of Zhengzhou Grain College, 1999, 20(2):55-57. (in Chinese with English abstract)
[21]	邹良明. 可见光谱法直接测定油脂碘值[J]. 粮食与油脂, 2015, 28(4): 56-57.
	ZOU L M. Direct measurement of oil iodine value through visible spectrometry[J]. Cereals & Oils, 2015, 28(4): 56-57. (in Chinese with English abstract)
[22]	王建华, 沈其萍. 食用植物油中酸价测定结果的不确定度评定[J]. 中国卫生检验杂志, 2004, 14(6): 783.
	WANG J H, SHEN Q P. Uncertainty evaluation of acid value determination in edible vegetable oil[J]. Chinese Journal of Health Laboratory Technology, 2004, 14(6): 783. (in Chinese)
[23]	王春锋, 王欢, 王媛媛, 等. 菜籽油与7种小宗植物油的营养比较及储存品质变化分析[J]. 食品安全导刊, 2020(33): 94-96.
	WANG C F, WANG H, WANG Y Y, et al. Nutritional comparison and storage quality analysis of rapeseed oil and seven small vegetable oils[J]. China Food Safety Magazine, 2020(33): 94-96. (in Chinese)
[24]	张雨萌, 高秀洁, 娄雨婷, 等. 海南山茶油理化性质及储存条件研究[J]. 生物化工, 2020, 6(5): 89-91.
	ZHANG Y M, GAO X J, LOU Y T, et al. Primary exploration on acidification and antioxidant properties of Hainan Camellia oil[J]. Biological Chemical Engineering, 2020, 6(5): 89-91. (in Chinese with English abstract)
[25]	山瑛. 浅谈植物油中皂化值的测定[J]. 中国卫生检验杂志, 2011, 21(3): 767.
	SHAN Y. Determination of saponification value in vegetable oil[J]. Chinese Journal of Health Laboratory Technology, 2011, 21(3): 767. (in Chinese)
[26]	陈少东, 陈福北, 杨帮乐, 等. 几种食用油中不饱和脂肪酸和皂化值的测定研究[J]. 化工技术与开发, 2011, 40(10): 53-55.
	CHEN S D, CHEN F B, YANG B L, et al. Determination of unsaturated fatty acid and saponification value of different edible oil[J]. Technology & Development of Chemical Industry, 2011, 40(10): 53-55. (in Chinese with English abstract)
[27]	闫大伟. 食用植物油脂品质监测及预警指标的研究[J]. 科技创新导报, 2016, 13(5): 83-84.
	YAN D W. Study on quality monitoring and early warning index of edible vegetable oil[J]. Science and Technology Innovation Herald, 2016, 13(5): 83-84. (in Chinese)
[28]	苏维丹. 食品中油脂提取及过氧化值检测方法的优化[J]. 商品与质量, 2017(26):113.
	SU W D. Optimization of oil extraction and peroxide value detection method in food[J]. Commodity and quality, 2017(26):113. (in Chinese)
[29]	程伟, 王国强, 尹清强. 饲用植物油脂的品质分析[J]. 黑龙江畜牧兽医, 2014(19): 106-108.
	CHENG W, WANG G Q, YIN Q Q. Quality analysis of forage vegetable oil[J]. Heilongjiang Animal Science and Veterinary Medicine, 2014(19): 106-108. (in Chinese)
[30]	于晨, 李双, 袁勇军, 等. 基于脂肪酸指标的调和植物油品质评析[J]. 食品安全质量检测学报, 2021, 12(6): 2073-2079.
	YU C, LI S, YUAN Y J, et al. Quality assessment of blended vegetable oil based on fatty acid index[J]. Journal of Food Safety & Quality, 2021, 12(6): 2073-2079. (in Chinese with English abstract)
[31]	陈昊. 几种天然植物油脂肪酸组成及其保健功能[J]. 科技创新导报, 2010, 7(20): 227-228.
	CHEN H. Fatty acid composition and health care function of several natural vegetable oils[J]. Science and Technology Innovation Herald, 2010, 7(20): 227-228. (in Chinese)
[32]	陈章捷, 张艳燕, 钟坚海, 等. 气相色谱法同时测定食品模拟物中己内酰胺和十二内酰胺[J]. 分析试验室, 2015, 34(12): 1447-1450.
	CHEN Z J, ZHANG Y Y, ZHONG J H, et al. Simultaneous determination of caprolactam and laurolactam in food simulants by gas chromatography[J]. Chinese Journal of Analysis Laboratory, 2015, 34(12): 1447-1450. (in Chinese with English abstract)
[33]	苗欣. 桂花油的提取及抗氧化研究[D]. 开封: 河南大学, 2018.
	MIAO X. Extraction process and antioxidant activities of Osmanthus fragrans oil[D]. Kaifeng: Henan University, 2018. (in Chinese with English abstract)
[34]	严欢, 邵家丽, 郑健琨, 等. 新疆小麦麸皮脂肪含量及脂肪酸组成分析[J]. 粮食与油脂, 2021, 34(5): 27-30.
	YAN H, SHAO J L, ZHENG J K, et al. Analysis of fat content and fatty acid composition of Xinjiang wheat bran[J]. Cereals & Oils, 2021, 34(5): 27-30. (in Chinese with English abstract)

品种Variety	酸价Acid value/(mg·g^-1)	皂化值Saponification value/(mg·g^-1)	比重Specific gravity/（g·cm^-3）	过氧化值Peroxide value/%	碘值Iodine value/（g·kg^-1）	折光率Refractive index
Burley21	0.75±0.01 d	185.04±16.35	0.84±0.05^b	1.17±0.09 ab	1 520.5±24.8 ab	1.468±0.008
NC89	0.60±0.01 e	178.38±3.35	0.82±0.03 b	1.33±0.12 a	1 558.5±49.8 a	1.471±0.001
Rustica	1.10±0.09 c	181.44±6.11	0.87±0.05 ab	1.26±0.24 a	1 431.0±45.1 c	1.470±0.002
保山4号 Baoshan 4	1.28±0.08 a	182.38±3.93	0.88±0.01 ab	0.93±0.05^b	1 464.4±66.2 bc	1.469 74±0.002
大竖把直把 Dashubazhiba	0.65±0.09 de	179.65±10.77	0.93±0.08 a	1.44±0.14 a	1 531.3±28.2 ab	1.472±0.001
红大 Hongda	0.60±0.01 e	185.13±7.22	0.83±0.03 b	1.18±0.10 ab	1523.8±25.1 ab	1.473±0.001
云香2号 Yunxiang 2	1.65±0.01^a	190.81±9.24	0.86±0.03 ab	1.14±0.12 ab	1 518.6±45.5 ab	1.472±0.001
云雪2号 Yunxue 2	0.68±0.08 de	176.13±6.58	0.88±0.04 ab	1.12±0.31 ab	1 410.7±66.0 c	1.472±0.001

品种Variety	酸价Acid value/(mg·g^-1)	皂化值Saponification value/(mg·g^-1)	比重Specific gravity/（g·cm^-3）	过氧化值Peroxide value/%	碘值Iodine value/（g·kg^-1）	折光率Refractive index
Burley21	0.75±0.01 d	185.04±16.35	0.84±0.05^b	1.17±0.09 ab	1 520.5±24.8 ab	1.468±0.008
NC89	0.60±0.01 e	178.38±3.35	0.82±0.03 b	1.33±0.12 a	1 558.5±49.8 a	1.471±0.001
Rustica	1.10±0.09 c	181.44±6.11	0.87±0.05 ab	1.26±0.24 a	1 431.0±45.1 c	1.470±0.002
保山4号 Baoshan 4	1.28±0.08 a	182.38±3.93	0.88±0.01 ab	0.93±0.05^b	1 464.4±66.2 bc	1.469 74±0.002
大竖把直把 Dashubazhiba	0.65±0.09 de	179.65±10.77	0.93±0.08 a	1.44±0.14 a	1 531.3±28.2 ab	1.472±0.001
红大 Hongda	0.60±0.01 e	185.13±7.22	0.83±0.03 b	1.18±0.10 ab	1523.8±25.1 ab	1.473±0.001
云香2号 Yunxiang 2	1.65±0.01^a	190.81±9.24	0.86±0.03 ab	1.14±0.12 ab	1 518.6±45.5 ab	1.472±0.001
云雪2号 Yunxue 2	0.68±0.08 de	176.13±6.58	0.88±0.04 ab	1.12±0.31 ab	1 410.7±66.0 c	1.472±0.001

脂肪酸 Fatty acid	缩写 Abbreviation	红大 Hongda	NC89	大竖把直把 Dashubazhiba	云雪2号 Yunxue 2	云香2号 Yunxiang 2	保山4号 Baoshan 4	Burley 21	Rustica
丁酸 Butryic acid	C4:0	0.80 ±0.69	0.61 ±0.53	0.59 ±0.51	0.75 ±0.68	0.73 ±0.66	1.02 ±0.19	0.90 ±0.11	0.63 ±0.04
己酸 Caproic acid	C6:0	—	—	—	0.10 ±0.11	—	—	—	—
肉豆蔻酸 Myristic acid	C14:0	0.36 ±0.04 a	0.27 ±0.01 b	0.28 ±0.04 ab	0.39 ±0.10 a	0.29 ±0.05 ab	0.31 ±0.02 ab	0.30 ±0.03 ab	0.26 ±0.02 b
棕榈酸 Palmitic acid	C16:0	104.24 ±13.75	92.94 ±6.07	92.45 ±12.31	102.80 ±26.44	95.50 ±12.88	106.08 ±9.66	93.52 ±12.96	96.03 ±10.82
棕榈油酸 Palmitoleic acid	C16:1	1.26 ±0.19 b	0.92 ±0.17 b	1.38 ±0.95 ab	1.19 ±0.26 b	1.32 ±0.31 b	1.53 ±0.19 ab	1.00 ±0.23 b	2.10 ±0.27 a
十七烷酸 Heptadecanoic acid	C17:0	1.35 ±0.19 ab	1.38 ±0.08 ab	1.33 ±0.08 ab	1.75 ±0.47 a	1.64 ±0.23 a	1.43 ±0.15 ab	1.36 ±0.22 ab	1.17 ±0.11 b
十七碳一烯酸 cis-10-Heptadecenoic acid	C17:1	0.61 ±0.07 ab	0.58 ±0.10 ab	0.62 ±0.02 ab	0.73 ±0.19 a	0.78 ±0.11 a	0.70 ±0.07 a	0.58 ±0.07 ab	0.51 ±0.02 b
硬脂酸 Stearic acid	C18:0	35.74 ±4.77	34.88 ±2.56	36.94 ±5.50	42.54 ±11.29	40.97 ±5.69	39.47 ±4.02	34.73 ±5.07	38.69 ±4.31
反油酸 Elaidic acid	C18:1n9t	—	—	—	—	—	—	—	36.14 ±62.60
油酸 Oleic acid	C18:1n9c	150.18 ±19.05	142.54 ±6.03	157.23 ±23.42	164.37 ±41.56	150.10 ±21.14	173.83 ±19.45	145.07 ±23.66	150.89 ±18.96
反亚油酸 Linolelaidic acid	C18:2n6t	4.00 ±0.63	3.42 ±0.17	4.22 ±0.38	4.14 ±2.23	4.89 ±1.31	4.65 ±1.15	4.03 ±0.76	4.28 ±0.58
亚油酸 Linoleic acid	C18:2n6c	894.71 ±118.25	772.41 ±159.95	832.42 ±39.01	944.20 ±243.61	857.40 ±118.16	841.63 ±72.00	879.69 ±126.66	781.79 ±124.41
α-亚油酸 α-Linolenic acid	C18:3n3	14.53 ±1.99	9.11 ±0.52	13.80 ±0.51	16.50 ±4.20	14.17 ±1.97	9.92 ±1.00	6.13 ±0.98	13.43 ±1.60
花生酸 Arachidic acid	C20:0	2.35 ±0.33	2.30 ±0.16	2.52 ±0.63	2.70 ±0.72	2.59 ±0.35	2.52 ±0.28	2.34 ±0.36	2.99 ±0.38
花生一烯酸 Eicosenoic acid	C20:1	1.61 ±0.19 a	1.49 ±0.09 a	1.37 ±0.18 ab	1.82 ±0.55 a	1.37 ±0.18 ab	1.54 ±0.15 a	1.55 ±0.22 a	0.93 ±0.13 b
花生二烯酸 Eicosadienoic acid	C20:2	1.20 ±0.23	1.05 ±0.13	0.96 ±0.06	1.15 ±0.49	1.02 ±0.26	0.95 ±0.10	1.06 ±0.14	0.92 ±0.07
二十一碳酸 Henicosanoic acid	C21:0	0.13 ±0.22	0.20 ±0.18	0.12 ±0.21	0.14 ±0.24	0.13 ±0.23	—	0.10 ±0.18	—
二十碳五烯酸 cis-5,8,11,14,17-Eicosapentaenoic acid	C20:5n3	—	—	0.26 ±0.45	—	—	—	—	—
山嵛酸（二十二烷酸） Behenic acid	C22:0	0.96 ±0.12 abc	0.93 ±0.06 bc	0.97 ±0.15 abc	0.82 ±0.22 c	1.10 ±0.12 abc	1.23 ±0.15 a	1.13 ±0.16 ab	1.07 ±0.15 abc
芥酸 Erucic acid	C22:1n9	0.22 ±0.39	—	0.25 ±0.43	—	0.20 ±0.34	—	—	—
二十三酸 Tricosanoic acid	C23:0	0.40 ±0.69	—	0.43 ±0.74	—	0.36 ±0.63	—	—	—
二十四酸 Lignoceric acid	C24:0	2.41 ±1.24 b	1.23 ±0.38 b	4.26 ±2.09 a	0.93 ±0.09 b	0.91 ±0.61 b	0.83 ±0.28 b	0.67 ±0.11b	0.87 ±0.29 b
二十四碳单烯酸 Nervonic acid	C24:1	2.00 ±1.46 ab	0.74 ±0.31 ab	4.77 ±5.65 a	0.77 ±0.12 ab	1.49 ±1.65 ab	0.57 ±0.56 b	0.50 ±0.43 b	0.19 ±0.33 b
饱和脂肪酸 Saturated fatty acids	SFA	148.74	134.74	139.89	152.92	144.22	152.89	135.05	141.78
单不饱和脂肪酸 Monounsaturated fatty acids	MUFA	155.88	146.27	165.62	168.88	155.26	178.17	148.70	190.76
多不饱和脂肪酸 Polyunsaturated fatty acids	PUFA	914.44	785.99	851.66	965.99	877.48	857.15	890.91	800.42
总和 Sum	SUM	1219.06	1067.01	1157.17	1287.77	1176.97	1188.20	1174.66	1132.97
多不饱和脂肪酸/饱和脂肪酸Polyunsaturated fatty acids/ Saturated fatty acids	PUFA/SFA	6.15	5.83	6.09	6.32	6.08	5.61	6.60	5.65

脂肪酸 Fatty acid	缩写 Abbreviation	红大 Hongda	NC89	大竖把直把 Dashubazhiba	云雪2号 Yunxue 2	云香2号 Yunxiang 2	保山4号 Baoshan 4	Burley 21	Rustica
丁酸 Butryic acid	C4:0	0.80 ±0.69	0.61 ±0.53	0.59 ±0.51	0.75 ±0.68	0.73 ±0.66	1.02 ±0.19	0.90 ±0.11	0.63 ±0.04
己酸 Caproic acid	C6:0	—	—	—	0.10 ±0.11	—	—	—	—
肉豆蔻酸 Myristic acid	C14:0	0.36 ±0.04 a	0.27 ±0.01 b	0.28 ±0.04 ab	0.39 ±0.10 a	0.29 ±0.05 ab	0.31 ±0.02 ab	0.30 ±0.03 ab	0.26 ±0.02 b
棕榈酸 Palmitic acid	C16:0	104.24 ±13.75	92.94 ±6.07	92.45 ±12.31	102.80 ±26.44	95.50 ±12.88	106.08 ±9.66	93.52 ±12.96	96.03 ±10.82
棕榈油酸 Palmitoleic acid	C16:1	1.26 ±0.19 b	0.92 ±0.17 b	1.38 ±0.95 ab	1.19 ±0.26 b	1.32 ±0.31 b	1.53 ±0.19 ab	1.00 ±0.23 b	2.10 ±0.27 a
十七烷酸 Heptadecanoic acid	C17:0	1.35 ±0.19 ab	1.38 ±0.08 ab	1.33 ±0.08 ab	1.75 ±0.47 a	1.64 ±0.23 a	1.43 ±0.15 ab	1.36 ±0.22 ab	1.17 ±0.11 b
十七碳一烯酸 cis-10-Heptadecenoic acid	C17:1	0.61 ±0.07 ab	0.58 ±0.10 ab	0.62 ±0.02 ab	0.73 ±0.19 a	0.78 ±0.11 a	0.70 ±0.07 a	0.58 ±0.07 ab	0.51 ±0.02 b
硬脂酸 Stearic acid	C18:0	35.74 ±4.77	34.88 ±2.56	36.94 ±5.50	42.54 ±11.29	40.97 ±5.69	39.47 ±4.02	34.73 ±5.07	38.69 ±4.31
反油酸 Elaidic acid	C18:1n9t	—	—	—	—	—	—	—	36.14 ±62.60
油酸 Oleic acid	C18:1n9c	150.18 ±19.05	142.54 ±6.03	157.23 ±23.42	164.37 ±41.56	150.10 ±21.14	173.83 ±19.45	145.07 ±23.66	150.89 ±18.96
反亚油酸 Linolelaidic acid	C18:2n6t	4.00 ±0.63	3.42 ±0.17	4.22 ±0.38	4.14 ±2.23	4.89 ±1.31	4.65 ±1.15	4.03 ±0.76	4.28 ±0.58
亚油酸 Linoleic acid	C18:2n6c	894.71 ±118.25	772.41 ±159.95	832.42 ±39.01	944.20 ±243.61	857.40 ±118.16	841.63 ±72.00	879.69 ±126.66	781.79 ±124.41
α-亚油酸 α-Linolenic acid	C18:3n3	14.53 ±1.99	9.11 ±0.52	13.80 ±0.51	16.50 ±4.20	14.17 ±1.97	9.92 ±1.00	6.13 ±0.98	13.43 ±1.60
花生酸 Arachidic acid	C20:0	2.35 ±0.33	2.30 ±0.16	2.52 ±0.63	2.70 ±0.72	2.59 ±0.35	2.52 ±0.28	2.34 ±0.36	2.99 ±0.38
花生一烯酸 Eicosenoic acid	C20:1	1.61 ±0.19 a	1.49 ±0.09 a	1.37 ±0.18 ab	1.82 ±0.55 a	1.37 ±0.18 ab	1.54 ±0.15 a	1.55 ±0.22 a	0.93 ±0.13 b
花生二烯酸 Eicosadienoic acid	C20:2	1.20 ±0.23	1.05 ±0.13	0.96 ±0.06	1.15 ±0.49	1.02 ±0.26	0.95 ±0.10	1.06 ±0.14	0.92 ±0.07
二十一碳酸 Henicosanoic acid	C21:0	0.13 ±0.22	0.20 ±0.18	0.12 ±0.21	0.14 ±0.24	0.13 ±0.23	—	0.10 ±0.18	—
二十碳五烯酸 cis-5,8,11,14,17-Eicosapentaenoic acid	C20:5n3	—	—	0.26 ±0.45	—	—	—	—	—
山嵛酸（二十二烷酸） Behenic acid	C22:0	0.96 ±0.12 abc	0.93 ±0.06 bc	0.97 ±0.15 abc	0.82 ±0.22 c	1.10 ±0.12 abc	1.23 ±0.15 a	1.13 ±0.16 ab	1.07 ±0.15 abc
芥酸 Erucic acid	C22:1n9	0.22 ±0.39	—	0.25 ±0.43	—	0.20 ±0.34	—	—	—
二十三酸 Tricosanoic acid	C23:0	0.40 ±0.69	—	0.43 ±0.74	—	0.36 ±0.63	—	—	—
二十四酸 Lignoceric acid	C24:0	2.41 ±1.24 b	1.23 ±0.38 b	4.26 ±2.09 a	0.93 ±0.09 b	0.91 ±0.61 b	0.83 ±0.28 b	0.67 ±0.11b	0.87 ±0.29 b
二十四碳单烯酸 Nervonic acid	C24:1	2.00 ±1.46 ab	0.74 ±0.31 ab	4.77 ±5.65 a	0.77 ±0.12 ab	1.49 ±1.65 ab	0.57 ±0.56 b	0.50 ±0.43 b	0.19 ±0.33 b
饱和脂肪酸 Saturated fatty acids	SFA	148.74	134.74	139.89	152.92	144.22	152.89	135.05	141.78
单不饱和脂肪酸 Monounsaturated fatty acids	MUFA	155.88	146.27	165.62	168.88	155.26	178.17	148.70	190.76
多不饱和脂肪酸 Polyunsaturated fatty acids	PUFA	914.44	785.99	851.66	965.99	877.48	857.15	890.91	800.42
总和 Sum	SUM	1219.06	1067.01	1157.17	1287.77	1176.97	1188.20	1174.66	1132.97
多不饱和脂肪酸/饱和脂肪酸Polyunsaturated fatty acids/ Saturated fatty acids	PUFA/SFA	6.15	5.83	6.09	6.32	6.08	5.61	6.60	5.65

挥发性有机物Volatile organic compounds	红大 Hongda	NC89	大竖把直把 Dashubazhiba	云雪2号 Yunxue 2	云香2号 Yunxiang 2	保山4号 Baoshan 4	Burley 21	Rustica
己内酰胺 Caprolactam	0.66	0.64	0.64	0.99	1.00	1.11	0.69	0.80
棕榈酸甲酯Hexadecanoic acid, methyl ester	—	1.12	1.01	0.83	1.13	0.85	0.78	0.58
棕榈酸n-Hexadecanoic acid	10.89	8.79	6.87	7.54	8.87	8.69	5.32	8.59
亚油酸甲酯9,12-Octadecadienoic acid, methyl ester	2.56	3.32	3.82	3.51	3.65	2.91	2.97	2.40
油酸甲酯9-Octadecenoic acid (Z)-, methyl ester	1.00	0.76	1.04	1.18	1.12	0.83	0.83	—
亚油酸9,12-Octadecadienoic acid (Z,Z)-	24.96	13.37	14.79	25.73	17.39	25.68	17.99	22.88
2,2'-亚甲基双-(4-甲基-6-叔丁基苯酚) Phenol, 2,2'-methylenebis[6-(1,1-dmethylethyl)-4-methyl-	2.71	2.78	1.72	1.51	1.52	1.95	2.34	2.12

不同烟草品种烟籽油理化性质及脂肪酸和挥发性成分评价

Evaluation of physicochemical properties, fatty acids and volatile components of different tobacco seed oils

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