Determination of 39 fatty acids in liver of rats by gas chromatography-mass spectrometry

doi:10.3724/SP.J.1123.2022.09014

Abstract

Abstract:

Fatty acids not only form phospholipids that contribute to the formation of cell membranes but also participate in many metabolic activities, such as energy storage and cell signal transduction. The liver plays a key role in the synthesis and metabolism of fatty acids. The composition and contents of fatty acids in the liver are closely related to body health. Most fatty acid-detection methods require a large sample size and can detect only a small number of fatty acids. Therefore, a sensitive and efficient method to determine fatty acids in the liver is urgently required. Herein, a method based on gas chromatography-mass spectrometry (GC-MS) was established for the simultaneous determination of 39 fatty acids in 1.1 mg of liver tissue. Different extraction methods and derivatization conditions were compared to develop an optimal sample-treatment method. The performance of two different columns in separating the target fatty acids were also compared. A total of 10 mg of liver was added to 450 μL of normal saline and ground at -35 ℃ to obtain a homogenate. Next, 50 μL of the homogenate (equivalent to 1.1 mg of liver) was added with 750 μL of chloroform-methanol (1∶2, v/v) to extract total fatty acids. The fatty acid extracts were dried under nitrogen, and then derivatized at 100 ℃ for 90 min after being added with methanol containing 5% sulfuric acid. The fatty acid methyl esters were extracted with hexane and then separated on an SP-2560 capillary column (100 m×0.25 mm×0.2 μm; Supelco, USA) via GC-MS. The results revealed that all 39 fatty acid methyl esters detected had good linearities in the certain mass concentration ranges with correlation coefficients (R²) greater than 0.9940. The limits of detection (LOD) and quantification (LOQ) of these methyl esters in the liver were 2-272 ng/mg and 7-906 ng/mg, respectively. The accuracy and precision of the method were evaluated by spiking the liver homogenate with tridecylic acid and eicosanoic acid at low (0.09 μg/mg), moderate (0.90 μg/mg), and high (5.40 μg/mg) concentration levels. The recoveries ranged from 82.4% to 101.0% with an intraday relative standard deviations (RSDs) (n=5) of 3.2%-12.0% and interday RSDs (n=3) of 5.4%-13.4%. The method was successfully applied to detect fatty acids in the livers of four healthy male Sprague-Dawley (SD) rats and four male SD rats with abnormal liver function induced by perfluorooctane sulfonate (PFOS). PFOS is a persistent organic pollutant. Twenty-six fatty acids were detected in the livers of both groups. Among the fatty acids investigated, pentadecanoic acid (C15∶0), γ-linolenic acid (C18∶3n6), and elaidic acid (C18∶1n9t) cannot be detected by the methods reported in the literature. By contrast, the method developed in this study could separate the isomers of oleic acid (elaidic acid, C18∶1n9t; oleic acid, C18∶1n9c) and linolenic acid (linolelaidic acid, C18∶2n6t; linoleic acid, C18∶2n6c). In conclusion, the developed method is simple and can detect a large number of fatty acids using small sample amounts and few reagents. More importantly, it could successfully separate fatty acid isomers. These findings indicate that the developed method is suitable for the detection of fatty acid composition and contents in the liver in clinical and experimental research.

Key words: gas chromatography-mass spectrometry (GC-MS), fatty acids, liver

CLC Number:

O658

WU Yingxia, MU Yan, LIU Peishan, ZHANG Yitian, ZENG Yingxuan, ZHOU Zhifeng. Determination of 39 fatty acids in liver of rats by gas chromatography-mass spectrometry[J]. Chinese Journal of Chromatography, 2023, 41(5): 443-449.

Figures/Tables 8

Fig. 1 Total ion current chromatograms of the 39 fatty acid methyl esters and internal standard (IS) in mixed standard solutions separated on (a) SP-2560 column and (b) DB-23 column Contents of the fatty acids: C16∶0 at 40 μg/mL, other fatty acid methyl esters at 20 μg/mL and IS at 10 μg/mL. Peak identifications: 1. methyl hexanoate (C6∶0); 2. methyl octanoate (C8∶0); 3. methyl decanoate (C10∶0); 4. methyl undecanoate (C11∶0); 5. methyl laurate (C12∶0); 6. methyl tridecanoate (C13∶0); 7. methyl tetradecanoate (C14∶0); 8. methyl myristoleate (C14∶1); 9. methyl pentadecanoate (C15∶0); 10. methyl cis-10-pentadecenoate (C15∶1); 11. methyl palmitate (C16∶0); 12. methyl palmitoleate (C16∶1); 13. methyl heptadecanoate (C17∶0); 14. cis-10-heptadecanoic acid methyl ester (C17∶1); 15. methyl stearate (C18∶0); 16. trans-9-elaidic acid methyl ester (C18∶1n9t); 17. cis-9-oleic acid methyl ester (C18∶1n9c); 18. methyl decanoate (C19∶0, IS); 19. methyl linolelaidate (C18∶2n6t); 20. methyl linoleate (C18∶2n6c); 21. methyl arachidate (C20∶0); 22. methyl γ-linolenate (C18∶3n6); 23. methyl cis-11-eicosenoate (C20∶1); 24. methyl linolenate (C18∶3n3); 25. methyl heneicosanoate (C21∶0); 26. cis-11,14-eicosadienoic acid methyl ester (C20∶2); 27. methyl behenate (C22∶0); 28. cis-8,11,14-eicosatrienoic acid methyl ester (C20∶3n6); 29. methyl erucate (C22∶1n9); 30. cis-11,14,17-eicosatrienoic acid methyl ester (C20∶3n3); 31. methyl tricosanoate (C23∶0); 32. cis-5,8,11,14-eicosatetraenoic acid methyl ester (C20∶4n6); 33. cis-13,16-docosadienoic acid methyl ester (C22∶2); 34. methyl lignocerate (C24∶0); 35. cis-5,8,11,14,17-eicosapentaenoic acid methyl ester (C20∶5n3); 36. methyl nervonate (C24∶1); 37. cis-13,16,19-docosatrienoic acid methyl ester (C22∶3); 38. cis-7,10,13,16-docosatetraenoic acid methyl ester (C22∶4n6); 39. cis-4,7,10,13,16,19-docosahexaenoic acid methyl ester (C22∶5); 40. cis-4,7,10,13,16,19-docosahexaenoic acid methyl ester (C22∶6n3).

Fig. 2 Effects of extraction methods on the contents of the fatty acids from liver (n=3)

Fig. 3 Effect of different derivatization methods on the contents of fatty acids from liver (n=3)

Fig. 4 Effects of (a) volume fractions of sulfate in methanol, (b) derivatization temperatures and (c) derivatization times on the contents of fatty acids from liver (n=3)

Table 1 Linear ranges, correlation coefficients (R2), LODs and LOQs of the 39 fatty acid methyl esters

Compound	Linear range/ (μg/mL)		R²	LOD/ (μg/mg)	LOQ/ (μg/mg)	Compound	Linear range/ (μg/mL)		R²	LOD/ (μg/mg)	LOQ/ (μg/mg)
C6∶0	0.115-	28.680	0.9997	0.004	0.013	C18∶3n6	0.115-	28.680	0.9983	0.074	0.246
C8∶0	0.115-	28.680	0.9997	0.004	0.012	C20∶1	0.115-	17.208	0.9995	0.013	0.043
C10∶0	0.115-	28.680	0.9982	0.004	0.014	C18∶3n3	0.574-	57.360	0.9981	0.075	0.249
C11∶0	0.115-	28.680	0.9940	0.005	0.018	C21∶0	0.115-	17.208	0.9976	0.003	0.011
C12∶0	0.115-	17.208	0.9971	0.008	0.026	C20∶2	1.147-	57.360	0.9996	0.012	0.040
C13∶0	0.115-	286.801	0.9977	0.007	0.022	C22∶0	0.115-	28.680	0.9945	0.002	0.007
C14∶0	0.115-	28.680	0.9998	0.009	0.030	C20∶3n6	1.147-	172.081	0.9997	0.015	0.050
C14∶1	0.115-	28.680	0.9967	0.034	0.113	C22∶1n9	0.115-	28.680	0.9990	0.008	0.025
C15∶0	0.115-	28.680	0.9996	0.014	0.047	C20∶3n3	0.574-	28.680	0.9978	0.147	0.492
C15∶1	0.115-	28.680	0.9985	0.021	0.068	C23∶0	0.057-	286.801	0.9970	0.008	0.025
C16∶0	11.472-	803.044	0.9989	0.003	0.011	C20∶4n6	5.736-	401.522	0.9961	0.006	0.021
C16∶1	0.574-	28.680	0.9952	0.125	0.416	C22∶2	0.115-	28.680	0.9968	0.007	0.023
C17∶0	1.147-	172.081	1.0000	0.015	0.051	C24∶0	0.115-	28.680	0.9986	0.005	0.016
C17∶1	0.574-	28.680	0.9978	0.107	0.356	C20∶5	0.115-	28.680	0.9988	0.019	0.062
C18∶0	5.736-	401.522	0.9995	0.002	0.007	C24∶1	0.574-	57.360	0.9974	0.019	0.063
C18∶1n9t	0.574-	57.360	0.9985	0.137	0.457	C22∶3	0.402-	60.300	0.9999	0.015	0.049
C18∶1n9c	5.736-	286.802	0.9973	0.021	0.069	C22∶4n6	0.382-	57.300	0.9986	0.014	0.045
C18∶2n6t	0.574-	28.680	0.9961	0.272	0.906	C22∶5	0.438-	65.700	0.9988	0.010	0.033
C18∶2n6c	5.736-	401.522	0.9967	0.008	0.027	C22∶6n3	2.868-	286.801	0.9998	0.003	0.010
C20∶0	0.115-	17.208	0.9991	0.002	0.007

Table 2 Recoveries, intra-day RSDs and inter-day RSDs of tridecanoic acid and tricosanoic acid added in liver

Compound	Spiked/ (μg/mg)	Recovery (n=5)/%	Intra-day RSD (n=5)/%	Inter-day RSD (n=3)/%
Tridecanoic	0.09	85.9	9.9	8.2
acid	0.90	101.0	5.3	5.4
	5.40	95.5	9.5	12.9
Tricosanoic	0.09	99.9	12.0	13.2
acid	0.90	82.4	3.2	9.0
	5.40	89.0	5.1	13.4

Table 3 Contents of different fatty acids in the liver of healthy and perfluorooctane sulfonate (PFOS) exposed rats (n=4)

Compound	PFOS/(μg/mg)	Healthy/(μg/mg)
C12∶0	0.017±0.001	0.042±0.017
C16∶0	25.237±2.634	18.090±5.037
C20∶0	0.043±0.017	0.152±0.017
C20∶1	0.077±0.003	0.223±0.098
C21∶0	0.211±0.036	0.103±0.037
C20∶2	0.139±0.057	0.277±0.083
C22∶0	0.048±0.040	0.180±0.058
C20∶3n6	1.101±0.309	0.384±0.083
C20∶3n3	0.039±0.022	0.166±0.015
C24∶0	0.183±0.034	0.274±0.049
C20∶5	0.167±0.059	0.369±0.150

Table 4 Comparison of this method with the literature methods

Reference	Sample amount of liver	Number of fatty acids	Separated isomers
This work	1.1 mg	39	C18∶2n6t, C18∶2n6c;
			C18∶1n9t, C18∶1n9c
[3]	not mentioned	13	none
[9]	100 mg	24	none
[14]	200 mg	23	none
[16]	5 mg	15	none

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