三相中空纤维液相微萃取-高效液相色谱法测定铁皮石斛和金线莲中3种植物生长调节剂

doi:10.3724/SP.J.1123.2023.03007

摘要/Abstract

摘要：

在铁皮石斛和金线莲药材的人工培育过程中通常需要使用各种植物生长调节剂(PGRs),然而使用过量的PGRs不仅会影响药材的品质和疗效,而且会引发一系列的安全性问题,因此建立精准分析测定药材中残留的痕量PGRs技术方法具有重要意义。本研究基于三相中空纤维液相微萃取(3P-HF-LPME)-高效液相色谱法,建立了一种同时测定铁皮石斛和金线莲药材中吲哚乙酸、吲哚丁酸、萘乙酸3种PGRs的分析方法。首先通过参数优化确定最佳色谱条件,然后采用超声+低温静置的提取手段制备样本溶液,优化影响3P-HF-LPME萃取效果的各个参数。确定的最佳前处理过程如下:以正辛醇作为中间相(萃取剂), pH 11.0的氢氧化钠溶液作为内相,稀盐酸调节外相溶液pH值为3.0,并在外相溶液中添加质量浓度为150 g/L的氯化钠溶液,在温度为40 ℃、搅拌速度为1600 r/min条件下萃取2.0 h。3种PGRs采用Welch Ultimate XB-C₁₈色谱柱(250 mm×4.6 mm, 5 μm)进行分离,以乙酸水溶液-甲醇(45∶55, v/v)为流动相进行等度洗脱。实验结果表明,在优化的条件下,所测定的3种PGRs在0.5~100.0 μg/L范围内线性关系良好(决定系数(r²)=0.9999),检出限(LOD)为0.02~0.15 μg/L,加标回收率为88.5%~102.2%,相对标准偏差(RSD)≤3.7%(n=3)。该方法对铁皮石斛和金线莲药材中3种PGRs的萃取效率为42.0%~86.8%,富集倍数为140~289。该方法灵敏、准确、可靠、环保,且富集倍数高,适用于铁皮石斛和金线莲药材中残留的微量酸性PGRs的检测。

关键词: 三相中空纤维液相微萃取, 高效液相色谱, 植物生长调节剂, 铁皮石斛

Abstract:

Dendrobium officinale (D. officinale) and Anoectochilus roxburghii (A. roxburghii) are precious raw materials for traditional Chinese medicine. The growing demand for D. officinale and A. roxburghii cannot be met by current production techniques. Hence, the widespread artificial cultivation of D. officinale and A. roxburghii using substantial amounts of plant growth regulators (PGRs) has emerged. The excessive use of PGRs not only affects the quality and efficacy of medicinal materials but also causes a series of safety issues. Therefore, expanding research on residual PGRs in valuable Chinese medicinal materials is important to avoid the health hazards caused by these substances. Unfortunately, the identification of PGRs is challenging because of their trace and complex matrices.

High performance liquid chromatography (HPLC) has become one of the mainstream analytical methods for PGR determination. An important consideration in the application of this technique to the detection of trace acidic PGRs is how to improve its accuracy and sensitivity. Three-phase hollow fiber liquid phase microextraction (3P-HF-LPME) has the advantages of a high enrichment factor, complex sample purification ability, low reagent consumption, low cost, and easy integration with chromatographic systems. Thus, the 3P-HF-LPME method overcomes the many shortcomings of traditional sample pretreatment methods. In this study, a novel, simple, and effective analytical method based on 3P-HF-LPME combined with HPLC was developed to extract, purify, enrich, and detect three trace acidic PGRs (indole-3-acetic acid, naphthyl acetic acid and indolebutyric acid) in D. officinale and A. roxburghii. The chromatographic separation conditions and 3P-HF-LPME model parameters were systematically optimized for this purpose. First, the sample solution was prepared by ultrasonication and low-temperature standing, and then adjusted to pH 3.0 using dilute hydrochloric acid. The sample solution (10 mL) and NaCl (1.50 g) were stored in a 15 mL brown extraction bottle with a built-in magnetic stirrer. Next, 30 μL of NaOH solution (pH 11.0) as the inner phase solution was injected into the inner cavity of a hollow fiber tube, which was subsequently sealed at both ends. The hollow fiber tube was soaked in n-octanol for 5 min and dried naturally to remove excess extraction solvent from its surface. Finally, the fiber tube was placed in a brown extraction bottle and stirred using a thermostatic magnetic stirrer at 40 ℃ and 1600 r/min for 2 h. After extraction, the three target analytes were separated on a Welch Ultimate XB-C₁₈ column (250 mm×4.6 mm, 5 μm) under isocratic elution conditions using acetic acid aqueous solution and methanol (45∶55, v/v) as the eluent. The results indicated that the three PGRs showed good linearity in the range of 0.5-100.0 μg/L (coefficients of determination (r²)=0.9999), with limits of detection (LODs) of 0.02-0.15 μg/L. The method recoveries were 88.5-102.2%, with relative standard deviations (RSDs) of less than 3.7% (n=3). The extraction efficiencies and enrichment factors of the three PGRs in 15 batches of fresh D. officinale and A. roxburghii products were found to be 42.0%-86.8% and 140-289. Full-scan mass spectrometry was used to further identify positive samples to avoid false-positive results and enhance the reliability of the experimental method. In summary, the proposed method is sensitive, accurate, reliable, environment friendly, and capable of high enrichment. It could be used to determine the residues of three acidic PGRs in D. officinale and A. roxburghii. Moreover, it can provide technical support for the residue detection of PGRs in other Chinese medicinal materials.

Key words: three-phase hollow fiber liquid phase microextraction (3P-HF-LPME), high performance liquid chromatography (HPLC), plant growth regulators (PGRs), Dendrobium officinale

中图分类号:

O658

吴萍萍, 林仁义, 黄丽英. 三相中空纤维液相微萃取-高效液相色谱法测定铁皮石斛和金线莲中3种植物生长调节剂[J]. 色谱, 2023, 41(8): 683-689.

WU Pingping, LIN Renyi, HUANG Liying. Determination of three plant growth regulators in Dendrobium officinale and Anoectochilus roxburghii by three-phase hollow fiber liquid phase microextraction- high performance liquid chromatography[J]. Chinese Journal of Chromatography, 2023, 41(8): 683-689.

图/表 8

表1 铁皮石斛和金线莲样品信息

Table 1 Sample information of D. officinale and A. roxburghii

Name of medicinal material	Source	Nos.	Number of batches
Dendrobium officinale (Wall.) ex Lindl.	Fujian Yonggeng Agricultural Development Co., Ltd.	A	1
(D. officinale)	Fuqing Jiajia Agricultural Development Co., Ltd.	B	1
	Fuzhou Youye Agricultural Development Co., Ltd.	C1-C6	6
	Fujian Kanglin Agricultural Development Co., Ltd.	D1, D2	2
Anoectochilus roxburghii (Wall.) Lindl.	Fuzhou Youye Agricultural Development Co., Ltd.	E1, E2	2
(A. roxburghii)	Fujian Kanglin Agricultural Development Co., Ltd.	F1-F3	3

图1 萃取剂对萃取效率的影响

Fig. 1 Effects of extraction solvent on the extraction efficiencies IAA: indole-3-acetic acid; IBA: indolebutyric acid; NAA: naphthyl acetic acid.

图2 内外相pH值对萃取效率的影响

Fig. 2 Effects of pH of external and internal phase on the extraction efficiencies

图3 不同盐添加量对萃取效率的影响

Fig. 3 Effects of different amount of sodium chloride on the extraction efficiencies

表2 3种PGRs的回归方程、线性范围、检出限、定量限和富集倍数

Table 2 Regression equations, linear ranges, LODs, LOQs and enrichment factors (EFs) of the three PGRs

Analyte	Regression equation	r²	Linear range/(μg/L)	LOD/(μg/L)	LOQ/(μg/L)	EF
IAA	Y=0.00580X-0.00030	0.9999	0.5-100.0	0.15	0.50	140
IBA	Y=0.00930X-0.00080	0.9999	0.5-100.0	0.10	0.33	267
NAA	Y=0.01360X+0.00200	0.9999	0.5-100.0	0.02	0.06	289

表3 3种PGRs在铁皮石斛样品中的加标回收率及其RSD(n=3)

Table 3 Spiked recoveries and RSDs of the three PGRs in a D. officinale sample (n=3)

Analyte	Added/(μg/g)	Found/(μg/g)	Recovery/%	RSD/%
IAA	1.0	1.02	101.4	2.0
	2.0	2.04	102.2	2.9
	4.0	3.92	98.3	2.4
IBA	1.0	0.91	90.5	3.7
	2.0	1.89	94.5	1.6
	4.0	3.54	88.5	2.1
NAA	1.0	0.92	92.4	1.3
	2.0	2.01	101.1	1.6
	4.0	3.75	93.8	2.0

图4 混合标准溶液、D1样品溶液及空白样品加标溶液萃取前后的色谱图

Fig. 4 Chromatograms of mixed standard solution, D1 sample solution and blank sample solution spiked with standards before and after extraction a. mixed working solution at 10 μg/L; b,c. D1 sample solution (b) before and (c) after extraction; d,e. blank sample solution spiked with standards at 40 μg/L (d) before and (e) after extraction.

图5 标准品与样本溶液萃取后的质谱图

Fig. 5 Mass spectra of PGRs standards and samples after extraction

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