基于定量指纹图谱技术的经典名方清骨散基准样品量值传递分析

doi:10.3724/SP.J.1123.2022.09024

色谱 ›› 2023, Vol. 41 ›› Issue (2): 142-151.DOI: 10.3724/SP.J.1123.2022.09024

基于定量指纹图谱技术的经典名方清骨散基准样品量值传递分析

徐鑫¹^,², 魏彤³, 薛倩倩¹^,², 艾嘉浩¹^,², 李桂馨³, 刘忠国³, 李丹⁴, 侯金才⁴, 金红利¹^,²^,³^,^*(), 刘艳芳¹^,²^,³, 梁鑫淼¹^,²^,³

1.赣江中药创新中心, 江西南昌 330000
2.江西省中药药效物质基础重点实验室, 江西南昌 330000
3.中国科学院大连化学物理研究所, 辽宁大连 116023
4.神威药业集团有限公司, 河北石家庄 051430

收稿日期:2022-09-25 出版日期:2023-02-08 发布日期:2023-02-01
通讯作者: 金红利
基金资助:
江西省“双千计划”;赣江新区重点研发项目(2020005)

Analysis on quality value transmitting of Qinggusan reference sample of classical prescription based on quantitative fingerprint technology

XU Xin¹^,², WEI Tong³, XUE Qianqian¹^,², AI Jiahao¹^,², LI Guixin³, LIU Zhongguo³, LI Dan⁴, HOU Jincai⁴, JIN Hongli¹^,²^,³^,^*(), LIU Yanfang¹^,²^,³, LIANG Xinmiao¹^,²^,³

1. Ganjiang Chinese Medicine Innovation Center, Nanchang 330000, China
2. Jiangxi Provincial Key Laboratory for Pharmacodynamic Material Basis of Traditional Chinese Medicine, Nanchang 330000, China
3. Dalian Institute of Chemical Physics, Chinese Academy of Sciences, Dalian 116023, China
4. Shineway Pharmaceutical Group Co., Ltd., Shijiazhuang 051430, China

Received:2022-09-25 Online:2023-02-08 Published:2023-02-01
Contact: JIN Hongli
Supported by:
Jiangxi“Double Thousand Plan”;Key R&D Program of Ganjiang New Area,Jiangxi(2020005)

摘要/Abstract

摘要：

清骨散为第一批《古代经典名方目录》中的第69方,现代临床常用于治疗非感染性发热。但目前关于清骨散基准样品及其量值传递的研究较少,制约了其复方制剂的研发与上市,因此亟须建立一种全面、准确的质量控制方法,阐明关键质量属性。通过制备15批清骨散基准样品,明确干膏率范围,建立基准样品高效液相色谱(HPLC)定量指纹图谱测定方法并进行相似度评价,采用高效液相色谱-四极杆-飞行时间质谱(HPLC-Q-TOF-MS)技术对特征峰进行指认与归属,结合指标成分龙胆苦苷、芒果苷、胡黄连苷Ⅱ、胡黄连苷Ⅰ和甘草酸的含量范围及转移率范围进行量值传递分析。结果表明,15批清骨散基准样品的干膏率为24.10%~26.88%,指纹图谱相似度均大于0.95,对12个共有峰进行指认,包括6个环烯醚萜类、2个黄酮类、1个生物碱类、1个三萜皂苷类以及2个其他类,其中5个成分来源于胡黄连,3个成分来源于秦艽,2个成分来源于知母,1个成分来源于银柴胡,1个成分来源于甘草;15批基准样品中指标成分的含量范围分别为龙胆苦苷17.92~27.55 mg/g、芒果苷1.83~4.42 mg/g、胡黄连苷Ⅱ 23.08~36.44 mg/g、胡黄连苷Ⅰ 8.43~15.04 mg/g、甘草酸0.94~2.39 mg/g,从饮片到基准样品的转移率分别为龙胆苦苷47.91%~63.95%、芒果苷22.96%~59.39%、胡黄连苷Ⅱ 60.82%~77.82%、胡黄连苷Ⅰ 64.25%~99.53%、甘草酸15.30%~39.30%。该研究通过清骨散基准样品定量指纹图谱与质谱定性技术相结合,基本明确其化学组成,进行量值传递研究,阐明关键质量属性,为清骨散复方制剂的质量控制提供依据。

关键词: 定量指纹图谱, 量值传递, 清骨散, 基准样品

Abstract:

Qinggusan is the 69th prescription in the first batch of “Catalogue of Ancient Chinese Classic Formulas”. In modern clinical practice, Qinggusan is mainly used to treat noninfectious fever. However, because few studies on Qinggusan reference samples and their quality value transfer are available, the development and promotion of its compound preparations are restricted. Therefore, establishing an accurate and comprehensive quality control method to clarify the critical quality attributes of Qinggusan reference samples is of great importance. In this study, 15 batches of Qinggusan reference samples were processed to determine the range of their dry extract ratios. Quantitative high-performance liquid chromatography (HPLC) fingerprint analysis was performed using a Waters Symmetry Shield RP18 column (250 mm×4.6 mm, 5 μm) with acetonitrile-0.1% (v/v) formic acid aqueous solution as the mobile phase in gradient elution mode. The flow rate was 1.0 mL/min, the column temperature was 30 ℃, and the detection wavelength was 254 nm. The HPLC fingerprints of the Qinggusan reference samples were established under these conditions to evaluate their similarity. The established method was systematically validated and found to demonstrate good precision, repeatability, and sample stability. Subsequently, characteristic peaks were identified and attributed by HPLC-quadrupole-time-of-flight-mass spectrometry (HPLC-Q-TOF-MS) analysis. MS was performed in electrospray ionization mode, the data were collected in both positive- and negative-ion modes, and the detection range was m/z 50-2000. The contents and transfer rate ranges of the index components, namely, gentiopicrin, mangiferin, picroside Ⅱ, picroside Ⅰ, and glycyrrhizic acid, were determined to analyze the quality value transfer of the samples. The results demonstrated that the dry extract rate of the 15 batches of Qinggusan reference samples ranged from 24.10% to 26.88% and that their fingerprint similarities were generally greater than 0.95. Twelve common peaks were identified by reference identification, literature comparison, and high-resolution MS analysis. Twelve compounds, including six iridoid glycosides, two flavonoids, one alkaloid, one triterpenoid saponin, and two others. Among them, L-picein, androsin, picroside Ⅳ, picroside Ⅱ and picroside Ⅰ were from Picrorhizae Rhizoma, loganin acid, swertiamarin and gentiopicrin were from Gentianae Macrophyllae Radix, neomangiferin and mangiferin were from Anemarrhenae Rhizoma, dichotomine B was from Stellariae Radix, and glycyrrhizic acid was from Glycyrrhizae Radix et Rhizoma. The five key components presented good linear relationships in their respective linear ranges, and all correlation coefficients were higher than 0.999. The relative standard deviations (RSDs) of precision, stability, and repeatability were less than 1.3%. The average recoveries varied between 95.92% and 102.5%, with RSDs less than 3.9%; these values meet the requirements defined in the 2020 edition of the Chinese Pharmacopoeia. The contents of gentiopicrin, mangiferin, picroside Ⅱ, picroside Ⅰ, and glycyrrhizic acid in the 15 batches of reference samples were in the range of 17.92-27.55, 1.83-4.42, 23.08-36.44, 8.43-15.04, and 0.94-2.39 mg/g, respectively, and their transfer rates from the decoction pieces to the reference samples were 47.91%-63.95%, 22.96%-59.39%, 60.82%-77.82%, 64.25%-99.53%, and 15.30%-39.30%, respectively. In this study, the chemical components of Qinggusan reference samples were comprehensively identified and their quality value transfer was studied through the combination of HPLC fingerprinting and MS. Clarification of the critical quality attributes of Qinggusan reference samples could provide a basis for the quality control of Qinggusan compound preparations.

Key words: quantitative fingerprint, quality value transfer, Qinggusan, reference sample

中图分类号:

O658

徐鑫, 魏彤, 薛倩倩, 艾嘉浩, 李桂馨, 刘忠国, 李丹, 侯金才, 金红利, 刘艳芳, 梁鑫淼. 基于定量指纹图谱技术的经典名方清骨散基准样品量值传递分析[J]. 色谱, 2023, 41(2): 142-151.

XU Xin, WEI Tong, XUE Qianqian, AI Jiahao, LI Guixin, LIU Zhongguo, LI Dan, HOU Jincai, JIN Hongli, LIU Yanfang, LIANG Xinmiao. Analysis on quality value transmitting of Qinggusan reference sample of classical prescription based on quantitative fingerprint technology[J]. Chinese Journal of Chromatography, 2023, 41(2): 142-151.

图/表 8

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Medicinal material	Base resource	Medicinal part	Geographical origins
Stellariae Radix (YCH)	Stellaria dichotoma L. var. lanceolata Bge.	dried radix root	5 batches from Tongxin,Ningxia;5 batches from Pingluo,Ningxia;5 batches from Guyuan,Ningxia
Anemarrhenae Rhizoma(ZM)	Anemarrhena asphodeloides Bge.	dried rhizome	5 batches from Anguo,Hebei;5 batches from Bozhou,Anhui;5 batches from Zhangjiakou,Hebei
Picrorhizae Rhizoma (HHL)	Picrorhiza scrophulariiflora Pennell	dried rhizome	5 batches from Dangxiong,Xizang;5 batches from Shigatse,Xizang;5 batches from Shannancuona,Xizang
Lycii Cortex(DGP)	Lycium chinense Mill.	dried radix root cortex	5 batches from Yuncheng,Shanxi;5 batches from Julu,Hebei;5 batches from Longxi,Gansu
Gentianae Macrophyllae Radix(QJ)	Gentiana macrophylla Pall.	dried radix root	5 batches from Zhashui,Shanxi;5 batches from Longxian,Shanxi;5 batches from Zhengning,Gansu
Artemisiae annuae Herba(QH)	Artemisia annua L.	dried aerial part	5 batches from Yongzhou,Hunan;5 batches from Qichun,Hubei;5 batches from Xiangfan,Hubei
Trionycis carapax(CBJ)	Trionyx sinensis Wiegmann	dried carapace	5 batches from Wuhan,Hubei;5 batches from Xiaoxian,Anhui;5 batches from Yueyang,Hunan
Glycyrrhizae Radix et Rhizoma(GC)	Glycyrrhiza uralensis Fisch.	dried root and rhizome	5 batches from Minqin,Gansu;5 batches from Longxi,Gansu;5 batches from Tacheng,Xinjiang

Medicinal material	Base resource	Medicinal part	Geographical origins
Stellariae Radix (YCH)	Stellaria dichotoma L. var. lanceolata Bge.	dried radix root	5 batches from Tongxin,Ningxia;5 batches from Pingluo,Ningxia;5 batches from Guyuan,Ningxia
Anemarrhenae Rhizoma(ZM)	Anemarrhena asphodeloides Bge.	dried rhizome	5 batches from Anguo,Hebei;5 batches from Bozhou,Anhui;5 batches from Zhangjiakou,Hebei
Picrorhizae Rhizoma (HHL)	Picrorhiza scrophulariiflora Pennell	dried rhizome	5 batches from Dangxiong,Xizang;5 batches from Shigatse,Xizang;5 batches from Shannancuona,Xizang
Lycii Cortex(DGP)	Lycium chinense Mill.	dried radix root cortex	5 batches from Yuncheng,Shanxi;5 batches from Julu,Hebei;5 batches from Longxi,Gansu
Gentianae Macrophyllae Radix(QJ)	Gentiana macrophylla Pall.	dried radix root	5 batches from Zhashui,Shanxi;5 batches from Longxian,Shanxi;5 batches from Zhengning,Gansu
Artemisiae annuae Herba(QH)	Artemisia annua L.	dried aerial part	5 batches from Yongzhou,Hunan;5 batches from Qichun,Hubei;5 batches from Xiangfan,Hubei
Trionycis carapax(CBJ)	Trionyx sinensis Wiegmann	dried carapace	5 batches from Wuhan,Hubei;5 batches from Xiaoxian,Anhui;5 batches from Yueyang,Hunan
Glycyrrhizae Radix et Rhizoma(GC)	Glycyrrhiza uralensis Fisch.	dried root and rhizome	5 batches from Minqin,Gansu;5 batches from Longxi,Gansu;5 batches from Tacheng,Xinjiang

No.	t_R/ min	Formula	Adduct ion	Theoretical mass (m/z)	Experimental mass(m/z)	Mass error/ ppm	MS²(m/z)	Identification	Medicine
1	17.043	C₁₆H₂₄O₁₀	[M-H]^-	375.1297	375.1298	0.27	151.0761,113.0241,59.0140	loganin acid^[13]	QJ
		C₁₄H₁₈O₇	[M+HCOO]^-	343.1035	343.1039	1.17	135.0451,120.0227	L-picein^[14]	HHL
2	20.530	C₁₆H₂₂O₁₀	[M+HCOO]^-	419.1195	419.1197	0.48	141.0194,101.0243,89.0243, 71.0139,59.0141	swertiamarin^[13]	QJ
		C₁₅H₂₀O₈	[M+HCOO]^-	373.1140	373.1170	8.04	165.0558,150.0323	androsin^[14]	HHL
3	22.866	C₂₅H₂₈O₁₆	[M+H]⁺	585.1450	585.1452	0.34	369.0599,327.0499,303.0498, 273.0387	neomangiferin^[15]	ZM
4^*	23.885	C₁₆H₂₀O₉	[M+HCOO]^-	401.1189	401.1176	-3.24	149.0607,113.0243,71.0139, 59.0140	gentiopicrin^[13]	QJ
5	25.267	C₁₄H₁₂N₂O₄	[M+H]⁺	273.0870	273.0870	0	227.0813,209.0707,181.0758, 169.0757,154.0649	dichotomine B^[16,17]	YCH
6	29.135	/	[M-H]^-	/	353.0890	/	/	/	HHL
7^*	37.815	C₁₉H₁₈O₁₁	[M+H]⁺	423.0922	423.0922	0	351.0496,339.0498,327.0501, 273.0392,303.0499,285.0393, 273.0392	mangiferin^[15]	ZM
8	50.980	C₂₄H₂₈O₁₂	[M-H]^-	507.1558	507.1514	-8.68	163.0398,145.0292,119.0498, 117.0342	picroside Ⅳ^[14]	HHL
9^*	54.774	C₂₃H₂₈O₁₃	[M-H]^-	511.1457	511.1453	-0.82	207.0660,167.0348,152.0111, 123.0450	picroside Ⅱ^[14]	HHL
10^*	67.260	C₂₄H₂₈O₁₁	[M+HCOO]^-	537.1614	537.1641	5.03	147.0453,103.0551,97.0293	picroside Ⅰ^[14]	HHL
11	97.516	/	[M+HCOO]^-	/	753.4022	/	707.4059,689.3950	/	HHL
12^*	103.348	C₄₂H₆₂O₁₆	[M-H]^-	821.3965	821.3952	-1.58	351.0565,193.0350,175.0252	glycyrrhizic acid^[18]	GC

No.	t_R/ min	Formula	Adduct ion	Theoretical mass (m/z)	Experimental mass(m/z)	Mass error/ ppm	MS²(m/z)	Identification	Medicine
1	17.043	C₁₆H₂₄O₁₀	[M-H]^-	375.1297	375.1298	0.27	151.0761,113.0241,59.0140	loganin acid^[13]	QJ
		C₁₄H₁₈O₇	[M+HCOO]^-	343.1035	343.1039	1.17	135.0451,120.0227	L-picein^[14]	HHL
2	20.530	C₁₆H₂₂O₁₀	[M+HCOO]^-	419.1195	419.1197	0.48	141.0194,101.0243,89.0243, 71.0139,59.0141	swertiamarin^[13]	QJ
		C₁₅H₂₀O₈	[M+HCOO]^-	373.1140	373.1170	8.04	165.0558,150.0323	androsin^[14]	HHL
3	22.866	C₂₅H₂₈O₁₆	[M+H]⁺	585.1450	585.1452	0.34	369.0599,327.0499,303.0498, 273.0387	neomangiferin^[15]	ZM
4^*	23.885	C₁₆H₂₀O₉	[M+HCOO]^-	401.1189	401.1176	-3.24	149.0607,113.0243,71.0139, 59.0140	gentiopicrin^[13]	QJ
5	25.267	C₁₄H₁₂N₂O₄	[M+H]⁺	273.0870	273.0870	0	227.0813,209.0707,181.0758, 169.0757,154.0649	dichotomine B^[16,17]	YCH
6	29.135	/	[M-H]^-	/	353.0890	/	/	/	HHL
7^*	37.815	C₁₉H₁₈O₁₁	[M+H]⁺	423.0922	423.0922	0	351.0496,339.0498,327.0501, 273.0392,303.0499,285.0393, 273.0392	mangiferin^[15]	ZM
8	50.980	C₂₄H₂₈O₁₂	[M-H]^-	507.1558	507.1514	-8.68	163.0398,145.0292,119.0498, 117.0342	picroside Ⅳ^[14]	HHL
9^*	54.774	C₂₃H₂₈O₁₃	[M-H]^-	511.1457	511.1453	-0.82	207.0660,167.0348,152.0111, 123.0450	picroside Ⅱ^[14]	HHL
10^*	67.260	C₂₄H₂₈O₁₁	[M+HCOO]^-	537.1614	537.1641	5.03	147.0453,103.0551,97.0293	picroside Ⅰ^[14]	HHL
11	97.516	/	[M+HCOO]^-	/	753.4022	/	707.4059,689.3950	/	HHL
12^*	103.348	C₄₂H₆₂O₁₆	[M-H]^-	821.3965	821.3952	-1.58	351.0565,193.0350,175.0252	glycyrrhizic acid^[18]	GC

Compound	Linear equation	R²	Linear range/(mg/L)	LOD/(mg/L)	LOQ/(mg/L)
Gentiopicrin	Y=1.062×10⁴X+2.934×10⁴	0.9994	24.72-247.2	0.1360	0.4533
Mangiferin	Y=4.095×10⁴X-8.598×10²	0.9993	3.997-39.97	0.0581	0.1938
Picroside Ⅱ	Y=9.961×10³X+3.833×10⁴	0.9993	35.13-351.3	0.2237	0.7457
Picroside Ⅰ	Y=2.336×10⁴X+1.533×10⁴	0.9994	9.972-99.72	0.3307	1.1023
Glycyrrhizic acid	Y=8.126×10³X+3.679×10³	0.9994	3.750-37.50	0.1099	0.3662

基于定量指纹图谱技术的经典名方清骨散基准样品量值传递分析

Analysis on quality value transmitting of Qinggusan reference sample of classical prescription based on quantitative fingerprint technology

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Metrics

No.	Gentiopicrin			Mangiferin			Picroside Ⅱ			Picroside Ⅰ			Glycyrrhizic acid
No.	w_RS/ (mg/g)	w_DP/ (mg/g)	r_t/ %	w_RS/ (mg/g)	w_DP/ (mg/g)	r_t/ %	w_RS/ (mg/g)	w_DP/ (mg/g)	r_t/ %	w_RS/ (mg/g)	w_DP/ (mg/g)	r_t/ %	w_RS/ (mg/g)	w_DP/ (mg/g)	r_t/ %
S1	23.82	85.74	55.00	2.79	18.64	31.60	31.12	105.23	60.82	11.39	36.48	64.25	1.78	24.85	28.68
S2	21.20	80.53	56.77	3.10	17.11	39.07	30.50	107.78	61.21	13.10	39.63	71.41	1.23	25.63	20.37
S3	25.10	87.11	59.91	2.60	15.95	35.27	25.60	76.54	68.90	11.60	29.74	80.62	1.15	20.86	22.23
S4	20.33	82.70	57.91	2.30	17.63	30.53	34.54	107.88	73.60	11.50	40.07	65.97	1.75	28.29	28.97
S5	18.27	75.30	50.14	2.46	18.71	28.13	34.19	98.65	71.51	13.35	28.00	98.35	1.78	25.69	28.81
S6	23.61	93.85	52.91	1.87	17.66	22.96	25.52	77.13	68.75	10.56	27.64	79.49	1.40	22.60	25.63
S7	17.92	84.30	47.91	1.83	15.86	25.15	33.65	107.30	62.76	14.93	38.34	82.23	1.79	25.52	30.58
S8	18.88	72.87	61.33	3.87	19.69	43.25	33.06	101.64	70.78	11.55	37.44	67.10	2.39	26.36	38.91
S9	21.23	79.31	58.38	2.83	17.91	36.05	25.09	75.72	72.34	11.64	29.08	87.41	1.34	22.66	25.37
S10	27.55	94.69	63.95	4.42	16.47	59.39	33.89	95.87	77.82	13.27	28.81	99.53	1.81	28.38	28.88
S11	22.93	80.80	50.23	3.19	14.64	45.27	26.10	73.24	71.99	10.14	26.54	77.27	1.90	23.70	33.58
S12	21.77	93.00	61.97	2.25	19.09	27.32	23.08	75.64	67.69	8.43	25.44	73.39	2.17	24.60	39.30
S13	18.94	85.13	48.11	2.72	16.32	34.62	34.52	97.34	71.82	10.11	30.05	68.17	1.61	23.20	27.93
S14	26.24	95.84	57.37	1.99	16.89	25.70	36.44	101.64	75.21	15.04	29.89	99.28	0.94	24.98	15.30
S15	24.97	103.61	52.32	3.07	17.66	38.37	34.62	101.94	71.97	13.12	30.00	92.49	2.25	27.76	36.25
Average value	22.19	86.32	55.61	2.75	17.35	34.84	30.97	93.56	69.81	11.98	31.81	80.46	1.69	25.01	28.72
Fluctuation	17.92-	72.87-	86.15-	1.83-	14.64-	65.89-	23.08-	73.24-	87.12-	8.43-	25.44-	79.85-	0.94-	20.86-	53.27-
range	27.55	103.61	114.98	4.42	19.69	170.44	36.44	107.88	111.48	15.04	40.07	123.69	2.39	28.38	136.83

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