Determination of trace α -amanitin in urine of mushroom poisoning patient by online solid phase extraction-liquid chromatography-tandem mass spectrometry

doi:10.3724/SP.J.1123.2020.03010

Abstract

Abstract:

An analytical method was established for the determination of trace α -amanitin in the urine of patients suffering from mushroom poisoning by online solid phase extraction-liquid chromatography-tandem mass spectrometry (online SPE-LC-MS/MS). The sample was protein precipitated with formic acid acidified acetonitrile-methanol (5:1, v/v). Reversed-phase liquid-liquid microextraction was used to remove the organic solvent from the sample extract. The toxin was purified by online SPE using an ODS micro column (5 mm×2.1 mm, 5 μm), and separated on an XBridge^TM BEH C₁₈ column (150 mm×3.0 mm, 2.5 μm). Finally, the toxin was measured by MS/MS in the negative electrospray ionization (ESI^- ) mode. Multiple reaction monitoring (MRM) was used, and the conditions were m /z 917.4>205.1 (quantitative ion transition) and m /z 917.4>257.1. Collision energy for both transitions was 55 eV. A fast valve-switching technique with a quantitative loop was used as an interface between the online SPE and LC-MS/MS modules. The two modules were independent, neither the mobile phase nor the pressure would interfere with each other, thus ensuring the stability of the system. Precise purification by the online system could effectively eliminate the matrix effects in the subsequent MS detection. Weak matrix suppression effects were found, with results of 88.7%-96.5%. The linear range of α -amanitin in urine was 0.1-50 μg/L with a correlation coefficient (r ² ) of 0.9983. The limit of detection (LOD) and limit of quantification (LOQ) in the sample matrix were 0.03 μg/L and 0.1 μg/L, respectively. The average recoveries at three spiked levels (0.1, 2.0 and 20 μg/L) were 84.3%-91.7% with relative standard deviations (RSDs) of 3.8%-7.2%. The accuracy and precision were evaluated using quality control samples with toxin contents of 0.1 μg/L (LOQ), 0.2 μg/L (2-fold LOQ), 2.0 μg/L (medium level), and 20 μg/L (high level). The calculated average intra-day accuracy was 85.1%-96.0% with the precision of 4.1%-7.8%. The inter-day accuracy was 82.9%-94.8% with the precision of 5.0%-9.5%. The specificity of the method was verified by negative samples derived from patients who suffered only gastroenteritis poisoning, without hepatotoxic symptoms. α -Amanitin was found in urine samples from nine mushroom poisoning patients with hepatotoxic symptoms. The sampling time ranged from 19 h to 92 h. The toxin contents were 0.11-53.1 μg/L. For patients with a high intake of poisonous mushrooms, the toxin content was 53.1 μg/L in a patient's urine sampled 19 h after accidental consumption and 0.19 μg/L in another patient's urine sampled 92 h after poisoning. The content of α -amanitin was only 0.53 μg/L in the urine sample obtained 23 h after consumption for a patient with low intake and 0.11 μg/L in the urine sampled from another patient 40 h after poisoning. Amatoxins can metabolize rapidly in vivo. The laboratory identification of amatoxin poisoning requires a method for trace-level analysis in the biological matrix. It is proved that this method is simple, accurate and sensitive by the application to the analysis of actual samples. The protein precipitation and reversed-phase liquid-liquid microextraction steps are fast and simple. Hence, they can be used as a rapid and effective pre-treatment method for online SPE-LC-MS/MS analysis of water-soluble toxins in biomaterial matrix. Highly sensitive analysis of α -amanitin in urine can be obtained using a precise purification technology via online SPE in this study. The problem of qualitative confirmation of the toxin at trace levels (0.03 μg/L) after poisoning can be solved. The laboratory identification time for amatoxin poisoning in some patients exceeds 90 h. The developed analytical method at trace level (0.1 μg/L of LOQ) can provide reliable technical support for establishing the dose-response relationship of α -amanitin in vivo. It can satisfy for the determination of trace α -amanitin in urine samples from patients with hepatotoxic mushroom poisoning.

Key words: liquid chromatography-tandem mass spectrometry (LC-MS/MS), online solid phase extraction (online SPE), α -amanitin, urine, trace level, mushroom poisoning, foodborne disease

Xiaomin XU, Jingshun ZHANG, Zengxuan CAI, Zhen MENG, Baifen HUANG, Qing CHEN. Determination of trace α -amanitin in urine of mushroom poisoning patient by online solid phase extraction-liquid chromatography-tandem mass spectrometry[J]. Chinese Journal of Chromatography, 2020, 38(11): 1281-1287.

Figures/Tables 7

Fig. 1 Diagram of the flow path switching in the online SPE-LC-MS/MS system

Fig. 2 Elution curves of α -amanitin with volume fractions of methanol of 30%, 35%, and 40% at 2.0-3.0 min in the online SPE elution gradient procedure

Fig. 3 Chromatograms of α -amanitin cleaned by online SPE and offline SPE a. blank matrix; b. positive sample (0.53 μg/L); c. positive sample (0.53 μg/L).

Fig. 4 Full scan mass and MS/MS spectra of α -amanitin

Table 1 Matrix effects (MEs) of α -amanitin in the six blank urine samples (n =6)

Source of the blank matrix	0.1 μg/L		50 μg/L
Source of the blank matrix	ME/%	RSD/%	ME/%	RSD/%
* Mushroom poisoning patient only with normal gastroenteritis symptoms.
Female volunteer 1	96.5	3.6	92.9	3.8
Female volunteer 2	91.5	4.1	91.5	3.4
Male volunteer 1	93.4	5.6	88.7	4.8
Male volunteer 2	89.2	4.3	94.0	3.7
Patient 1^*	96.1	4.7	91.5	2.7
Patient 2^*	89.0	5.0	95.4	3.9

Table 2 Intra- and inter-day accuracies and precisions of α -amanitin

Level/(μg/L)	Intra-day (n =6)		Inter-day (n =3)
Level/(μg/L)	Accuracy/%	Precision/%	Accuracy/%	Precision/%
0.1	85.1	7.8	82.9	9.5
0.2	88.2	7.0	86.5	8.3
2.0	96.0	4.7	94.8	5.5
20	90.3	4.1	90.1	5.0

Fig. 5 Contents of α -amanitin in the urines of the nine poisoning patients (n =3)

References

1	Li H , Zhang H , Zhang Y , et al.. China CDC Weekly, 2020, 2 (2): 19
2	White J , Weinstein S A , De Haro L , et al.. Toxicon, 2019, 157: 53
3	Sun J , Sun C Y , Li H J , et al.. Chinese Journal of Emergency Medicine, 2016, 25 (8): 1076
3	孙健 , 孙承业 , 李海蛟 , et al.. 中华急诊医学杂志, 2016, 25 (8): 1076
4	Garcia J , Costa V M , Carvalho A , et al.. Food Chem Toxicol, 2015, 86: 41
5	Chen Z H , Hu J S , Zhang Z G , et al.. Mycosystema, 2003, 22 (4): 565
5	陈作红 , 胡劲松 , 张志光 , et al.. 菌物系统, 2003, 22 (4): 565
6	Wei J H , Wu J F , Chen J , et al.. Chinese Journal of Analytical Chemistry, 2017, 45 (6): 817
6	魏佳会 , 吴剑峰 , 陈佳 , et al.. 分析化学, 2017, 45 (6): 817
7	Xu X M , Zhang J S , Cai Z X , et al.. Chinese Journal of Chromatography, 2017, 35 (6): 613
7	徐小民 , 张京顺 , 蔡增轩 , et al.. 色谱, 2017, 35 (6): 613
8	Chen Z H , Zhang P , Zhang Z G Fungal Divers, 2014, 64: 123
9	Abuknesha R A , Maragkou A Anal Bioanal Chem, 2004, 379: 853
10	Sun J , Niu Y M , Zhang Y T , et al.. Toxicon, 2018, 143: 59
11	Zhang S , Zhao Y , Li H , et al.. Toxins (Basel), 2016, 8 (5): 128
12	Robinson-Fuentes V A , Jaime-Sanchez J L , Garcia-Aguilar L , et al.. J Pharm Biomed Anal, 2008, 47 (4/5): 913
13	Zhang X Y , Cai X X Chinese Journal of Analytical Chemistry, 2010, 38 (1): 39
13	张秀尧 , 蔡欣欣分析化学, 2010, 38 (1): 39
14	Xiao S Z , Lin F , Fu W S , et al.. Chinese Journal of Food Science, 2018, 39 (22): 312
14	肖绍震 , 林锋 , 傅武胜 , et al.. 食品科学, 2018, 39 (22): 312
15	Abbott N L , Hill K L , Garrett A , et al.. Toxicon, 2018, 152: 71
16	Nomura M , Suzuki Y , Kaneko R , et al.. Forensic Toxicol, 2012, 30 (2): 185
17	Leite M , Freitas A , Azul A M , et al.. Anal Chim Acta, 2013, 799: 77
18	Miralles P , Chisvert A , Alonso M J , et al.. J Chromatogr A, 2018, 1543: 34
19	Chisvert A , Benede J L , Peiro M , et al.. Talanta, 2017, 166: 81
20	Pan J , Zhang C , Zhang Z , et al.. Anal Chim Acta, 2014, 815: 1
21	Xu X M , Cai Z X , Zhang J S , et al.. Food Control, 2017, 71: 393
22	Food and Drug Administration, USA. Bioanalytical Method Validation Guidance for Industry.[2018-05-24]. https://www.fda.gov/files/drugs/published/Bioanalytical-Method-Validation-Guidance-for-Industry.pdf
23	Yu C M , Li H J , Sun C Y , et al.. Chinese Journal of Emergency Medicine, 2020, 29 (2): 171
23	余成敏 , 李海蛟 , 孙承业 , et al.. 中华急诊医学杂志, 2020, 29 (2): 171

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