基于超高效液相色谱-高分辨质谱和渗透压校正样本浓度变异性的尿液代谢组学分析

doi:10.3724/SP.J.1123.2020.06018

色谱 ›› 2021, Vol. 39 ›› Issue (4): 391-398.DOI: 10.3724/SP.J.1123.2020.06018

基于超高效液相色谱-高分辨质谱和渗透压校正样本浓度变异性的尿液代谢组学分析

何祉安¹^,², 林厚维³^,⁴, 桂娟², 朱伟超⁵, 何建华⁵, 汪航², 冯蕾¹^,²^,^*()

1.上海交通大学药学院, 上海 200240
2.上海交通大学分析测试中心, 上海 200240
3.上海交通大学医学院附属新华医院小儿泌尿外科, 上海 200092
4.嘉兴学院附属嘉兴市妇幼保健院小儿外科, 浙江嘉兴 314051
5.宁波大学医学院附属医院小儿外科浙江宁波 315020

收稿日期:2020-06-12 出版日期:2021-04-08 发布日期:2021-03-08
通讯作者: 冯蕾
作者简介:*E-mail:fiona.fenglei@sjtu.edu.cn.
基金资助:
上海市自然科学基金(18ZR1424700);上海交通大学医工交叉项目(YG2017QN65)

Urine metabolomics analysis based on ultra performance liquid chromatography-high resolution mass spectrometry combined with osmolality calibration sample concentration variability

HE Zhian¹^,², LIN Houwei³^,⁴, GUI Juan², ZHU Weichao⁵, HE Jianhua⁵, WANG Hang², FENG Lei¹^,²^,^*()

1. School of Pharmacy, Shanghai Jiao Tong University, Shanghai 200240, China
2. Instrumental Analysis Center, Shanghai Jiao Tong University, Shanghai 200240, China
3. Department of Pediatric Urology,Xinhua Hospital Affiliated to Shanghai Jiao Tong University School of Medicine, Shanghai 200092,China
4. Department of Pediatric Surgery, Jiaxing University Affiliated Women and Children Hospital, Jiaxing 314051, China
5. Department of Pediatric Surgery, the Affiliated Hospital of Medical School of Ningbo University, Ningbo 315020, China

Received:2020-06-12 Online:2021-04-08 Published:2021-03-08
Contact: FENG Lei
Supported by:
Natural Science Foundation of Shanghai(18ZR1424700);Medical-Engineering Joint Fund of Shanghai Jiao Tong University(YG2017QN65)

摘要/Abstract

摘要：

尿液是代谢组学研究中主要关注的体液样本之一。尿液样本中的代谢物浓度受饮食、疾病等因素影响变异较大,这极大阻碍了高质量组学数据的获取和可靠生物标志物的鉴定。研究为克服尿液样本的浓度变异性,在原始数据采集前,根据样本渗透压的大小,针对性地调整进样量或者稀释样本,从而确保代谢组学分析样本的渗透压与进样量的乘积相当,再经超高效液相色谱-高分辨质谱技术(UPLC-HRMS)分析,采用总离子丰度或总有用峰面积(MSTUS)对数据集进行归一化处理。研究利用临床样本及其梯度稀释的溶液,对该方法与现有研究普遍使用的方法进行了比较,随后通过先天性肾积水患者及健康志愿者的尿液样本做了进一步的方法学验证。数据集经校正后,峰面积RSD<30%的提取峰数量增加,主成分分析结果较校正前有更高的组内聚集和组间分群效应,正交偏最小二乘判别分析的统计模型更不易过拟合。与肌酐比较,渗透压值与质谱信号间呈现了更好的线性关系。以上结果表明,数据采集前通过样本渗透压进行校正,能有效消除因样本本身代谢物浓度变化引起的组内差异,提高方法的重复性和统计模型的可靠度。以渗透压为基准的校正策略,比肌酐校正法适用范围更广,结果也更准确。研究可对后续各类来源的尿液代谢组学研究提供数据归一化的指导和参考。

关键词: 超高效液相色谱-高分辨质谱, 代谢组学, 渗透压, 归一化, 尿液

Abstract:

Urine is an important source of biomolecular information for metabolomic studies. However, the acquisition of high-quality metabolomic datasets or reliable biomarkers from urine is difficult owing to the large variations in the concentrations of endogenous metabolites in the biofluid, which are caused by diverse factors such as water consumption, drugs, and diseases. Thus, normalization or calibration is essential in urine metabolomics for eliminating such deviations. The urine osmolality (Π), which is a direct measure of the total urinary solute concentration and is not affected by circadian rhythms, diet, gender, and age, is often considered the gold standard for estimation of the urine concentration. In this study, a pre-data acquisition calibration strategy based on osmolality was investigated for its feasibility to overcome sample concentration variability. Before data acquisition, the product of the osmolality×injection volume of all samples was set to be equivalent through the uses of a customized injection volume or dilution. After ultra performance liquid chromatography-high resolution mass spectrometry (UPLC-HRMS) analysis of the sample, the raw dataset was normalized to the total ion abundance or total useful MS signals (MSTUS) to achieve further calibration. The osmolality of each urine sample was determined with a freezing-point depression osmometer. For the instrumental analysis, a Vanquish UPLC system coupled to a Q-Exactive Plus HRMS device was used for metabolite analysis and accurate mass measurement. Full-scan mass spectra were acquired in the range of m/z 60-900, and the MS/MS experiments were conducted in “Top5” data-dependent mode. A Waters UPLC column (100 mm×2.1 mm, 1.8 μm) was used for chromatography separation. The raw data were imported into Progenesis QI software for peak picking, alignment, deconvolution, and normalization. SIMCA-P software was used for the principal component analysis (PCA) and orthogonal partial least-squares discrimination analysis (OPLS-DA). This strategy was first applied to sequentially diluted urine samples, where three frequently used normalization methods were compared. In the identical injection volume experiment, the points were scattered and showed relevant distribution according to the dilution multiple in the plot of PCA scores. There was little improvement after normalization to either the total ion abundance or MSTUS. In the customized injection volume experiment, the urine samples derived from the same source showed ideal clustering. With total ion abundance and MSTUS normalization, the dataset was further improved in the PCA model fitting and prediction. As a result, there were more peaks with a peak area RSD of <30%, which indicated better parallelism. The diluted urine solutions had higher Spearman’s coefficient values with their sample source than those without calibration, which suggested less intra-group differences. The strategy was further validated using data from a metabolomic study of children with congenital hydronephrosis and healthy controls. As a concentration estimator, osmolality showed better linear correlation with the mass signal and was less influenced by physiological or pathological factors, thus obtaining broader application and more accurate results than creatinine. The concentration variability was effectively eliminated after customized dilution calibration and showed a more obvious clustering effect in the PCA score plot. The OPLS-DA-based statistical model used to identify discriminate metabolites was improved, with less chance of overfitting. In conclusion, the calibration strategy based on osmolality combined with total ion abundance or MSTUS normalization significantly overcame the problem of urine concentration variability, eliminated intra-group differences, and possessed better parallelism, thus giving better clustering effects in PCA or OPLS-DA and higher reliability of the statistical model. The results of this study provide guidance and a reference for future metabolomic studies on urine.

Key words: ultra performance liquid chromatography-high resolution mass spectrometry (UPLC-HRMS), metabolomics, osmolality, normalization, urine

中图分类号:

O658

何祉安, 林厚维, 桂娟, 朱伟超, 何建华, 汪航, 冯蕾. 基于超高效液相色谱-高分辨质谱和渗透压校正样本浓度变异性的尿液代谢组学分析[J]. 色谱, 2021, 39(4): 391-398.

HE Zhian, LIN Houwei, GUI Juan, ZHU Weichao, HE Jianhua, WANG Hang, FENG Lei. Urine metabolomics analysis based on ultra performance liquid chromatography-high resolution mass spectrometry combined with osmolality calibration sample concentration variability[J]. Chinese Journal of Chromatography, 2021, 39(4): 391-398.

图/表 7

表 1 样本的渗透压及进样体积

Table 1 Osmolalities (Π) and injection volumes (V) of samples

Dilution multiple	Sample A			Sample B			Sample C
Dilution multiple	Π/mOsm	V/μL	Π×V/(mOsm·μL)	Π/mOsm	V/μL	Π×V/(mOsm·μL)	Π/mOsm	V/μL	Π×V/(mOsm·μL)
1	593	0.5	296.5	644	0.5	322.0	455	0.7	318.5
2	304	1.0	304.0	326	1.0	326.0	232	1.3	301.6
4	152	2.0	304.0	163	1.9	309.7	115	2.7	310.5
8	74	4.2	310.8	82	3.8	311.6	38	8.2	311.6
12	51	6.1	311.1	53	5.9	312.7	31	10.0	310.0

图 1 校正前、后尿液样本及其稀释溶液的PCA得分图(PC个数=4)

Fig. 1 Principal component analysis (PCA) score plots of urine and their sequentially diluted solution before and after calibration (number of principal components=4) A, B, C refer to three sample sources, the following numbers indicate different dilution multiples.

图 2 峰面积RSD<30%的提取峰数量(n=3)

Fig. 2 Numbers of peaks with peak area RSD<30% (n=3) MSTUS: mass total useful signal; * p<0.05.

图 3 样品及其梯度稀释溶液的Spearman相关系数

Fig. 3 Spearman coefficients of samples and their sequentially diluted solutions * Two regression curves were significantly different (p<0.01).

图 4 样本渗透压值和肌酐峰面积的箱型图(n=10)

Fig. 4 Box charts of osmolality and creatinine peak area (n=10)

图 5 健康志愿者和先天性肾积水患者尿液样本的PCA得分图(PC个数=5)

Fig. 5 PCA score plots of urine samples from healthy volunteers and patients with congenital hydronephrosis (Number of principal components=5) Q: quality control; HC: healthy control; U: children with congenital hydronephrosis.

图 6 健康志愿者和肾积水患者尿液样本的OPLS-DA得分图(PC个数=2)

Fig. 6 Orthogonal partial least squares discrimination analysis (OPLS-DA) score plots of urine samples from healthy volunteers and patients with congenital hydronephrosis (Number of principal components=2)

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基于超高效液相色谱-高分辨质谱和渗透压校正样本浓度变异性的尿液代谢组学分析

Urine metabolomics analysis based on ultra performance liquid chromatography-high resolution mass spectrometry combined with osmolality calibration sample concentration variability

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