基于非对称场流分离技术分离表征天麻多糖:空间位阻转变效应

doi:10.3724/SP.J.1123.2022.11020

摘要/Abstract

摘要：

采用非对称场流分离(AF4)在线联用多角度光散射(MALS)检测器和示差折光(dRI)检测器(AF4-MALS-dRI)对天麻多糖(GEPs)的相对分子质量(M)、回转半径(R_g)和构象进行了表征。GEPs粒径分布较宽,在AF4分离过程中存在空间位阻转变效应,导致粒径大小不同的GEPs分子被同时洗脱,无法准确表征其M、R_g分布和构象。本文研究了恒定交叉流流速、指数衰减交叉流流速、样品质量浓度和垫片高度对空间位阻转变效应的影响。结果表明,较高的样品质量浓度会导致空间位阻转变现象的发生;垫片高度会影响样品的分离度和保留时间,改变空间位阻转变点(d_i);对于多分散GEPs样品,指数衰减交叉流流速不仅能调整d_i,而且能改善样品的分离度,缩短分析时间。在样品质量浓度为0.50 mg/mL、进样体积为50 μL、检测器流速为1.0 mL/min、垫片高度为350 μm、初始交叉流流速由0.2 mL/min呈指数衰减至0.05 mL/min、半衰期为2 min的条件下,解决了AF4分离GEPs时存在的空间位阻转变效应问题。此外,在最佳洗脱条件下研究了不同产地及不同超声时间对GEPs 的M、R_g和构象的影响。结果表明,随着超声时间的增加,云南和四川产地GEPs的R_g和M均减小,分布变窄;当超声时间为15 min时,云南产地GEPs为松散的高度支化构象,四川产地GEPs为球状构象;当超声时间增加到30 min或60 min时,两产地GEPs的构象主要为高度支化结构,表明GEPs发生了降解。实验结果证明,在最佳洗脱条件下,AF4-MALS-dRI对GEPs的表征具有良好的重复性,GEPs的R_g和M相对标准偏差分别为0.5%和1.7%。

关键词: 非对称场流分离, 天麻多糖, 空间位阻转变

Abstract:

Asymmetrical flow field-flow fractionation (AF4), a gentle tool for the separation and characterization of particles and macromolecules, has attracted increased interest in recent years owing to its broad dynamic size range and utilization of “open channel” voids in the packing or stationary phase. A steric transition phenomenon in which the sample elution mode change from the normal mode to the steric/hyperlayer mode occurs. Accurate characterization by AF4 requires the absence of steric transition, particularly when the sample has a broad size distribution, because the effect of the combination of different modes is difficult to interpret. In this study, the relative molecular mass (M), radius of gyration (R_g), and conformation of Gastrodia elata polysaccharides (GEPs) were characterized using AF4 coupled with online multi-angle light scattering (MALS) and differential refractive index (dRI) detection (AF4-MALS-dRI). Steric transition was observed during GEP separation by AF4 owing to the broad size distribution of the molecules. This phenomenon would result in the inaccurate characterization of the GEPs in terms of M and R_g because two GEP groups of different sizes may elute together. In this study, the effects of constant and exponentially decaying cross-flow rates, sample mass concentration, and spacer thickness on steric transition were systematically investigated. The results indicated that a high GEP mass concentration (i. e., 0.75 mg/mL) can lead to steric transition. The spacer thickness affected the resolution and retention time of the GEPs and changed the steric transition point (d_i). An exponentially decaying cross-flow rate not only adjusted the d_i of the polydisperse GEP samples but also improved the GEP resolution and shortened the analysis time. The influence of steric transition was solved under the following operating conditions: injected GEP mass concentration=0.5 mg/mL; injection volume=50 μL; spacer thickness=350 μm; detector flow rate=1.0 mL/min; and cross-flow rate exponentially decayed from 0.2 to 0.05 mL/min with a half-life of 2 min. Moreover, the influence of GEP origins and ultrasound treatment time on the M and R_g distributions and conformation of GEPs were investigated under the optimized operating conditions. The results showed that the M and R_g distributions of Yunnan and Sichuan GEPs decreased with increasing ultrasound time. When the ultrasound treatment time was 15 min, the Yunnan GEPs had a loosely hyperbranched chain conformation, whereas the Sichuan GEPs had a spherical conformation. When the ultrasound treatment time was increased to 30 or 60 min, the GEPs from both Yunnan and Sichuan had a hyperbranched chain conformation, indicating that ultrasound treatment resulted in GEP degradation. Under the same extraction conditions, GEPs from Yunnan had larger M and R_g values than those from Sichuan. AF4-MALS-dRI showed good repeatability for the characterization of GEPs under the optimized operating conditions. The relative standard deviations of R_g and M were 0.5% and 1.7%, respectively. The data presented in this study can be used as a starting point for in-depth studies on the structural bioactivity of GEPs.

Key words: asymmetrical flow field-flow fractionation (AF4), Gastrodia elata polysaccharides (GEPs), steric transition

中图分类号:

O658

王沐, 张西瑞, 窦雨薇, 叶红, 窦海洋. 基于非对称场流分离技术分离表征天麻多糖:空间位阻转变效应[J]. 色谱, 2023, 41(8): 714-721.

WANG Mu, ZHANG Xirui, DOU Yuwei, YE Hong, DOU Haiyang. Separation and characterization of Gastrodia elata polysaccharides based on asymmetrical flow field-flow fractionation: steric transition phenomenon[J]. Chinese Journal of Chromatography, 2023, 41(8): 714-721.

图/表 8

图1 不同恒定交叉流流速下Y-GEP-15的AF4-MALS-dRI洗脱图谱、相对分子质量和回转半径分布图

Fig. 1 AF4-MALS-dRI fractograms, relative molecular mass (M) and radius of gyration (Rg) distributions of Y-GEP-15 obtained with different constant cross-flow rates (Vc) a. MALS response and M distribution; b. dRI response and Rg distribution. Y-GEP-15: Yunnan Gastrodia elata polysaccharides (GEPs) treated with ultrasound time of 15 min; AF4: asymmetrical flow field-flow fractionation; MALS: multi-angle light scattering; dRI: differential refractive index; tr: retention time.

图2 指数衰减交叉流不同初始流速下Y-GEP-15的AF4-MALS-dRI洗脱图谱、M和Rg分布图

Fig. 2 AF4-MALS-dRI fractograms, M and Rg distributions of Y-GEP-15 obtained with different initial exponentially decaying Vc a. MALS response and M distribution; b. dRI response and Rg distribution.

图3 不同质量浓度下Y-GEP-15的AF4-MALS-dRI洗脱图谱、M和Rg分布图

Fig. 3 AF4-MALS-dRI fractograms, M and Rg distributions of Y-GEP-15 obtained with different mass concentrations a. MALS response and M distribution; b. dRI response and Rg distribution.

图4 不同垫片高度下Y-GEP-15的AF4-MALS-dRI洗脱图谱、M和Rg分布图

Fig. 4 AF4-MALS-dRI fractograms, M and Rg distributions of Y-GEP-15 obtained with different spacer thicknesses a. MALS response and M distribution; b. dRI response and Rg distribution.

图5 Y-GEP-15的AF4-MALS-dRI洗脱图谱、M和Rg分布图的重复性

Fig. 5 Repeatability of AF4-MALS-dRI fractograms, M and Rg distributions of Y-GEP-15 a. MALS response and M distribution; b. dRI response and Rg distribution.

图6 不同产地及不同超声时间提取GEPs的AF4-MALS-dRI洗脱图谱、M和Rg分布图

Fig. 6 AF4-MALS-dRI fractograms, M and Rg distributions of GEPs extracted from different habitats and ultrasound times a. MALS response and M distribution; b. dRI response and Rg distribution; Y-GEP: Yunnan GEPs; S-GEP: Sichuan GEPs.

表1 不同产地及不同超声时间提取GEPs的分子特性

Table 1 Molecular characteristics of GEPs extracted from different habitats and ultrasound times

Sample	Habitat	Ultrasound time/min	M distribution	R_g distribution/nm	PDI/(M_w/M_n)
Y-GEP-15	Yunnan	15	3.14×10⁷-2.40×10⁹	90.9-287.7	2.93
Y-GEP-30	Yunnan	30	1.98×10⁷-8.70×10⁸	87.1-234.2	2.91
Y-GEP-60	Yunnan	60	1.82×10⁷-7.17×10⁸	68.5-209.9	2.83
S-GEP-15	Sichuan	15	1.75×10⁷-8.58×10⁸	67.2-247.3	2.37
S-GEP-30	Sichuan	30	1.49×10⁷-4.46×10⁸	62.7-210.0	1.79
S-GEP-60	Sichuan	60	1.42×10⁷-3.44×10⁸	58.8-209.9	1.61

图7 不同产地及不同超声时间提取GEPs的构象

Fig. 7 Conformation of GEPs extracted with different habitats and ultrasound times a. evaluation of GEP conformation based on the value of Rg/Rh; b. evaluation of GEP conformation based on the value of scaling exponent (v).

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