在線二維柱切換高效液相色譜法同時測定牙膏中三七皂苷R1、人參皂苷Rg1、Re和Rb1

張巖等

摘 要 使用雙梯度液相色譜系統(tǒng)紫外檢測器，建立了二維液相色譜法全自動快速同時測定牙膏中三七皂苷R1、人參皂苷Rg1、Re和Rb1的含量。樣品經(jīng)超聲提取后，以Syncronis C18為一維分析柱，ODS C18為二維分析柱，利用一維色譜柱完成三七皂苷R1和人參皂苷Rb1分離測定以及人參皂苷Rg1和人參皂苷Re的凈化； 利用二維色譜柱完成人參皂苷Rg1和人參皂苷Re的分析。一維分析和二維分析均以乙腈水體系作為流動相，梯度洗脫，檢測波長為203 nm，整個分析過程僅需30 min。三七皂苷R1、人參皂苷Rg1、Re和Rb1在0.5～200 mg/L范圍內(nèi)線性良好，相關系數(shù)R2分別為0.9994， 0.9996， 0.9995和0.9994，平均回收率均在86.4%～95.1%之間。本方法簡便快速，測定結(jié)果準確可靠，可用于牙膏中三七皂苷R1、人參皂苷Rg1、Re和Rb1含量的測定。

3.3 一維流動相的選擇

考察了流動相為乙腈水體系和甲醇水體系對一維

色譜保留時間及峰形的影響，結(jié)果表明，使用甲醇水為流動相三七皂苷R1、人參皂苷Rg1和Re三者不能達到基線分離，且峰形較寬（圖4）。無法確定人參皂苷Rg1和Re切入二維色譜柱的時間，因色譜峰形過寬，需要切入時間長，造成流動相比例不匹配，容易引起壓力波動，從而影響到二維色譜中目標物保留時間的漂移。采用乙腈水作為一維色譜流動相時，雖然人參皂苷Rg1和Re重合在一起，但二者能夠與三七皂苷R1達到基線分離分析，且峰形良好，峰窄，從而確定了二維分析的切入時間，故選擇了乙腈水體系作為一維流動相（圖4）。通過優(yōu)化實驗條件發(fā)現(xiàn)乙腈水體系應用于二維色譜能夠?qū)⑷藚⒃碥誖g1和Re分離，為了使流動相匹配，避免壓力波動，所以二維流動相選擇乙腈水體系。

在一維分析中三七皂苷R1和人參皂苷Rb1較容易分離，所以在一維色譜中采用高比例的有機相和細粒徑的色譜柱，提高分析速度，使在一維色譜中較難分離且存在基質(zhì)干擾的人參皂苷Rg1和Re切換到二維色譜柱中繼續(xù)分離，常規(guī)色譜分析4種物質(zhì)需60 min以上，本方法僅需30 min，提高了分析速度，同時解決了人參皂苷Rg1和Re存在干擾和分離的難題。

實驗結(jié)果表明， 通過在線二維柱切換，雙梯度洗脫，簡化了分析過程，提高了分析速度，有效去除了復雜基質(zhì)的干擾。本方法可作為牙膏中三七皂苷R1、人參皂苷Rg1， Re和Rb1的常規(guī)檢測方法，為監(jiān)管部門規(guī)范管理口腔衛(wèi)生產(chǎn)品市場提供了技術支撐。

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Simultaneous Quantification of Notoginsenoside R1 and Ginsenoside

Rg1， Re， Rb1 in Tooth Paste by Liquid Chromatography Coupled

with Fully Automated Online Twodimensional Column Switching Method

ZHANG Yan1，2， MA XiaoFei2， L Pin1， CONG Bin*1

1（Hebei Key Laboratory of Forensic Medicine， Department of Forensic Medicine，

Hebei Medical University， Shijiazhuang 050017， China）

2（Hebei Key Laboratory of Food Safety， Hebei Food Inspection and Research Institute， Shijiazhuang 050091， China）

Abstract A novel automated method for simultaneous quantification of notoginsenoside R1 and ginsenoside Rg1， Re， Rb1 in tooth paste was developed using twodimensional columnswitching chromatography with dual gradient liquid chromatography system coupled with UV detector. The determination of notoginsenoside R1 and ginsenoside Rb1 and the purification of ginsenoside Rg1， Re were accomplished in the onedimensional column. The separation of ginsenoside Rg1， Re was finished on the twodimensional column. Syncronis C18 was used as the onedimensional column with the mobile phase of acetonitrile and water， and ODS C18 was employed as the twodimensional column with the mobile phase was as same as in onedimensional column. The detection wavelength was set at 203 nm. The determination was completed in 30 min. The good linearities of notoginsenoside R1 and ginsenoside Rg1， Re， Rb1 were proved respectively in the range of 0.5-200 mg/L and the correlation coefficients （R2） were 0.9994， 0.9996， 0.9995 and 0.9994 respectively. The mean recoveries of notoginsenoside R1 and ginsenoside Rg1， Re， Rb1 were 86.4%-95.1%. It was proved that this method could greatly improve the efficiency of sample analysis.

Keywords High performance liquid chromatography； Twodimensional separation； Notoginsenoside； Ginsenoside

（Received 20 August 2014； accepted 7 October 2014

14 Zu Y G， Yan M M， Fu Y J， Liu W， Zhang L， Gu C B， Efferth T. J. Sep. Sci.， 2009， 32（4）： 517-525

15 Bompadre S， Tagliabracci A， Battino M， Giorgetti R. J. Chromatogr. B， 2008， 863（1）： 177-180

Simultaneous Quantification of Notoginsenoside R1 and Ginsenoside

Rg1， Re， Rb1 in Tooth Paste by Liquid Chromatography Coupled

with Fully Automated Online Twodimensional Column Switching Method

ZHANG Yan1，2， MA XiaoFei2， L Pin1， CONG Bin*1

1（Hebei Key Laboratory of Forensic Medicine， Department of Forensic Medicine，

Hebei Medical University， Shijiazhuang 050017， China）

2（Hebei Key Laboratory of Food Safety， Hebei Food Inspection and Research Institute， Shijiazhuang 050091， China）

Abstract A novel automated method for simultaneous quantification of notoginsenoside R1 and ginsenoside Rg1， Re， Rb1 in tooth paste was developed using twodimensional columnswitching chromatography with dual gradient liquid chromatography system coupled with UV detector. The determination of notoginsenoside R1 and ginsenoside Rb1 and the purification of ginsenoside Rg1， Re were accomplished in the onedimensional column. The separation of ginsenoside Rg1， Re was finished on the twodimensional column. Syncronis C18 was used as the onedimensional column with the mobile phase of acetonitrile and water， and ODS C18 was employed as the twodimensional column with the mobile phase was as same as in onedimensional column. The detection wavelength was set at 203 nm. The determination was completed in 30 min. The good linearities of notoginsenoside R1 and ginsenoside Rg1， Re， Rb1 were proved respectively in the range of 0.5-200 mg/L and the correlation coefficients （R2） were 0.9994， 0.9996， 0.9995 and 0.9994 respectively. The mean recoveries of notoginsenoside R1 and ginsenoside Rg1， Re， Rb1 were 86.4%-95.1%. It was proved that this method could greatly improve the efficiency of sample analysis.

Keywords High performance liquid chromatography； Twodimensional separation； Notoginsenoside； Ginsenoside

（Received 20 August 2014； accepted 7 October 2014

14 Zu Y G， Yan M M， Fu Y J， Liu W， Zhang L， Gu C B， Efferth T. J. Sep. Sci.， 2009， 32（4）： 517-525

15 Bompadre S， Tagliabracci A， Battino M， Giorgetti R. J. Chromatogr. B， 2008， 863（1）： 177-180

Simultaneous Quantification of Notoginsenoside R1 and Ginsenoside

Rg1， Re， Rb1 in Tooth Paste by Liquid Chromatography Coupled

with Fully Automated Online Twodimensional Column Switching Method

ZHANG Yan1，2， MA XiaoFei2， L Pin1， CONG Bin*1

1（Hebei Key Laboratory of Forensic Medicine， Department of Forensic Medicine，

Hebei Medical University， Shijiazhuang 050017， China）

2（Hebei Key Laboratory of Food Safety， Hebei Food Inspection and Research Institute， Shijiazhuang 050091， China）

Abstract A novel automated method for simultaneous quantification of notoginsenoside R1 and ginsenoside Rg1， Re， Rb1 in tooth paste was developed using twodimensional columnswitching chromatography with dual gradient liquid chromatography system coupled with UV detector. The determination of notoginsenoside R1 and ginsenoside Rb1 and the purification of ginsenoside Rg1， Re were accomplished in the onedimensional column. The separation of ginsenoside Rg1， Re was finished on the twodimensional column. Syncronis C18 was used as the onedimensional column with the mobile phase of acetonitrile and water， and ODS C18 was employed as the twodimensional column with the mobile phase was as same as in onedimensional column. The detection wavelength was set at 203 nm. The determination was completed in 30 min. The good linearities of notoginsenoside R1 and ginsenoside Rg1， Re， Rb1 were proved respectively in the range of 0.5-200 mg/L and the correlation coefficients （R2） were 0.9994， 0.9996， 0.9995 and 0.9994 respectively. The mean recoveries of notoginsenoside R1 and ginsenoside Rg1， Re， Rb1 were 86.4%-95.1%. It was proved that this method could greatly improve the efficiency of sample analysis.

Keywords High performance liquid chromatography； Twodimensional separation； Notoginsenoside； Ginsenoside

（Received 20 August 2014； accepted 7 October 2014