Reduction in delay time of high‐dwell volume pumps in LC‐MS applications using short‐term low‐ratio split flow

We present a simple hardware design which reduces run time of gradient‐based LC/MS applications and improves system equilibration. Our approach does not sacrifice efficiency of chromatographic separation, and does not affect analyte retention time and therefore does not require revalidation. Our technical design is based on a six‐port/two‐position switching valve and flow splitter installed prior to the LC column. This design minimizes time delays caused by the high‐dwell volume of some LC pumps. Implementation of short‐term (40–55 s) low‐ratio (1:10) flow splitting reduced delay times by over four‐fold in our application. This approach allowed hardware‐associated time delays to be minimized. Alternative plumbing suggestions are also discussed.     

A New Splitting Method for Both Analytical and Preparative LC/MS

This paper presents a novel splitting method for liquid chromatography/mass spectrometry (LC/MS) application, which allows fast MS detection of LC-separated analytes and subsequent online analyte collection. In this approach, a PEEK capillary tube with a micro-orifice drilled on the tube side wall is used to connect with LC column. A small portion of LC eluent emerging from the orifice can be directly ionized by desorption electrospray ionization (DESI) with negligible time delay (6~10 ms) while the remaining analytes exiting the tube outlet can be collected. The DESI-MS analysis of eluted compounds shows narrow peaks and high sensitivity because of the extremely small dead volume of the orifice used for LC eluent splitting (as low as 4 nL) and the freedom to choose favorable DESI spray solvent. In addition, online derivatization using reactive DESI is possible for supercharging proteins and for enhancing their signals without introducing extra dead volume. Unlike UV detector used in traditional preparative LC experiments, this method is applicable to compounds without chromophores (e.g., saccharides) due to the use of MS detector. Furthermore, this splitting method well suits monolithic column-based ultra-fast LC separation at a high elution flow rate of 4 mL/min.

Low flow high-performance liquid chromatography solvent delivery system designed for tandem capillary liquid chromatography-mass spectrometry

A solvent delivery system is described that is designed to increase the efficiency of liquid chromatography-mass spectrometry (LC/MS) analyses. Gradients formed by using two low pressure syringe pumps are stored in a length of narrow bore tubing (gradient loop) mounted on a standard high pressure switching valve. The preformed gradient is pushed through the column by using a high pressure syringe pump. The system is fully automated and can be controlled with either a personal computer or the mass spectrometer data system. Advantages include gradient operation without the use of split flows, pressure programed flow control for rapid sample loading and recycling to initial conditions, and a flow rate range of 0.1–20 μL/min, which is suitable for packed capillary columns 50–500 μm in diameter. The system has been used extensively for rapid molecular weight determinations of intact protein samples, as well as LC/MS and liquid chromatography-tandem mass spectrometry analyses of complex peptide mixtures.     

A simplified device for protein identification by microcapillary gradient liquid chromatography-tandem mass spectrometry

A simplified device and procedure have been developed for microcapillary gradient liquid chromatography-tandem mass spectrometry (LC-MS/MS). This procedure has proved useful in identifying low level quantities of proteins from sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) gel bands. Microelectrospray needles are packed with reversed-phase resin and function both as a high performance liquid chromatography (HPLC) column and a nanospray mass spectrometer tip when interfaced between an HPLC and ion trap mass spectrometer. Variable submicroliter flow rates are generated by flow splitting between the microelectrospray capillary and an HPLC system. A manual injector is used to inject a protein digest mixture that binds to the column and is then washed at a high flow rate (2 microL/min post split). Gradient elution of bound peptides was initiated by the injection of a filled loop of 70% v/v methanol (5 microL) concomitant with a reduction of flow rate (0.1 microL/min post split). This forms a diffusion-dependent gradient of variable length (typically 15-30 min in length) depending upon the final flow rate. Chromatographic separations of a standard solution digest demonstrate that this diffusion-dependent gradient provides reasonable separations such that multiple peptide identifications by MS/MS can be obtained. Application of this methodology to the analysis of several in-gel-digested gel-separated proteins is presented to demonstrate its utility.     

Increased productivity in quantitative bioanalysis using a monolithic column coupled with high-flow direct-injection liquid chromatography/tandem mass spectrometry

The feasibility of using a monolithic column as the analytical column in conjunction with high-flow direct-injection liquid chromatography/tandem mass spectrometry (LC/MS/MS) to increase productivity for quantitative bioanalysis has been investigated using plasma samples containing a drug and its epimer metabolite. Since the chosen drug and its epimer metabolite have the same selected reaction monitoring (SRM) transitions, chromatographic baseline separation of these two compounds was required. The results obtained from this monolithic column system were directly compared with the results obtained from a previously validated assay using a conventional C18 column as the analytical column. Both systems have the same sample preparation, mobile phases and MS conditions. The eluting flow rate for the monolithic column system was 3.2 mL/min (with 4:1 splitting) and for the C18 column system was 1.2 mL/min (with 3:1 splitting). The monolithic column system had a run time of 5 min and the conventional C18 column system had a run time of 10 min. The methods on the two systems were found to be equivalent in terms of accuracy, precision, sensitivity and chromatographic separation. Without sacrificing the chromatographic separation, sensitivity, accuracy and precision of the method, the reduced run time of the monolithic column method increased the sample throughput by a factor of two.     

Rapid determination of rifaximin on dried blood spots by LC‐ESI‐MS

The use of blood spot collection cards is a simple way to obtain specimens for therapeutic drug monitoring, assessing adherence to medications and preventing toxicity in a clinical setting. A high‐throughput liquid chromatography–electrospray ionization mass spectrometric (LC‐ESI‐MS) method for determination of rifaximin on dried blood spots (DBS) was developed and validated. It involves solvent extraction of a punch of DBS followed by reversed‐phase LC on a monolithic column consisting of a silica rod with bimodal pore structure and detection by ESI‐MS. Rifampicin was used as an internal standard (IS). The run time was within 5.0 min with a very low back‐pressure at a flow rate of 0.5 mL/min. The assay was linear from 0.1 to 10 ng/mL. The mean recovery was 98.42%. The developed method is very simple, rapid and useful for clinical applications. Copyright © 2011 John Wiley & Sons, Ltd.     

Development of a validated high-throughput LC-ESI-MS method for determination of sirolimus on dried blood spots

A high‐throughput liquid chromatography–electrospray ionization mass spectrometric (LC–ESI‐MS) method for screening of sirolimus on dried blood spots (DBS) was developed and validated. It involves solvent extraction of a punch of DBS followed by reversed‐phase LC on a relatively new monolithic column consisting of a silica rod with bimodal pore structure and detection by ESI‐MS. The run time was less than 3 min with a very low backpressure at a flow rate of 0.5 mL/min. The method can analyze more than 100 samples in an 8 h working day, including sample preparation. The assay was linear from 1 to 100 ng/mL. The mean recovery was 92.42%. The mean inter‐day and intra‐day precisions were 1.23 and 1.41%, respectively. The developed method is simple, rapid and useful for clinical applications. Copyright © 2010 John Wiley & Sons, Ltd.     

采用柱后抑制器技术降低流动相中三氟乙酸对质谱信号抑制作用的研究

研究柱后抑制器(CSRS)技术有效降低流动相中三氟乙酸(TFA)对质谱信号的抑制.采用双三元液相系统,左泵以反相模式分离细胞色素C酶解肽段(流动相含0.1%TFA,流速0.25 m L/min),柱后选择CSRS作为抑制器.同时右泵提供碳酸氢铵(浓度为0.05 mol/L,流速1.00 m L/min)作为再生液.碳酸氢铵和三氟乙酸在抑制器CSRS中通过阴离子交换膜进行离子交换,降低流动相中TFA离子抑制效应,提高肽段在质谱上的响应(S/N提高1~16倍).采用柱后抑制器技术对硫酸依替米星主成分及杂质进行定性分析(0.2 mol/L TFA),流动相经过抑制器后由强酸性变成中性,实现样品在LC和MS之间无缝连接分析.     

Ternary-column system for high-throughput direct-injection bioanalysis by liquid chromatography/tandem mass spectrometry

As a continuation of our efforts to improve our high-flow on-line bioanalytical approach for high-throughput quantitation of drugs and metabolites in biological matrices by high-performance liquid chromatography (LC) and tandem mass spectrometry (MS/MS), we have developed a ternary-column on-line LC/MS/MS system with dual extraction columns used in parallel for purification and an analytical column for analysis. The advantage of the dual extraction column system is that sample analysis can take place in one of the extraction columns while the other column is being equilibrated. Thus, the equilibration time does not add to the run time, hence shortening the injection cycle time and increasing the sample throughput. Moreover, the use of two extraction columns in parallel increases the number of samples that can be injected before the system fails due to an overused extraction column. Such a system has successfully been used to develop and validate a positive ion electrospray LC/MS/MS bioanalytical method for the quantitative determination of a guanidine-containing drug candidate in rat plasma. The system used for this work utilized two Oasis HLB extraction columns (1 x 50 mm, 30 microm), one C18 analytical column (3.9 x 50 mm, 5 microm), a ten-port switching value and a tandem mass spectrometer. The on-line analysis was accomplished by the direct injection of 10 microL of the sample, obtained by mixing a rat plasma sample 1:1 with an aqueous internal standard solution. Selected reaction monitoring (SRM) was utilized for the detection of the analyte and internal standard. The standard curve range was 1.00-200 ng/mL. The intra- and inter-day precision and accuracy were within 6.6%. The on-line purification step lasted for only 0.3 min and total run time was only 1.6 min.     

A novel interface for variable flow nanoscale LC/MS/MS for improved proteome coverage

A variable flow "peak trapping" liquid chromatography (LC) interface has been developed for the coupling of nanoscale LC to electrospray ionization mass spectrometry (ESI-MS). The presented peak trapping LC interface allows for the extended analysis time of co-eluting compounds and has been employed for the identification of proteins via tandem mass spectrometry (MS/MS). The variable flow process can be controlled either manually or in a completely automated manner where the mass spectrometer status determines the status of the variable flow interface. When the mass spectrometer operates in MS survey mode, the interface is operated in a so-called "high-flow" mode. Alternatively, the interface is operated in a "low-flow" mode during MS/MS analysis. In the "high-flow" mode of the variable flow process the column flow rate is typically around 200 nL/min, whereas in the "low-flow" mode the column effluent is introduced into the source of the mass spectrometer at 25 nL/min. In addition to the flow reduction during MS/MS analysis, the gradient is paused to preserve the peptide separation on the analytical nanoscale LC column. The performance of the variable flow nanoscale LC/MS/MS interface is demonstrated by the automated analysis of standard peptide mixtures and protein digests utilizing variable flow, data-dependent scanning MS/MS techniques, and automated database searching.     

Ultra-fast tandem mass spectrometry scanning combined with monolithic column liquid chromatography increases throughput in proteomic analysis

Liquid chromatography combined with electrospray ionization mass spectrometry (LC/ESI-MS) has been used successfully for the characterization of biomolecules in proteomics in the last few years. This methodology relied largely on the use of reversed-phase chromatography, in particular C18-based resins, which are suitable for separation of peptides. Here we show that polymeric [polystyrene divinylbenzene] monolithic columns can be used to separate peptide mixtures faster and at a higher resolution. For 500 fmol bovine serum albumin, up to 68% sequence coverage and Mascot Mowse scores of >2000 were obtained using a 9 min gradient on a monolithic column coupled to an ion trap mass spectrometer with ultra-fast MS/MS scan rates. In order to achieve similar results using C18 columns, it was necessary to extend gradient times to 30 min. In addition, we demonstrate the utility of this approach for the analysis of whole Escherichia coli cell lysates by one-dimensional sodium dodecyl sulfate polyacrylamide gel electrophoresis (1D-SDS-PAGE) in combination with LC/MS/MS using 4 min gradients on monolithic columns. Our results indicate higher throughput capabilities of monolithic columns (3-fold gain in time or more) for conventional proteomics applications, such as protein identification and high sequence coverage usually required for detection of post-translational modifications (PTMs). Further optimization of sensitivity and quality of sequence information is discussed, in particular when combined with mass spectrometers that have very fast MS-MS/MS switching and scanning capabilities.     

Validation of a liquid chromatography ionspray mass spectrometry method for the analysis of flavanones, flavones and flavonols

The application of liquid chromatography/mass spectrometry (LC/MS) with a TurboIonspray (TIS) interface was investigated as a new method for the analysis of flavonoids. Eleven compounds belonging to three different classes of flavonoids were studied: eriocitrin, neoeriocitrin, naringin, narirutin, hesperidin, neohesperidin (flavanone glycosides), quercetin, kaempferol, galangin (flavonol aglycones), chrysin, apigenin (flavone aglycones). Chromatographic separations were performed under reversed-phase conditions using a C18 narrow-bore LC column; a mixture of an aqueous solution of formic acid (pH 2.4) and acetonitrile was used as the mobile phase. Isocratic elution was operated in the case of flavanones, whereas gradient elution was used for the simultaneous separation of flavones and flavonols. The adaptability of TIS to high flow applications allows the use of LC eluent flow rates at 200 μL/min without post-column splitting. Qualitative analysis was performed in negative-ion (NI) full-scan mode, whereas response linearity, detection limits and precision of the method were studied under NI selected ion monitoring (SIM) conditions. Characterization of isomers differing in the glycosylation was found to be possible on the basis of different mass spectra. Detection limits in the low-ng range (0.08-0.4 ng) were found, about twenty-fold lower than those reported previously. The method was applied to identify and determine the content of flavonoids in an orange juice sample. Copyright 1999 John Wiley & Sons, Ltd.     

Development and validation of a rapid and high‐sensitivity liquid chromatography–tandem mass spectrometry assay for the determination of neostigmine in small‐volume beagle dog plasma and its application to a pharmacokinetic study

A simple, rapid and high sensitive liquid chromatography–tandem mass spectrometry (LC‐MS/MS) method for the determination of neostigmine in small‐volume beagle dog plasma was developed to assess the plasma pharmacokinetics of neostigmine. After protein precipitation in a Sirocco 96‐well filtration plate, the filtrate was directly injected into the LC‐MS/MS system. The analytes were separated on a Hanbon Hedera CN column (100 × 4.6 mm, 5 µm) with a mobile phase composed of methanol–water (60:40, v/v) and the water containing 0.01% formic acid at a flow rate of 0.6mL/min, with a split ratio of 1:1 flowing 300 μL into the mass spectrometer. The run time was 3 min. Detection was accomplished by electrospray ionization source in multiple reactions monitoring mode with the precursor‐to‐product ion transitions m/z 223.0 → 72.0 and 306.0 → 140.0 for neostigmine and anisodamine (internal standard), respectively. The method was sensitive with a lower limit of quantitation of 0.1 ng/mL, and good linearity in the range 0.1–100ng/mL for neostigmine (r ≥ 0.998). All the validation data, such as accuracy, intra‐run and inter‐run precision, were within the required limits. The method was successfully applied to pharmacokinetic study of neostigmine methylsulfate injection in beagle dogs. Copyright © 2013 John Wiley & Sons, Ltd.     

Combination of liquid chromatography/tandem mass spectrometry and gas chromatography/mass spectrometry for the detection of 21 anabolic steroid residues in bovine urine

For the detection of anabolic steroid residues in bovine urine, a highly sensitive liquid chromatographic/electrospray ionization tandem mass spectrometric (LC/ESI-MS/MS) method was developed using both positive and negative ionization. For four compounds the ESI mode was not sensitive enough and gas chromatographic/mass spectrometric GC/MS detection was therefore still necessary as a complementary method. The sample clean-up consisted of solid-phase extraction (SPE) on a C(18) column followed by enzymatic hydrolysis and a second solid-phase extraction on a combination of a C(18) and a NH(2) column. After this last SPE clean-up, the eluate was split into two equal aliquots. One aliquot was further purified and after derivatization used for GC/MS analysis. The other aliquot was analyzed with LC/MS/MS in both ESI+ and ESI- modes. The method was validated according to the European Commission Decision 2002/657/EC. Decision limits (CCalpha) were between 0.16 and 1 ng ml(-1) for the compounds detected with the LC/MS/MS method. The developed method is used in routine analysis in our laboratory.     

Ultralow flow liquid chromatography and related approaches: A focus on recent bioanalytical applications

Ultralow flow LC employs ultra-narrow bore columns and mid-range pL/min to low nL/min flow rates (i.e., ≤20 nL/min). The separation columns that are used under these conditions are typically 2–30 μm in inner diameter. Ultralow flow LC systems allow for exceptionally high sensitivity and frequently high resolution. There has been an increasing interest in the analysis of scarce biological samples, for example, circulating tumor cells, extracellular vesicles, organelles, and single cells, and ultralow flow LC was efficiently applied to such samples. Hence, advances towards dedicated ultralow flow LC instrumentation, technical approaches, and higher throughput (e.g., tens-to-hundreds of single cells analyzed per day) were recently made. Here, we review the types of ultralow flow LC technology, followed by a discussion of selected representative ultralow flow LC applications, focusing on the progress made in bioanalysis of amount-limited samples during the last 10 years. We also discuss several recently reported high-sensitivity applications utilizing flow rates up to 100 nL/min, which are below commonly used nanoLC flow rates. Finally, we discuss the path forward for future developments of ultralow flow LC.     

High-throughput liquid chromatography ultraviolet/mass spectrometric analysis of combinatorial libraries using an eight-channel multiplexed electrospray time-of-flight mass spectrometer

We report a high-throughput liquid chromatography/mass spectrometry (LC/MS) protocol for analyzing large combinatorial libraries using an eight-channel parallel LC/UV/MS (MUX-LCT) system. System configuration, linear response range in UV absorbance, LC column selection, and flow rate were optimized for 24 h/7 day unattended operations. Combinatorial libraries were analyzed on this system at a rate of 3200 compounds per day for a 3.5 min cycle time per injection. This parallel system is compared with a single-channel system in terms of performance and operation.     

Addressing the analytical throughput challenges in ADME screening using rapid ultra-performance liquid chromatography/tandem mass spectrometry methodologies

High-throughput ADME screening for compound drug development properties has become an essential part of the modern drug discovery process, allowing more informed decisions to be made on the best compounds to take forward in the discovery/development process. This however is a time-consuming process requiring multiple tests to be performed, demanding a significant amount of liquid chromatography/mass spectrometry (LC/MS) instrument time. This article focuses on the use of sub-2 microm porous particle LC coupled to tandem quadrupole MS/MS mass spectrometry for the rapid screening of ADME properties. Using this approach analysis times from 30 s to 1 min were achievable allowing analysis times to be cut by 80%. The use of the small particles coupled to high flow rates allowed for sufficient resolution, even with very short analysis time, to resolve the analytes of interest from similar compounds that would interfere with the assay. The use of dedicated, intelligent, software packages allowed for the user-free generation of MS/MS conditions and the processing of the data.     

Development of a LC‐MS/MS method for simultaneous determination of metoprolol and its metabolites, α‐hydroxymetoprolol and O‐desmethylmetoprolol,in rat plasma: application to the herb–drug interaction study of metoprolol and breviscapine

A simple, specific and sensitive LC‐MS/MS method was developed and validated for the simultaneous determination of metoprolol (MET), α‐hydroxymetoprolol (HMT) and O‐desmethylmetoprolol (DMT) in rat plasma. The plasma samples were prepared by protein precipitation, then the separation of the analytes was performed on an Agilent HC‐C₁₈ column (4.6 × 250 mm, 5 µm) at a flow rate of 1.0 mL/min, and post‐column splitting (1:4) was used to give optimal interface flow rates (0.2 mL/min) for MS detection; the total run time was 8.5 min. Mass spectrometric detection was achieved using a triple‐quadrupole mass spectrometer equipped with an electrospray source interface in positive ionization mode. The method was fully validated in terms of selectivity, linearity, accuracy, precision, stability, matrix effect and recovery over a concentration range of 3.42–7000 ng/mL for MET, 2.05‐4200 ng/mL for HMT and 1.95‐4000 ng/mL for DMT. The analytical method was successfully applied to herb–drug interaction study of MET and breviscapine after administration of breviscapine (12.5 mg/kg) and MET (40 mg/kg). The results suggested that breviscapine have negligible effect on pharmacokinetics of MET in rats; the information may be beneficial for the application of breviscapine in combination with MET in clinical therapy. Copyright © 2015 John Wiley & Sons, Ltd.     

Bioanalysis of erythromycin 2'-ethylsuccinate in plasma using phase-system switching continuous-flow fast atom bombardment liquid chromatography-mass spectrometry

A specific method for the determination of erythromycin 2'-ethylsuccinate (EM-ES) in plasma is described. The method involves a liquid-liquid extraction procedure followed by the analysis of extracts using phase-system switching (PSS) continuous-flow fast atom bombardment (CF-FAB) liquid chromatography-mass spectrometry (LC-MS). In PSS EM-ES is enriched after analytical separation on a short trapping column, from which it is desorbed to the LC-MS interface. In this way, favourable mobile phases can be used for the LC separation and for the MS detection. Using the PSS approach a flow-rate reduction from 1.0 ml/min in the LC system to 15 microliters/min going into the mass spectrometer was achieved without splitting. The determination limit for EM-ES was 0.1 microgram/ml.