Liquid Plasticine Integrated with Isoelectric Focusing for Miniaturized Protein Analysis.

Developing miniaturized and rapid protein analytical platforms is urgently needed for on-site protein analysis, which is important for disease diagnosis and monitoring. Liquid marbles (LMs), a kind of particle-coated droplets, as ideal microreactors have been used in various fields. However, their application as analytical platforms is limited due to the difficulty of pretreating complex samples in simple LMs. Herein, inspired by the microfluidic chip, we propose a strategy through fabricating fluid channels using deformable LM, termed liquid plasticine (LP), to achieve sample pretreatment function. Through combining isoelectric focusing (IEF) with an LP channel, an LP-IEF platform with simultaneous protein separation and concentration functions is realized. The pretreatment capability of the LP-IEF system for proteins in physiological samples is proven using standard proteins and human serum with the results of a clear separation, 10-fold concentration, and a resolution of 0.03 pH. Through cutting the LP after IEF to LMs and transiting isolated LMs containing target proteins for further downstream colorimetric and mass spectrometry measurements, the quantitative analysis of clinical microalbuminuria and identification of α-1-microglobulin/bikunin precursor in clinical diabetic urine samples are achieved. This work proposes a strategy to develop LMs/LPs as a multifunctional integrated analytical platform and the miniaturized LP-IEF device as a rapid protein analytical platform.

Carrier ampholyte-free free-flow isoelectric focusing for separation of protein.

Free-flow isoelectric focusing (FFIEF) has the merits of mild separation conditions, high recovery and resolution, but suffers from the issues of ampholytes interference and high cost due to expensive carrier ampholytes. In this paper, a home-made carrier ampholyte-free FFIEF system was constructed via orientated migration of H+ and OH- provided by electrode solutions. When applying an electric field, a linear pH gradient from pH 4 to 9 (R2 = 0.994) was automatically formed by the electromigration of protons and hydroxyl ions in the separation chamber. The carrier ampholyte-free FFIEF system not only avoids interference of ampholyte to detection but also guarantees high separation resolution by establishing stable pH gradient. The separation selectivity was conveniently adjusted by controlling operating voltage and optimizing the composition, concentration and flow rate of the carrier buffer. The constructed system was applied to separation of proteins in egg white, followed by MADLI-TOF-MS identification. Three major proteins, ovomucoid, ovalbumin and ovotransferrin, were successfully separated according to their pI values with 15 mmol/L Tris-acetic acid (pH = 6.5) as carrier buffer at a flow rate of 12.9 mL/min.

High Resolution Capillary Isoelectric Focusing Mass Spectrometry Analysis of Peptides, Proteins, And Monoclonal Antibodies with a Flow-through Microvial Interface.

Capillary isoelectric focusing directly coupled to high resolution mass spectrometry (cIEF-MS) provides information on amphoteric molecules, including isoelectric point and accurate mass, which enables structural interrogation of biopolymer pI variants. The coupling of cIEF with MS was facilitated by a flow-through microvial interface, made by stainless steel with high chemical resistance and mechanical robustness. Two on-column electrolyte configurations of cIEF-MS were demonstrated using peptide and protein pI markers. The pI resolution was 0.02 pH unit in the pH range of 5.5 to 7.0, with no anticonvective reagent (glycerol) added. High resolution Orbitrap detector provides mass spectra for midsized proteins (<30 kDa), enabling deconvolution with high accuracy for IEF-focused low abundance species. Charge heterogeneity of therapeutic monoclonal antibodies (mAb) is one of the most important attributes in the biopharmaceutical industry, and it is routinely monitored by IEF and fractionation-based methods. As a proof of concept, the commercial formulation of infliximab was directly analyzed using cIEF-MS for separation and online identification of mAb charge variants. The main intact antibody species along with two basic and one acidic variants were observed, and their accurate molecular weights ( Mw) recorded by MS detector readily revealed the structural differences of these variants. Variants with 0.1 unit in pI difference and 1 Da difference in molecular weight were readily resolved. The deconvoluted intact Mw values showed ppm level accuracy compared to theoretical predictions.

Simultaneous pre-concentration and separation on simple paper-based analytical device for protein analysis.

In this work, fast isoelectric focusing (IEF) was successfully implemented on an open paper fluidic channel for simultaneous concentration and separation of proteins from complex matrix. With this simple device, IEF can be finished in 10 min with a resolution of 0.03 pH units and concentration factor of 10, as estimated by color model proteins by smartphone-based colorimetric detection. Fast detection of albumin from human serum and glycated hemoglobin (HBA1c) from blood cell was demonstrated. In addition, off-line identification of the model proteins from the IEF fractions with matrix-assisted laser desorption ionization time-of-flight mass spectrometry (MALDI-TOF-MS) was also shown. This PAD IEF is potentially useful either for point of care test (POCT) or biomarker analysis as a cost-effective sample pretreatment method.

Interference-free mass spectrometric detection of capillary isoelectric focused proteins, including charge variants of a model monoclonal antibody.

CIEF represents an elegant technique especially for the separation of structural similar analytes, whereas MS is a state-of-the-art instrumentation for the identification and characterization of biomolecules. The combination of both techniques can be realized by hyphenating CIEF with CZE-ESI-MS applying a mechanical valve. During the CZE step, the remaining ESI-interfering components of the CIEF electrolyte are separated from the analytes prior to MS detection. In this work, a multiple heart-cut approach is presented expanding our previous single heart-cut concept resulting in a dramatical reduction of analysis time. Moreover, different sample transfer loop volumes are systematically compared and discussed in regard to peak width and transfer efficiency. With this major enhancement, model proteins (1.63-9.75 mg/L), covering a wide pI range (5-10), and charge variants from a deglycosylated model antibody were analyzed on intact level. The promising CIEF-CZE-MS setup is expected to be applicable in different bioanalytical fields, e.g. for the fast and information rich characterization of therapeutic antibodies.

Surface isoelectric focusing (sIEF) with carrier ampholyte pH gradient.

Isoelectric focusing (IEF) is a powerful tool for amphoteric protein separations because of high sensitivity, bio-compatibility, and reduced complexity compared to chromatography or mechanical separation techniques. IEF miniaturization is attractive because it enables rapid analysis, easier adaptation to point of care applications, and smaller sample demands. However, existing small-scale IEF tools have not yet been able to analyze single protein spots from array libraries, which are ubiquitous in many pharmaceutical discovery and screening protocols. Thus, we introduce an in situ, novel, miniaturized protein analysis approach that we have termed surface isoelectric focusing (sIEF). Low volume printed sIEF gels can be run at length scales of ∼300 µm, utilize ∼0.9 ng of protein with voltages below 10 V. Further, the sIEF device platform is so simple that it can be integrated with protein library arrays to reduce cost; devices demonstrate reusability above 50 uses. An acrylamide monomer solution containing broad-range carrier ampholytes was microprinted with a Nano eNablerTM between micropatterned gold electrodes spaced 300 µm apart on a glass slide. The acrylamide gel was polymerized in situ followed by protein loading via printed diffusional exchange. A pH gradient formed via carrier ampholyte stacking when electrodes were energized; the gradient was verified using ratiometric pH-sensitive FITC/TRITC dyes. Green fluorescent protein (GFP) and R-phycoerythrin (R-PE) were utilized both as pI markers and to test sIEF performance as a function of electric field strength and ampholyte concentration. Factors hampering sIEF included cathodic drift and pH gradient compression, but were reduced by co-printing non-ionic Synperonic® F-108 surfactant to reduce protein-gel interactions. sIEF gels achieved protein separations in <10 min yielding bands < 50 µm wide with peak capacities of ∼8 and minimum pI differences from 0.12 to 0.14. This new sIEF technique demonstrated comparable focusing at ∼100 times smaller dimensions than any previous IEF. Further, sample volumes required were reduced four orders of magnitude from 20 µL for slab gel IEF to 0.002 µL for sIEF. In summary, sIEF advantages include smaller volumes, reduced power consumption, and microchip surface accessibility to focused bands along with equivalent separation resolutions to prior IEF tools. These attributes position this new technology for rapid, in situ protein library analysis in clinical and pharmaceutical settings.

Recent advances in CE-MS coupling: Instrumentation, methodology, and applications.

This review focuses on the latest development of microseparation electromigration methods in capillaries and microfluidic devices coupled with MS for detection and identification of important analytes. It is a continuation of the review article on the same topic by Kleparnik (Electrophoresis 2015, 36, 159-178). A wide selection of 161 relevant articles covers the literature published from June 2014 till May 2016. New improvements in the instrumentation and methodology of MS interfaced with capillary or microfluidic versions of zone electrophoresis, isotachophoresis, and isoelectric focusing are described in detail. The most frequently implemented MS ionization methods include electrospray ionization, matrix-assisted desorption/ionization and inductively coupled plasma ionization. Although the main attention is paid to the development of instrumentation and methodology, representative examples illustrate also applications in the proteomics, glycomics, metabolomics, biomarker research, forensics, pharmacology, food analysis, and single-cell analysis. The combinations of MS with capillary versions of electrochromatography, and micellar electrokinetic chromatography are not included.

Two-Dimensional Gel Electrophoresis: A Reference Protocol.

Two-dimensional gel electrophoresis (2DE) has been a mainstay of proteomic techniques for more than four decades. It was even in use for several years before the term proteomics was actually coined in the early 1990s. Over this time, it has been used in the study of many diseases including cancer, diabetes, heart disease, and psychiatric disorders through the proteomic analysis of body fluids and tissues. This chapter presents a general protocol which can be applied in the study of biological samples such as blood serum or plasma and multiple tissues including the brain.

Simple Means for Fractionating Protein Based on Isoelectric Point without Ampholyte.

In this paper, we develop a simple electrokinetic means for fractionating protein samples according to their pI values without using ampholytes. The method uses inexpensive equipment, and its consumables are primarily ammonium acetate buffers. A key component of its apparatus is a dialysis membrane interface that eliminates electrolysis-caused protein oxidation/reduction and constrains proteins in the desired places. We demonstrate its feasibility for fractionating standard proteins and real-world samples. With the elimination of ampholytes, we can analyze the fractionated proteins directly by a matrix assisted laser desorption/ionization time-of-flight mass spectrometer. Important experimental parameters are also discussed in order to obtain good fractionation results.

CIEF-CZE-MS applying a mechanical valve.

Separation and determination of proteins by capillary isoelectric focusing (CIEF) and mass spectrometry (MS) are essential and complementary techniques in the field of bioanalysis. The hyphenation of these two techniques is challenging due to the nonvolatile substances required for the CIEF separation. An additional separation step prior to MS enables the removal of the nonvolatile substances. However, it is complicated due to the small transfer volume and the required high voltages in the CIEF process. In order to remove nonvolatile substances and transfer the analytes toward the mass spectrometer, we applied a four-port valve to couple CIEF online to capillary electrophoresis-mass spectrometry. To demonstrate the power of this concept, hemoglobin and glycated hemoglobin with an isoelectric point difference of 0.037 were separated via isoelectric focusing and characterized by MS. In general, this setup guaranties interference-free mass spectra and will provide an information-rich and sensitive top down protein characterization. Graphical abstract Interference free coupling of capillary isoelectric focusing to mass spectrometry by applying a mechanical valve. The focused proteins were tranferred from the isoelectric focusing to capillary electrophoresis by a mechanical valve. Afterwards, the transferred protein was sepearated from ionization interfering substances in the capillary electrophoresis prior to the mass spectrometry detection.

On-chip intermediate LED-IF-based detection for the control of electromigration in multichannel networks.

Monitoring analytes during the transfer step from the first to the second dimension in multidimensional electrophoretic separations is crucial to determine and control the optimal time point for sample transfer and thus to avoid band broadening or unwanted splitting of the sample band with consequent sample loss. A spatially resolved intermediate on-chip LED-induced fluorescence detection system was successfully implemented for a hybrid capillary-chip glass interface. The setup includes a high-power 455-nm LED prototype as an excitation light source and a linear light fiber array consisting of 23 light fibers with a diameter of 100 µm for spatially resolved fluorescence detection in combination with a push-broom imager for hyperspectral detection. Using a basic FITC solution, the linear working range was determined to be 0.125 to 25 µg/ml for a single light guide and the absolute detection limit was 0.04 fmol at a signal-to-noise ratio of 4. With the setup presented here, labeled ß-lactoglobulin focused via capillary isoelectric focusing was detectable on-chip with a sufficient intensity to monitor the analyte band transfer in the glass-chip interface demonstrating its applicability for full or intermediate on-chip detection.

Computer simulations of sample preconcentration in carrier-free systems and isoelectric focusing in microchannels using simple ampholytes.

In this work, electrophoretic preconcentration of protein and peptide samples in microchannels was studied theoretically using the 1D dynamic simulator GENTRANS, and experimentally combined with MS. In all configurations studied, the sample was uniformly distributed throughout the channel before power application, and driving electrodes were used as microchannel ends. In the first part, previously obtained experimental results from carrier-free systems are compared to simulation results, and the effects of atmospheric carbon dioxide and impurities in the sample solution are examined. Simulation provided insight into the dynamics of the transport of all components under the applied electric field and revealed the formation of a pure water zone in the channel center. In the second part, the use of an IEF procedure with simple well defined amphoteric carrier components, i.e. amino acids, for concentration and fractionation of peptides was investigated. By performing simulations a qualitative description of the analyte behavior in this system was obtained. Neurotensin and [Glu1]-Fibrinopeptide B were separated by IEF in microchannels featuring a liquid lid for simple sample handling and placement of the driving electrodes. Component distributions in the channel were detected using MALDI- and nano-ESI-MS and data were in agreement with those obtained by simulation. Dynamic simulations are demonstrated to represent an effective tool to investigate the electrophoretic behavior of all components in the microchannel.

Microchip with an open tubular immobilized ph gradient for UV whole column imaging detection.

This study reports a new method for establishing an open tubular IPG in a microchip coupled with a whole column image detection (WCID) system for protein separation applications. This method allows a wider range of immobilized pH (2.6-9.5) to be established in a PDMS/quartz channel by controlling the diffusion of acidic and basic polymer solutions into the channel through well-designed channel dimensions. The developed pH gradient was experimentally validated by performing the separation of a mixture of standard pI markers. It was further validated by the separation of the hemoglobin control AFSC sample. This method is advantageous over existing IPG methods because it has a wider range of pH and maintains the open tubular feature that matches the UV WCID to improve the sensitivity.

Label-free microfluidic free-flow isoelectric focusing, pH gradient sensing and near real-time isoelectric point determination of biomolecules and blood plasma fractions.

We demonstrate the fabrication, characterization and application of microfluidic chips capable of continuous electrophoretic separation via free flow isoelectric focussing (FFIEF). By integration of a near-infrared (NIR) fluorescent pH sensor layer under the whole separation bed, on-line observation of the pH gradient and determination of biomolecular isoelectric points (pI) was achieved within a few seconds. Using an optical setup for imaging of the intrinsic fluorescence of biomolecules at 266 nm excitation, labelling steps could be avoided and the native biomolecules could be separated, collected and analysed for their pI. The fabricated microchip was successfully used for the monitoring of the separation and simultaneous observation of the pH gradient during the isoelectric focussing of the proteins α-lactalbumin and ß-lactoglobulin, blood plasma proteins and the antibiotics ampicillin and ofloxacin. The obtained pIs are in good agreement with literature data, demonstrating the applicability of the system. Mass spectra from the separated antibiotics taken after 15 minutes of continuous separation from different fractions at the end of the microchip validated the separation via microfluidic isoelectric focussing and indicate the possibility of further on- or off-chip processing steps.

Comparison of different mobilization strategies for capillary isoelectric focusing of ovalbumin variants.

One pressure and three chemical mobilization strategies have been optimized and tested for two-step capillary isoelectric focusing with ultraviolet detection with simultaneous refining of the composition of carrier ampholytes as well as of anodic and cathodic spacers. The comparison of individual mobilization strategies was performed on basis of model proteins and peptides covering a pI range of 4.1-10.0, finally targeting an acidic major food allergen, that is, ovalbumin. Resolution was improved by combining Pharmalyte 3-10 with Pharmalyte 5-6 with concentration adjustment of carrier ampholytes and the anodic and cathodic spacer, respectively. Analytes within pI 5-6 but not ovalbumin were prone to artificial peak duplication under selected capillary isoelectric focusing conditions due to retardation during focusing. l-Arginine and iminodiacetic acid were included as spacer to prevent drifts of the pH gradient and optionally block the distal capillary part. l-Arginine affected the baseline in the acidic regime in some instances by introducing irregularities that interfered with ovalbumin. Cathodic mobilization with an acidic zwitterion provided the best selectivity for ovalbumin and was successfully applied for the characterization of three commercial products of ovalbumin, revealing differences between the respective profiles. Up to 12 different fractions situated between pI 4.51 and 4.72 could be addressed.

Membrane-assisted isoelectric focusing device as a micropreparative fractionator for two-dimensional shotgun proteomics.

Recently, we introduced an online multijunction capillary isoelectric focusing (OMJ-CIEF) fractionator to fractionate proteins and peptides in electrospray-friendly solution. In this follow-up study, the original configuration of the fractionator was modified to improve the resolving power and reproducibility of separation. The major improvements include stabilization of the electrical current through the device using a voltage divider and stepwise elution of peptide zones in conjunction with the repeated refocusing of remaining peptides. Also, a novel algorithm was developed to calculate more accurately the pI values of peptides identified from experimental data. The standard deviation of calculated pI values for unmodified peptides from the theoretically predicted pI values was on average 0.21 pH units, which is more accurate than in standard-resolution gel-based methods. In order to characterize the analytical performance of the improved device, it was applied for the pI fractionation of yeast proteome digest into 18 fractions, with the collected fractions being analyzed by reverse-phase liquid chromatography coupled with tandem mass spectrometry. Approximately 37% of 20047 identified peptides were detected in only one fraction and 27% - in two fractions. On average, every peptide was found in 2.4 fractions. These results strongly indicate the suitability of the improved device as a first dimension of separation in multidimensional shotgun proteomics analysis, with a potential for fully automated workflow.

Simple power supply for power load controlled isoelectric focusing.

The power supply for IEF based on features of the Cockcroft-Walton voltage multiplier (CW VM) is described in this work. The article describes a design of the IEF power supply, its electric characteristics, and testing by IEF analysis. A circuit diagram of the power supply included two opposite charged branches (each consisting of four voltage doublers). The designed CW VM was powered by 230 V/50 Hz alternate current and it generated up to 5 kV and 90 mW at the output. Voltage and current characteristics of the power supply were measured by known load resistances in the range from 10 kΩ to 1 GΩ, which is a common resistance range for IEF strip geometry. Further, the power supply was tested by a separation of a model mixture of colored pI markers using a 175 × 3 × 0.5 mm focusing bed. Automatically limited power load enabled analysis of samples without previous optimization of the focusing voltage or electric current time courses according to sample composition. Moreover, the developed power supply did not produce any intrinsic heat and was easy to set up with cheap and commonly available parts.

Performance implications of chemical mobilization after microchannel IEF.

Chemical mobilization following IEF enables single-point detection of an ideally stationary equilibrium electrophoresis mode. Despite prior studies exploring optimization of chemical mobilization conditions and recent insight from numerical simulations, understanding of both chemical mobilization mechanisms and the implications of mobilization on IEF analytical performance remains limited. In this study, we utilize full-field imaging of microchannel IEF to assess the performance of a range of canonical chemical mobilization schemes. We empirically demonstrate and characterize key areas where limited understanding of performance implications exists, including: the effects of mobilization solution pH and ion concentration, differences between ionic and zwitterionic mobilization, and diffusion as a source of zone broadening. We utilize Simul5 simulations to gain insight into the sources of the measured performance differences. Measurements of the location, linearity, and slope of the IEF pH gradient (via fluorescent pH markers imaged before and during mobilization) as well as mobilization-associated broadening of focused analytes were performed to quantify performance and determine the dominant sources of variability. Our results suggest that nonuniform broadening of the pH gradient and changes in the pH gradient linearity stem from conductivity nonuniformities in the separation channel and not diffusion-associated band broadening during mobilization.

Interface solution isoelectric focusing with in situ MALDI-TOF mass spectrometry.

This paper describes a simple and reusable microfluidic device combining solution IEF (sIEF) with MALDI-TOF MS for rapid proteomic and metabolic analysis of microliter samples. The device contains two glass plates with nanoliter microwell arrays, which can be assembled to form a fluidic path for sIEF separation, and reconfigured for dividing separated bands. One microliter samples can be loaded and separated by sIEF into static bands in 10∼30 min. After a slipping operation, the static IEF bands can be divided into nanoliter droplets in microwells without mobilization, and the device can be opened for in situ MALDI-TOF MS detection without loss of separation resolution. The performance of the device is characterized by separating and identifying intact proteins. The applicability in metabolic analysis is demonstrated by preliminary experiments on profiling small molecular metabolites in cerebrospinal fluid microdialysates from rat brain.

No peptide left behind: the "out of range" recovery in IPG-IEF fractionation.

IEF is often used in multidimensional shotgun proteomics and the narrow range of 3.5-4.5 is the recommended pH interval for the fractionation of tryptic peptides. Usually, even if IEF is performed in IPG strip with a narrow range pH, the entire sample must be loaded onto the strip, including the "out of IPG range" peptides. We describe a simple protocol to recover at least a part of these missing peptides and show that this recovery significantly influences the overall fractionation result, increasing the number of the identified proteins and the protein coverage.