On-line Size Exclusion Chromatography Research Articles

High-Throughput Quantification and Characterization of Dual Payload mRNA/LNP Cargo via Deformulating Size Exclusion and Ion Pairing Reversed Phase Assays.

Therapeutic drugs and multivalent vaccines based on the delivery of mRNA via lipid nanoparticle (LNP) technologies are expected to dominate the biopharmaceutical industry landscape in the coming years. Many of these innovative therapies include several nucleic acid components (e.g., nuclease mRNA and guide RNA) posing unique analytical challenges when monitoring the quantity and quality of each individual payload substance in the formulated LNP. Current methods were optimized for single payload analysis and often lack resolving power needed to investigate nucleic acid mixtures. Ion pairing reversed phase (IP-RP) and size exclusion chromatography (SEC) are increasingly being used to characterize nucleic acids. Here, we studied their application for payload quantification in formulated LNP drug-like products. Using a detergent to disrupt the LNPs, the liberated payloads can be separated on an octadecyl RP column using a fast gradient. Reproducible results were obtained as lipids, and surfactants were efficiently eluted using a high organic solvent wash protocol. Alternatively, we also established an online SEC disruption analysis of the mRNA/LNPs wherein an alcohol and detergent containing a mobile phase was applied. Such conditions universally deformulated all tested LNP samples, indicating that a 5 min-long SEC separation can be used as a high-throughput platform method. In both approaches, the measurements facilitate a multiattribute analysis. Apart from quantitation, the characterization of specific impurities is achieved: IP-RP reveals mRNA-lipid adducts, while SEC informs on size variants, which in turn reduces a laboratory's analytical workload. These easy-to-adopt LC-based assays are expected to fortify the analytical toolbox for emerging gene therapeutics.

Coupling Online Size Exclusion Chromatography with Charge Detection-Mass Spectrometry Using Hadamard Transform Multiplexing.

Charge detection mass spectrometry (CD-MS) is a powerful technique for the analysis of large, heterogeneous biomolecules. By directly measuring the charge states of individual ions, CD-MS can measure the masses from spectra where conventional deconvolution approaches fail due to the lack of isotopic resolution or distinguishable charge states. However, CD-MS is inherently slow because hundreds or thousands of spectra need to be collected to produce adequate ion statistics. The slower speed of CD-MS complicates efforts to couple it with online separation techniques, which limit the number of spectra that can be acquired during a chromatographic peak. Here, we present the application of Hadamard transform multiplexing to online size exclusion chromatography (SEC) coupled with Orbitrap CD-MS, with a goal of using SEC for separating complex mixtures prior to CD-MS analysis. We developed a microcontroller to deliver pulsed injections from a large sample loop onto a SEC for online CD-MS analysis. Data showed a series of peaks spaced according to the pseudorandom injection sequence, which were demultiplexed with a Hadamard transform algorithm. The demultiplexed data revealed improved CD-MS signals while preserving retention time information. This multiplexing approach provides a general solution to the inherent incompatibilities of online separations and CD-MS detection that will enable a range of applications.

Not All Arms of IgM Are Equal: Following Hinge-Directed Cleavage by Online Native SEC-Orbitrap-Based CDMS.

Immunoglobulins M (IgM) are key natural antibodies produced initially in humoral immune response. Due to their large molecular weights and extensive glycosylation loads, IgMs represent a challenging target for conventional mass analysis. Charge detection mass spectrometry (CDMS) may provide a unique approach to tackle heterogeneous IgM assemblies, although this technique can be quite laborious and technically challenging. Here, we describe the use of online size exclusion chromatography (SEC) to automate buffer exchange and sample introduction, and demonstrate its adaptability with Orbitrap-based CDMS. We discuss optimal experimental parameters for online SEC-CDMS experiments, including ion activation, choice of column, and resolution. Using this approach, CDMS histograms containing hundreds of individual ion signals can be obtained in as little as 5 min from single injections of <1 μg of sample. To demonstrate the unique utility of online SEC-CDMS, we performed real-time kinetic monitoring of pentameric IgM digestion by the protease IgMBRAZOR, which cleaves specifically in the hinge region of IgM. Several digestion intermediates corresponding to processive losses of F(ab')2 subunits could be mass-resolved and identified by SEC-CDMS. Interestingly, we find that for the J-chain linked IgM pentamer, cleavage of one of the F(ab')2 subunits is much slower than the other four F(ab')2 subunits, which we attribute to the symmetry-breaking interactions of the J-chain within the pentameric IgM structure. The online SEC-CDMS methodologies described here open new avenues into the higher throughput automated analysis of heterogeneous, high-mass protein assemblies by CDMS.

Structural Plasticity of NFU1 Upon Interaction with Binding Partners: Insights into the Mitochondrial [4Fe-4S] Cluster Pathway

In humans, the biosynthesis and trafficking of mitochondrial [4Fe-4S]2+ clusters is a highly coordinated process that requires a complex protein machinery. In a mitochondrial pathway among various proposed to biosynthesize nascent [4Fe-4S]2+ clusters, two [2Fe-2S]2+ clusters are converted into a [4Fe-4S]2+ cluster on a ISCA1-ISCA2 complex. Along this pathway, this cluster is then mobilized from this complex to mitochondrial apo recipient proteins with the assistance of accessory proteins. NFU1 is the accessory protein that first receives the [4Fe-4S]2+ cluster from ISCA1-ISCA2 complex. A structural view of the protein–protein recognition events occurring along the [4Fe-4S]2+ cluster trafficking as well as how the globular N-terminal and C-terminal domains of NFU1 act in such process is, however, still elusive. Here, we applied small-angle X-ray scattering coupled with on-line size-exclusion chromatography and paramagnetic NMR to disclose structural snapshots of ISCA1-, ISCA2- and NFU1-containing apo complexes as well as the coordination of [4Fe-4S]2+ cluster bound to the ISCA1-NFU1 complex, which is the terminal stable species of the [4Fe-4S]2+ cluster transfer pathway involving ISCA1-, ISCA2- and NFU1 proteins. The structural modelling of ISCA1-ISCA2, ISCA1-ISCA2-NFU1 and ISCA1-NFU1 apo complexes, here reported, reveals that the structural plasticity of NFU1 domains is crucial to drive protein partner recognition and modulate [4Fe-4S]2+ cluster transfer from the cluster-assembly site in the ISCA1-ISCA2 complex to a cluster-binding site in the ISCA1-NFU1 complex. These structures allowed us to provide a first rational for the molecular function of the N-domain of NFU1, which can act as a modulator in the [4Fe-4S]2+ cluster transfer.

Microflow size exclusion chromatography to preserve micromolar affinity complexes and achieve subunit separations for native state mass spectrometry

For high throughput native mass spectrometry (MS) protein characterization, it is advantageous to desalt and separate proteins by size exclusion chromatography (SEC). Sensitivity, resolution, and speed in these methods remain limited by standard SEC columns. Moreover, the efficient packing of small bore columns is notoriously difficult. SEC sensitivity is inherently limited because solutes are not focused into concentrated bands and low affinity native complexes may dissociate on column. Recent work evaluated the suitability of crosslinked gel media in small bore formats for online desalting. Here, small bore format online SEC for native MS studies is again investigated but with alternative materials. We systematically studied the utility of diol and hydroxy terminated polyethylene oxide (PEO) bonded 1.7 µm organosilica particles as packed into 1 mm ID stainless steel (SS) hardware and hardware treated with hydrophilic hybrid surface technology (h-HST). For the equivalent diol-bonded particle and hardware, UV limits of detection (LODs) were reduced 32 to 89% with a microflow separation (15 µL/min) on a 1 × 50 mm column as compared to a 4.6 × 150 mm high-flow separation (300 µL/min) at the same linear velocity. Run times were also shortened by 45%. A switch from SS to h-HST hardware led to a significant reduction in secondary interactions and a corresponding improvement in detection limits for trastuzumab, myoglobin, IgG and albumin for both UV and MS. Coupling of the small bore columns to multichannel microflow emitters resulted in 10 to 100-fold gains in MS sensitivity, depending on the analyte. MS LOD values were significantly reduced into the low attomole ranges. Columns were then evaluated for their effects on the preservation of complexes, including concanavalin A, in its apo and ligand-bound states, and three therapeutically relevant noncovalent systems previously undetected on large column formats. The results suggest that the detection of large complexes by SEC is not just a function of sensitivity but is directly affected by chemical secondary interactions. The ability to detect 0.1 to 1 MDa complexes, with between 1 and 40 micromolar dissociation constants, represents a critical advancement for high-throughput native MS workflows as applied to the analysis of therapeutics.

Performance of the new biological small- and wide-angle X-ray scattering beamline 13A at the Taiwan Photon Source.

Recent developments in the instrumentation and data analysis of synchrotron small-angle X-ray scattering (SAXS) on biomolecules in solution have made biological SAXS (BioSAXS) a mature and popular tool in structural biology. This article reports on an advanced endstation developed at beamline 13A of the 3.0 GeV Taiwan Photon Source for biological small- and wide-angle X-ray scattering (SAXS-WAXS or SWAXS). The endstation features an in-vacuum SWAXS detection system comprising two mobile area detectors (Eiger X 9M/1M) and an online size-exclusion chromatography system incorporating several optical probes including a UV-Vis absorption spectrometer and refractometer. The instrumentation and automation allow simultaneous SAXS-WAXS data collection and data reduction for high-throughput biomolecular conformation and composition determinations. The performance of the endstation is illustrated with the SWAXS data collected for several model proteins in solution, covering a scattering vector magnitude q across three orders of magnitude. The crystal-model fittings to the data in the q range ∼0.005-2.0 Å-1 indicate high similarity of the solution structures of the proteins to their crystalline forms, except for some subtle hydration-dependent local details. These results open up new horizons of SWAXS in studying correlated local and global structures of biomolecules in solution.

Global fitting of multiple data frames from SEC-SAXS to investigate the structure of next-generation nanodiscs.

The combination of online size-exclusion chromatography and small-angle X-ray scattering (SEC-SAXS) is rapidly becoming a key technique for structural investigations of elaborate biophysical samples in solution. Here, a novel model-refinement strategy centred around the technique is outlined and its utility is demonstrated by analysing data series from several SEC-SAXS experiments on phospholipid bilayer nanodiscs. Using this method, a single model was globally refined against many frames from the same data series, thereby capturing the frame-to-frame tendencies of the irradiated sample. These are compared with models refined in the traditional manner, in which refinement is based on the average profile of a set of consecutive frames from the same data series without an in-depth comparison of individual frames. This is considered to be an attractive model-refinement scheme as it considerably lowers the total number of parameters refined from the data series, produces tendencies that are automatically consistent between frames, and utilizes a considerably larger portion of the recorded data than is often performed in such experiments. Additionally, a method is outlined for correcting a measured UV absorption signal by accounting for potential peak broadening by the experimental setup.

SEC-SAXS: Experimental set-up and software developments build up a powerful tool.

A monodispersed and ideal solution is a key requirement of BioSAXS to allow one to extract structural information from the recorded pattern. On-line size exclusion chromatography (SEC) marked a major breakthrough, separating particles present in solution according to their size. Scattering curves with identical shape under an elution peak can be averaged and further processed free from contamination. However, this is not always straightforward, separation is often incomplete. Software have been developed to deconvolve the contributions from the different species (molecules or oligomeric forms) within the sample. In this chapter, we present the general workflow of a SEC-SAXS experiment. We present recent instrumental and data analysis developments that have improved the quality of recorded data, extended the potential of SEC-SAXS and turned it into a mainstream approach. We report a comparative analysis of two macromolecular systems using various deconvolution approaches that have been developed over the last years. Parallel analysis appears to be the best cross-validation method to assess the reliability of the reconstructed isolated species patterns that can safely be used as a support for meaningful molecular modeling.

Pushing the limits of native MS: Online SEC-native MS for structural biology applications

Native mass spectrometry (nMS) is now widely applied to investigate non-covalently assembled biomolecule complexes. nMS requires the use of near-neutral pH and volatile buffers to preserve the native state of proteins. However, buffer exchange into nMS-compatible solvent is usually performed manually, which results in a time-consuming and tedious process, thus appearing as a major drawback for nMS analysis. Conversely, online coupling of size exclusion chromatography (SEC) to nMS affords a fast-automated and improved desalting, but also provides an additional dimension of separation for complex protein mixtures. We illustrate here the benefits of SEC-nMS compared to manual offline desalting for the characterization of a wide variety of biological systems, ranging from multiprotein assemblies, protein–ligand and protein–nucleic acid complexes, to proteins in a detergent environment. We then highlight the potential of the coupling to further integrate ion mobility while preserving the native conformations of proteins, allowing for rapid collision cross section measurement and even collision-induced unfolding experiments. Finally, we show that online SEC coupling can also serve as the basis for multidimensional non-denaturing liquid chromatography (LC) workflows, with the SEC acting as a fast desalting device, helping to achieve first dimension LC separation in optimal chromatographic conditions while being compatible with further nMS analysis.

Toward Automation of Collision-Induced Unfolding Experiments through Online Size Exclusion Chromatography Coupled to Native Mass Spectrometry

Ion mobility (IM)-based collision-induced unfolding (CIU) has gained increasing attention to probe gas-phase unfolding of proteins and their noncovalent complexes, notably for biotherapeutics. CIU detects subtle conformational changes of proteins and emerges as an attractive alternative to circumvent poor IM resolution. However, CIU still lacks in automation for buffer exchange and data acquisition, precluding its wide adoption. We present here an automated workflow for CIU experiments, from sample preparation to data interpretation using online size exclusion chromatography coupled to native IM mass spectrometry (SEC-CIU). Online automated SEC-CIU experiments offer several benefits over nanoESI-CIU, among which are (i) improved and fast desalting compared to manual buffer exchange used for classical CIU experiments; (ii) drastic reduction of the overall data collection time process; and (iii) maintaining the number of unfolding transitions. We then evaluate the potential of SEC-CIU to distinguish monoclonal antibody (mAb) subclasses, illustrating the efficiency of our method for rapid mAb subclass identification at both intact and middle levels. Finally, we demonstrate that CIU data acquisition time can be further reduced either by setting up a scheduled CIU method relying on diagnostic trap collision voltages or by implementing mAb-multiplexed SEC-CIU analyses to maximize information content in a single experiment. Altogether, our results confirm the suitability of SEC-CIU to automate CIU experiments, particularly for the fast characterization of next-generation mAb-based products.

Introducing SEC-SANS for studies of complex self-organized biological systems.

Small-angle neutron scattering (SANS) is maturing as a method for studying complex biological structures. Owing to the intrinsic ability of the technique to discern between 1H- and 2H-labelled particles, it is especially useful for contrast-variation studies of biological systems containing multiple components. SANS is complementary to small-angle X-ray scattering (SAXS), in which similar contrast variation is not easily performed but in which data with superior counting statistics are more easily obtained. Obtaining small-angle scattering (SAS) data on monodisperse complex biological structures is often challenging owing to sample degradation and/or aggregation. This problem is enhanced in the D2O-based buffers that are typically used in SANS. In SAXS, such problems are solved using an online size-exclusion chromatography (SEC) setup. In the present work, the feasibility of SEC-SANS was investigated using a series of complex and difficult samples of membrane proteins embedded in nanodisc particles that consist of both phospholipid and protein components. It is demonstrated that SEC-SANS provides data of sufficient signal-to-noise ratio for these systems, while at the same time circumventing aggregation. By combining SEC-SANS and SEC-SAXS data, an optimized basis for refining structural models of the investigated structures is obtained.

SAXS and stability studies of iron-induced oligomers of bacterial frataxin CyaY.

Frataxin is a highly conserved protein found in both prokaryotes and eukaryotes. It is involved in several central functions in cells, which include iron delivery to biochemical processes, such as heme synthesis, assembly of iron-sulfur clusters (ISC), storage of surplus iron in conditions of iron overload, and repair of ISC in aconitase. Frataxin from different organisms has been shown to undergo iron-dependent oligomerization. At least two different classes of oligomers, with different modes of oligomer packing and stabilization, have been identified. Here, we continue our efforts to explore the factors that control the oligomerization of frataxin from different organisms, and focus on E. coli frataxin CyaY. Using small-angle X-ray scattering (SAXS), we show that higher iron-to-protein ratios lead to larger oligomeric species, and that oligomerization proceeds in a linear fashion as a results of iron oxidation. Native mass spectrometry and online size-exclusion chromatography combined with SAXS show that a dimer is the most common form of CyaY in the presence of iron at atmospheric conditions. Modeling of the dimer using the SAXS data confirms the earlier proposed head-to-tail packing arrangement of monomers. This packing mode brings several conserved acidic residues into close proximity to each other, creating an environment for metal ion binding and possibly even mineralization. Together with negative-stain electron microscopy, the experiments also show that trimers, tetramers, pentamers, and presumably higher-order oligomers may exist in solution. Nano-differential scanning fluorimetry shows that the oligomers have limited stability and may easily dissociate at elevated temperatures. The factors affecting the possible oligomerization mode are discussed

Probing the Acid-Induced Packing Structure Changes of the Molten Globule Domains of a Protein near Equilibrium Unfolding.

Using simultaneously scanning small-angle X-ray scattering (SAXS) and UV-vis absorption with integrated online size exclusion chromatography, supplemental with molecular dynamics simulations, we unveil the long-postulated global structure evolution of a model multidomain protein bovine serum albumin (BSA) during acid-induced unfolding. Our results differentiate three global packing structures of the three molten globule domains of BSA, forming three intermediates I1, I2, and E along the unfolding pathway. The I1-I2 transition, overlooked in all previous studies, involves mainly coordinated reorientations across interconnected molten globule subdomains, and the transition activates a critical pivot domain opening of the protein for entering into the E form, with an unexpectedly large unfolding free energy change of -9.5 kcal mol-1, extracted based on the observed packing structural changes. The revealed local packing flexibility and rigidity of the molten globule domains in the E form elucidate how collective motions of the molten globule domains profoundly influence the folding-unfolding pathway of a multidomain protein.

A Successful Combination: Coupling SE-HPLC with SAXS.

A monodispersed and ideal solution is a central (unique?) requirement of SAXS to allow one to extract structural information from the recorded pattern. On-line Size Exclusion Chromatography (SEC) marked a major breakthrough, separating particles present in solution according to their size. Identical frames under an elution peak can be averaged and further processed free from contamination. However, this is not always straightforward, separation is often incomplete and software have been developed to deconvolve the contributions from the different species (molecules or oligomeric forms) within the sample. In this chapter, we present the general workflow of a SEC-SAXS experiment. We present recent instrumental and data analysis improvements that have improved the quality of recorded data, extended its potential and turn it into a mainstream approach. We describe into some details two specific applications of SEC-SAXS that provide more than just separating associated forms from the particle of interest.

Analysis of pesticide residues in tobacco with online size exclusion chromatography with gas chromatography and tandem mass spectrometry.

An ultrasensitive method for the simultaneous analysis of pesticides residues in tobacco was developed with online size exclusion chromatography with gas chromatography and tandem mass spectrometry. Tobacco samples were extracted with the solvent mixture of cyclohexane and acetone (7:3, v/v) and centrifuged. Then, the supernatant liquors were injected directly into the online size exclusion chromatography with gas chromatography and tandem mass spectrometry without any other purification procedures after being filtered with a 0.22 μm organic phase filter. The matrix interferences were effectively removed and recoveries of most pesticides were in the range of 72-121%. Especially, for chlorothalonil, the analysis efficiency of this method was much more favorable than that of the general method, in which dispersive solid-phase extraction was used as an additional purified procedure. In addition, the limits of quantitation of this method were from 1 to 50 μg/kg. Therefore, a rapid, cost-effective, labor-saving method was proposed in the present work, which was suitable for the analysis of 41 pesticide residues in tobacco.

Investigations of multiple detection of polymers.

Theoretical and experimental aspects of multiple detection analysis of polymers are critically revised for size exclusion chromatography (SEC). In particular, different combinations of detectors, the importance of the injected mass and the influence of the tacticity of polymers are evaluated in respect to the accuracy of the weight fractions of the polymer components. It is also shown how overlapping detector responses of the chemical components will affect the accuracy of the weight fractions. The calculation of the weight fractions is performed with equations derived for n different chemical components and detectors by using the slopes and intercepts of the linear response equations. Several detector combinations of dual detection in SEC are evaluated with PS-b-PMMA diblock copolymers to determine the comonomer compositions and for the first time different combinations of triple detections are performed for the determination of the weight fractions of a blend of three homopolymers, respectively. The correct determination of the weight fractions of minor and main components of polymers is strongly affected by the chosen combination of detectors, the injected mass and the intercept of the response calibrations. It is shown how these conditions have to be changed to obtain correct quantifications of the weight fractions according to the experimental setups. The experimental results are approved with online SEC-(1)H/NMR where no response factors are required.

Polymer Characterization by Static Laser Light Scattering

Low angle laser light scattering (LALLS) and multi-angle laser light scattering (MALLS) methods have become valuable, if not indispensable, tools for the chemist and biochemist, since they can be used to determine the absolute molecular weight and size of molecules in solution. When linked to a gel permeation chromatography system, they become even more powerful tools, providing information on molecular weight averages and their distributions (polydispersity). LALLS has essenttially been superseded by the development of on-line MALLS and size-exclusion chromatography (SEC)/MALLS systems, which have facilitated the greater application of light scattering theory in structure elucidation. For example, the determination of root mean square radii, molecular conformation and structure, branching ratios etc., are now readily achievable. This paper reviews the “theoretical backbone” of light scattering methods and the technology available for use in this particular aspect of macromolecular characterisation. Particular emphasis is placed on the use of SEC/MALLS and SEC/LALLS for the molecular weight elucidation of polysaccharides (such as carrageenans, starch, hyaluronic acid and dextrans), proteins, and the examination of branching in large macromolecular structures

All-Atom Ensemble Modeling to Analyze Small-Angle X-Ray Scattering of Glycosylated Proteins

The flexible and heterogeneous nature of carbohydrate chains often renders glycoproteins refractory to traditional structure determination methods. Small-angle X-ray scattering (SAXS) can be a useful tool for obtaining structural information of these systems. All-atom modeling of glycoproteins with flexible glycan chains was applied to interpret the solution SAXS data for a set of glycoproteins. For simpler systems (single glycan, with a well-defined protein structure), all-atom modeling generates models in excellent agreement with the scattering pattern and reveals the approximate spatial occupancy of the glycan chain in solution. For more complex systems (several glycan chains, or unknown protein substructure), the approach can still provideinsightful models, though the orientations of glycans become poorly determined. Ab initio shape reconstructions appear to capture the global morphology of glycoproteins but in most cases offer littleinformation about glycan spatial occupancy. The all-atom modeling methodology is available as a web server at http://salilab.org/allosmod-foxs.

Molecular characterization and functional activity of an IL-15 antagonist MutIL-15/Fc human fusion protein.

Fc fusion proteins are a new emerging class of molecules for immune-targeted delivery of therapeutic proteins. Biophysical and bioanalytical characterization is critical for clinical development and delivery of therapeutic proteins. Here we report molecular and functional characterization of a recombinant human fusion protein Mutant IL-15/Fc. MutIL-15/Fc has a molecular weight of ∼95 kDa as determined by multiangle laser light scattering with online size exclusion chromatography and migrated at a faster rate (lower retention time) in gel filtration column. The kinetics of binding of MutIL-15/Fc to Fcγ receptor is best fitted in a bivalent modal with K(D1) 5 μM and K(D2) 9 μM determined by surface plasmon resonance (BIAcore). N-Glycoprofiling analysis revealed extensive glycosylation of MutIL-15/Fc. The Fc and IL-15 components in the MutIL-15/Fc are detected using the dual mode ELISA. The HT-2 cell proliferation inhibition assay is qualified as a quantitative in vitro marker functional assay. Molecular state changes associated with forced stress analyzed by SEC-MALS resulted in changes in bioactivity and Fc:Fcγ receptor interaction affinity. These data provide a systematic approach to molecular and functional characterization of the MutIL-15/Fc to establish product consistency and stability monitoring during storage and under drug delivery conditions.

Characterization of N-acetyltryptophan degradation products in concentrated human serum albumin solutions and development of an automated high performance liquid chromatography–mass spectrometry method for their quantitation

N-acetyltryptophan (NAT) has long been used as a stabilizer in some protein solutions, such as human serum albumin, to prevent oxidative protein degradation. However, the fate of NAT has not been discussed in literature. Two NAT degradation products have been observed in concentrated albumin solutions (20% and 25%) and identified as 1-acetyl-3a-hydroxy-1,2,3,3a,8,8a-hexahydropyrrolo[2,3-b]indole-2-carboxylic acid and 1-acetyl-3a,8a-dihydroxy-1,2,3,3a,8,8a-hexahydropyrrolo[2,3-b]indole-2-carboxylic acid. To monitor the levels of these two previously unidentified NAT degradation products in concentrated albumin solutions, a fully automated method, incorporating online size exclusion chromatography (SEC) trapping and reversed-phase high performance liquid chromatography–mass spectrometry (HPLC–MS) with multiple reaction monitoring (MRM) analysis, has been developed and validated for their quantitative analysis. The method does not require an internal standard. The only sample manipulation is to obtain an albumin concentration of 4% in all standards and test HPLC samples. A limit of quantitation (LOQ) as low as 20 ng/mL has been achieved for both compounds. This method can readily be adopted for the quantitative determination of other small molecules in concentrated protein solutions.