Matthew Szapacs

Albiglutide, a Long Lasting Glucagon-Like Peptide-1 Analog, Protects the Rat Heart against Ischemia/Reperfusion Injury: Evidence for Improving Cardiac Metabolic Efficiency

Background The cardioprotective effects of glucagon-like peptide-1 (GLP-1) and analogs have been previously reported. We tested the hypothesis that albiglutide, a novel long half-life analog of GLP-1, may protect the heart against I/R injury by increasing carbohydrate utilization and improving cardiac energetic efficiency. Methods/Principal Findings Sprague-Dawley rats were treated with albiglutide and subjected to 30 min myocardial ischemia followed by 24 h reperfusion. Left ventricle infarct size, hemodynamics, function and energetics were determined. In addition, cardiac glucose disposal, carbohydrate metabolism and metabolic gene expression were assessed. Albiglutide significantly reduced infarct size and concomitantly improved post-ischemic hemodynamics, cardiac function and energetic parameters. Albiglutide markedly increased both in vivo and ex vivo cardiac glucose uptake while reducing lactate efflux. Analysis of metabolic substrate utilization directly in the heart showed that albiglutide increased the relative carbohydrate versus fat oxidation which in part was due to an increase in both glucose and lactate oxidation. Metabolic gene expression analysis indicated upregulation of key glucose metabolism genes in the non-ischemic myocardium by albiglutide. Conclusion/Significance Albiglutide reduced myocardial infarct size and improved cardiac function and energetics following myocardial I/R injury. The observed benefits were associated with enhanced myocardial glucose uptake and a shift toward a more energetically favorable substrate metabolism by increasing both glucose and lactate oxidation. These findings suggest that albiglutide may have direct therapeutic potential for improving cardiac energetics and function.

Development of a highly sensitive and selective UPLC/MS/MS method for the simultaneous determination of testosterone and 5α-dihydrotestosterone in human serum to support testosterone replacement therapy for hypogonadism

A highly sensitive and selective quantitative method to accurately determine testosterone (Te) and 5alpha-dihydrotestosterone (DHT) in human serum is crucial to the success of Te replacement therapy for hypogonadism. To this end we have developed and validated a semi-automated and relatively high-throughput method in a 96-well plate format using ultra-performance liquid chromatography coupled with tandem mass spectrometry (UPLC/MS/MS) for the simultaneous determination of Te and DHT in human serum. Te and DHT along with the internal standards [(2)H(3)]-Te and [(2)H(3)]-DHT were extracted from 300 microL of human serum by liquid-liquid extraction using methyl tertiary-butyl ether (MTBE), followed by derivatization with 2,3-pyridinedicarboxylic anhydride and solid-phase extraction for sample clean up. A novel chemical derivatization approach using 2,3-pyridinedicarboxylic anhydride was employed to achieve the MS sensitivity and selectivity required for DHT. Baseline separation of Te and DHT derivatives from endogenous steroid derivatives was achieved using UPLC technology on a C18 stationary-phase column with 1.7 microm particle size. The validity of using double charcoal-stripped female human serum as surrogate matrix for preparation of calibration standards was demonstrated through standard addition experiments. The method was validated over the concentration ranges of 0.2-40 ng/mL for Te and 0.01-2 ng/mL for DHT. The validation and study sample analysis results show that the method is rugged, precise, accurate, and well suited to support pharmacokinetic studies where approximately 300 samples can be extracted and analyzed in 1 day.

Comparison of the quantification of a therapeutic protein using nominal and accurate mass MS/MS

BACKGROUND The quantification of proteins and peptides in in vivo samples is a critical part of supporting the drug development process for biotherapeutics. LC-MS/MS using tandem quadrupole mass spectrometers is well established as the technology of choice for the quantification of small-molecule drugs and their metabolites in biological fluid. The application of accurate mass MS for quantification in a DMPK environment has attracted considerable interest in recent years. MATERIALS & METHODS In this article we describe and compare the application of LC-high-resolution MS and LC-selected reaction monitoring (SRM) for the quantification of a therapeutics proteins. RESULTS The accurate mass instrumentation showed acceptable linearity and sensitivity to quantify the protein therapeutic to the level of 10 ng/ml. The accurate mass instrument was operated in accurate mass SRM using high resolution (SRM-HR), the assay was demonstrated to be linear over three orders of magnitude. By narrowing the mass window from 100 mDa to 40 mDa and then to 20 mDa the assay specificity was significantly improved, hence increasing the S/N and improving the assay sensitivity. CONCLUSION The high-resolution instrument was demonstrated to be reproducible over the course of the assay. The accurate mass method sensitivity was determined to be within one order of magnitude of that obtained with a tandem quadrupole MS/MS assay.

Application of DBS for the quantitative assessment of a protein biologic using on-card digestion LC–MS/MS or immunoassay

BACKGROUND Dried blood spot (DBS) sampling has recently gained popularity in the bioanalysis community for quantitation of small molecules. Since the pharmaceutical industry continues to increase investment in biopharmaceuticals, DBS technologies were investigated to determine if immunoassay and/or LC-MS/MS techniques would be amenable for quantitation of a large protein therapeutic (>70 kDa). RESULTS Methods were successfully qualified for the protein therapeutic utilizing DBS technology. DBS methods in rat blood were qualified for this therapeutic protein using either immunoassay or enzymatic digestion directly off the DBS card followed by UHPLC-MS/MS separation and detection. Both qualifications were carried out in accordance with current acceptable practices defined by international acceptance criteria. Card selection was critical to both DBS methods. CONCLUSION The advantages gained by DBS technology can successfully be applied to the quantitative assessment of biologics. This UHPLC-MS/MS method illustrates that digestion of large molecules directly off blood spot cards allows quantitation of these molecules. In addition, DBS technologies are amenable to immunoassay analysis. The immunoassay was 20-fold more sensitive than the UHPLC-MS/MS method, however the UHPLC-MS/MS assay had a much broader dynamic range.

Absolute quantification of a therapeutic domain antibody using ultra-performance liquid chromatography–mass spectrometry and immunoassay

BACKGROUND Domain antibodies (dAbs; ∼10-15 kDa) are made up of the variable heavy chain or the variable light chain of the antibody structure, and retain binding capability. dAbs have proved difficult to detect in plasma using immunoassay without specific antibodies raised against the dAb. RESULTS A sensitive and selective UPLC-MS/MS method for the absolute quantification of a dAb in monkey plasma was developed (range: 1 to 500 ng/ml) without the need for a specific capture antibody. This method was used to analyze pharmacokinetic studies early on in drug development. Furthermore, an immunoassay was developed and the pharmacokinetic samples were reanalyzed. CONCLUSION The two assays show good correlation (r(2) = 0.92), giving confidence in using either method for quantification of the dAb.

The Gyrolab™ immunoassay system: a platform for automated bioanalysis and rapid sample turnaround

BACKGROUND The Gyrolab™ workstation benefits from fully automated transfer of reagents and samples originating from a storage microplate onto a compact disc containing solid-phase microstructures composed of a 15 nl streptavidin-derivitized bead bed. RESULTS This paper describes the development, full validation and use of the method in a regulated environment to measure a humanized bispecific monoclonal antibody-domain antibody (GSK-A) molecule using the Gyrolab immunoassay system in cynomolgus nonhuman primate plasma ranging from 5 to 250 µg/ml. The method was subsequently used in support of the TK portion of a regulated preclinical study in monkeys. CONCLUSION The Gyrolab immunoassay system proved to be a viable alternative to traditional immunoassays and was used to support a regulated preclinical TK study. The speed of analysis that the Gyrolab provides was beneficial in meeting timelines to complete this project as multiple assays and repeat sample analysis could be completed in the same day.

Application of high-resolution MS for development of peptide and large-molecule drug candidates

BACKGROUND For quantitative bioanalysis utilizing MS, the instrument of choice is typically a triple quadruple mass spectrometer. However, advances in high-resolution MS have allowed sensitivity and dynamic ranges to approach that of triple quadrupole instruments. RESULTS A matrix-free protein digest, a digested therapeutic protein and the intact peptide therapeutic liraglutide were each analyzed on high-resolution and triple quadrupole mass spectrometers with data compared. Samples from a mouse PK study with liraglutide were analyzed using the two different instruments, and equivalent PK exposure data were demonstrated. CONCLUSION High-resolution and triple quadrupole mass spectrometers can generate data resulting in identical PK parameters from an in-life sample set, thus giving confidence in either technique in support of biotherapeutic PK exposure studies.

Integrating internal and external bioanalytical support to deliver a diversified pharmaceutical portfolio.

The portfolios of pharmaceutical companies have diversified substantially over recent years in recognition that monotherapies and/or small molecules are less suitable for modulating many complex disease etiologies. Furthermore, there has been increased pressure on drug-development budgets over this same period. This has placed new challenges in the path of bioanalytical scientists, both within the industry and with contract research organizations (CROs). Large pharmaceutical, biotechnology and small-medium healthcare enterprises have had to make important decisions on what internal capabilities they wish to retain and where CROs offers a significant strategic benefit to their business model. Our journey has involved asking where we believe an internal bioanalytical facility offers the greatest benefit to progressing drug candidates through the drug-development cycle and where externalization can help free up internal resources, adding flexibility to our organization in order to deal with the inevitable peaks and troughs in workload.

Camphanic acid chloride: a powerful derivatization reagent for stereoisomeric separation and its DMPK applications.

BACKGROUND Camphanic acid chloride has proven to be an efficient chiral derivatization reagent for determination of stereoisomers. RESULTS The utility of chemical derivatization of various stereoisomers containing hydroxy functional groups with camphanic acid chloride in the presence or absence of a base is highlighted. This procedure is shown to be relatively simple, fast and a cost-effective method of separating racemic drugs and stereoisomeric metabolites in biological matrices. Camphanic derivatives contain two additional chirogenic centers, which are found to enhance stereoisomeric separation on both traditional and chiral stationary phases. CONCLUSION Four methodologies described herein for separation of multiple stereoisomers in biological samples confirm camphanic acid chloride to be a powerful chiral reagent for stereoisomeric resolution for drug metabolism and PK applications.

Quantitative immunocapture MS: current status and challenges in drug discovery

Immunocapture is poised to play an increasingly vital role in therapeutic protein quantitation. In recent years, MS has emerged as an alternative to immunoassay for quantitative work. MS analysis can be achieved with or without an immunocapture step; however, the inherent selectivity of the technique typically affords LLOQ coupling immunocapture-MS methods [1]. With an ever-growing need to develop high-sensitivity assays while retaining selectivity, immunocapture followed by digestion before analysis by MS is a viable approach for protein quantitation [2,3]. Here, a brief summary on the status and challenges of protein quantitation by immunocapture followed by MS are discussed.