The Use of Dried Blood Spots for the Quantification of Antihypertensive Drugs

Hypertension or high blood pressure is a harbinger of cardiovascular diseases. There are several classes of drugs used to treat hypertension. This review discusses the use of dried blood spots (DBSs) for the quantification by mass spectrometry (MS), tandem mass spectrometry (MS/MS), or, in some cases, by fluorescence detection methods the following antihypertensive medications: angiotensin-converting enzyme inhibitors (ramipril, ramiprilat, captopril, and lisinopril); angiotensin II receptor antagonists (valsartan, irbesartan, losartan, and losartan carboxylic acid); calcium channel blockers (verapamil, amlodipine, nifedipine, pregabalin, and diltiazem); α blockers (guanfacine, doxazosin, and prazosin); β blockers (propranolol, bisoprolol, atenolol, and metoprolol); endothelin receptor antagonists (bosentan and ambrisentan); and statins (simvastatin, atorvastatin, and rosuvastatin).

The use of mass spectrometry to analyze dried blood spots

Dried blood spots (DBS) typically consist in the deposition of small volumes of capillary blood onto dedicated paper cards. Comparatively to whole blood or plasma samples, their benefits rely in the fact that sample collection is easier and that logistic aspects related to sample storage and shipment can be relatively limited, respectively, without the need of a refrigerator or dry ice. Originally, this approach has been developed in the sixties to support the analysis of phenylalanine for the detection of phenylketonuria in newborns using bacterial inhibition test. In the nineties tandem mass spectrometry was established as the detection technique for phenylalanine and tyrosine. DBS became rapidly recognized for their clinical value: they were widely implemented in pediatric settings with mass spectrometric detection, and were closely associated to the debut of newborn screening (NBS) programs, as a part of public health policies. Since then, sample collection on paper cards has been explored with various analytical techniques in other areas more or less successfully regarding large-scale applications. Moreover, in the last 5 years a regain of interest for DBS was observed and originated from the bioanalytical community to support drug development (e.g., PK studies) or therapeutic drug monitoring mainly. Those recent applications were essentially driven by improved sensitivity of triple quadrupole mass spectrometers. This review presents an overall view of all instrumental and methodological developments for DBS analysis with mass spectrometric detection, with and without separation techniques. A general introduction to DBS will describe their advantages and historical aspects of their emergence. A second section will focus on blood collection, with a strong emphasis on specific parameters that can impact quantitative analysis, including chromatographic effects, hematocrit effects, blood effects, and analyte stability. A third part of the review is dedicated to sample preparation and will consider off-line and on-line extractions; in particular, instrumental designs that have been developed so far for DBS extraction will be detailed. Flow injection analysis and applications will be discussed in section IV. The application of surface analysis mass spectrometry (DESI, paper spray, DART, APTDCI, MALDI, LDTD-APCI, and ICP) to DBS is described in section V, while applications based on separation techniques (e.g., liquid or gas chromatography) are presented in section VI. To conclude this review, the current status of DBS analysis is summarized, and future perspectives are provided.

Dried blood spot analysis without dilution: Application to the LC-MS/MS determination of BMS-986001 in rat dried blood spot

Sample dilution is one major challenge in dried blood spot (DBS) bioanalysis. To resolve this issue, we applied a no-dilution strategy for DBS analysis by using a calibration curve with very wide linear range. We developed an LC-MS/MS DBS assay with a linear range of 5 orders of magnitude (50-5000,000ng/mL) for BMS-986001, an HIV drug under development, by simultaneously monitoring two selective reaction monitoring transitions of different intensity. The assay was validated and successfully applied to the analysis of DBS samples collected in a toxicology study in rats dosed with BMS-986001. All samples were analyzed without any dilution. We also compared the concentration data generated from the DBS method and a validated plasma assay for the same study. The two sets of data agreed well with each other, demonstrating the validity of this strategy for DBS analysis. This approach provides an effective and convenient way to eliminate complicated dilution for DBS and other sample collection techniques.

Automated direct extraction and analysis of dried blood spots employing on-line SPE high-resolution accurate mass bioanalysis

Background: Online automated extraction of dried blood spots (DBS) via direct extraction to a solid-phase extraction (SPE) cartridge and bioanalysis by high-resolution accurate mass spectrometry was examined. The methodology was validated and used to investigate the effect of hematocrit on assay bias using partial and whole spot extractions from accurately dispensed blood samples. Results: The completed analysis of a DBS sample was accomplished within 2 to 3 min using the online DBS-SPE platform. Hematocrit related bias was observed (>15%) for the partial DBS extractions, but not when the whole DBS was eluted. Conclusion: Results demonstrate successful implementation of automated online DBS-SPE high-resolution accurate mass spectrometry analysis and the remediation of hematocrit bias using a capillary micro dispenser for accurate spotting of blood samples.

Evaluation of matrix microsampling methods for therapeutic drug candidate quantification in discovery-stage rodent pharmacokinetic studies

Background: AMG 517 or 1-aminobenzotriazole were quantified by LC–MS/MS from low blood/plasma volumes for rat pharmacokinetic (PK) characterization in order to qualify manual/automated dried blood spot (DBS) sampling and plasma separation capillary sampling. In addition, mouse serial automated blood sampling was compared with standard composite sampling. Materials & methods: AMG 517 or 1-aminobenzotriazole was administered to rats or mice and multiple microsampling techniques were used to obtain blood or plasma. Results: PK parameters derived from DBS and whole blood-obtained drug concentrations were within 7% for manual DBS and 20% for automated DBS. Plasma PK parameters derived from capillary or standard plasma-obtained drug concentrations differed by 6%. Plasma PK parameters obtained from serial automated blood sampling or manual composite sampling were within 20%. Conclusion: Collectively, these results suggest that the microsampling applications that were investigated are attractive approaches for quantifying drug candidates in low matrix volumes that can be successfully employed within discovery-stage rodent PK studies.

Liquid chromatography-tandem mass spectrometry method for simultaneous quantification of bisoprolol, ramiprilat, propranolol and midazolam in rat dried blood spots

Dried blood spot (DBS) sampling represents a suitable method for pharmacokinetic studies in rats, particularly if serial sampling is needed. To study the pharmacokinetics of drugs in a rat heart failure (HF) model, we developed and validated a method for the simultaneous determination of bisoprolol, ramiprilat, propranolol and midazolam in DBS samples. Bisoprolol and ramipril are widely used in the treatment of HF, and midazolam and propranolol are markers of hepatic metabolism, which can be altered in HF. A 20μL sample of rat blood was pipetted onto Whatman 903 Protein Saver Card and allowed to dry. The whole spot was excised and 300μL of solvent (methanol with 10% ultrapure water and 0.1% formic acid) was added. After mixing and incubating the sample in an ultrasonic bath, a mixture of isotopically labeled internal standards was added. After centrifugation, the extracts were cleaned on an Ostro™ plate and analyzed using liquid chromatography-tandem mass spectroscopy. The method was successfully validated. No significant interference was observed in the retention times of analytes or internal standards. The intraday and interday accuracy and precision were within a ±15% interval. The method was linear in the range 5-250μg/L and the lower limit of quantification was 5μg/L for all four analytes. The absolute matrix effect ranged from 98.7% for midazolam to 121% for ramiprilat. The recovery was lowest for ramiprilat and highest for propranolol. Samples were stable at all tested temperatures. The method has been used successfully in a real-time pharmacokinetic study in rats.

Recent advances in the bioanalytical applications of dried matrix spotting for the analysis of drugs and their metabolites

DBS techniques for the bioanalysis of drugs and metabolites from whole blood have been demonstrated to be a useful tool in drug development. The term dried matrix spot (DMS) has been used to indicate that the DBS technique has been applied to nonblood matrices. DMS methods often employ a color-indicating process that enhances the ability to analyze these mostly transparent fluids when spotted onto collection paper. The color-indicating dye allows the analyst to visually confirm the location of the dried sample spot. Other benefits of using a color-indicating dye include improved method accuracy and precision, because the process of adding the dye allows for the concurrent addition of the IS prior to sample addition and extraction. To date, matrices that have been analyzed using DMS include cerebrospinal fluid, synovial fluid, saliva, tears, urine and plasma.

Evaluation of dried blood spots for the quantification of therapeutic monoclonal antibodies and detection of anti-drug antibodies

BACKGROUND

Recently, the potential of dried blood spots (DBS) for small-molecule bioanalysis by LC-MS has been explored. The goal of this investigation was to evaluate the use of DBS for the quantification of biologics, where bioanalysis is with immunoassay.

RESULTS

Therapeutic monoclonal antibodies were successfully eluted from DBS and detected by immunoassays, and the procedure could be validated in alignment with current guidelines. Accuracy, precision, selectivity and dilution linearity were all within the acceptance criteria currently used for the validation of binding assays with serum samples. Serum and DBS samples obtained in parallel during a PK research study in rats were analyzed for drug and anti-drug antibodies using AlphaLISA(®) technology. Drug concentrations in both sample types showed a strong correlation, and there was very good alignment in detection of immunogenicity positive animals.

CONCLUSION

Using two examples, we have demonstrated that therapeutic monoclonal antibodies can be accurately quantified in DBS, and since anti-drug antibodies could also be successfully detected, there is scope for application of DBS to preclinical and clinical bioanalysis of monoclonal antibody drugs and anti-drug antibodies.

Automated dried blood spots standard and QC sample preparation using a robotic liquid handler

Background: A dried blood spot (DBS) bioanalysis assay involves many steps, such as the preparation of standard (STD) and QC samples in blood, the spotting onto DBS cards, and the cutting-out of the spots. These steps are labor intensive and time consuming if done manually, which, therefore, makes automation very desirable in DBS bioanalysis. Results: A robotic liquid handler was successfully applied to the preparation of STD and QC samples in blood and to spot the blood samples onto DBS cards using buspirone as the model compound. This automated preparation was demonstrated to be accurate and consistent. However the accuracy and precision of automated preparation were similar to those from manual preparation. The effect of spotting volume on accuracy was evaluated and a trend of increasing concentrations of buspirone with increasing spotting volumes was observed. Conclusion: The automated STD and QC sample preparation process significantly improved the efficiency, robustness and safety of DBS bioanalysis.

Design and operation of an automated high-throughput monoclonal antibody facility

Monoclonal antibodies now form a key part of the biochemist's toolbox, and are important reagents for therapeutic applications. This has resulted in a need for high-throughput production to satisfy the demand from the global community. Manual production involves overwhelming amounts of tissue culture and associated liquid handling steps to achieve high-throughput operation. By contrast, automated systems can readily cope with the numbers required. In this review, we address the development of automated systems, and discuss the pros and cons of their operation.

Perforated dried blood spot accurate microsampling: the concept and its applications in toxicokinetic sample collection

Dried blood spot (DBS) sampling has gained considerable interest as a microsampling technique to support drug discovery and development owing to its enormous ethical and practical benefits. Quantitative determinations of drugs and/or their metabolites collected in DBS matrix in its current format, however, have encountered technical challenges and regulatory uncertainty. The challenges of DBS bioanalysis are largely ascribed to the way how samples are collected and analyzed. Currently, an uncontrolled amount of a blood sample, e.g. 20 µl, is collected per time point per sample and spotted onto cellulose paper. Quantitation is based on removal of a fixed area of the DBS sample, resulting in sample waste, a need for mechanical punching and concomitant potential punching carryover, uncertainty in recovery assessment and the adverse impact of hematocrit on accurate quantitation. Here, we describe the concept and applications of a novel concept, namely perforated dried blood spot (PDBS), for accurate microsampling that addresses previous challenges. Advantages of PDBS are enumerated and compared with conventional DBS in the context of microsampling and liquid chromatography tandem mass spectrometry bioanalysis. Two approaches for accurate microsampling of a small volume of blood (5 µl) are proposed and demonstrated, i.e. Microsafe® pipettes and the Drummond incremental pipette. Two online sample enrichment techniques to enhance liquid chromatography tandem mass spectrometry sensitivity for microsampling bioanalysis are discussed. The PDBS concept was successfully applied for accurate sample collection (5 µl) in a toxicokinetic study in rats given a single oral gavage dose of acetaminophen. Perspectives on bioanalytical method validation for regulated DBS/PDBS microsampling are also presented.

Application of automated dried blood spot sampling and LC–MS/MS for pharmacokinetic studies of AMG 517 in rats

Background: The use of dried blood spot (DBS) sampling technique is of particular interest for drug discovery pharmacokinetic studies due to the small blood volume requirement. In addition, automated blood sampling is an attractive approach for rat pharmacokinetic studies as animal handling work is minimized. The goal of this study was to use an automated DBS sampler for automated blood collection and spotting onto DBS paper for pharmacokinetic studies in rats. AMG 517, a potent and selective vanilloid receptor antagonist, was dosed to rats (n = 3) intravenously and blood samples were collected at nine time points over a 24 h period using the automated DBS sampler. After drying, storage and shipment, the DBS samples were extracted and analyzed by LC–MS/MS. Results: The developed bioanalytical method for the analysis of DBS samples had good accuracy and precision within the context of a discovery, non-GLP analysis. The concentration–time data and pharmacokinetic parameters generated from automated spotted samples were very similar to those derived from manually spotted DBS samples. The manual DBS data were also comparable to plasma data after correction for blood-to-plasma ratio. Conclusion: The automated DBS sampling is a promising technique for rodent pharmacokinetic studies and will improve the efficiency and quality of DBS sampling.