Qin C Ji

A device for dried blood microsampling in quantitative bioanalysis: overcoming the issues associated blood hematocrit

AIMS A cross-laboratory experiment has been performed on a novel dried blood sampler in order to investigate whether it overcomes issues associated with blood volume and hematocrit (HCT) that are observed when taking a subpunch from dried blood spot samples. MATERIALS & METHODS An average blood volume of 10.6 μl was absorbed by the samplers across the different HCTs investigated (20-65%). RESULTS No notable change of volume absorbed was noted across the HCT range. Furthermore, the variation in blood sample volumes across six different laboratories was within acceptable limits. CONCLUSION The novel volumetric absorptive microsampling device has the potential to deliver the advantages of dried blood spot sampling while overcoming some of the issues associated with the technology.

Strategy and Its Implications of Protein Bioanalysis Utilizing High-Resolution Mass Spectrometric Detection of Intact Protein

Currently, mass spectrometry-based protein bioanalysis is primarily achieved through monitoring the representative peptide(s) resulting from analyte protein digestion. However, this approach is often incapable of differentiating the measurement of protein analyte from its post-translational modifications (PTMs) and/or potential biotransformation (BTX) products. This disadvantage can be overcome by direct measurement of the intact protein analytes. Selected reaction monitoring (SRM) on triple quadrupole mass spectrometers has been used for the direct measurement of intact protein. However, the fragmentation efficiency though the SRM process could be limited in many cases, especially for high molecular weight proteins. In this study, we present a new strategy of intact protein bioanalysis by high-resolution (HR) full scan mass spectrometry using human lysozyme as a model protein. An HR linear ion-trap/Orbitrap mass spectrometer was used for detection. A composite of isotopic peaks from one or multiple charge states can be isolated from the background and used to improve the signal-to-noise ratio. The acquired data were processed by summing extracted ion chromatograms (EIC) of the 10 most intense isotopic ions of octuply protonated lysozyme. Quantitation of the plasma lysozyme was conducted by utilizing high resolving power and an EIC window fitting to the protein molecular weight. An assay with a linear dynamic range from 0.5 to 500 μg/mL was developed with good accuracy and precision. The assay was successfully employed for monitoring the level of endogenous lysozyme and a potential PTM in human plasma. The current instrumentation limitations and potential advantages of this approach for the bioanalysis of large proteins are discussed.

Strategy of accelerated method development for high-throughput bioanalytical assays using ultra high-performance liquid chromatography coupled with mass spectrometry.

Here we report a strategy for rapid method development of high-throughput bioanalytical assays using ultra high-performance liquid chromatography coupled with tandem mass spectrometry (uHPLC-MS/MS). First, a data set was established for the removal of representative phospholipids under different sample treatments to guide subsequent method development for various compounds. The recovery information of the analyte(s) of interest under different extraction conditions was then obtained during method development. With the recovery profiles and the pre-established knowledge of phospholipids removal in place, an optimal extraction condition was identified to give not only a satisfactory recovery but also a good cleanup of the sample. A rapid LC or uHPLC method was developed without the need of extensive column wash after the elution of the analyte. This strategy was demonstrated through the method development of a uHPLC-MS/MS bioanalytical assay for the quantitation of ketoconazole in human plasma with liquid-liquid extraction using a hexane and ethyl acetate solvent system. The retention time for ketoconazole through an isocratic elution was 18 s. Good accuracy and precision were obtained. Assay ruggedness was demonstrated by consistent internal standard responses and retention time for 500 sequential injections. In addition, consistent results were obtained for incurred sample reanalysis.

Approach to evaluating dried blood spot sample stability during drying process and discovery of a treated card to maintain analyte stability by rapid on-card pH modification.

Unstable drug candidates often lead to complexity for both sample collection and bioanalysis. Dried blood spot (DBS) technology is believed to be a viable solution to address this problem. However, it is currently a challenge to evaluate compound stability on DBS due to its solid format. The observed compound loss on a DBS card could be degradation and/or incomplete recovery. Therefore, a reliable bioanalytical method which can differentiate recovery loss from degradation is necessary for such stability evaluation. In this paper, the stability of an unstable drug candidate (KAI-9803) in human blood was evaluated using DBS. A reliable approach to evaluating analyte stability on DBS was developed with an appropriate time-zero sample, a consistent DBS sample processing method, and a suitable positive control. Commercially available DBS cards were evaluated, and it was found that KAI-9803 degraded during the drying process. An in-house modified DBS card was developed and demonstrated to be able to stabilize KAI-9803 during the drying process by rapidly lowering the pH of the spotted blood sample. The storage stability of KAI-9803 in human blood on this new card has been established for at least 48 days at room temperature. This in-house modified DBS card could provide a generic approach for other compounds which require stabilization at a low pH.

Identifying, Evaluating, and Controlling Bioanalytical Risks Resulting from Nonuniform Matrix Ion Suppression/Enhancement and Nonlinear Liquid Chromatography−Mass Spectrometry Assay Response

Matrix ion suppression/enhancement is a well-observed and discussed phenomenon in electrospray ionization mass spectrometry. Nonuniform matrix ion suppression/enhancement across different types of samples in an analytical run is widely believed to be well compensated for by using a stable isotope-labeled internal standard (SIL-IS) in bioanalysis using liquid chromatography coupled with tandem mass spectrometry (LC-MS/MS). Therefore, the risk of nonuniform matrix ion suppression/enhancement is usually deemed low when an SIL-IS is used. Here, we have identified, evaluated, and proposed solutions to control bioanalytical risks from nonuniform matrix ion suppression/enhancement even with an SIL-IS through a case study using omeprazole. Two lots of human blank urine were tested, and ion enhancement of about 500% for omeprazole was observed in one lot but not in the other. When a quadratic regression model had to be used, the assay failed the industry acceptance criteria due to unacceptable positive bias for the middle and high quality control (QC) samples. The failure was attributed to different extents of matrix ion enhancement between the standards (STDs) and QCs, which resulted in the misaligned results from the regression model. It was concluded that, for the same amount of drug, nonuniform ion enhancement for different types of samples (STD or QC) resulted in different ion intensities, therefore leading to different response behaviors (linear or nonlinear) at the mass spectrometer detector. A simplified mathematical model was used to evaluate the risk when unmatched response models occurred for different types of samples. A diagnostic factor Q (Q = X(ULOQ)(-A/B)) was proposed to monitor the risks, where X(ULOQ) is the upper limit of quantitation of the assay, A is the quadratic slope of the curve, and B is the linear slope of the curve. The potential maximum errors were estimated on the basis of the mathematical model for different scenarios, and Q values were given to control the risks under these conditions for bioanalysis using LC-MS/MS.

Simple and efficient digestion of a monoclonal antibody in serum using pellet digestion: comparison with traditional digestion methods in LC–MS/MS bioanalysis

BACKGROUND Fast, efficient and reproducible digestion is critical for LC-MS/MS quantitative bioanalysis of therapeutic proteins. Traditional digestion methods require a pretreatment, such as sequential denaturation, reduction and alkylation, which are very time-consuming. RESULTS Pellet digestion, which does not require the serial pretreatments of denaturation, reduction and alkylation, was evaluated using a test monoclonal antibody (mAb) with 16 disulfide bonds, and compared with traditional digestion methods. For the test mAb, pellet digestion provided much better digestion efficiency compared with direct digestion, and provided similar or better digestion efficiency compared with digestion-with-pretreatment. In particular, for two peptides with very low digestion efficiency under direct digestion, pellet digestion improved the digestion yield by approximately 30-fold, which was similar to or better than what digestion-with-pretreatment offered. This method was then successfully applied to an LC-MS/MS assay of the test mAb in monkey serum. CONCLUSION Pellet digestion will be a very useful technique for high-throughput and reliable LC-MS/MS bioanalysis of mAbs and other large proteins, including ones with multiple disulfide bonds.

Systematic investigation of orthogonal SPE sample preparation for the LC–MS/MS bioanalysis of a monoclonal antibody after pellet digestion

BACKGROUND Increasing assay sensitivity is critical for promoting the application of LC-MS/MS quantitative bioanalysis of therapeutic proteins. A sample processing method that can selectively remove the abundant background peptides in the serum tryptic digests and retain the target peptides can greatly improve the assay sensitivity. RESULTS Mixed-mode strong-cation exchange SPE was systematically investigated as an orthogonal sample separation technique to reversed-phase UHPLC for the analysis of a test monoclonal antibody, BMS-986012, in monkey serum after pellet digestion. Strong cation exchange SPE efficiently removed most of the background peptides and reduced the matrix effect and background level in the monitored mass transition channels. As a result, improved sensitivity was observed for the surrogate peptides VVSV and SLIY. CONCLUSION This orthogonal approach provides a simple and easy-to-develop sample preparation method that can selectively remove most background peptides and extract the target peptides, therefore, improving the LC-MS/MS assay sensitivity.

What is next for dried blood spots

In the last several years, dried blood spot (DBS) sampling has re-emerged and attracted a great interest in the pharmaceutical industry as a microsampling technology for drug discovery and development studies. Although significant progress has been made to understand strengths and weaknesses of the technique, many organizations are still at the evaluation stage and experimental observations have resulted in more questions being raised as to whether there is a real future for this technology in pharmaceutical research, especially in support of pharmacokinetic studies. This article summarizes recently gained knowledge against the originally projected advantages of this technique, discusses some practical challenges that need to be overcome before DBS can be widely applied in drug development studies, and highlights some specific study types where DBS can be applied with a good benefit:risk ratio. The authors hope this article can stimulate further discussions about what are the next steps for DBS.

Fit-for-purpose bioanalytical cross-validation for LC–MS/MS assays in clinical studies

The paradigm shift of globalized research and conducting clinical studies at different geographic locations worldwide to access broader patient populations has resulted in increased need of correlating bioanalytical results generated in multiple laboratories, often across national borders. Cross-validations of bioanalytical methods are often implemented to assure the equivalency of the bioanalytical results is demonstrated. Regulatory agencies, such as the US FDA and European Medicines Agency, have included the requirement of cross-validations in their respective bioanalytical validation guidance and guidelines. While those documents provide high-level expectations, the detailed implementation is at the discretion of each individual organization. At Bristol-Myers Squibb, we practice a fit-for-purpose approach for conducting cross-validations for small-molecule bioanalytical methods using LC-MS/MS. A step-by-step proposal on the overall strategy, procedures and technical details for conducting a successful cross-validation is presented herein. A case study utilizing the proposed cross-validation approach to rule out method variability as the potential cause for high variance observed in PK studies is also presented.

A simple, effective approach for rapid development of high-throughput and reliable LC–MS/MS bioanalytical assays

BACKGROUND Rapidly developing LC-MS/MS assays with high-throughput and quality are challenging yet desired. Methodology & results: A simple method development approach was reported and demonstrated with the quantitative bioanalysis of BMS-984478, a hepatitis C virus nonstructural protein 5A inhibitor. An accurate, precise and robust LC-MS/MS method for the quantitation of BMS-984478 in rat and monkey plasma was developed and validated. Incurred sample reanalysis evaluation passed with 100% of samples meeting the acceptance criteria. The validated assay was successfully applied in toxicology studies without any failed runs. CONCLUSION The approach was successfully applied to the bioanalysis of BMS-984478 in toxicology and clinical studies. This approach was shown to be effective and reliable in speeding the development of high-throughput and reliable LC-MS/MS assays.