Validation of an LC-MS/MS method for the determination of sotorasib, a KRASG12C inhibitor, in human plasma.

Background: Sotorasib (AMG 510) is a first-in-class KRASG12C inhibitor that received accelerated US FDA approval in 2021 for the treatment of patients with KRASG12C-mutated locally advanced or metastatic non-small-cell lung cancer. Method: An LC-MS/MS method was developed and validated for the determination of sotorasib in human plasma to support clinical development studies. Samples were prepared using protein precipitation and analyzed by LC-MS/MS using gradient elution with a calibration standard curve range of 10.0-10,000 ng/ml. Stable isotope labeled [13C, D3]-sotorasib was used as an internal standard. Results & conclusion: The method fully met FDA guidelines for all validation parameters, including precision, accuracy, selectivity, matrix effect, recovery and stability and has been extensively used to support multiple clinical studies.

Leveraging patient-centric sampling for clinical drug development and decentralized clinical trials: Promise to reality.

Advances in the technologies to enable patient-centric sampling (PCS) have the potential to improve blood sample collection by enabling clinical trial participants to collect samples via self-collection or with the help of a caregiver in their home. Typically, blood samples to assess pharmacokinetics and pharmacodynamics of a drug during clinical development are collected at a clinical site via venous blood draw. In this position paper by the International Consortium for Innovation and Quality in Pharmaceutical Development (IQ), the potential value PCS can bring to patients, to the clinical datasets generated, and to clinical trial sponsors is discussed, along with considerations for program decision making, bioanalytical feasibility, operations, and regulatory implications. With an understanding of the value of PCS and considerations when implementing during clinical drug development, we can bring the promise of PCS closer to reality and enable decentralized clinical trials.

Bioanalytical method development and validation for the determination of glycine in human cerebrospinal fluid by ion-pair reversed-phase liquid chromatography-tandem mass spectrometry.

A LC-MS/MS method has been developed and validated for the determination of glycine in human cerebrospinal fluid (CSF). The validated method used artificial cerebrospinal fluid as a surrogate matrix for calibration standards. The calibration curve range for the assay was 100-10,000ng/mL and (13)C2, (15)N-glycine was used as an internal standard (IS). Pre-validation experiments were performed to demonstrate parallelism with surrogate matrix and standard addition methods. The mean endogenous glycine concentration in a pooled human CSF determined on three days by using artificial CSF as a surrogate matrix and the method of standard addition was found to be 748±30.6 and 768±18.1ng/mL, respectively. A percentage difference of -2.6% indicated that artificial CSF could be used as a surrogate calibration matrix for the determination of glycine in human CSF. Quality control (QC) samples, except the lower limit of quantitation (LLOQ) QC and low QC samples, were prepared by spiking glycine into aliquots of pooled human CSF sample. The low QC sample was prepared from a separate pooled human CSF sample containing low endogenous glycine concentrations, while the LLOQ QC sample was prepared in artificial CSF. Standard addition was used extensively to evaluate matrix effects during validation. The validated method was used to determine the endogenous glycine concentrations in human CSF samples. Incurred sample reanalysis demonstrated reproducibility of the method.

Ask the experts: method transfer.

As part of this themed issue, Bioanalysis invited a selection of researchers to express their views on method transfer in the bioanalytical field. The topics discussed include the main challenges in method transfer, the importance of communication and approaches for assessing the acceptability of transfers. Their responses provide a valuable insight into the considerations that need to be taken into account for successful method transfer.

Validation of a method for the determination of AMG 579 in cerebrospinal fluid with a focus on sample collection procedures for clinical trials.

Analysis of pharmaceutical compounds in cerebrospinal fluid (CSF) may present challenges due to the combination of the low protein content in this matrix and relatively low drug concentrations, often corresponding to free drug concentrations in plasma, typically found in CSF. A 30% loss of AMG 579 was observed during preparation of quality control samples and further investigation determined that this loss was likely due to binding to collection tubes. This observation also highlighted the possibility of additional losses of AMG 579 that could occur during collection of clinical samples, such as binding to catheters used in the collection of CSF. Loss of AMG 579 in QC samples was reduced from 30% to 5% when the volume of CSF stored in 1.5 mL vials was increased from 0.06 mL to 1 mL. Modest but unavoidable losses of about 20% of AMG 579 were also found following perfusion through both silicone and polypropylene (Pharmed(®) BPT) collection catheters. Silicone tubing was used for CSF collection based on clinical site preference. An LC-MS/MS method was validated to quantify AMG 579 in human CSF to support clinical testing. The original range of the assay was 1-1000 ng/mL but the LLOQ was subsequently lowered to 0.1 ng/mL to better meet project requirements. Interday bias (% RE) and precision (% CV) were -4.2% and 12.3% at the LLOQ, and less than ± 0.9% and 8.3% for higher concentrations, respectively. The compound was stable in human CSF for at least 5h at room temperature, 55 days at -70 °C (-60 to -80 °C range), and through three freeze-thaw cycles. Careful selection of assay conditions and materials minimized losses of the compound during sample collection and storage. While these losses could not be entirely eliminated, practical sample collection and storage conditions were established to allow for analysis of AMG 579 in human clinical trials.

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.

Ask the experts: chromatographic baselines.

Bioanalysis invited a selection of leading researchers to express their views on chromatographic baseline assignment in the bioanalytical laboratory. The topics discussed include the challenges presented with ensuring automated baseline assignment is correct, when reintegration is necessary, regulation and consistency in terminology. Their enlightening responses provide a valuable insight into developing an industry consensus towards reintegration. An accompanying commentary article in this issue, authored by Howard Hill and colleagues (Huntingdon Life Sciences), provides background to this much debated topic.

Determination of rosiglitazone and 5-hydroxy rosiglitazone in rat plasma using LC-HRMS by direct and indirect quantitative analysis: a new approach for metabolite quantification.

BACKGROUND: With recent advances in mass spectrometry instrumentation, HRMS is of increasing interest for quantitative bioanalysis due to its high sensitivity, rapid acquisition of full scan data, and advanced software for metabolite identification. In particular, there is strong interest in use of HRMS for simultaneous quantification of parent drug and metabolites without authentic metabolite standard materials. MATERIALS & METHODS: Rosiglitazone and 5-hydroxy rosiglitazone in rat plasma were analyzed using LC-Q-TOF by both direct and indirect quantitative analysis. Direct quantitative analysis used an authentic metabolite standard (5-hydroxy rosiglitazone). Indirect quantitative analysis firstly used the parent drug (rosiglitazone) calibration curve to provide a semiquantitative measure of metabolite concentration. A correction factor was then applied to the original data to re-calculate the 5-hydroxy rosiglitazone metabolite concentration. RESULTS: The ratio of the calibration curve slope of rosiglitazone to that of 5-hydroxy rosiglitazone was determined to be 2.09 ± 0.28 using different batches of mobile phases and columns. The correction factor 2.09 was then used to correct for the 5-hydroxy rosiglitazone concentrations found from the semiquantitative results using the rosiglitazone calibration standard curve. The concentrations of 5-hydroxy rosiglitazone found by direct and indirect quantitative analysis were highly comparable (within ±8%). CONCLUSION: Indirect quantitative analysis provides an alternative approach for metabolite quantification for discovery PK studies.

Simultaneous analysis of multiple monoclonal antibody biotherapeutics by LC-MS/MS method in rat plasma following cassette-dosing.

We have recently developed a general liquid chromatography-tandem mass spectrometric (LC-MS/MS) method using a stable isotope-labeled (SIL) monoclonal antibody (mAb) as an internal standard (IS) for single-analyte quantification of mAb (Li et al. Anal Chem 84(3):1267-1273, 2012). The method offers an advantage over ligand binding assay in reducing the time and resources needed for bioanalytical support in preclinical stages of drug development. In this paper, we report another marked increase in assay efficiency for multi-analyte bioanalysis using unique surrogate peptides for each analyte and the strategic choice of the SIL-IS peptide. The method was qualified for the simultaneous determinations of four mAbs in rat plasma and applied to samples from discrete- and cassette-dosed rats. The pharmacokinetic parameters of the four mAbs of cassette dosing were comparable to those of discrete dosing and of enzyme-linked immunosorbent assay results. Although there may be limitations and special considerations for cassette-dosing of biologics, these results demonstrate the robust performance of the multi-analyte LC-MS/MS method allowing cassette-dosing that would ultimately reduce animal use and improve efficiency.

Application of DBS sampling in combination with LC-MS/MS for pharmacokinetic evaluation of a compound with species-specific blood-to-plasma partitioning.

BACKGROUND: Dried blood spot (DBS) sampling in combination with LC-MS/MS has been used increasingly in drug discovery for quantitative analysis to support pharmacokinetic (PK) studies. In this study, we assessed the effect of blood-to-plasma (B:P) partitioning on the bioanalytical performance and PK data acquired by DBS for a compound AMG-1 with species and concentration-dependent B:P ratio. RESULTS: B:P partitioning did not adversely affect bioanalytical performance of DBS for AMG-1. For rat, (B:P ratio of 0.63), PK profiles from DBS and plasma methods were comparable. For dog, concentration-dependence of B:P ratio was observed both in vivo and in vitro. Additional studies demonstrated concentration-dependence of the compound's unbound fraction in plasma, which may contribute to the concentration-dependence of the B:P ratio. CONCLUSION: DBS is a promising sampling technique for preclinical pharmacokinetic studies. For compounds with high B:P ratio, caution needs to be applied for data comparison and interpretation between matrices.

Critical review of p38 MAP kinase inhibitors: a bioanalytical perspective.

p38 MAP kinase is a key enzyme in the proinflammatory response and a large number of compounds have been studied as potential therapeutic drugs. This review summarizes the bioanalytical methods used for the analysis of p38 MAP kinase inhibitors, with a special focus on sample preparation and chromatographic analysis. Biological sample extraction techniques utilized included protein precipitation, liquid-liquid extraction and SPE. Applications include determinations of compounds in a variety of biological fluids and tissues. Extracted samples are typically separated by reverse-phase LC and quantitated either by UV or MS/MS detection. The benefits and limitations of each sample preparation strategy are discussed. The importance of chromatographic separation to avoid matrix effect and interference from endogenous compounds or drug-related biotransformation products are also discussed herein.

Direct quantitative analysis of a 20 kDa PEGylated human calcitonin gene peptide antagonist in cynomolgus monkey serum using in-source CID and UPLC-MS/MS.

PEGylation is a successful strategy to improve the pharmacokinetic and pharmaceutical properties of therapeutic peptides. However, quantitative analysis of PEGylated peptides in biomatrix by LC-MS/MS poses significant analytical challenge due to the polydispersity of the polyethylene glycol (PEG), and the multiple charge states observed for both the peptide and PEG moieties. In this report, a novel LC-MS/MS method for direct quantitative analysis of 20 kDa PEGylated CGRP[Cit, Cit] in cynomolgus monkey serum is presented. CGRP[Cit, Cit] is an investigational human calcitonin gene peptide receptor antagonist with amino acid sequence Ac -WVTH[Cit]LAGLLS[Cit]SGGVVRKNFVPT DVGPFAF-NH(2). In-source collision-induced dissociation (in-source CID) of 20 kDa PEGylated peptide was used to generate CGRP[Cit, Cit] fragment ions, among which the most abundant b(8)(+) ion was selected and measured as a surrogate for the 20 kDa PEGylated peptide. A solid phase extraction (SPE) method was used to extract the PEGylated peptides from the biomatrix prior to the UPLC-MS/MS analysis. This method achieved a lower limit of quantitation (LLOQ) of 5.00 ng/mL with a serum sample volume of 100 µL, and was linear over the calibration range of 5.00 to 500 ng/mL in cynomolgus monkey serum. Intraday and interday accuracy and precision from QC samples were within ±15%. This method was successfully applied to a pharmacokinetic study of the 20 kDa PEGylated CGRP[Cit, Cit] in cynomolgus monkeys.

Development of a method for the determination of glycine in human cerebrospinal fluid using pre-column derivatization and LC-MS/MS.

An LC-MS/MS method using pre-column derivatization with phenylisothiocyanate (PITC) was developed to quantify glycine in human cerebrospinal fluid (CSF) and applied to the determination of glycine in human samples collected during clinical testing. The calibration curve range for the assay was 50-10,000 ng/mL and ¹³C2¹5N-glycine was used as an internal standard. Artificial CSF was used as a surrogate matrix for standards due to the presence of endogenous glycine in human CSF and this approach was validated with additional experiments involving either standard addition, or stable labeled glycine as an alternate calibration standard for endogenous glycine. Interday bias (% RE) and precision (% CV) were -4.2 and 12.3% at the LLOQ, and less than ±0.9 and 8.3% for higher concentrations, respectively. Glycine was stable in artificial CSF for at least 5h at room temperature, 55 days at -70 °C (-60 to -80 °C range), and through three freeze-thaw cycles.

Development of a method for the sensitive and quantitative determination of hepcidin in human serum using LC-MS/MS.

INTRODUCTION: Hepcidin, a 25-amino acid peptide hormone, plays a crucial regulatory role in iron metabolism. Elevated hepcidin has been observed in response to inflammation and is speculated to be a causative factor in inflammatory anemia due to induction of functional iron deficiency. Hepcidin has been suggested as a biomarker of anemia of inflammation. An accurate assessment of human serum hepcidin is critical to understand its role in anemia. METHODS: An LC-MS/MS method was developed to quantify hepcidin in human serum using chemically synthesized hepcidin as a standard and stable isotope labeled hepcidin as internal standard. Rabbit serum was used as a surrogate matrix for standards due to the presence of endogenous hepcidin in human serum. The method was validated to FDA criteria for bioanalytical assays. RESULTS: The calibration curve was validated over the range of 2.5 to 500 ng/mL. Hepcidin was stable in serum for at least 16 h at room temperature, 90 days at -60 to -80 degrees C, and after three F/T cycles. Interday accuracy (% RE) and precision (%CV) were -11.2% and 5.6%, respectively at the LLOQ, and less than +/-7.0% and 9.2%, respectively for higher concentrations. The mean accuracy of quality control samples (5.00, 15.0, 100 and 400 ng/mL) in 21 analytical batches was between -0.7 and +2.1%, with mean precision between 5.1% and 13.4%. Hepcidin was below 2.5 ng/mL in 31 of 60 healthy subjects, while the mean concentration was less than 10 ng/mL. Sepsis and chronic kidney disease patients had mean serum concentrations of 252 ng/mL (n=16, median 121 ng/mL) and 99 ng/mL (n=50, median 68 ng/mL), respectively. CONCLUSIONS: A fully validated LC-MS/MS method has been described for the determination of hepcidin in human serum. This method was applied to the determination of hepcidin in over 1200 human samples.