Bioanalytical LC-MS of therapeutic oligonucleotides

Development of a Versatile High-through-put Oligonucleotide LC-MS Method to Accelerate Drug Discovery

Liquid chromatography-mass spectrometry (LC-MS) is an effective tool for high-throughput quantification of oligonucleotides that is crucial for understanding their biological roles and developing diagnostic tests. This paper presents a high-throughput LC-MS/MS method that may be versatilely applied for a wide range of oligonucleotides, making it a valuable tool for rapid screening and discovery. The method is demonstrated using an in-house synthesized MALAT-1 Antisense oligonucleotide (ASO) as a test case. Biological samples were purified using a reversed liquid-liquid extraction process automated by a liquid handling workstation and analyzed with ion-pairing LC-MS/MS. The assay was evaluated for sensitivity (LLOQ = 2 nM), specificity, precision, accuracy, recovery, matrix effect, and stability in rat cerebrospinal fluid (CSF) and plasma. Besides some existing considerations such as column selection, ion-pairing reagent, and sample purification, our work focused on the following four subtopics: 1) selecting the appropriate Multiple Reaction Monitoring (MRM) transition to maximize sensitivity for trace-level ASO in biological samples; 2) utilizing a generic risk-free internal standard (tenofovir) to avoid crosstalk interference from the oligo internal standard commonly utilized in the LC-MS assay; 3) automating the sample preparation process to increase precision and throughput; and 4) comparing liquid-liquid extraction (LLE) and solid-phase extraction (SPE) as sample purification methods in oligo method development. The study quantified the concentration of MALAT-1 ASO in rat CSF and plasma after intrathecal injection and used the difference between the two matrices to evaluate the injection technique. The results provide a solid foundation for further internal oligonucleotide discovery and development.

Bioanalysis of free antisense oligonucleotide payload from antibody-oligonucleotide conjugate by hybridization LC-MS/MS

Background: Antisense oligonucleotides (ASOs) have been conjugated to various moieties, such as peptides, antibodies or Fab regions of antibodies, to enhance their delivery to target tissues. The quantitation of free ASO (ASO payload) is critical to characterize its pharmacokinetics/pharmacodynamics (PK/PD) properties and biodistribution after delivery of the peptide/antibody/Fab ASO conjugates.Results: We developed a hybridization-based LC-MS/MS methodology for quantification of free ASO in tissues in the presence of Fab-ASO and ASO with linker (ASO-linker).Conclusion: The developed method was applied to measure accurately the free ASO concentrations in liver and gastrocnemius in mice that were dosed with Fab-ASO. This methodology has also been applied to free ASO bioanalysis for other antibody-ASO and Fab-ASO conjugates in various tissues and plasma/serum samples.

Development and validation of an HILIC/MS/MS method for determination of nusinersen in rabbit plasma

A hydrophilic interaction liquid chromatography tandem mass spectrometry (HILIC/MS/MS) method was developed and validated for the quantitative analysis of the fully phosphorothioate modified oligonucleotide nusinersen. HILIC/MS/MS method is more robust and compatible with mass spectrometry than ion pair reversed-phase liquid chromatography-tandem mass spectrometry (IP-RP-LC/MS/MS). Various types and concentrations of additives and different pH of mobile phase affected the mass spectrometry response, chromatographic peak shape and retention of nusinersen. The optimized extraction method of nusinersen employs hydrophilic-lipophilic balance solid phase extraction, with a recovery of up to 80 %. Chromatographic quantification was performed using a gradient system on an amide column and the mobile phase consisted of ammonium acetate, acetonitrile and water in a certain proportion. The fully phosphorothioate modified nusinersen can obtain a high mass spectrometry response by providing greater peak symmetry and high ionization efficiency in a high-pH mobile phase. Moreover, the significant carry over interference was observed at the pH 6.3 of the mobile phase. Adjusting the pH value up to 10, and the carry over interference disappeared. The lower limit of quantitation of this developed HILIC/MS/MS assay was 30.0 ng/mL and the method was systematic methodology validated. This HILIC/MS/MS method provides an attractive and robust alternative for the quantitative analysis of nusinersen and was applied in the pharmacokinetic study of nusinersen in rabbits.

Observations from a decade of oligonucleotide bioanalysis by LC-MS

There is a growing need for efficient bioanalysis of oligonucleotide therapeutics. This broad class of molecules presents numerous challenges relative to traditional small molecule therapeutics. Methodologies including ligand-binding assays or polymerase chain reaction may be fit-for-purpose in many instances, but liquid chromatography coupled to mass spectrometry (LC-MS) often delivers the best balance of sensitivity and selectivity. Over the last decade, we have engaged with many such molecules and derived insights into challenges and solutions. Herein, we provide four case studies illustrating challenges we have encountered. These issues include low or variable analyte recovery, poor resolution from related species, chromatographic abnormalities or challenging sensitivity. We present a summary of considerations, based on these experiences, to assist others working in the area.

Development, validation and application of an ion-pair reversed-phase liquid chromatography-tandem mass spectrometry method for the quantification of nusinersen

Background: The fully phosphorothioate-modified oligonucleotide (OGN) nusinersen has low ionization efficiency in the negative ion mode, resulting in a low mass spectrometry response. There have been no relevant reports on developing a LC-MS method for the determination of nusinersen by optimizing mobile phase composition. Materials & methods: Mobile phase additives comprised of 15 mM triethylamine/25 mM 1,1,1,3,3,3-hexafluoro-2-propanol with a pH of 9.6. Nusinersen was extracted from plasma using Oasis® HLB solid-phase extraction (Waters, MA, USA). Results & conclusion: By adjusting the pH of the mobile phase to 9.6 by optimizing the type and concentration of ion-pair reagents, a high mass spectrometry response was obtained. The developed method was applied to nusinersen and met the requirements for the pharmacokinetic study of nusinersen in rabbits.

Resultant inward imbalanced seeding force (RIISF)-induced concave gold nanostar (CAuNS) for non-enzymatic electrocatalytic detection of serotonin and Kynurenine in human serum

CTAC-based gold nanoseed-induced concave curvature evolution of surface boundary planes from concave gold nanocube (CAuNC) to concave gold nanostar (CAuNS) has been achieved by a novel synthetic methodology simply by controlling the extent of seed used and hence the generated 'Resultant Inward Imbalanced Seeding Force (RIISF)'. The resultant CAuNS shows an excellent enhancement in catalytic activity compared to CAuNC and other intermediates as a function of curvature-induced anisotropy. Detailed characterization evaluates the presence of an enhanced number of multiple defect sites, high energy facets, larger surface area, and roughened surface which ultimately results in an increased mechanical strain, coordinately unsaturation, and multifacet-oriented anisotropic behavior suitable for positive influence on the binding affinity of CAuNSs. While different crystalline and structural parameters improve their catalytic activity, the resultant uniform three-dimensional (3D) platform shows comparatively easy pliability and well absorptivity on the glassy carbon electrode surface for increased shelf life, a uniform structure to confine a large extent of stoichiometric systems, and long-term stability under ambient conditions for making this newly developed material a unique nonenzymatic scalable universal electrocatalytic platform. With the help of various electrochemical measurements, the ability of the platform has been established by performing highly specific and sensitive detection of the two most important human bio messengers: Serotonin (STN) and Kynurenine (KYN) which are metabolites of L-Tryptophan in the human body system. The present study mechanistically surveys the role of seed-induced RIISF-modulated anisotropy in controlling the catalytic activity which offers a universal 3D electrocatalytic sensing tenet by an electrocatalytic approach.

A Novel Hybridization LC-MS/MS Methodology for Quantification of siRNA in Plasma, CSF and Tissue Samples

Therapeutic oligonucleotides, such as antisense oligonucleotide (ASO) and small interfering RNA (siRNA), are a new class of therapeutics rapidly growing in drug discovery and development. A sensitive and reliable method to quantify oligonucleotides in biological samples is critical to study their pharmacokinetic and pharmacodynamic properties. Hybridization LC-MS/MS was recently established as a highly sensitive and specific methodology for the quantification of single-stranded oligonucleotides, e.g., ASOs, in various biological matrices. However, there is no report of this methodology for the bioanalysis of double-stranded oligonucleotides (e.g., siRNA). In this work, we investigated hybridization LC-MS/MS methodology for the quantification of double-stranded oligonucleotides in biological samples using an siRNA compound, siRNA-01, as the test compound. The commonly used DNA capture probe and a new peptide nucleic acid (PNA) probe were compared for the hybridization extraction of siRNA-01 under different conditions. The PNA probe achieved better extraction recovery than the DNA probe, especially for high concentration samples, which may be due to its stronger hybridization affinity. The optimized hybridization method using the PNA probe was successfully qualified for the quantitation of siRNA-01 in monkey plasma, cerebrospinal fluid (CSF), and tissue homogenates over the range of 2.00-1000 ng/mL. This work is the first report of the hybridization LC-MS/MS methodology for the quantification of double-stranded oligonucleotides. The developed methodology will be applied to pharmacokinetic and toxicokinetic studies of siRNA-01. This novel methodology can also be used for the quantitative bioanalysis of other double-stranded oligonucleotides.

Microflow LC-MS/MS to improve sensitivity for antisense oligonucleotides bioanalysis: critical role of sample cleanness

Background: Quantitative bioanalysis of antisense oligonucleotides (ASOs) is crucial to study their pharmacokinetic properties. An ultrasensitive bioanalytical method is often desired for quantifying low-concentration ASOs. Results: Effects of microflow LC and sample cleanness on sensitivity improvement of ASOs were evaluated. Sixfold sensitivity improvement of ASO-001 was achieved using microflow LC-MS/MS compared with conventional analytical flow method. Different sample extracts (hybridization, SPE and protein precipitation) were evaluated for sensitivity improvement by microflow LC. More sensitivity improvement was observed in the cleaner sample extract. Conclusion: Microflow LC increases sensitivity for ASO bioanalysis. The cleaner the sample extract, the better the sensitivity improvement. An ultrasensitive hybridization microflow LC-MS/MS method with lower limit of quantification of 0.100 ng/ml was developed and qualified for quantifying ASO-001 in plasma.

Validation and application of hybridization liquid chromatography-tandem mass spectrometry methods for quantitative bioanalysis of antisense oligonucleotides

Background: Antisense oligonucleotide (ASO), an emerging modality in drug research and development, demands accurate and sensitive bioanalysis to understand its pharmacokinetic and pharmacodynamic properties. Results: By combining the advantages of both ligand binding and liquid chromatography-mass spectrometry/tandem mass (LC-MS/MS), hybridization LC-MS/MS methods were successfully developed and validated/qualified in a good lab practice (GLP) environment for the quantitation of an ASO drug candidate in monkey serum, cerebrospinal fluid (CSF) and tissues in the range of 0.5-500 ng/ml. Special treatment of CSF samples was employed to mitigate nonspecific binding, improve long-term storage stability and enable the usage of artificial CSF as a more accessible surrogate matrix. The method was also qualified and applied to ASO quantitation in various monkey tissue samples using a cocktail tissue homogenate as a surrogate matrix. Conclusion: This work was the first reported GLP validation and application of ASO bioanalysis using the hybridization LC-MS/MS platform.

Data-Independent Acquisition for the Detection of Mononucleoside RNA Modifications by Mass Spectrometry

RNA is dynamically modified in cells by a plethora of chemical moieties to modulate molecular functions and processes. Over 140 modifications have been identified across species and RNA types, with the highest density and diversity of modifications found in tRNA (tRNA). The methods used to identify and quantify these modifications have developed over recent years and continue to advance, primarily in the fields of next-generation sequencing (NGS) and mass spectrometry (MS). Most current NGS methods are limited to antibody-recognized or chemically derivatized modifications and have limitations in identifying multiple modifications simultaneously. Mass spectrometry can overcome both of these issues, accurately identifying a large number of modifications in a single run. Here, we present advances in MS data acquisition for the purpose of RNA modification identification and quantitation. Using this approach, we identified multiple tRNA wobble position modifications in Arabidopsis thaliana that are upregulated in salt-stressed growth conditions and may stabilize translation of salt stress induced proteins. This work presents improvements in methods for studying RNA modifications and introduces a possible regulatory role of wobble position modifications in A. thaliana translation.

Bioanalytical Methods and Strategic Perspectives Addressing the Rising Complexity of Novel Bioconjugates and Delivery Routes for Biotherapeutics

In recent years, an increase in the discovery and development of biotherapeutics employing new modalities, such as bioconjugates or novel routes of delivery, has created bioanalytical challenges. The inherent complexity of conjugated molecular structures means that quantification of the bioconjugate and its multiple components is critical for preclinical/clinical studies to inform drug discovery and development. Moreover, bioconjugates involve additional multifactorial complexity because of the potential for in vivo catabolism and biotransformation, which may require thorough investigations in multiple biological matrices. Furthermore, excipients that enhance absorption are frequently evaluated and employed for the development of oral and inhaled biotherapeutics. Risk-benefit assessments are required for novel or existing excipients that utilize dosages above previously approved levels. Bioanalytical methods that can measure both excipients and potential drug metabolites in biological matrices are highly relevant to these emerging bioanalysis challenges. We discuss the bioanalytical strategies for analyzing bioconjugates such as antibody-drug conjugates and antibody-oligonucleotide conjugates and review recent advances in bioanalytical methods for the quantification and characterization of novel bioconjugates. We also discuss bioanalytical considerations for both biotherapeutics and excipients through novel administration routes and review analyses in various biological matrices, from the extensively studied serum or plasma to tissue biopsy in the context of preclinical and clinical studies from both technical and regulatory perspectives.

Hydrophilic-Phase Extraction: A New Avenue of Solid-Phase Extraction for Oligonucleotide Bioanalysis

A novel mode of bioanalytical solid-phase extraction (SPE) has been developed and used for a quantitative application involving an RNA oligonucleotide therapeutic candidate. Previously established protocols and media showed very little recovery, and so this new approach, based on hydrophilic interaction liquid chromatography (HILIC) with an aminopropyl-bonded phase on a silica support and providing an essentially uncharted avenue of selectivity, was explored. The procedure featured only one step prior to sample load, high-organic sorbent conditioning, two washes following the load that switched between low and high pH, followed by elution in an a highly eluotropic HILIC composition. The moniker of “hydrophilic-phase extraction” (HPE) was given to the procedure. The HPE was proven to be a critical part of a fully quantitative HILIC–high-resolution mass spectrometry (HRMS) method for the RNA oligonucleotide and has potential for general application.

Recent advances in therapeutic nucleic acids and their analytical methods

Therapeutic nucleic acids are various chemically modified RNA or DNA with different functions, which mainly play roles at the gene level. Owing to its accurately targeting at pathogenic genes, nucleic acid based therapeutics have a wide range of application prospects. Recently, the improvement on chemical synthesis and delivery materials accelerated the development of therapeutic nucleic acids rapidly. Up to now, 17 nucleic acid based therapeutics approved by Food and Drug Administration (FDA) or European Medicines Agency (EMA). The development of therapeutics raised higher requirements for analytical methods, both in quality control and in clinical research. The first part of this review introduces different classes of therapeutic nucleic acids, including antisense oligonucleotide (ASO), RNA interference (RNAi) therapy, mRNA, aptamer and other classes which are under research. The second part reviews the therapeutic nucleic acids commercialized from 2019 to now. The third part discusses the analytical methods for nucleic acid based therapeutics, including liquid chromatography-based methods, capillary gel electrophoresis (CGE), hybridization enzyme-linked immunosorbent assay (ELISA) and other infrequently used methods. Finally, the advantages and shortcomings of these methods are summarized, and the future development of analysis methods are prospected.

High-sensitivity workflow for LC-MS-based analysis of GalNAc-conjugated oligonucleotides: a case study

Aim: Mass-selective quantitation is a powerful attribute of LC-MS as a platform for bioanalysis. Here, a sensitive LC-MS approach has been validated for an oligonucleotide having chemical modifications (e.g., N-acetylgalactosamine [GalNAc] conjugated), to distinguish between the conjugated and unconjugated forms of the oligonucleotide, thereby enabling a nuanced view of the pharmacokinetic profile. Results: A high-sensitivity methodology for mass-specific measurement of AZD8233, a GalNAc-conjugated 16-mer oligonucleotide, using LLE-SPE with optimized LC conditions and detection of a low-mass fragment ion was successfully validated in the range of 0.20-100 ng/ml in human plasma. Conclusion: The AZD8233 LC-MS methodology adds valuable insight on the GalNAc linker's in vivo stability to the program and should be broadly applicable to oligonucleotides requiring high sensitivity and mass-selective measurement for quantitative discrimination from metabolites and endogenous interferences.

BIOANALYSIS AND BIOTRANSFORMATION OF OLIGONUCLEOTIDE THERAPEUTICS BY LIQUID CHROMATOGRAPHY-MASS SPECTROMETRY

Since 2016, eight new oligonucleotide therapies have been approved which has led to increased interest in oligonucleotide analysis. There is a particular need for powerful bioanalytical tools to study the metabolism and biotransformation of these molecules. This review provides the background on the biological basis of these molecules as currently used in therapies. The article also reviews the current state of analytical methodology including state of the art sample preparation techniques, liquid chromatography-mass spectrometry methods, and the current limits of detection/quantitation. Finally, the article summarizes the challenges in oligonucleotide bioanalysis and provides future perspectives for this emerging field. © 2020 John Wiley & Sons Ltd.

The role of ligand-binding assay and LC-MS in the bioanalysis of complex protein and oligonucleotide therapeutics

Ligand-binding assay (LBA) and LC-MS have been the preferred bioanalytical techniques for the quantitation and biotransformation assessment of various therapeutic modalities. This review provides an overview of the applications of LBA, LC-MS/MS and LC-HRMS for the bioanalysis of complex protein therapeutics including antibody-drug conjugates, fusion proteins and PEGylated proteins as well as oligonucleotide therapeutics. The strengths and limitations of LBA and LC-MS, along with some guidelines on the choice of appropriate bioanalytical technique(s) for the bioanalysis of these therapeutic modalities are presented. With the discovery of novel and more complex therapeutic modalities, there is an increased need for the biopharmaceutical industry to develop a comprehensive bioanalytical strategy integrating both LBA and LC-MS.

Distribution and biotransformation of therapeutic antisense oligonucleotides and conjugates

Drug properties of antisense oligonucleotides (ASOs) differ significantly from those of traditional small-molecule therapeutics. In this review, we focus on ASO disposition, mainly as characterized by distribution and biotransformation, of nonconjugated and conjugated ASOs. We introduce ASO chemistry to allow the following in-depth discussion on bioanalytical methods and determination of distribution and elimination kinetics at low concentrations over extended periods of time. The resulting quantitative data on the parent oligonucleotide, and the identification and quantification of formed metabolites define the disposition. Proper quantitative understanding of disposition is pivotal for nonclinical to clinical predictions, supports communication with health agencies, and increases the probability of delivering optimal ASO therapy to patients.

Evaluation of alkylamines and stationary phases to improve LC-MS of oligonucleotides

This study evaluated four bridged-ethylene hybrid (BEH) columns containing C₁₈ (130 Å), peptide C₁₈ (300 Å), phenyl, or a mixed-mode charged surface hybrid (CSH C₁₈ ) using a wide range of antisense oligonucleotide therapeutics. The BEH C₁₈ , peptide, and phenyl columns were all capable of providing significant retention of oligonucleotide samples across multiple ion-pairing systems using alkylamines and 1,1,1,3,3,3,-hexafluoroisopropanol (HFIP). The retention of the oligonucleotides varied depending on the choice of alkylamine, with the order of retention being dimethylcyclohexylamine > diisopropylethylamine > triethylamine. The selectivity of these columns for several closely eluting impurities was similar. Although overall the C₁₈ , peptide, and phenyl columns were all found to be capable of analyzing oligonucleotide therapeutics, the phenyl column was found to be the most retentive and the C₁₈ column provided the best peak shape. The CSH C₁₈ column was found to be degraded by the alkylamine-HFIP mobile phase despite the mobile phase being within the pH stability range of the column.

Dopamine Sensing Based on Ultrathin Fluorescent Metal-Organic Nanosheets

The importance of dopamine (DA) detection as a biomarker for several diseases, especially Parkinson''s disease, has persuaded scientists to develop new nanomaterials for efficient sensing of DA in clinical samples. Ultrathin metal-organic nanosheets due to their exceptional thickness, large surface area, and flexibility are endowed with many accessible active sites and optimal surface interaction with the target analyte molecules. In this regard, a novel layered fluorescent metal-organic nanomaterial with a honeycomb topology based on europium, [Eu(pzdc)(Hpzdc)(H₂O)]_n (ECP) (H₂pzdc = 2,3-pyrazine dicarboxylic acid), was synthesized. X-ray crystallography revealed that the 3D supramolecular architecture of ECP is constructed from noncovalent interactions of coordinated water molecules between the 2D layers along the b axis. These layers that are only ∼4 nm thick were conveniently separated through ultrasound-induced liquid phase exfoliation. Optical studies show that the reduction of ECP thickness enhances the fluorescence intensity and serves as an efficient optical marker for DA detection. ECP nanoflakes exhibited fast response and high selectivity for DA detection in clinical samples. Good linearity for DA detection in the range of 0.1-10 μM with a detection limit of 21 nM proves the potential of ECP nanoflakes in DA sensing applications.

In vivo and in vitro studies of antisense oligonucleotides - a review

The potential of antisense oligonucleotides in gene silencing was discovered over 40 years ago, which resulted in the growing interest in their chemistry, mechanism of action, and metabolic pathways. This review summarizes the selected mechanisms of antisense drug action, as well as therapeutics which are to date approved by the Food and Drug Administration and European Medicines Agency. Moreover, bioanalytical methods used for ASO pharmacokinetics and metabolism studies are briefly summarized. Special attention is paid to the primary pharmacokinetic properties of the different chemistry classes of antisense oligonucleotides. Moreover, in vivo and in vitro metabolic pathways of these compounds are widely described with the emphasis on the different animal models as well as in vitro models, including tissues homogenates, enzyme solutions, and human liver microsomes.

Current State of Oligonucleotide Characterization Using Liquid Chromatography-Mass Spectrometry: Insight into Critical Issues

As interests increase in oligonucleotide therapeutics, there has been a greater need for analytical techniques to properly analyze and quantitate these biomolecules. This article looks into some of the existing chromatographic approaches for oligonucleotide analysis, including anion exchange, hydrophilic interaction liquid chromatography, and ion pair chromatography. Some of the key advantages and challenges of these chromatographic techniques are discussed. Colloid formation in mobile phases of alkylamines and fluorinated alcohols, a recently discovered analytical challenge, is discussed. Mass spectrometry is the method of choice to directly obtain structural information about oligonucleotide therapeutics. Mass spectrometry sensitivity challenges are reviewed, including comparison to other oligonucleotide techniques, salt adduction, and the multiple charge state envelope. Ionization of oligonucleotides through the charge residue model, ion evaporation model, and chain ejection model are analyzed. Therapeutic oligonucleotides have to undergo approval from major regulatory agencies, and the impurities and degradation products must be well-characterized to be approved. Current accepted thresholds for oligonucleotide impurities are reported. Aspects of the impurities and degradation products from these types of molecules are discussed as well as optimal analytical strategies to determine oligonucleotide related substances. Finally, ideas are proposed on how the field of oligonucleotide therapeutics may improve to aid in future analysis.

Hybridization Liquid Chromatography-Tandem Mass Spectrometry: An Alternative Bioanalytical Method for Antisense Oligonucleotide Quantitation in Plasma and Tissue Samples

Quantitative bioanalysis in plasma and tissues samples is required to study the pharmacokinetic and pharmacodynamic properties of antisense oligonucleotides (ASOs). To overcome intrinsic drawbacks in specificity, sensitivity, and throughput of traditional ligand-binding assay (LBA) and liquid chromatography-tandem mass spectrometry (LC-MS/MS) methods, an alternative bioanalytical method was developed by combining oligonucleotide hybridization and LC-MS/MS technologies. Target ASOs were extracted from biological samples by hybridization with biotinylated sense-strand oligonucleotides coupled to streptavidin magnetic beads. Using ion-pairing chromatography and tandem mass spectrometry, this method demonstrated high sensitivity (0.5 ng/mL using 100 μL of plasma), high specificity, wide linear range, complete automation, and generic applications in tests with multiple ASOs. The typical challenge of sensitivity drop in traditional ion-pairing LC-MS/MS was for the first time overcome by the introduction of a ternary pump system. Due to the high specificity, quantitation in various biological matrixes was achieved using calibration standards in plasma, largely improving efficiency and consistency. Another major advantage was the capability of simultaneous quantitation of ASO metabolites. The hybridization LC-MS/MS was considered an improved alternative for quantitation of ASOs and metabolites in plasma and tissue samples, showing a great potential to replace traditional LBA and LC-MS/MS methods.

Oligonucleotide quantification and metabolite profiling by high-resolution and accurate mass spectrometry

Aim: Advancements in RNA interference therapeutics have triggered development of improved bioanalytical methods for oligonucleotide metabolite profiling and high-throughput quantification in biological matrices. Results & methodology: HPLC coupled with high-resolution mass spectrometry (LC-HRMS) methods were developed to investigate the metabolism of a REVERSIR™ molecule in vivo. Plasma and tissue samples were extracted using solid-phase extraction followed by LC-HRMS analysis for metabolite profiling and quantification. The method was qualified from 10 to 5000 ng/ml (plasma) and 100 to 50000 ng/g (liver and kidney). In rat liver, intra and interday accuracy ranged from 80.9 to 118.5% and 88.4 to 111.9%, respectively, with acceptable precision (<20% CV). Conclusion: The LC-HRMS method can be applied for metabolite profiling and quantification of oligonucleotides in biological matrices.

RT-qPCR Methods to Support Pharmacokinetics and Drug Mechanism of Action to Advance Development of RNAi Therapeutics

The goal of this study was to develop a reverse transcription quantitative polymerase chain reaction (RT-qPCR) method for the accurate quantification of chemically modified small interfering RNA (siRNA) including but not restricted to thermally destabilizing modifications such as glycol nucleic acid (GNA). RT-qPCR was found to be superior to mass spectrometry-based siRNA detection in terms of sensitivity and throughput. However, mass spectrometry is still the preferred method when specific metabolite detection is required and is also insensitive to siRNA chemical modifications such as GNA. The RT-qPCR approach can be optimized to take chemical modifications into account and works robustly in different matrices without optimization, unlike mass spectrometry. RT-qPCR and mass spectrometry both have their strengths and weaknesses for the detection of siRNA and must be used appropriately depending on the questions at hand. Considerations such as desired throughput, assay sensitivity, and metabolite identification must be weighed when choosing which methodology to apply.

Two-dimensional liquid chromatography coupled to mass spectrometry for impurity analysis of dye-conjugated oligonucleotides

Two-dimensional liquid chromatography coupled to mass spectrometry (2D-LC/MS) has been successfully implemented for several biopharmaceutical applications, but applications for oligonucleotide analysis have been relatively unexplored. When analyzing oligonucleotides in one-dimension, selecting an ion-pairing agent often requires a balance between acceptable chromatographic and mass spectrometric performance. When oligonucleotides are modified or conjugated to include extremely hydrophobic groups, such as fluorophores, the separation mechanism is further complicated by the impact the fluorophore has on retention. Triethylamine (TEA) buffered in hexafluoroisopropanol (HFIP) is the most commonly used ion-pairing agent for analyses requiring mass spectrometry, but the elution order of dye-conjugated failed sequences relative to the main peak is not length-based compared to what would be predicted for unconjugated oligonucleotides having the same sequence. Hexylammonium acetate (HAA) offers more efficient ion-pairing for a length-based separation, but MS response is compromised due to ion suppression. In this study, 2D-LC/MS is used to show that dye-conjugated oligonucleotide failed sequences can be resolved from the parent oligonucleotide using a strong ion-pairing agent in the first-dimension and further identified using a weaker but MS compatible ion-pairing agent in the second-dimension, results that are not achievable in a one-dimensional analysis. More specifically, a heart-cut configuration using ion-pair reversed-phase chromatography in both the first and second dimension (IP-RP - IP-RP) is used to transfer the n-1 impurity from a length-based separation in the first-dimension to a second-dimension analysis for identity confirmation using a single quadrupole detector. Identical C₁₈ column chemistry is used in both the first and second dimension to exploit changes in selectivity that are due to mobile phase selection. The n-1 impurity from the two-dimensional analysis can be detected at low nanogram levels, comparable to results achieved in a one-dimensional dilution series, which approaches the limit of detection of the instrumentation. This work has future applicability to more complex impurity profiling using high-resolution instrumentation, where a more extensive set of impurities could not be evaluated using one-dimensional techniques.

An oligonucleotide bioanalytical LC-SRM methodology entirely liberated from ion-pairing

Aim: Reliable quantitative LC-MS methodology has been established and validated for an oligonucleotide in plasma in a fresh and unique fashion, free of ion-pairing reagents and the various associated deleterious effects from primary solution preparation through sample preparation and extraction to the LC-MS analytical end point, offering a highly selective mixed-mode solid-phase extraction with hydrophilic-interaction liquid chromatography as the chromatographic element prior to SRM detection. Results: Inter- and intra-assay accuracy and precision ranged from 97.9 to 111% and 2.75 to 9.66%, respectively. Recoveries of 50% were attained, and there was no significant matrix effect manifestation. Conclusion: The method demonstrated rugged performance and reliability under the optimized conditions, indicating a possible exciting new avenue, free of ion-pairing, for general application in oligonucleotide quantitative LC-MS.

Direct identification of microribonucleic acid miR-451 from plasma using liquid chromatography mass spectrometry

In recent years, small endogenous RNAs have come to the forefront of both basic and translational research. For example, many studies have pointed to the potential role of microRNAs (miRNAs) as disease biomarkers. However, precise quantitative methods for the analysis of miRNAs are still lacking. In this study, we report the first mass spectrometry-based quantitation of miR-451, a circulatory microRNA. Using a highly selective sample preparation method with an average recovery of 83.6% and a novel mobile phase chemistry, we were able to reach an LOQ of 0.5 ng/mL. Because of such high sensitivity, we could detect and quantify the endogenous miR-451 from both human and rat plasma. Considering the increased precision of LC-MS compared to other methods, these results usher in a new era of miRNA biomarker discovery and validation.

Alkylamine ion-pairing reagents and the chromatographic separation of oligonucleotides

Alkylamines are commonly used to improve both chromatographic and mass spectral performance of electrospray ionization liquid chromatography mass spectrometry based methods for the analysis of oligonucleotides. Recently several new alkylamines have been introduced to enhance the electrospray mass spectral response for oligonucleotides; however, the chromatographic properties of these new alkylamines have not been rigorously assessed. We have investigated the retention, peak width, resolution and general chromatographic performance of fifteen different alkylamines for the separation of a model DNA, RNA and an antisense therapeutic oligonucleotide. Eleven of the fifteen alkylamines were shown to provide similar chromatographic performance across all three classes of oligonucleotides. Based on these findings, a model for the mechanism of retention of oligonucleotides using alkylamines and hexafluoroisopropanol mobile phases is proposed. Depending on the concentrations of alkylamines and pH adjustment, oligonucleotides can be retained by micellar chromatography and not the generally held ion-pairing mechanism. This conclusion is supported by light scattering, transmission electron microscopy and ion mobility experiments detecting three micron aggregates in the mobile phase at concentrations that are routinely used for LC-MS analysis of oligonucleotides. These aggregates are not detected at lower alkylamine concentrations where the retention mechanism follows an ion-pairing mechanism. The formation of these aggregates appears to be dependent on the pH of the mobile phase.

Drug metabolism and pharmacokinetic strategies for oligonucleotide- and mRNA-based drug development

Oligonucleotide and modified mRNA therapeutics have great potential to treat diseases that are currently challenging to cure and are expanding into global and chronic disease areas such as cancer and various cardiovascular diseases. Advanced drug delivery systems or ligand-drug conjugates are utilized to achieve 'the right dose to the right target' to benefit efficacy and safety in patients. Chemistry and ADME characteristics distinguish these therapeutics from small molecules. Understanding the scalability and translatability between species and compound properties is crucial for robust nonclinical PKPD predictions to support clinical study design. Although the field has been developing for three decades, there is still room for innovation but also a need for nonclinical regulatory guidance to address these new modalities.

Review on sample preparation methods for oligonucleotides analysis by liquid chromatography

Antisense oligonucleotides have been successfully investigated for the treatment of different types of diseases. Detection and determination of antisense oligonucleotides and their metabolites are necessary for drug development and evaluation. This review focuses mainly on the first step of the analysis of oligonucleotides i.e. the sample preparation stage, and in particular on the techniques used for liquid chromatography and liquid chromatography coupled with mass spectrometry. Exceptional sample preparation techniques are required as antisense oligonucleotides need to be determined in complex biological matrices. The text discusses general issues in oligonucleotide sample preparation and approaches to their solution. The most popular techniques i.e. protein precipitation, protein enzyme digestion and liquid-liquid extraction are reviewed. Solid phase extraction methods are discussed and the issues connected with the application of each method are highlighted. Other newly reported promising techniques are also described. Finally, there is a summary of actually used techniques and the indication of the direction of future research.

Quantitative analysis of imetelstat in plasma with LC-MS/MS using solid-phase or hybridization extraction

AIM

Imetelstat, a 13-mer oligonucleotide with a lipid tail is being evaluated for treating hematologic myeloid malignancies. This report describes the development of extraction and quantification methods for imetelstat. Methodology & results: Imetelstat was extracted using SPE (rat plasma) or by hybridization using a biotinylated capture probe (human plasma) and was quantified by LC-MS/MS. Calibration curves were established (0.1-50 μg/ml). Stability of imetelstat in plasma was demonstrated. Concentrations of imetelstat extracted using either of the methods and quantified with LC-MS/MS were comparable with a validated ELISA.

CONCLUSION

Two extraction methods (solid phase and hybridization) were developed for quantifying imetelstat in plasma using LC-MS/MS. The hybridization extraction in combination with LC-MS/MS is a novel extraction approach.

Characterization of Byproducts from Chemical Syntheses of Oligonucleotides Containing 1-Methyladenine and 3-Methylcytosine

Oligonucleotides serve as important tools for biological, chemical, and medical research. The preparation of oligonucleotides through automated solid-phase synthesis is well-established. However, identification of byproducts generated from DNA synthesis, especially from oligonucleotides containing site-specific modifications, is sometimes challenging. Typical high-performance liquid chromatography (HPLC), mass spectrometry (MS), and gel electrophoresis methods alone are not sufficient for characterizing unexpected byproducts, especially for those having identical or very similar molecular weight (MW) to the products. We used a rigorous quality control procedure to characterize byproducts generated during oligonucleotide syntheses: (1) purify oligonucleotides by different HPLC systems; (2) determine exact MW by high-resolution MS; (3) locate modification position by MS/MS or exonuclease digestion with matrix-assisted laser desorption ionization-time of flight analysis; and (4) conduct, where applicable, enzymatic assays. We applied these steps to characterize byproducts in the syntheses of oligonucleotides containing biologically important methyl DNA adducts 1-methyladenine (m1A) and 3-methylcytosine (m3C). In m1A synthesis, we differentiated a regioisomeric byproduct 6-methyladenine, which possesses a MW identical to uncharged m1A. As for m3C, we identified a deamination byproduct 3-methyluracil, which is only 1 Da greater than uncharged m3C in the ∼4900 Da context. The detection of these byproducts would be very challenging if the abovementioned procedure was not adopted.

Quantitative determination of a siRNA (AD00370) in rat plasma using peptide nucleic acid probe and HPLC with fluorescence detection

AIM

Toxicokinetic and pharmacokinetic studies of therapeutic oligonucleotides require validated bioanalytical methods for sensitive and specific quantification of oligonucleotide drug candidates in biological samples.

RESULTS

A peptide nucleic acid (PNA) hybridization-based HPLC-fluorescence assay was developed and validated for quantification of Arrowhead Pharmaceuticals' proprietary siRNA in rat plasma samples via hybridization and anion-exchange-HPLC (AEX-HPLC) with fluorescence detection.

CONCLUSION

The validated method provided a sensitive and selective approach for quantification of siRNA in biological samples at a linear quantitation range of 1-1000 ng/ml. The assay requires only 25 μl of plasma sample and shows excellent accuracy and precision even without using an internal standard, providing a useful quantification method for siRNA determination in biological matrix with limited sample volume.

Identification of GalNAc-Conjugated Antisense Oligonucleotide Metabolites Using an Untargeted and Generic Approach Based on High Resolution Mass Spectrometry

Antisense oligonucleotides linked by phosphorothioates are an important class of therapeutics under investigation in various pharmaceutical companies. Antisense oligonucleotides may be coupled to high-affinity ligands (triantennary N-acetyl galactosamine = GalNAc) for hepatocyte-specific asialoglycoprotein receptors (ASGPR) to enhance uptake to hepatocytes and to increase potency. Since disposition and biotransformation of GalNAc-conjugated oligonucleotides is different from unconjugated oligonucleotides, appropriate analytical methods are required to identify main cleavage sites and degradation products of GalNAc conjugated and unconjugated oligonucleotides in target cells. A highly sensitive method was developed to identify metabolites of oligonucleotides using capillary flow liquid chromatography with column switching coupled to a high resolution Orbitrap Fusion mass spectrometer. Detection of GalNAc-conjugated oligonucleotides and their metabolites was achieved by combining full scan MS with two parallel MS² experiments, one data-dependent scan and an untargeted MS² experiment (all ion fragmentation) applying high collision energy. In the all ion fragmentation scan, a diagnostic fragment originating from the phosphorothioate backbone (O₂PS-: m/z 94.936) was formed efficiently upon collisional activation. Based on this fragment an accurate determination of metabolites of oligonucleotides was achieved, independent of their sequence or conjugation in an untargeted but highly selective manner. The method was effectively applied to investigate uptake and metabolism of GalNAc-conjugated oligonucleotides in incubations of primary rat hepatocytes; the elucidation of expected and unexpected degradation products was achieved in subnanomolar range.

Pharmacokinetics and Pharmacodynamics of a 13-mer LNA-inhibitor-miR-221 in Mice and Non-human Primates

Locked nucleic acid (LNA) oligonucleotides have been successfully used to efficiently inhibit endogenous small noncoding RNAs in vitro and in vivo. We previously demonstrated that the direct miR-221 inhibition by the novel 13-mer LNA-i-miR-221 induces significant antimyeloma activity and upregulates canonical miR-221 targets in vitro and in vivo. To evaluate the LNA-i-miR-221 pharmacokinetics and pharmacodynamics, novel assays for oligonucleotides quantification in NOD.SCID mice and Cynomolgus monkeys (Macaca fascicularis) plasma, urine and tissues were developed. To this aim, a liquid chromatography/mass spectrometry method, after solid-phase extraction, was used for the detection of LNA-i-miR-221 in plasma and urine, while a specific in situ hybridization assay for tissue uptake analysis was designed. Our analysis revealed short half-life, optimal tissue biovailability and minimal urine excretion of LNA-i-miR-221 in mice and monkeys. Up to 3 weeks, LNA-i-miR-221 was still detectable in mice vital organs and in xenografted tumors, together with p27 target upregulation. Importantly, no toxicity in the pilot monkey study was observed. Overall, our findings indicate the suitability of LNA-i-miR-221 for clinical use and we provide here pilot data for safety analysis and further development of LNA-miRNA-based therapeutics for human cancer.

Mass spectrometry of modified RNAs: recent developments

A common feature of ribonucleic acids (RNAs) is that they can undergo a variety of chemical modifications. As nearly all of these chemical modifications result in an increase in the mass of the canonical nucleoside, mass spectrometry has long been a powerful approach for identifying and characterizing modified RNAs. Over the past several years, significant advances have been made in method development and software for interpreting tandem mass spectra resulting in approaches that can yield qualitative and quantitative information on RNA modifications, often at the level of sequence specificity. We discuss these advances along with instrumentation developments that have increased our ability to extract such information from relatively complex biological samples. With the increasing interest in how these modifications impact the epitranscriptome, mass spectrometry will continue to play an important role in bioanalytical investigations revolving around RNA.

Advances in quantitative bioanalysis of oligonucleotide biomarkers and therapeutics

Technical advances and demands for high-throughput accurate quantification of oligonucleotide therapeutics and biomarkers in pharmaceutical research and clinical diagnosis have aided evolution in quantitative bioanalysis of oligonucleotides. Many bioanalytical methods are available for absolute quantification of oligonucleotides in biological matrices. They can be broadly classified into two categories: hybridization-based assays commonly used by molecular biologists and chromatographic assays routinely used by chemists. Each category has its own advantages and disadvantages for specific applications. This review summarizes the mechanisms and applications of some of the current most commonly used techniques in each category.

Quantitation of a low level coeluting impurity present in a modified oligonucleotide by both LC-MS and NMR

This paper describes the use of two complementary techniques, LC-MS and NMR, to quantify a low level mono phosphate substituted impurity in an oligonucleotide drug substance. This impurity is the result of a sulphurisation failure, leading to the production of a sequence where a phosphorothioate linkage is replaced by a phosphate. Few quantitative methods are possible to analyse these challenging molecules especially if reversed phase ion pair chromatography, one of the most commonly used techniques for the separation of oligonucleotides, is unable to resolve the impurity in question. With the use of a standard addition method it could be demonstrated that both analytical techniques show equivalency and furthermore, the LC-MS method alone with additional validation has the potential to perform this quantitative assay with a high degree of accuracy.

LC-MS of oligonucleotides: applications in biomedical research

Recent findings have elucidated numerous novel biological functions for oligonucleotides. Current standard methods for the study of oligonucleotides (i.e., hybridization and PCR) are not fully equipped to deal with the experimental needs arising from these new discoveries. More importantly, as the intracellular capacity of oligonucleotides is being harnessed for biomedical applications, alternative bioanalytical techniques become indispensable in order to comply with ever-increasing regulatory requirements. Owing to its ability to detect oligonucleotides independent of their sequence, LC-MS is emerging as the analytical method of choice for oligonucleotides. In this article, the current applications of LC-MS in the analysis of oligonucleotides, with an emphasis on RNA therapeutics and biomarkers, will be examined. In addition, the theoretical framework of oligonucleotide ESI is carefully inspected with the purpose of identifying the contributing factors to MS signal intensity.

Quantification of oligonucleotides by LC-MS/MS: the challenges of quantifying a phosphorothioate oligonucleotide and multiple metabolites

BACKGROUND

LC-MS/MS allows quantification of therapeutic oligonucleotides in biological fluids at low ng/ml concentrations. Achieving selectivity between metabolites and parent molecules in a single assay is one of the biggest challenges when developing a method. We present a strategy that allows quantification of an 18-mer antisense therapeutic, trabedersen, and six metabolites in human plasma. RESULTS/METHODOLOGY: The method utilizes phenol-chloroform and SPE with UHPLC-MS/MS to independently quantify trabedersen and the 5´n-1, 5´n-2, 5´n-3, 3´n-1, 3´n-2 and 3´n-3 metabolites in a single assay. The qualification data indicate that if the method was validated it would meet regulatory expectations for precision, accuracy and selectivity.

CONCLUSION

We show that quantification of an oligonucleotide and multiple metabolites, including isobaric 3´ and 5´ metabolites, is achievable in a single assay through good sample clean-up and careful optimization of the LC-MS/MS parameters. The strategy presented here can be applied elsewhere and may be useful for other oligonucleotides and their metabolites.

Preliminary investigation into the use of a real-time PCR method for the quantification of an oligonucleotide in human plasma and the development of novel acceptance criteria

BACKGROUND

The aim of the work was to evaluate the sensitivity and reproducibility of real-time reverse transcriptase PCR for quantitative analysis of an oligonucleotide in a biological matrix. A novel approach for the identification of outliers when assessing the suitability of calibration standards and QC samples is investigated.

RESULTS

A suitable assay was established for the determination of the oligonucleotide in human plasma over a range of 0.5-100 ng/ml.

CONCLUSION

In these preliminary investigations, the precision and accuracy of the method was established for the quantification of the oligonucleotide in human plasma. It was established that the method was precise and accurate for quantification of the oligonucleotide in human plasma. The acceptability of the data was assessed using a novel three-step process to identify any outliers, involving the use of the Grubbs' test. The analytical method only requires a small sample volume (<0.01 ml), so would be applicable in analysis of low-volume samples.

Systematic optimization of ion-pairing agents and hexafluoroisopropanol for enhanced electrospray ionization mass spectrometry of oligonucleotides

RATIONALE

New methods to enhance the electrospray ionization (ESI) signals are essential for low-level analysis of oligonucleotides. We report a systematic evaluation comparing 13 ion-pairing agents with and without hexafluoroisopropanol to understand their effect on the ion abundance of hetero-oligonucleotides.

METHODS

A Waters Synapt G2 HDMS quadrupole time-of-flight instrument was used to compare oligonucleotide signal intensity with 13 alkylamine ion-pairing agents at varying concentrations. The alkylamines that yielded the highest signal intensity were further evaluated with hexafluoroisopropanol at concentrations between 5 and 100 mM. The chemical properties of the solution components and analytes were evaluated to identify key factors in predicting optimal mobile phase conditions for different classes of oligonucleotides.

RESULTS

We identified a series of optimized mobile phase systems using diisopropylamine, tripropylamine, dimethylbutylamine, methyldibutylamine, and dimethylhexylamine along with 25 to 50 mM hexafluoroisopropanol that yielded significantly higher MS signal intensity for both siRNA and DNA compared with the traditionally used triethlyamine/hexafluoroisopropanol system. We explored charge state reduction, adduct formation and ESI mechanisms and identify the Henry's Law constant k aq/g as a key chemical property in predicting alkylamines that will increase oligonucleotide ion intensity. We also find that the hydrophobicity of the oligonucleotide plays a major role in choosing ion-pairing agents that will increase ion abundance.

CONCLUSIONS

This comprehensive and systematic optimization finds that the hydrophobicity of the oligonucleotide was a key factor in choosing alkylamine ion-pairing agents to increase ESI abundance. We identified that diisopropylamine and tripropylamine combined with lower concentrations of hexafluoroisopropanol yielded the highest signal intensity for these oligonucleotides.

Toward reading the sequence of short oligonucleotides from their retention factors obtained by means of hydrophilic interaction chromatography and ion-interaction reversed-phase liquid chromatography

Retention characteristics of selected synthetic 5'-terminal phosphate absent penta-nucleotides containing adenine, guanine, and thymine were studied in relation to their sequence by hydrophilic interaction chromatography and ion-interaction reversed-phase liquid chromatography. The organic solvent content, pH, and buffer concentration in mobile phases were evaluated as influential separation conditions. Data demonstrate that both compared chromatographic modes can be used to separate synthetic penta-nucleotides according to their nucleotide composition. Moreover, reversed-phase liquid chromatography allows separation according to their sequence. We have found a simple linear additive model to describe the retention order in both separation modes in regard to their sequence. In hydrophilic interaction chromatography, the retention behavior is controlled primarily by the hydrophilicity of involved nucleotides and minimally by their sequence position. For reversed-phase liquid chromatography, the nucleotide hydrophobicity plays an important role in their retention properties and the influence of their location in sequence on the retention increases toward the center and decreases toward the termini. Our results show that the penta-nucleotide sequence, and thus its spatial arrangement induced by the surrounding environment, is highly related to the retention properties, so it may be hypothetically used to read the sequence from the retention properties acquired under particular separation conditions.