Oligonucleotide Analysis

Summary

Oligonucleotides are polymeric sequences of nucleotides (RNA, DNA, and their analogs) that are utilized extensively as PCR and microarray-based reagents in life science research and DNA-based diagnostic test kits (target specific primers and probes). Increasingly they are being developed as therapeutic drugs for a wide range of disease conditions. While there are just eight FDA-approved oligonucleotide-based therapeutic drugs on the market today, there are over 200 in the clinical pipeline and many more in earlier stages of development.

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Overview

Literature

Application Notes

Oligonucleotide Therapeutics

Oligonucleotide, or nucleic acid-based therapeutics hold great promise and are being developed across a wide range of modalities – from antisense oligonucleotides (AON) and small interfering RNA (siRNA) molecules that make up the majority of the clinical pipeline today, to microRNA inhibitors (antiMir’s) and activators (ProMir’s), aptamers, and most recently, CRISPR-based drugs for gene editing as well as full-length messenger RNA transcripts (mRNA) for gene therapy and vaccine applications.

To enhance their stability in-vivo, nucleic acid-based therapeutics often incorporate chemically-modified nucleotides, and increasingly are being conjugated to other chemical moieties (GalNac, Cholesterol, Peptides, Antibodies, Fatty Acids, etc.), or are being encapsulated within lipid nano-particles or viral vectors (e.g.: Adeno-Associated Virus (AAV) particles) in order to achieve targeted delivery to specific cells within the body.

Like all other biologics, the biophysical characteristics and purity of these molecules must be precisely understood and controlled to meet regulatory requirements. Most oligonucleotides are produced via an automated solid-phase synthesis process, which invariably results in failure sequences and other process-related impurities that need to be separated to the greatest extent possible, and impurities as low as 0.005% of the full-length product (FLP) that co-elute or closely elute with the FLP must also be identified and fully characterized to ensure the safety and efficacy of the final drug formulation.

Unrivaled Separation Performance

By combining our ACQUITY UPLC instrument technology with our industry leading Oligo Separation Technology (OST) columns, and pre-validated MassPrep OST reference standard, Waters brings an unrivaled level of chromatographic performance for oligonucleotide separations and analysis.

Fit-for-Purpose MS Detection & Informatics

To this front-end separation, we offer several fit-for-purpose mass analysis options on the back-end to meet the needs of our customers:

Our ACQUITY QDa mass detector workflow generates nominal mass data and is a highly deployable and scalable solution suited for customers who wish to confirm the identity of oligonucleotide samples (including pooled samples) via mass, and carry out purity assessments. (Note: if GMP compliance is needed, please reference the BioAccord workflow listed below)
Our Xevo G2-XS QTof workflow generates high-resolution mass spectrometry (HRMS) data and delivers enhanced sensitivity for in-depth characterization work, including ms/ms sequence confirmation.
Our new BioAccord System mass confirmation workflow provides an end-to-end compliance-ready solution for GMP manufacturers, CMC developers and QC groups who need to carry out mass confirmation and purity assessments in a compliant-ready manner. Leveraging our new Smart-MS enabled BioAccord System which generates high-resolution mass spectrometry (HRMS) data, and UNIFI Scientific Information System , providing compliance-ready data acquisition, processing and reporting along with user-level security and full audit trail capabilities to ensure compliance and data integrity.
Our SYNAPT G2-Si High-Definition Mass Spectrometry (HDMS) workflow is for researchers working at the limits of conventional mass spectrometry who need to further characterize oligonucleotides and/or associated impurities. Combining high-efficiency ion mobility-based measurements and separations with quadrupole time-of-flight (Tof) mass spectrometry, the SYNAPT G2-Si System enables the analysis of oligonucleotides differentiated by size and shape, as well as mass, to deliver increased selectivity and sensitivity beyond what is achievable by conventional mass spectrometry.

Of these four workflows, three utilize our MassLynx Software for instrument control and data acquisition, and leverage ProMass for Masslynx (Novatia, Ltd.) to carry out automated data analysis and reporting. Our new BioAccord mass confirmation workflow utilizes UNIFI providing a single complete audit trail for acquisition, processing, and reporting, reducing risk and simplifying audit preparation.