Your search keyword '"Enmark, Martin"' showing total 5 results

1. Analytical and preparative separation of phosphorothioated oligonucleotides: columns and ion-pair reagents.

Author

Enmark, Martin, Bagge, Joakim, Samuelsson, Jörgen, Thunberg, Linda, Örnskov, Eivor, Leek, Hanna, Limé, Fredrik, and Fornstedt, Torgny

Subjects

*OLIGONUCLEOTIDES, *ION pairs, *SOLID-phase synthesis, *OLIGONUCLEOTIDE synthesis, *DRUG development, *SYSTEM analysis

Abstract

Oligonucleotide drugs represent an emerging area in the pharmaceutical industry. Solid-phase synthesis generates many structurally closely related impurities, making efficient separation systems for purification and analysis a key challenge during pharmaceutical drug development. To increase the fundamental understanding of the important preparative separation step, mass-overloaded injections of a fully phosphorothioated 16mer, i.e., deoxythymidine oligonucleotide, were performed on a C18 and a phenyl column. The narrowest elution profiles were obtained using the phenyl column, and the 16mer could be collected with high purity and yield on both columns. The most likely contribution to the successful purification was the quantifiable displacement of the early-eluting shortmers on both columns. In addition, the phenyl column displayed better separation of later-eluting impurities, such as the 17mer impurity. The mass-overloaded injections resulted in classical Langmuirian elution profiles on all columns, provided the concentration of the ion-pairing reagent in the eluent was sufficiently high. Two additional column chemistries, C4 and C8, were also investigated in terms of their selectivity and elution profile characteristics for the separation of 5–20mers fully phosphorothioated deoxythymidine oligonucleotides. When using triethylamine as ion-pairing reagent to separate phosphorothioated oligonucleotides, we observed peak broadening caused by the partial separation of diastereomers, predominantly seen on the C4 and C18 columns. When using the ion-pair reagent tributylamine, to suppress diastereomer separation, the greatest selectivity was found using the phenyl column followed by C18. The present results will be useful when designing and optimizing efficient preparative separations of synthetic oligonucleotides. [ABSTRACT FROM AUTHOR]

Published

2020

2. Investigation of factors influencing the separation of diastereomers of phosphorothioated oligonucleotides.

Author

Enmark, Martin, Rova, Maria, Samuelsson, Jörgen, Örnskov, Eivor, Schweikart, Fritz, and Fornstedt, Torgny

Subjects

*CHROMATOGRAPHIC analysis, *DIASTEREOISOMERS, *OLIGONUCLEOTIDES, *ION pairs, *THIOPHOSPHATES

Abstract

This study presents a systematic investigation of factors influencing the chromatographic separation of diastereomers of phosphorothioated pentameric oligonucleotides as model solutes. Separation was carried out under ion-pairing conditions using an XBridge C18 column. For oligonucleotides with a single sulfur substitution, the diastereomer selectivity was found to increase with decreasing carbon chain length of the tertiary alkylamine used as an ion-pair reagent. Using an ion-pair reagent with high selectivity for diastereomers, triethylammonium, it was found the selectivity increased with decreased ion-pair concentration and shallower gradient slope. Selectivity was also demonstrated to be dependent on the position of the modified linkage. Substitutions at the center of the pentamer resulted in higher diastereomer selectivity compared to substitutions at either end. For mono-substituted oligonucleotides, the retention order and stereo configuration were consistently found to be correlated, with Rp followed by Sp, regardless of which linkage was modified. The type of nucleobase greatly affects the observed selectivity. A pentamer of cytosine has about twice the diastereomer selectivity of that of thymine. When investigating the retention of various oligonucleotides eluted using tributylammonium as the ion-pairing reagent, no diastereomer selectivity could be observed. However, retention was found to be dependent on both the degree and position of sulfur substitution as well as on the nucleobase. When analyzing fractions collected in the front and tail of overloaded injections, a significant difference was found in the ratio between Rp and Sp diastereomers, indicating that the peak broadening observed when using tributylammonium could be explained by partial diastereomer separation. [ABSTRACT FROM AUTHOR]

Published

2019

3. Development of a unified gradient theory for ion-pair chromatography using oligonucleotide separations as a model case.

Author

Enmark, Martin, Samuelsson, Jörgen, and Fornstedt, Torgny

Subjects

*GRADIENT elution (Chromatography), *ION pairs, *ELUTION (Chromatography), *CHROMATOGRAPHIC analysis, *ADSORPTION isotherms, *RF values (Chromatography), *SURFACE potential

Abstract

• The electrostatic theory applied for modeling gradient elution of oligonucleotides. • Unified retention time model developed for co-solvent and ion-pair gradient modes. • The retention time model was extensively verified for both types of gradient modes. • A unified adsorption isotherm model was developed for both gradient modes. • The isotherms predicted well overloaded elution bands using both gradient modes. Ion-pair chromatography is the de facto standard for separating oligonucleotides and related impurities, particularly for analysis but also often for small-scale purification. Currently, there is limited understanding of the quantitative modeling of both analytical and overloaded elution profiles obtained during gradient elution in ion-pair chromatography. Here we will investigate a recently introduced gradient mode, the so-called ion-pairing reagent gradient mode, for both analytical and overloaded separations of oligonucleotides. The first part of the study demonstrates how the electrostatic theory of ion-pair chromatography can be applied for modeling gradient elution of oligonucleotides. When the ion-pair gradient mode is used in a region where the electrostatic surface potential can be linearized, a closed-form expression of retention time can be derived. A unified retention model was then derived, applicable for both ion-pair reagent gradient mode as well as co-solvent gradient mode. The model was verified for two different experimental systems and homo- and heteromeric oligonucleotides of different lengths. Quantitative modeling of overloaded chromatography using the ion-pairing reagent gradient mode was also investigated. Firstly, a unified adsorption isotherm model was developed for both gradient modes. Then, adsorption isotherms parameter of a model oligonucleotide and two major synthetic impurities were estimated using the inverse method. Secondly, the parameters of the adsorption isotherm were then used to investigate how the productivity of oligonucleotide varies with injection volume, gradient slope, and initial retention factor. Here, the productivity increased when using a shallow gradient slope combined with a low initial retention factor. Finally, experiments were conducted to confirming some of the model predictions. Comparison with the conventional co-solvent gradient mode showed that the ion-pairing reagent gradient leads to both higher yield and productivity while consuming less co-solvent. [ABSTRACT FROM AUTHOR]

Published

2023

4. Building machine-learning-based models for retention time and resolution predictions in ion pair chromatography of oligonucleotides.

Author

Enmark, Martin, Häggström, Jakob, Samuelsson, Jörgen, and Fornstedt, Torgny

Subjects

*ION exchange chromatography, *RF values (Chromatography), *ION pairs, *ELUTION (Chromatography), *OLIGONUCLEOTIDES, *OLIGONUCLEOTIDE synthesis

Abstract

• SVR models predicting oligonucleotide retention times were trained and validated. • Ion-pair chromatography using two different elution modes was investigated • Model achieves low RMSE (< 0.2 min) and high Q2 (> 0.99) for all conditions. • Probability for resolving the n – 1 impurity for 250,000 sequences, investigated. • Oligonucleotide composition, gradient mode/slope, affect probability of R s > 1.5. Support vector regression models are created and used to predict the retention times of oligonucleotides separated using gradient ion-pair chromatography with high accuracy. The experimental dataset consisted of fully phosphorothioated oligonucleotides. Two models were trained and validated using two pseudo-orthogonal gradient modes and three gradient slopes. The results show that the spread in retention time differs between the two gradient modes, which indicated varying degree of sequence dependent separation. Peak widths from the experimental dataset were calculated and correlated with the guanine-cytosine content and retention time of the sequence for each gradient slope. This data was used to predict the resolution of the n – 1 impurity among 250 000 random 12- and 16-mer sequences; showing one of the investigated gradient modes has a much higher probability of exceeding a resolution of 1.5, particularly for the 16-mer sequences. Sequences having a high guanine-cytosine content and a terminal C are more likely to not reach critical resolution. The trained SVR models can both be used to identify characteristics of different separation methods and to assist in the choice of method conditions, i.e. to optimize resolution for arbitrary sequences. The methodology presented in this study can be expected to be applicable to predict retention times of other oligonucleotide synthesis and degradation impurities if provided enough training data. [ABSTRACT FROM AUTHOR]

Published

2022

5. Selectivity limits of and opportunities for ion pair chromatographic separation of oligonucleotides.

Author

Enmark, Martin, Harun, Said, Samuelsson, Jörgen, Örnskov, Eivor, Thunberg, Linda, Dahlén, Anders, and Fornstedt, Torgny

Subjects

*OLIGONUCLEOTIDES, *ION pairs, *ELECTRIC potential, *GRADIENT elution (Chromatography), *SURFACE potential, *ION exchange chromatography, *ELECTROSTATIC interaction

Abstract

• Key parameters for increasing selectivity were fundamentally investigated. • Oligonucleotide retention is predominantly driven by electrostatic interactions. • Short- and longmer selectivity increases with increasing surface potential. • Diastereomer selectivity increases with decreasing co-solvent concentration. • Novel ion-pair reagent gradient improved selectivity for certain separations. Here it was investigated how oligonucleotide retention and selectivity factors are affected by electrostatic and non-electrostatic interactions in ion pair chromatography. A framework was derived describing how selectivity depends on the electrostatic potential generated by the ion-pair reagent concentration, co-solvent volume fraction, charge difference between the analytes, and temperature. Isocratic experiments verified that, in separation problems concerning oligonucleotides of different charges, selectivity increases with increasing surface potential and analyte charge difference and with decreasing co-solvent volume fraction and temperature. For analytes of the same charge, for example, diastereomers of phosphorothioated oligonucleotides, selectivity can be increased by decreasing the co-solvent volume fraction or the temperature and has only a minor dependency on the ion-pairing reagent concentration. An important observation is that oligonucleotide retention is driven predominantly by electrostatic interaction generated by the adsorption of the ion-pairing reagent. We therefore compared classical gradient elution in which the co-solvent volume fraction increases over time versus gradient elution with a constant co-solvent volume fraction but with decreasing ion-pair reagent concentration over time. Both modes decrease the electrostatic potential. Oligonucleotide selectivity was found to increase with decreasing ion-pairing reagent concentration. The two elution modes were finally applied to two different model antisense oligonucleotide separation problems, and it was shown that the ion-pair reagent gradient increases the selectivity of non-charge–based separation problems while maintaining charge-difference–based selectivity. [ABSTRACT FROM AUTHOR]

Published

2021