Johnny N. Naoum scite author profile

Accelerating solid-phase synthesis is crucial for accessing a large number of peptides in a short time. Since standard peptide synthesis is usually done under poor diffusion conditions with slow or no mixing of the solid support, acceleration of the process is achieved by applying a large excess of reagents. In this work, overhead stirring and heating were combined to provide accelerated solid-phase peptide synthesis without using an excess of reagent. A new setup that allows both heating and fast stirring was designed specifically for research laboratory-scale peptide synthesis. By increasing the diffusion of both reagents and beads in a narrow dimension reactor, solid-phase reactions were done in seconds and medium-size peptides were synthesized in minutes.

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Diffusion-Enhanced Amide Bond Formation on a Solid Support

Naoum

Alshanski

Gitlin-Domagalska

et al. 2019

Org. Process Res. Dev.

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Mixing of polystyrene resins in solid-phase synthesis is performed by shaking or gentle agitation of the reaction vessel to avoid breaking the brittle beads. These mixing strategies result in poor diffusion to and into the beads. Using a large excess of reagents is the common way to compensate for these deficiencies. We use fast overhead stirring for performing coupling reactions on a solid support. We show that fast overhead stirring enhances the efficiency of amide bond formation on the solid support compared to the state-of-the-art mixing method, while preserving the integrity of the beads. We find that fast overhead stirring minimizes the effect of decomposition of the activated species by increasing the diffusion-dependent coupling reaction. This allows decreasing the excess of reagents used for the multistep synthesis of peptides, thus providing a greener and more sustainable alternative for peptide synthesis on solid supports.

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A highly efficient in situ N-acetylation approach for solid phase synthesis

et al. 2014

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We describe a new general N-acetylation method for solid phase synthesis. Malonic acid is used as a precursor and the reaction proceeds by in situ formation of a reactive ketene intermediate at room temperature. We have successfully applied this methodology to peptides and non-peptidic molecules containing a variety of functional groups. The reaction gave high yields compared to known acetylation methods, irrespective of the structure, conformation and sequence of the acetylated molecule. Computational studies revealed that the concerted mechanism via the ketene intermediate is kinetically favorable and leads to a thermodynamically stable acetylated product. In conclusion, our method can be easily applied to acetylation in a wide variety of chemical reactions performed on the solid phase.

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DMAP-assisted sulfonylation as an efficient step for the methylation of primary amine motifs on solid support

Naoum¹,

Chandra²,

Shemesh³

et al. 2017

Beilstein J. Org. Chem.

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Several multistep strategies were developed to ensure single methylation of amines on solid support. These strategies rely on the introduction of the o-NBS protecting/activating group as a key step. We found that the state-of-the-art strategies fail for the methylation of several primary amine motifs, largely due to inefficient sulfonylation. Here we show that using the superior nucleophilic base DMAP instead of the commonly used base collidine as a sulfonylation additive is essential for the introduction of the o-NBS group to these amine motifs. DFT calculations provide an explanation by showing that the energy barrier of the DMAP intermediate is significantly lower than the one of the collidine. We demonstrate that using DMAP as a sole additive in the sulfonylation step results in an overall effective and regioselective N-methylation. The method presented herein proved highly efficient in solid-phase synthesis of a somatostatin analogue bearing three N α-methylation sites that could not be synthesized using the previously described state-of-the-art methods.

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Diffusion Enhanced Amide Bond Formation on Solid Support

Naoum¹,

Alshanski²,

Gitlin-Domagalska³

et al. 2019

Preprint

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Johnny N. Naoum

Stirring Peptide Synthesis to a New Level of Efficiency

Diffusion-Enhanced Amide Bond Formation on a Solid Support

A highly efficient in situ N-acetylation approach for solid phase synthesis

DMAP-assisted sulfonylation as an efficient step for the methylation of primary amine motifs on solid support

Diffusion Enhanced Amide Bond Formation on Solid Support

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