Sequence-Defined Mikto-Arm Star-Shaped Macromolecules.

The synthesis of sequence-defined, discrete star-shaped macromolecules is a major challenge due to the lack of straightforward and versatile approaches. Here, a robust strategy is proposed that allows not only the preparation of sequence-defined mikto-arm star-shaped macromolecules but also the synthesis of a series of unprecedented discrete, multifunctional complex architectures with molar masses above 11 kDa. The iterative approach reported makes use of readily available building blocks and results in asymmetrically branched macromolecules with high purity and yields, which is showcased with monodisperse mikto-arm three-, four-, and five-arm star-shaped structures that were all characterized via LC-MS, MALDI-ToF, and NMR. This effective strategy drastically improves upon synthetic abilities of polymer chemists by enabling simultaneously sequence definition, precision insertion of branching points, as well as the orthogonal end-group functionalization of complex polymeric architectures. The presented approach, which can be translated to different platforms such as peptides and peptoids, is therefore particularly interesting in biomedical applications for which multiple different functional moieties on a single discrete macromolecule are needed.

Telechelic sequence-defined oligoamides: their step-economical synthesis, depolymerization and use in polymer networks.

The application of sequence-defined macromolecules in material science remains largely unexplored due to their challenging, low yielding and time-consuming synthesis. This work first describes a step-economical method for synthesizing unnatural sequence-defined oligoamides through fluorenylmethyloxycarbonyl chemistry. The use of a monodisperse soluble support enables homogeneous reactions at elevated temperature (up to 65 °C), leading to rapid coupling times (<10 min) and improved synthesis protocols. Moreover, a one-pot procedure for the two involved iterative steps is demonstrated via an intermediate quenching step, eliminating the need for in-between purification. The protocol is optimized using γ-aminobutyric acid (GABA) as initial amino acid, and the unique ability of the resulting oligomers to depolymerize, with the formation of cyclic γ-butyrolactame, is evidenced. Furthermore, in order to demonstrate the versatility of the present protocol, a library of 17 unnatural amino acid monomers is synthesized, starting from the readily available GABA-derivative 4-amino-2-hydroxybutanoic acid, and then used to create multifunctional tetramers. Notably, the obtained tetramers show higher thermal stability than a similar thiolactone-based sequence-defined macromolecule, which enables its exploration within a material context. To that end, a bidirectional growth approach is proposed as a greener alternative that reduces the number of synthetic steps to obtain telechelic sequence-defined oligoamides. The latter are finally used as macromers for the preparation of polymer networks. We expect this strategy to pave the way for the further exploration of sequence-defined macromolecules in material science.