Polymerizing Phostones: A Fast Way to In-Chain Poly(phosphonate)s with Adjustable Hydrophilicity

Kristin N. Bauer, Lei Liu, Denis Andrienko, Manfred Wagner, Emily K. Macdonald, Michael P. Shaver, Frederik R. Wurm

Research output: Contribution to journalArticlepeer-review

Abstract / Description of output

Phostones, i.e. 2-alkoxy-2-oxo-1,3-oxaphospholanes, are accessible in a one-pot reaction from commercially available 1,3-dibromopropane and alkyl phosphites. These 5-membered cyclic phosphonic acid esters are used for the preparation of linear poly(phosphonate)s via ring-opening polymerization resulting in polymers with a hydrolytically stable P-C bond in the polymer backbone. Phostones have the stable P-C-bond within the cycle, which leads to a dramatic increase of the monomer stability towards hydrolysis and long shelf-lives compared to other cyclic phosphoesters, which hydrolyze immediately at contact with water. Two phostone-monomers containing ethoxy or butoxy pendant chains were prepared in a single step synthesis from inexpensive starting materials avoiding the usage of SOCl2 or POCl3. Polymers with ethoxy side chains are water-soluble without a lower critical solution temperature, non-toxic to murine macrophages, and hydrolytically degradable under basic conditions. The polymerization kinetics for different catalyst systems were evaluated for both monomers in order to identify optimal polymerization conditions, resulting in polyphosphonates with molecular weights between 3000 and 25100 g/mol with reasonable molecular weight dispersities (<1.6). Due to the ease of synthesis and distinct different hydrolysis kinetics compared to side-chain polyphosphonates, we believe that these new polyphostones represent a valuable addition to water-soluble biopolymers for future biomedical applications.
Original languageEnglish
JournalMacromolecules
Early online date6 Feb 2018
DOIs
Publication statusE-pub ahead of print - 6 Feb 2018

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