Monodisperse Linear and Cyclic Oligo[(
R)-3-hydroxybutanoates] Containing up to 128 Monomeric Units Using benzyl ester/(
tert-butyl)diphenylsilyl ether protection, (COCl)
2/pyridine esterification conditions, and a fragment-coupling strategy (with H
2/Pd-C debenzylation and HF · pyridine desilylation), linear oligomers of (
R)-3-hydroxybutanoic acid (3-HB) containing up to 128 3-HB building blocks (mol. weight > 11 000 Da) are assembled (
Schemes 1,2,5, and
6). In contrast to the previously employed protecting-group combination, and due to the low-temperature esterifying conditions, this procedure leads to monodisperse oligomers: all steps occur without loss of single 3-HB units. The product oligomers with two, one, and no terminal protecting groups (mostly prepared in multi-gram amounts) are characterized by all standard spectroscopic methods, especially by mass spectroscopy (
Figs. 2 and
3), by their optical activity, and by elemental analyses. Cyclization of the oligo[(
R)-3-hydroxybutanoic acids] with up to 32 3-HB units, using thiopyridine activation and CuBr
2 for the ring closure, produces oligolides consisting of up to 128 ring atoms (
Scheme 7). Mixed oligolides containing 3-HB and (
R)-3-hydroxypentanoic units are prepared from the corresponding linear trimers, using
Yamaguchi's method for the ring closure (
Scheme 8 and
Fig.4 (X-ray crystal structures of two folded conformers)). Comparisons of melting points (
Table 1), of [α] values (
Tables 2 and
3), of
1H-NMR coupling constants (
Table 3), and of molecular volume/hydroxyalkanoate unit (
Table 4) of linear and cyclic oligomer derivatives and of the high-molecular-weigh polymer show that the monodisperse oligomers appear to be surprisingly good models for the polymer. Besides this insight, our synthesis is supplying the samples to further test the role of P(3-HB) (
ca. 140 units) as a component of complexes forming channels through cell-wall phospholipid bilayers.
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