Plastics are ubiquitous in modern society. However, the reliance on fossil fuels and the environmental persistence of most polymers make them unsustainable. Scientists are facing the challenge of developing cost-effective and performance-competitive polymers from renewable resources. Carbohydrates are a renewable feedstock with tremendous potential: sugars are widely available, environmentally benign and are likely to impart biocompatibility and degradability properties to polymers due to their high oxygen content. Sugars are also a feedstock with great structurally diversity and functionalisation potential that can enable fine tuning of the resulting polymer properties. In recent years, Ring-Opening Polymerisation (ROP) has emerged as the method of choice for the controlled polymerisation of renewable cyclic monomers, in particular lactones and cyclic carbonates, to allow the precise synthesis of complex polymer architectures and address commodity and specialist applications. This feature article gives an overview of sugar-based polymers that can be made by ROP. In particular, recent advances in the synthetic routes towards monomers that preserve the original carbohydrate core structure are presented. The performances of various homogeneous catalysts and the properties of the resultant polymers are given, and future opportunities highlighted for the development of both the materials and catalysts.
Cyclic thionocarbonate and xanthate monomers were synthesised directly from ribose- and xylose-derived diols and CS2, and yielded novel sugar-based polymers with regioregular sulfur-containing linkages.
Therapeutic macromolecules
such as proteins and oligonucleotides
can be highly efficacious but are often limited to extracellular targets
due to the cell’s impermeable membrane. Cell-penetrating peptides
(CPPs) are able to deliver such macromolecules into cells, but limited
structure–activity relationships and inconsistent literature
reports make it difficult to design effective CPPs for a given cargo.
For example, polyarginine motifs are common in CPPs, promoting cell
uptake at the expense of systemic toxicity. Machine learning may be
able to address this challenge by bridging gaps between experimental
data in order to discern sequence–activity relationships that
evade our intuition. Our earlier data set and deep learning model
led to the design of miniproteins (>40 amino acids) for antisense
delivery. Here, we leveraged and expanded our model with data augmentation
in the short CPP sequence space of the data set to extrapolate and
discover short, low-arginine-content CPPs that would be easier to
synthesize and amenable to rapid conjugation to desired cargo, and
with minimal in vivo toxicity. The lead predicted peptide, termed P6, is as active as a polyarginine CPP for the delivery of
an antisense oligomer, while having only one arginine side chain and
18 total residues. We determined the pentalysine motif and the C-terminal
cysteine of P6 to be the main drivers of activity. The
antisense conjugate was able to enhance corrective splicing in an
animal model to produce functional eGFP in heart tissue in
vivo while remaining nontoxic up to a dose of 60 mg/kg. In
addition, P6 was able to deliver an enzyme to the cytosol
of cells. Our findings suggest that, given a data set of long CPPs,
we can discover by extrapolation short, active sequences that deliver
antisense oligomers.
The Baeyer–Villiger oxidation is a key transformation for sustainable chemical synthesis, especially when H2O2 and solid materials are employed as oxidant and catalyst, respectively. 4‐substituted cycloketones, which are readily available from renewables, present excellent platforms for Baeyer–Villiger upgrading. Such substrates exhibit substantially higher levels of activity and produce lactones at higher levels of lactone selectivity at all values of substrate conversion, relative to non‐substituted cyclohexanone. For 4‐isopropyl cyclohexanone, which is readily available from β‐pinene, continuous upgrading was evaluated in a plug‐flow reactor. Excellent selectivity (85 % at 65 % conversion), stability, and productivity were observed over 56 h, with over 1000 turnovers (mol product per mol Sn) being achieved with no loss of activity. A maximum space–time yield that was almost twice that for non‐substituted cyclohexanone was also obtained for this substrate [1173 vs. 607 g(product) kg(catalyst)−1 cm−3 h−1]. The lactone produced is also shown to be of suitable quality for ring opening polymerization. In addition to demonstrating the viability of the Sn‐β/H2O2 system to produce renewable lactone monomers suitable for polymer applications, the substituted alkyl cyclohexanones studied also help to elucidate steric, electronic, and thermodynamic elements of this transformation in greater detail than previously achieved.
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