Themed collection Chemical Advances in Additive Manufacturing

Andrew J. Boydston and Alshakim Nelson introduce this themed issue for Polymer Chemistry on chemical advances in additive manufacturing.

Herein, capsule shells containing hindered urea bonds were prepared using interfacial polymerization in an oil-in-oil Pickering emulsion stabilized by functionalized graphene oxide nanosheets.

Prototype drug eluting implants have been 3D printed using a supramolecular polyurethane-PEG formulation. The implants are capable of releasing a pharmaceutical active with effective drug release over a period of up to 8.5 months.

A multifunctional conjugated polymer (CP) of poly(3-hexylthiophene) grafted with photo-patternable and stretchable side chains is reported.

Creating polymeric materials with high thermal conductivity provides pathways to tailor the thermal transport of the 3D printed object during printing, effectively controlling heat transfer and offering a rational method to optimize properties.

Composite silicone inks provide access to 3D-printable elastomers that are mechanochemically active at lower strains that single component analogs.

Thiol–ene ‘click’ reactions between terpenes and a four-arm thiol were utilized to produced thermoset 3D printed structures using vat photopolymerisation.

An alkyne monomer, bis(propargyl) fumarate, is synthesized and mixed to a thiol monomer to produce DLP-3D printable formulations. Using off-stoichiometric formulations it is possible to print functionalizable objects.

3D printed micelle-based hydrogels were mechanically stabilized and crosslinked through the base catalyzed thiol-Michael addition in PBS buffer, without the use of potentially cytotoxic radical chemistry.

Printing of novel linear polypeptide hydrogel bioinks and stabilisation of structures by post-printing UV-triggered crosslinking through catalyst free thiol–yne click chemistry of cysteine and propiolated 4-arm PEG.

A green chemistry-based non-isocyanate polyurethanes with tunable material properties are synthesized by cyclic carbonate and click chemistry. Their excellent photopolymerization property enables light-based 3D printing of functional biomedical devices using polyurethanes.

Additive manufacturing is changing tissue engineering by offering pathways to otherwise unattainable, highly complex scaffold morphologies.

Hydrogel building blocks that are stimuli-responsive and self-adhesive could be utilized as a simple “do-it-yourself” construction set for soft machines and microfluidic devices.

Polymerizing through oxygen in open vials without any additional additives expands the utility of photocontrolled iniferter polymerization.

Vat photopolymerization of a trimethylammonium ethyl acrylate chloride solution (TMAEA) resulted in a well-defined, fully soluble, 3D printed rook.