posted on 2024-01-24, 23:09authored byAaron Priester, Jimmy Yeng, Yuwei Zhang, Krista Hilmas, Risheng Wang, Anthony J. Convertine
This study focused on the development of high-resolution
polymeric
structures using polymer-induced self-assembly (PISA) printing with
commercially available digital light-processing (DLP) printers. Significantly,
soluble solids could be 3D-printed using this methodology with controllable
aqueous dissolution rates. This was achieved using a highly branched
macrochain transfer agent (macro-CTA) containing multiple covalently
attached CTA groups. In this work, the use of acrylamide as the self-assembling
monomer in isopropyl alcohol was explored with the addition of N-(butoxymethyl)acrylamide
to modulate the aqueous dissolution kinetics. PISA-printed microneedles
were observed to have feature sizes as small as 27 μm, which
was close to the resolution limit of the DLP printer. Atomic force
measurements confirm the presence of a complex mixture of PISA morphologies,
including spheres and worms. Additionally, “poke and release”
microneedles were fabricated; their base dissolved rapidly in physiological
fluids, leaving behind more slowly dissolving tips, thereby demonstrating
the potential for sustained drug delivery.