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. 2024 Nov;36(44):e2404606.
doi: 10.1002/adma.202404606. Epub 2024 Sep 2.

3D-Printed Latticed Microneedle Array Patches for Tunable and Versatile Intradermal Delivery

Netra U Rajesh  1   2 Jihyun Luna Hwang  3 Yue Xu  1 Max A Saccone  1   3 Andy H Hung  1 Rosa A S Hernandez  3 Ian A Coates  3 Madison M Driskill  3 Maria T Dulay  1 Gunilla B Jacobson  1 Shaomin Tian  4 Jillian L Perry  5 Joseph M DeSimone  1   3
Affiliations

3D-Printed Latticed Microneedle Array Patches for Tunable and Versatile Intradermal Delivery

Netra U Rajesh et al. Adv Mater. 2024 Nov.

Abstract

Using high-resolution 3D printing, a novel class of microneedle array patches (MAPs) is introduced, called latticed MAPs (L-MAPs). Unlike most MAPs which are composed of either solid structures or hollow needles, L-MAPs incorporate tapered struts that form hollow cells capable of trapping liquid droplets. The lattice structures can also be coated with traditional viscous coating formulations, enabling both liquid- and solid-state cargo delivery, on a single patch. Here, a library of 43 L-MAP designs is generated and in-silico modeling is used to down-select optimal geometries for further characterization. Compared to traditionally molded and solid-coated MAPs, L-MAPs can load more cargo with fewer needles per patch, enhancing cargo loading and drug delivery capabilities. Further, L-MAP cargo release kinetics into the skin can be tuned based on formulation and needle geometry. In this work, the utility of L-MAPs as a platform is demonstrated for the delivery of small molecules, mRNA lipid nanoparticles, and solid-state ovalbumin protein. In addition, the production of programmable L-MAPs is demonstrated with tunable cargo release profiles, enabled by combining needle geometries on a single patch.

Keywords: 3D printing; intradermal drug delivery; lattices; microneedles; nucleic acids; proteins; small molecules.

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