3D printing fabrication process for fine control of microneedle shape

Microneedle electrode (ME) is used to monitor bioelectrical signals by penetrating via the skin, and it compensates for a limitation of surface electrodes. However, existing fabrication of ME have limited in controlling the shape of microneedles, which is directly relevant to the performance and dur...

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Bibliographic Details
Published in:Micro and nano systems letters 2023-12, Vol.11 (1), p.1-9, Article 1
Main Authors: Jeong, Jinwoong, Park, Jaeu, Lee, Sanghoon
Format: Article
Language:English
Subjects:
3-D printers
3D printing
Applied and Technical Physics
Aspect ratio
Bevels
Biocompatibility
Bioelectricity
Circuits and Systems
Electrical Engineering
Electrodes
Engineering
Letter
Mechanical Engineering
Microneedle electrode
Moldings
Nanotechnology
Needle-shape control
Needles
Penetration tests
Polyimide microneedle
Polyimide resins
Three dimensional printing
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Summary:Microneedle electrode (ME) is used to monitor bioelectrical signals by penetrating via the skin, and it compensates for a limitation of surface electrodes. However, existing fabrication of ME have limited in controlling the shape of microneedles, which is directly relevant to the performance and durability of microneedles as an electrode. In this study, a novel method using 3D printing is developed to control needle bevel angles. By controlling the angle of printing direction, needle bevel angles are changed. Various angles of printing direction (0–90°) are investigated to fabricate moldings, and those moldings are used for microneedle fabrications using biocompatible polyimide (PI). The height implementation rate and aspect ratio are also investigated to optimize PI microneedles. The penetration test of the fabricated microneedles is conducted in porcine skin. The PI microneedle of 1000 μm fabricated by the printing angle of 40° showed the bevel angle of 54.5°, which can penetrate the porcine skin. The result demonstrates that this suggested fabrication can be applied using various polymeric materials to optimize microneedle shape.
ISSN:2213-9621
2213-9621
DOI:10.1186/s40486-022-00165-4