Wet soft bio-adhesion of insect-inspired polymeric oil-loadable perforated microcylinders

[Display omitted] •The insect-inspired polymeric bio-adhesive exhibits high adhesion onto skin and organ tissue.•Polymeric hierarchical microstructures are fabricated by modifying the surface properties.•The proposed bio-adhesive can enhance wet adhesion via the capillarity-assisted suction effect.•...

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Bibliographic Details
Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2021-11, Vol.423, p.130194, Article 130194
Main Authors: Song, Jin Ho, Baik, Sangyul, Kim, Da Wan, Yang, Tae-Heon, Pang, Changhyun
Format: Article
Language:English
Subjects:
Bio-adhesive
Biomimetics
Meniscus
Polymer replication
Wet adhesion
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Summary:[Display omitted] •The insect-inspired polymeric bio-adhesive exhibits high adhesion onto skin and organ tissue.•Polymeric hierarchical microstructures are fabricated by modifying the surface properties.•The proposed bio-adhesive can enhance wet adhesion via the capillarity-assisted suction effect.•A highly conformal organ grasper is demonstrated through insect-inspired bio-adhesives. Insect adhesion systems can enhance adhesion forces on wet or rough surfaces via oil-loadable spherical chambers and mushroom-shaped tips, enabling the achievement of an improved suction effect. In addition, highly conformal polymeric bio-adhesives with multiscale 3-dimensional (3D) architectures have been developed for stable adhesion performance on soft, wet, and non-flat skin or organ tissue. In this work, we propose a highly adaptable, biofluid-controllable, and reversible bio-adhesive with enhanced pulling adhesion and omnidirectional shear resistance. The development of this bio-adhesive was inspired by the hairy structure found in diving beetles, characterized by an oil-loadable spherical suction chamber and a mushroom-shaped tip. By investigating various geometrical and material parameters, a novel fabrication method was developed to control the diameter of the spherical chambers within the microcylinders and to create mushroom-like tips on the micropillars with 3D chambers. Owing to the capillarity-assisted suction effect and the omnidirectional shear resistance, originated from structural and materials features, the proposed bioinspired adhesive exhibits improved adhesion against dry and wet skin, as well as organ surfaces. Furthermore, diving beetle-inspired adhesives were employed on the top surfaces of a surgical grasper to utilize bioinspired architectures as highly conformal, wet-tolerant adhesive elements to minimize the damage of the engaged liver surfaces.
ISSN:1385-8947
1873-3212
DOI:10.1016/j.cej.2021.130194