Bioinspired Physico-Chemical Surface Modifications for the Development of Advanced Retentive Systems

Eda Dzinovic; Lauren Clark; Niktash Keyhani; Nora Al Morhiby; Paul Byford; Siyang Wang; Sara Gamea; Kenneth Chu; Elizabeth Wnuk; Yu Liu; Nicole Rosik; Finn Giuliani; Nicola M. Pugno; Zhenyu J. Zhang; Owen Addison; Sherif Elsharkawy

doi:10.1002/admt.202400928

Bioinspired Physico-Chemical Surface Modifications for the Development of Advanced Retentive Systems

Eda Dzinovic, Lauren Clark, Niktash Keyhani, Nora Al Morhiby, Paul Byford, Siyang Wang, Sara Gamea, Kenneth Chu, Elizabeth Wnuk, Yu Liu, Nicole Rosik, Finn Giuliani, Nicola M. Pugno, Zhenyu J. Zhang, Owen Addison, Sherif Elsharkawy^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

A major aspiration in advanced materials is to create artificial adhesive surfaces for wearable medical devices to meet the demands of the body's challenging settings and dynamics. For instance, dentures replace missing teeth and operate within the oral cavity, where an interplay between forces, muscles, saliva, and roughness of mucosa undermine their ability to grip oral tissues. Consequently, the lack of effective retentive strategies represents a source of dissatisfaction for denture wearers globally. Nature is rich in examples that employ physical and chemical adhesive strategies to optimize interfacial forces in dry and wet environments. Here, keratin-coated octopus-like suction cups are presented at the micro- and macroscale to improve the retention of rigid poly(methyl methacrylate). Microtopographies are obtained using two-photon polymerization and maskless lithography, while denture prototypes with macrotopographies are derived via digital light processing 3D printing. Results suggest that microtopographies and keratin-coated surfaces sustain higher maximum adhesion stress than the non-topographical and non-coated surfaces in moist environments, where retention is typically lacking. Proof-of-concept dentures demonstrate higher maximum detachment forces than conventional dentures with and without denture adhesive within dry and wet environments. This interdisciplinary research highlights the potential application of a nature-inspired physico-chemical approach in the next generation of complete dentures.

Original language	English
Journal	Advanced Materials Technologies
DOIs	https://doi.org/10.1002/admt.202400928
Publication status	Accepted/In press - 2024

Keywords

3D printing
biomimetics
complete dentures
keratin
octopus
pull-off force
retention

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10.1002/admt.202400928

Cite this

Dzinovic, E., Clark, L., Keyhani, N., Al Morhiby, N., Byford, P., Wang, S., Gamea, S., Chu, K., Wnuk, E., Liu, Y., Rosik, N., Giuliani, F., Pugno, N. M., Zhang, Z. J., Addison, O., & Elsharkawy, S. (Accepted/In press). Bioinspired Physico-Chemical Surface Modifications for the Development of Advanced Retentive Systems. Advanced Materials Technologies. https://doi.org/10.1002/admt.202400928

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abstract = "A major aspiration in advanced materials is to create artificial adhesive surfaces for wearable medical devices to meet the demands of the body's challenging settings and dynamics. For instance, dentures replace missing teeth and operate within the oral cavity, where an interplay between forces, muscles, saliva, and roughness of mucosa undermine their ability to grip oral tissues. Consequently, the lack of effective retentive strategies represents a source of dissatisfaction for denture wearers globally. Nature is rich in examples that employ physical and chemical adhesive strategies to optimize interfacial forces in dry and wet environments. Here, keratin-coated octopus-like suction cups are presented at the micro- and macroscale to improve the retention of rigid poly(methyl methacrylate). Microtopographies are obtained using two-photon polymerization and maskless lithography, while denture prototypes with macrotopographies are derived via digital light processing 3D printing. Results suggest that microtopographies and keratin-coated surfaces sustain higher maximum adhesion stress than the non-topographical and non-coated surfaces in moist environments, where retention is typically lacking. Proof-of-concept dentures demonstrate higher maximum detachment forces than conventional dentures with and without denture adhesive within dry and wet environments. This interdisciplinary research highlights the potential application of a nature-inspired physico-chemical approach in the next generation of complete dentures.",

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author = "Eda Dzinovic and Lauren Clark and Niktash Keyhani and {Al Morhiby}, Nora and Paul Byford and Siyang Wang and Sara Gamea and Kenneth Chu and Elizabeth Wnuk and Yu Liu and Nicole Rosik and Finn Giuliani and Pugno, {Nicola M.} and Zhang, {Zhenyu J.} and Owen Addison and Sherif Elsharkawy",

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year = "2024",

doi = "10.1002/admt.202400928",

language = "English",

journal = "Advanced Materials Technologies",

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AU - Dzinovic, Eda

AU - Clark, Lauren

AU - Keyhani, Niktash

AU - Al Morhiby, Nora

AU - Byford, Paul

AU - Wang, Siyang

AU - Gamea, Sara

AU - Chu, Kenneth

AU - Wnuk, Elizabeth

AU - Liu, Yu

AU - Rosik, Nicole

AU - Giuliani, Finn

AU - Pugno, Nicola M.

AU - Zhang, Zhenyu J.

AU - Addison, Owen

AU - Elsharkawy, Sherif

PY - 2024

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AB - A major aspiration in advanced materials is to create artificial adhesive surfaces for wearable medical devices to meet the demands of the body's challenging settings and dynamics. For instance, dentures replace missing teeth and operate within the oral cavity, where an interplay between forces, muscles, saliva, and roughness of mucosa undermine their ability to grip oral tissues. Consequently, the lack of effective retentive strategies represents a source of dissatisfaction for denture wearers globally. Nature is rich in examples that employ physical and chemical adhesive strategies to optimize interfacial forces in dry and wet environments. Here, keratin-coated octopus-like suction cups are presented at the micro- and macroscale to improve the retention of rigid poly(methyl methacrylate). Microtopographies are obtained using two-photon polymerization and maskless lithography, while denture prototypes with macrotopographies are derived via digital light processing 3D printing. Results suggest that microtopographies and keratin-coated surfaces sustain higher maximum adhesion stress than the non-topographical and non-coated surfaces in moist environments, where retention is typically lacking. Proof-of-concept dentures demonstrate higher maximum detachment forces than conventional dentures with and without denture adhesive within dry and wet environments. This interdisciplinary research highlights the potential application of a nature-inspired physico-chemical approach in the next generation of complete dentures.

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ER -

Bioinspired Physico-Chemical Surface Modifications for the Development of Advanced Retentive Systems

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Keywords

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