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Date of Award
2022
Document Type
Campus Access Dissertation
Degree Name
Doctor of Philosophy in Biomedical Engineering (PhD)
Administrative Home Department
Department of Biomedical Engineering
Advisor 1
Bruce P. Lee
Committee Member 1
Jingfeng Jiang
Committee Member 2
Smitha R. Hatti
Committee Member 3
Kazuya Tajiri
Abstract
Catechol molecules in the adhesive proteins secreted by marine mussels are often used to design external stimulus (e.g., pH, temperature, or light)-responsive smart adhesives. Here, we are introducing electricity as an external stimulus to tune the adhesion of these adhesives. Controlling the extent of oxidation of catechol with electricity was the mechanism to tune adhesion. At first, tunable adhesion of a catechol adhesive with 1 - 9 V was obtained in water by utilizing a two-electrode-based (anode and cathode) Johnson–Kendall–Roberts (JKR) contact mechanics test setup. The electricity initiated water electrolysis, elevated pH near the cathode, and oxidized catechol exposed to the cathode to its poorly adhesive quinone form. We established that the applied voltage and current levels, exposure time, and salt concentration of the water were the controlling parameters to tune adhesive properties. However, the rapid deactivation needed elevated voltage due to the poorly conductive adhesive. Moreover, the adhesive was irreversible. Thus, in our second approach, a thin catechol-containing adhesive coating was coated on an aluminum disc, and its conductivity was increased by adding the conductive pyrene monomer. Increased conductivity enabled the deactivation of adhesive with only 1 V. In addition, phenylboronic acid (APBA) was added into the coating to impart reversibility. This coating was reversible after deactivation for up to five cycles utilizing pH-responsive catechol-boronate complexation chemistry. The deactivation process discussed in the last two approaches depended on the conductive surface. Therefore, in our final approach, a catechol adhesive was deactivated by a peripheral silver cathode while in direct contact with a nonconductive glass surface. Based on lap shear tests, deactivation was achieved within 4 min while applying 20 V. The deactivation rate was dependent on the applied voltage level, exposure time, area of the adhesive interface, and conductivity of the surface material. Additionally, electrochemical reversibility of the adhesive up to 3 cycles was obtained by changing electrode polarity and utilizing catechol-boronate complexation chemistry. Overall, this dissertation provides approaches to combine oft-used adhesion testing methods with electrical circuitry to tune the adhesion of catechol adhesives of different formulations and architectures utilizing novel chemistries.
Recommended Citation
Bhuiyan, Md Saleh Akram, "ELECTROCHEMICAL APPROACHES TO CONTROL CATECHOL-BASED ADHESION", Campus Access Dissertation, Michigan Technological University, 2022.
Application of 9 V for in situ deactivation of the adhesive
Videos S2 - application of 5 V for in situ deactivation of the adhesive.mp4 (5231 kB)
Application of 5 V for in situ deactivation of the adhesive
Videos S3 - application of 1 V for in situ deactivation of the adhesive.mp4 (26299 kB)
Application of 1 V for in situ deactivation of the adhesive
Video S4- Reversible D10B10Py26 adhesive coating.mp4 (17684 kB)
Reversible D10B10Py26 adhesive coating
Video S5- Deactivation of adhesive from nonconductive surface with 20 V.mp4 (20734 kB)
Deactivation of adhesive from nonconductive surface with 20 V
Video S6- In-situ detachment of adhesive from glass surface.mp4 (25675 kB)
In-situ detachment of adhesive from glass surface