Journal
JOURNAL OF MATERIALS CHEMISTRY B
Volume 5, Issue 45, Pages 9033-9044Publisher
ROYAL SOC CHEMISTRY
DOI: 10.1039/c7tb02469j
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Funding
- Academy of Finland [274670, 297360, 285015, 285526]
- Finnish Funding Agency for Innovation [211679]
- Academy of Finland (AKA) [274670] Funding Source: Academy of Finland (AKA)
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Here we investigated the electrochemical properties and dopamine (DA) detection capability of SU-8 photoresist based pyrolytic carbon (PyC) as well as its biocompatibility with neural cells. This approach is compatible with microfabrication techniques which is crucial for device development. X-ray photoelectron spectroscopy shows that PyC consists 98.5% of carbon, while oxygen plasma treatment (PyC-O-2) increases the amount of oxygen up to 27.1%. PyC showed nearly reversible (Delta E-p 63 mV) electron transfer kinetics towards outer sphere redox probe (Ru(NH3)(6)(2+/3+)), while the reaction on PyC-O-2 was quasi-reversible (Delta E-p > 75 mV). DA showed both diffusion and adsorption-defined reaction kinetics with fast electron transfer with the Delta E-p values of 50 mV and 30 mV, for PyC and PyC-O-2, respectively. The strong interaction between the hydroxyl groups on the surface and DA, as confirmed by simulations, facilitates the redox reactions of DA. DA showed a linear response in the measured physiologically relevant range (50 nM-1 mu M) and sensitivities were 1.2 A M-1 cm(-2) for PyC and 2.7 A M-1 cm(-2) for PyC-O-2. Plasma oxidation (PyC-O-2) improved cell adhesion even more than poly-L-lysine (PLL) coating on PyC, but best adhesion was achieved on PLL coated PyC-O-2. Glial cells, neuroblastoma cells and neural stem cells all showed similar behavior.
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