Abstract—
A method is proposed for controlling the wettability of the surface of a fluorinated material and for controlling its biofouling by introducing modified nanodiamonds into the structure. The optimal modification conditions were determined by means of a set of methods based on the example of a molecular oxygen sensor. They do not lead to a change in other functional properties of the material, such as the calibration curve and response time. In vitro tests have shown that a small amount of aminated nanodiamonds gives the surface bactericidal properties, but with a high content, improved adhesion of the biomaterial is observed due to a decrease in hydrophobicity. Long-term in situ tests under conditions simulating a bioreactor with actively growing biomass showed an almost complete absence of biological fouling of the modified material and revealed a significant fouling of the sensor from traditionally used polystyrene.
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The study was supported by the Russian Science Foundation (grant no. 17-79-10439).
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Aleksandrovskaya, A.Y., Melnikov, P.V., Safonov, A.V. et al. The Effect of Modified Nanodiamonds on the Wettability of the Surface of an Optical Oxygen Sensor and Biological Fouling During Long-Term in Situ Measurements. Nanotechnol Russia 14, 389–396 (2019). https://doi.org/10.1134/S1995078019040025
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DOI: https://doi.org/10.1134/S1995078019040025