Quantitative interpretation of the dynamic forces between micrometer-sized deformable droplets and bubbles has previously been limited by the lack of an independent measurement of their absolute separation. Here, we use in situ confocal fluorescence microscopy to directly image the position and separation of oil droplets in an atomic force microscopy experiment. Comparison with predicted force vs. separation behavior to describe the interplay of force and deformation showed excellent agreement with continuum hydrodynamic lubrication theory in aqueous films less than 30 nm thick. The combination of force measurement and 3D visualization of geometric separation and surface deformation is applicable to interactions between other deformable bodies.
Biosensors based on microcantilevers convert biological recognition events into measurable mechanical displacements. They offer advantages such as small size, low sample volume, label-free detection, ease of integration, high-throughput analysis, and low development cost. The design and development of a microcantilever-based aptasensor employing SU-8 polymer as the fabrication material is presented in this paper. Aptamers are employed as bioreceptor elements because they exhibit superior specificity compared to antibodies due to their small size and physicochemical stability. To immobilise thrombin DNA aptamer on the bare SU-8 surface of the aptasensor, a combined plasma mode treatment method is implemented which modifies the surface of the aptasensor. Label-free detection of thrombin molecules using the fabricated aptasensor is successfully demonstrated. The measured deflection is one order of magnitude higher than that of a silicon nitride microcantilever biosensor. The developed aptasensor also demonstrates high specificity.
Aptamers enhance flexibility in biosensor design. An aptasensor employs aptamers as a biological recognition element for biosensing. This paper presents design, fabrication, and evaluation of a microcantilever aptasensor. To identify and avoid potential bottlenecks in the aptasensor design, the parameters of the aptasensor are investigated through modelling and simulation. Next, thin SU-8 microcantilevers are fabricated to form the aptasensor. Characterization of the fabricated aptasensor is presented. Next, a plasma-based surface funtionalisation method is used to immobilize aptamers on the atasensor. Finally, an evaluation of the performance of the aptasensor is performed through detection of thrombin molecules. The evaluation results are presented and discussed.
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