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AFM-based cell force spectroscopy is an emerging research method that already has enhanced our understanding of the structural changes that take place in a cell as it becomes cancerous. However, the method is limited as it is not time-efficient in its current state of development. This paper presents the fabrication of an integrated long-range thermal bimorph actuator that controls the z-position of an AFM cantilever in liquid. Multiplied in arrays, such individually actuated probes can parallelize cell force spectroscopy measurements, thereby drastically reducing the time per measured cell. The need to accommodate differences in tip-sample distance implies an individual device actuation range of ≥10 µm out of plane. In addition, any cross-talk, i.e. between actuators or between the actuator and the force sensor, must be minimized. To meet these requirements, we designed and fabricated a novel thermal bimorph actuator that was incorporated with force sensing cantilevers. In order to keep temperatures in a bio-friendly range, the design was optimized for high thermo-mechanical sensitivity. FEM simulations confirmed that the surrounding liquid constitutes a large thermal reservoir that absorbs the generated heat. Furthermore, given that a cell substrate material of high thermal conductivity is chosen, in our case silicon, the thermal coupling between the cell and the substrate dominates over that between the cell and the actuator. Suspended silicon nitride structures with platinum electrodes were micro-fabricated through standard techniques. The finalized actuator was able to displace the cantilever out of plane by 17 µm in air.

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