Kasap, GokceGokdel, Yigit DaghanYelten, Mustafa BerkeFerhanoglu, Onur2024-07-182024-07-1820201530-43881558-2574https://doi.org/10.1109/TDMR.2020.2966043https://hdl.handle.net/11411/77913D printing is a rapidly emerging low-cost, high-yield, and high-speed manufacturing technique that has already been utilized in fabricating sensor and actuator devices. Here we investigate the cyclic fatigue and the effect of heating on 10 x 10 mm2-sized, 3D-printed polyamide-based laser scanning electromagnetic actuators, which are intended for integration with miniaturized laser-scanning imagers to yield a wide variety of optical imaging modalities. The tested actuators offer compact sizes and high-scan angles, comparable to their MEMS counterparts. We have tested N = 15 devices, at 5 different total optical scan angles between 40 degrees - 80 degrees, and observed their lifetimes (up to 108 cycles approximate to 10 days each), as well as the variability in their scan angle and mechanical resonance. A selected scanner was also tested under increased temperature conditions up to 60 degrees C for 10 hours, showing no sign of fatigue when returned to room temperature. Overall, it is concluded that 3D printed polymeric actuators are promising low-cost alternatives for short-term use in disposable opto-medical imaging units.eninfo:eu-repo/semantics/closedAccessThree-Dimensional PrintingMagnetic ActuatorsBiomedical Optical İmagingMaterials ReliabilityFatigueLifetime EstimationMechanical-PropertiesLaserDependenceArticle10.1109/TDMR.2020.2966043156115220Q3WOS:000526525700019