Design and Characterization of a Dual-Interval Elastic Force Sensor for Robot-Assisted Microinjection

Zekui Lyu, Nana Ai, Wei Ge, Qingsong Xu
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Abstract

Robot-assisted microinjection has been widely implemented in the field of experimental biology research. Force perception is more accurate than visual feedback in determining the state of interaction between the micropipette and the biological sample. The existing micro-force sensors are difficult to directly combine with micropipettes to fully utilize their capabilities. This paper develops a new integrated force-sensing microinjector with both micro-force sensing and micropipette carrying functions using a symmetrical compliant guide mechanism and highly sensitive semiconductor strain gauges. Overload protection is considered in the structure design of the sensor, which is beneficial in reducing damage caused by displacement overshot due to misuse. The mechanical performance of the proposed dual-interval force sensing device is verified through theoretical derivation, simulation analysis, and experimental testing. The sensitivity, resolution, accuracy, dynamic response, stability, and repeatability of the sensor are investigated and evaluated in the established experimental platform. Finally, puncture experiments are conducted on zebrafish larvae and crab eggs using the proposed force-sensing microinjector. The results indicate that the sensor is effective in recording force signals during penetration of the sample.

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用于机器人辅助显微注射的双区间弹性力传感器的设计与特性分析
机器人辅助显微注射已广泛应用于生物实验研究领域。在确定微量移液器与生物样本之间的相互作用状态时,力感比视觉反馈更准确。现有的微力传感器很难直接与微量移液器结合以充分发挥其功能。本文利用对称顺应式导向机构和高灵敏度半导体应变片,开发了一种新型集成力传感微注射器,兼具微力传感和微量移液器承载功能。在传感器的结构设计中考虑了过载保护,这有利于减少由于误操作造成的位移过大而导致的损坏。通过理论推导、仿真分析和实验测试,验证了所提出的双间隔力传感装置的机械性能。在已建立的实验平台上,对传感器的灵敏度、分辨率、精确度、动态响应、稳定性和可重复性进行了研究和评估。最后,使用所提出的力传感微型注射器对斑马鱼幼体和蟹卵进行了穿刺实验。结果表明,该传感器能有效记录样品穿透过程中的力信号。
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