蚊子的挑选和放置:在pfspz为基础的疟疾疫苗生产自动化的关键步骤

H. Phalen, P. Vagdargi, Michael Pozin, S. Chakravarty, G. Chirikjian, I. Iordachita, R. Taylor
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引用次数: 5

摘要

疟疾的治疗是一项全球卫生挑战,它将受益于广泛采用疟疾疫苗。已经开发出一种利用疟原虫恶性疟原虫(Pf)的孢子子(SPZ)制造活生物体疫苗的方法,这些孢子子集中在受感染蚊子的唾液腺中。目前的手工解剖方法来获得这些PfSPZ并不是大规模疫苗生产的最佳方法。我们演示了这个生产过程中关键步骤的自动化,将蚊子从一个分期装置中挑选和放置到一个解剖装置中。在计算机视觉系统的指导下,使用一个定制设计的微型抓手连接到一个四自由度(4-DOF)机器人上,对机器人蚊子拾取系统进行了单元测试。蚊子被自动地从一个网状平台上抓起来,拉到一对缺口切割刀片上,切除蚊子的头部,允许进入唾液腺。这些叶片的位置是根据计算机视觉的输出来调整的,以适应每只被抓住的蚊子的独特解剖结构和方向。在该系统对50只蚊子进行的初步测试中,我们证明了100%的抓取准确率和90%的准确率,将蚊子和脖子放在叶片凹槽内,以便可以去除头部。对于这种困难且非标准的拾取任务来说,这是一个很有希望的结果。对失败案例的分析为改进提供了见解,因为该机器人拾取和放置系统集成到正在开发的更大的自动蚊子解剖系统中。
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Mosquito Pick-and-Place: Automating a Key Step in PfSPZ-based Malaria Vaccine Production
The treatment of malaria is a global health challenge that stands to benefit from the widespread introduction of a vaccine for the disease. A method has been developed to create a live organism vaccine using the sporozoites (SPZ) of the parasite Plasmodium falciparum (Pf), which are concentrated in the salivary glands of infected mosquitoes. Current manual dissection methods to obtain these PfSPZ are not optimally efficient for large-scale vaccine production. We demonstrate the automation of a key step in this production process, the picking and placing of mosquitoes from a staging apparatus into a dissection assembly. This unit test of a robotic mosquito pick-and-place system is performed using a custom-designed micro-gripper attached to a four degree of freedom (4-DOF) robot under the guidance of a computer vision system. Mosquitoes are autonomously grasped from a mesh platform and pulled to a pair of notched dissection blades to remove the head of the mosquito, allowing access to the salivary glands. Placement into these blades is adapted based on output from computer vision to accommodate for the unique anatomy and orientation of each grasped mosquito. In this pilot test of the system on 50 mosquitoes, we demonstrate a 100% grasping accuracy and a 90% accuracy in placing the mosquito with its neck within the blade notches such that the head can be removed. This is a promising result for this difficult and non-standard pick-and-place task. An analysis of the failure cases provides insights for improvements to be implemented as this robotic pick-and-place system is integrated into a larger automated mosquito dissection system under development.
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