Biological agent detection with the use of an airborne biosensor

Field Analytical Chemistry and Technology Pub Date : 1999-01-01 DOI:10.1002/(SICI)1520-6521(1999)3:4/5<307::AID-FACT9>3.0.CO;2-M

G. Anderson, Keeley D. King, D. Cuttino, J. P. Whelan, F. Ligler, J. F. Mackrell, C. Bovais, David K. Indyke, R. Foch

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引用次数: 43

Abstract

The ability to identify aerosolized bacteria remotely with the use of a small unpiloted, all-electric aircraft was demonstrated. Swallow, an aircraft custom-built for the purpose of air-particle collection, was catapult-launched, flown by line of sight for 20-min missions, and recovered by landing on a short runway. Once airborne, the sensor payload, which included a particle collector, fluidics control unit, and biosensor, was activated. The sensor utilized was the Analyte 2000 fiber optic biosensor, which performs four simultaneous fluorescent sandwich immunoassays on the surface of tapered optical probes. Five-minute test cycles were conducted continuously and monitored at the ground station until the plane returned. Then Swallow and its sensor payload could be ready for additional flights within 30 min of landing. During the trial, Swallow successfully collected and identified an aerosolized bacterial sample. © 1999 John Wiley & Sons, Inc.* Field Analyt Chem Technol 3: 307–314, 1999

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利用机载生物传感器进行生物制剂检测

演示了使用小型无人驾驶全电动飞机远程识别雾化细菌的能力。“燕子”是一架专门为收集空气颗粒而设计的飞机，它是用弹射器发射的，在视线范围内飞行了20分钟，然后在一条短跑道上着陆。一旦升空，传感器的有效载荷，包括粒子收集器、流体控制单元和生物传感器，就会被激活。所使用的传感器是Analyte 2000光纤生物传感器，它可以在锥形光学探针表面同时进行四次荧光夹心免疫测定。在飞机返回之前，在地面站连续进行5分钟的测试并进行监测。然后，燕子和它的传感器载荷可以在着陆后30分钟内准备好进行额外的飞行。在试验中，Swallow成功地收集并鉴定了一种雾化的细菌样本。©1999 John Wiley & Sons, Inc.* Field analyst Chem technology 3: 307 - 314,1999

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Field Analytical Chemistry and Technology

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