Channel confined kinesin-microtubule biomolecular nanomotors

机译：通道受限的驱动蛋白-微管生物分子纳米马达

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Kinesins are molecular motors that move along microtubules, and provide a model system for force generation that can be exploited for kinesin-powered nano- and micro-machines. Microtubules are /spl sim/25 nm diameter cylindrical polymers of the protein tubulin and can be nm to /spl mu/m long. Kinesins bind to microtubules and use the energy of ATP hydrolysis to walk unidirectionally along them at speeds of /spl sim/1 /spl mu/m/s. In this work, we reverse the typical biological system and move microtubules along surfaces functionalized with kinesin motors. The microtubules then become potential transport vehicles for sensors and lab-on-a-chip applications. A key requirement for extracting useful work from this system is confinement and control of the movement of microtubules over kinesin coated surfaces.

机译：驱动蛋白是沿着微管运动的分子马达，并提供了用于产生力的模型系统，可将其用于驱动蛋白驱动的纳米和微型机器。微管是蛋白质微管蛋白的/ spl sim /直径为25 nm的圆柱形聚合物，长度可以为nm到/ spl mu / m。驱动蛋白与微管结合，并利用ATP水解的能量以/ spl sim / 1 / spl mu / m / s的速度单向移动。在这项工作中，我们颠倒了典型的生物系统，并使微管沿着用驱动蛋白马达功能化的表面移动。然后，微管成为传感器和芯片实验室应用的潜在运输工具。从该系统中提取有用功的关键要求是限制和控制微管在驱动蛋白涂层表面上的运动。

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《Device Research Conference, 2004. 62nd DRC. Conference Digest Includes 'Late News Papers' volume》|2004年|p.185-186|共2页
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Huang Y.M.; Uppalapati M.; Hancock W.O.; Jackson T.N.;
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中图分类无线电电子学、电信技术;
关键词
molecular biophysics; nanotechnology; micromotors; proteins; channel confined biomolecular nanomotors; kinesin-microtubule nanomotors; molecular motors; nanomachines; micromachines; tubulin protein cylindrical polymers; ATP hydrolysis energy; microtubule transport vehicles; sensor transport vehicles; lab-on-a-chip; microtubule confinement; microtubule movement control; kinesin coated surfaces; 25 nm; 1 micron/s;

机译：分子生物物理学;纳米技术;微电机;蛋白质;通道受限生物分子纳米电机;驱动蛋白-微管纳米电机;分子电机;纳米机械;微机械;微管蛋白蛋白质圆柱形聚合物; ATP水解能;微管运输工具;传感器运输工具;芯片实验室;微管限制;微管运动控制;驱动蛋白包被的表面; 25 nm; 1 micron / s;

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机译：通道限制了Kinesin-微管生物分子纳米纳米
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Channel confined kinesin-microtubule biomolecular nanomotors

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