Department of Computer Science, The University of Tokyo , 7-3-1 Hongo, Bunkyo-ku, Tokyo 113-8656, Japan .
Acc Chem Res. 2014 Jun 17;47(6):1681-90. doi: 10.1021/ar400318d. Epub 2014 Jun 6.
What we can call a molecular robot is a set of molecular devices such as sensors, logic gates, and actuators integrated into a consistent system. The molecular robot is supposed to react autonomously to its environment by receiving molecular signals and making decisions by molecular computation. Building such a system has long been a dream of scientists; however, despite extensive efforts, systems having all three functions (sensing, computation, and actuation) have not been realized yet. This Account introduces an ongoing research project that focuses on the development of molecular robotics funded by MEXT (Ministry of Education, Culture, Sports, Science and Technology, Japan). This 5 year project started in July 2012 and is titled "Development of Molecular Robots Equipped with Sensors and Intelligence". The major issues in the field of molecular robotics all correspond to a feedback (i.e., plan-do-see) cycle of a robotic system. More specifically, these issues are (1) developing molecular sensors capable of handling a wide array of signals, (2) developing amplification methods of signals to drive molecular computing devices, (3) accelerating molecular computing, (4) developing actuators that are controllable by molecular computers, and (5) providing bodies of molecular robots encapsulating the above molecular devices, which implement the conformational changes and locomotion of the robots. In this Account, the latest contributions to the project are reported. There are four research teams in the project that specialize on sensing, intelligence, amoeba-like actuation, and slime-like actuation, respectively. The molecular sensor team is focusing on the development of molecular sensors that can handle a variety of signals. This team is also investigating methods to amplify signals from the molecular sensors. The molecular intelligence team is developing molecular computers and is currently focusing on a new photochemical technology for accelerating DNA-based computations. They also introduce novel computational models behind various kinds of molecular computers necessary for designing such computers. The amoeba robot team aims at constructing amoeba-like robots. The team is trying to incorporate motor proteins, including kinesin and microtubules (MTs), for use as actuators implemented in a liposomal compartment as a robot body. They are also developing a methodology to link DNA-based computation and molecular motor control. The slime robot team focuses on the development of slime-like robots. The team is evaluating various gels, including DNA gel and BZ gel, for use as actuators, as well as the body material to disperse various molecular devices in it. They also try to control the gel actuators by DNA signals coming from molecular computers.
我们所谓的分子机器人是指一组分子器件,如传感器、逻辑门和执行器,它们被集成到一个一致的系统中。分子机器人应该能够通过接收分子信号并通过分子计算做出决策来自主地对其环境做出反应。长期以来,科学家们一直梦想着构建这样的系统;然而,尽管付出了广泛的努力,具有这三种功能(传感、计算和执行)的系统尚未实现。本账户介绍了由日本文部科学省(MEXT)资助的一个正在进行的分子机器人研究项目。该 5 年项目于 2012 年 7 月启动,名为“具有传感器和智能的分子机器人的开发”。分子机器人领域的主要问题都对应于机器人系统的反馈(即计划-执行-观察)循环。更具体地说,这些问题是(1)开发能够处理各种信号的分子传感器,(2)开发信号放大方法以驱动分子计算设备,(3)加速分子计算,(4)开发可由分子计算机控制的执行器,以及(5)提供封装上述分子器件的分子机器人主体,从而实现机器人的构象变化和运动。在本账户中,报告了该项目的最新贡献。该项目有四个研究团队,分别专注于传感、智能、变形虫样执行器和粘液样执行器。分子传感器团队专注于开发能够处理各种信号的分子传感器。该团队还在研究从分子传感器放大信号的方法。分子智能团队正在开发分子计算机,目前专注于一种新的光化学技术,以加速基于 DNA 的计算。他们还介绍了设计此类计算机所需的各种分子计算机背后的新型计算模型。变形虫机器人团队旨在构建变形虫样机器人。该团队正试图将包括驱动蛋白和微管(MTs)在内的马达蛋白用作执行器,将其作为机器人主体置于脂质体隔室中。他们还在开发一种将基于 DNA 的计算和分子马达控制联系起来的方法。粘液机器人团队专注于开发粘液样机器人。该团队正在评估各种凝胶,包括 DNA 凝胶和 BZ 凝胶,用作执行器,以及用于分散各种分子器件的主体材料。他们还试图通过来自分子计算机的 DNA 信号来控制凝胶执行器。
