CAREER: Achieving a Universal Stored-Program DNA Computer with a Buffered Power Supply

职业生涯：实现具有缓冲电源的通用存储程序 DNA 计算机

• 批准号: 2341011
• 负责人: Dominic Scalise
• 金额: $ 55.79万
• 依托单位: Washington State University
• 依托单位国家: 美国
• 项目类别: Continuing Grant
• 财政年份: 2024
• 资助国家: 美国
• 起止时间: 2024-02-01 至 2029-01-31
• 项目状态: 未结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=2341011&HistoricalAwards=false
• 关键词: CAREER; Achieving; Universal; Stored; Program

DNA computers can run programs outside of traditional electronics, integrating directly with materials, and enabling chemical control over physical matter. This novel technology has the potential to revolutionize diverse STEM fields, with applications such as intelligent medicine and nanofabrication. However, current DNA computer circuits have several key limitations. Most existing circuits have only enough energy to complete one round of computation. Additionally, current DNA circuits are hardcoded to perform a single task. Developing each new program requires constructing an entirely new circuit, which can take years. This project aims to address these limitations by developing a robust, high-power, easily programable, universal DNA computer to execute any task. Additionally, this project aims to integrate research with education to help grow the field of DNA computing. In this regard, the first comprehensive textbook in molecular programming will be produced to attract new researchers and pilot coursework at partner universities will be created for students to learn about molecular programming. A bridge for early career researchers will also be built to transfer chemical computing technology from academia to industry, fostering a more diverse, creative, and innovative engineering workforce. This project focuses on creating: (1) A robust DNA circuit, capable of running extremely high concentration reactions with reduced off-target activity; (2) High-energy DNA circuits with a chemical power supply capable of sustaining up to a hundred cycles of chemical computation; (3) Sequential DNA logic circuits; and (4) A universal DNA computer capable of executing software instructions stored in chemical memory, while the underlying chemical hardware can remain constant. The project represents a paradigm shift in chemical computing, enabling construction of DNA circuits with sustained dynamics while simplifying programming by separating the tasks of designing chemical hardware from writing chemical software. Successful completion of this project will enable novel research areas in high-concentration DNA computing, including construction of fundamental circuits such as flip-flops, robust oscillators, and universal stored-program hardware, dramatically simplifying the task of programming DNA computers and building towards programmable matter.This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

DNA计算机可以在传统电子设备之外运行程序，直接与材料集成，并实现对物理物质的化学控制。这项新技术有可能彻底改变STEM领域的各个领域，如智能医学和纳米制造。然而，目前的DNA计算机电路有几个关键的限制。大多数现有的电路只有足够的能量来完成一轮计算。此外，当前的DNA电路被硬编码为执行单一任务。开发每个新程序都需要构建一个全新的电路，这可能需要数年时间。这个项目旨在通过开发一个强大的、高功率的、易于编程的、通用的DNA计算机来解决这些限制，以执行任何任务。此外，该项目旨在将研究与教育相结合，以帮助发展DNA计算领域。在这方面，将制作第一本分子程序设计的综合教科书，以吸引新的研究人员，并将在合作大学创建试点课程，让学生学习分子程序设计。还将为早期职业研究人员建立一座桥梁，将化学计算技术从学术界转移到工业界，培养一支更加多样化、创造性和创新性的工程劳动力队伍。该项目的重点是创建：(1)一个强大的DNA电路，能够运行极高浓度的反应，降低脱靶活性；(2)具有能维持100次化学计算循环的化学电源的高能DNA电路；(3)序列DNA逻辑电路；(4)一种通用的DNA计算机，能够执行存储在化学存储器中的软件指令，而底层的化学硬件可以保持不变。该项目代表了化学计算的范式转变，能够构建具有持续动态的DNA电路，同时通过分离设计化学硬件和编写化学软件的任务来简化编程。该项目的成功完成将使高浓度DNA计算的新研究领域成为可能，包括构建基本电路，如触发器、鲁棒振荡器和通用存储程序硬件，极大地简化了编程DNA计算机的任务，并朝着可编程物质的方向发展。该奖项反映了美国国家科学基金会的法定使命，并通过使用基金会的知识价值和更广泛的影响审查标准进行评估，被认为值得支持。