{"title":"利用 DNA 胶体晶体工程实现数字计算","authors":"Xiaoyu Liu, Dongbao Yao*, Yun Wang, Dian Ni, Wenqiang Hua*, Jie Tian, Liulin Yang, Haixin Lin, Haojun Liang and Zhaoxiang Deng*, ","doi":"10.1021/jacs.4c1207810.1021/jacs.4c12078","DOIUrl":null,"url":null,"abstract":"<p >Toehold-mediated strand displacement (TMSD) provides a versatile toolbox for developing DNA digital computing systems. Although different logic circuits with diverse functions have achieved good performance in terms of complexity and scalability, most previous DNA logic circuits perform information processing only at the molecular level, and nonspecific signal leakages are often difficult to avoid. Here, we demonstrate the feasibility of constructing leakless digital computing systems in three-dimensionally ordered colloidal supercrystals. These systems possess a unique signal leakage resistance by integrating different TMSD-based logic gates with the catalytic assembly of DNA-functionalized gold colloids. A complete set of basic Boolean logic gates and different cascaded logic circuits is constructed on the basis of the catalytic assembly strategy enabled by a facilely designed catassembler, where the output signals are recognized by determining whether specific colloidal supercrystals are formed or not. In addition, a half adder is built through a combination of XOR and AND logic gates with two distinct crystal types as readouts. Finally, a leakless two-digit DNA keypad lock for information security protection is demonstrated. The combination of TMSD-based logic circuits with the universal nanoparticle catalytic assembly offers the possibility to develop highly complicated and leakage-free digital computing systems and promotes macroscopic colloidal superlattice materials with programmable logic functions.</p>","PeriodicalId":49,"journal":{"name":"Journal of the American Chemical Society","volume":"146 44","pages":"30573–30583 30573–30583"},"PeriodicalIF":14.4000,"publicationDate":"2024-10-24","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Implementation of Digital Computing by Colloidal Crystal Engineering with DNA\",\"authors\":\"Xiaoyu Liu, Dongbao Yao*, Yun Wang, Dian Ni, Wenqiang Hua*, Jie Tian, Liulin Yang, Haixin Lin, Haojun Liang and Zhaoxiang Deng*, \",\"doi\":\"10.1021/jacs.4c1207810.1021/jacs.4c12078\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p >Toehold-mediated strand displacement (TMSD) provides a versatile toolbox for developing DNA digital computing systems. Although different logic circuits with diverse functions have achieved good performance in terms of complexity and scalability, most previous DNA logic circuits perform information processing only at the molecular level, and nonspecific signal leakages are often difficult to avoid. Here, we demonstrate the feasibility of constructing leakless digital computing systems in three-dimensionally ordered colloidal supercrystals. These systems possess a unique signal leakage resistance by integrating different TMSD-based logic gates with the catalytic assembly of DNA-functionalized gold colloids. A complete set of basic Boolean logic gates and different cascaded logic circuits is constructed on the basis of the catalytic assembly strategy enabled by a facilely designed catassembler, where the output signals are recognized by determining whether specific colloidal supercrystals are formed or not. In addition, a half adder is built through a combination of XOR and AND logic gates with two distinct crystal types as readouts. Finally, a leakless two-digit DNA keypad lock for information security protection is demonstrated. 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引用次数: 0
摘要
以托架为媒介的链置换(TMSD)为开发 DNA 数字计算系统提供了一个多功能工具箱。虽然具有不同功能的逻辑电路在复杂性和可扩展性方面都取得了良好的性能,但以往大多数 DNA 逻辑电路仅在分子水平上进行信息处理,非特异性信号泄漏往往难以避免。在这里,我们证明了在三维有序胶体超晶体中构建无泄漏数字计算系统的可行性。通过将基于 TMSD 的不同逻辑门与 DNA 功能化金胶体的催化组装集成在一起,这些系统具有独特的抗信号泄漏能力。在催化组装策略的基础上,通过设计简便的催化组装器,构建了一整套基本的布尔逻辑门和不同的级联逻辑电路,通过判断是否形成了特定的胶体超晶体来识别输出信号。此外,还通过 XOR 和 AND 逻辑门的组合构建了一个半加法器,并将两种不同类型的晶体作为读出器。最后,演示了一种用于信息安全保护的无泄漏两位数 DNA 键盘锁。基于 TMSD 的逻辑电路与通用纳米粒子催化组装的结合为开发高度复杂且无泄漏的数字计算系统提供了可能,并促进了具有可编程逻辑功能的宏观胶体超晶格材料的发展。
Implementation of Digital Computing by Colloidal Crystal Engineering with DNA
Toehold-mediated strand displacement (TMSD) provides a versatile toolbox for developing DNA digital computing systems. Although different logic circuits with diverse functions have achieved good performance in terms of complexity and scalability, most previous DNA logic circuits perform information processing only at the molecular level, and nonspecific signal leakages are often difficult to avoid. Here, we demonstrate the feasibility of constructing leakless digital computing systems in three-dimensionally ordered colloidal supercrystals. These systems possess a unique signal leakage resistance by integrating different TMSD-based logic gates with the catalytic assembly of DNA-functionalized gold colloids. A complete set of basic Boolean logic gates and different cascaded logic circuits is constructed on the basis of the catalytic assembly strategy enabled by a facilely designed catassembler, where the output signals are recognized by determining whether specific colloidal supercrystals are formed or not. In addition, a half adder is built through a combination of XOR and AND logic gates with two distinct crystal types as readouts. Finally, a leakless two-digit DNA keypad lock for information security protection is demonstrated. The combination of TMSD-based logic circuits with the universal nanoparticle catalytic assembly offers the possibility to develop highly complicated and leakage-free digital computing systems and promotes macroscopic colloidal superlattice materials with programmable logic functions.
期刊介绍:
The flagship journal of the American Chemical Society, known as the Journal of the American Chemical Society (JACS), has been a prestigious publication since its establishment in 1879. It holds a preeminent position in the field of chemistry and related interdisciplinary sciences. JACS is committed to disseminating cutting-edge research papers, covering a wide range of topics, and encompasses approximately 19,000 pages of Articles, Communications, and Perspectives annually. With a weekly publication frequency, JACS plays a vital role in advancing the field of chemistry by providing essential research.