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Implementing Logic Gates by DNA Crystal Engineering.

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DNA self-assembly computation is attractive for its potential to perform massively parallel information processing at the molecular level while at the same time maintaining its natural biocompatibility. It has been… Click to show full abstract

DNA self-assembly computation is attractive for its potential to perform massively parallel information processing at the molecular level while at the same time maintaining its natural biocompatibility. It has been extensively studied at the individual molecule level, but not as much as ensembles in 3D. Here, we demonstrate the feasibility of implementing logic gates, the basic computation operations, in large ensembles: macroscopic, engineered 3D DNA crystals. The building blocks are recently developed DNA double crossover-like (DXL) motifs. They can associate with each other via sticky-end cohesion. By encoding the inputs within the sticky ends of the motifs, we are able to realize common logic gates. The outputs are demonstrated through the formation of macroscopic crystals that can be easily observed. This study points to a new direction of construction of complex 3D crystal architectures and DNA-based biosensors with easy readouts. This article is protected by copyright. All rights reserved.

Keywords: logic gates; gates dna; crystal engineering; dna crystal; implementing logic

Journal Title: Advanced materials
Year Published: 2023

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