Reusable Noncomplementary DNA-Based Neural Network

Reusable Noncomplementary DNA-Based Neural Network

Neural network computation is a cornerstone of modern artificial intelligence, with electronic software-based approaches achieving widespread success due to their ability to enable continuous, iterative learning on the same platform. DNA-based neural networks, with their potential advantages in vers...

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Bibliographic Details
Main Author: Chengjie Sun (1449106) (author)
Other Authors: Xiaoyang Liu (1815211) (author), Jiafeng Zhong (13026246) (author), Qin Zhou (239082) (author), Jianjun Cheng (646595) (author)
Published: 2025
Subjects:
Biophysics
Biotechnology
Computational Biology
Space Science
Environmental Sciences not elsewhere classified
Biological Sciences not elsewhere classified
Chemical Sciences not elsewhere classified
Information Systems not elsewhere classified
work pioneers reusability
weighting values modulated
raises operational costs
modern artificial intelligence
first successful demonstration
despite significant advancements
critical reusability challenge
based neural networks
based neural network
four input strands
implementing learning mechanisms
unprecedented noncomplementary dna
noncomplementary dna duplexes
molecular computing systems
noncomplementary “ winner
reusable noncomplementary dna
noncomplementary dna
reusable dna
based perceptron
traditional systems
four pairs
computing materials
learning capabilities
iterative learning
dna nucleobases
current dna
simply achieved
promising alternative
practical path
potential advantages
pattern recognition
energy efficiency
enable continuous
electronic software
duplex concentrations
displacement reactions
computation strategy
complementary pairing
also restricts
algorithm accuracy
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Summary:Neural network computation is a cornerstone of modern artificial intelligence, with electronic software-based approaches achieving widespread success due to their ability to enable continuous, iterative learning on the same platform. DNA-based neural networks, with their potential advantages in versatility, scalability, and energy efficiency, offer a promising alternative to traditional systems. However, despite significant advancements in pattern recognition and algorithm accuracy, current DNA-based neural networks, relying on the complementary pairing of DNA nucleobases, suffer from the nonreusability of their computing materials. This limitation not only raises operational costs but also restricts their capacity for implementing learning mechanisms. Here, we introduce an unprecedented noncomplementary DNA-based perceptron (NCP) computation strategy, marking the first successful demonstration of a reusable DNA-based neural network. We present a “tagging” strategy to facilitate the scaling-up of noncomplementary DNA-based neural network. We show that 4-bit molecular pattern recognition can be simply achieved through strand-displacement reactions between four input strands and four pairs of noncomplementary DNA duplexes in the NCP, with weighting values modulated by duplex concentrations. Furthermore, a noncomplementary “winner-take-all” module enables decision-making, as demonstrated in an “I Spy” game task. Most importantly, by utilizing removable input strands (lipid–oligonucleotide conjugates), our NCP-based neural network enables reliable multicycle computations, overcoming the critical reusability challenge in DNA-based neural network computation. This work pioneers reusability in DNA-based neural networks, offering a practical path to molecular computing systems with learning capabilities.

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