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Time‐Controlled Authentication Strategies for Molecular Information Transfer

Minghao Hu, Mengyao Yang, Xianzhi Cheng, Tongbo Wu

2024Small11 citationsDOIOpen Access PDF

Abstract

Modern cryptography based on computational complexity theory is mainly constructed with silicon-based circuits. As DNA nanotechnology penetrates the molecular domain, utilizing molecular cryptography for data access protection in the biomolecular domain becomes a unique approach to information security. However, building security devices and strategies with robust security and compatibility is still challenging. Here, this study reports a time-controlled molecular authentication strategy using DNAzyme and DNA strand displacement as the basic framework. A time limit exists for authorization and access, and this spontaneous shutdown design further protects secure access. Multiple hierarchical authentications, temporal Boolean logic authentication, and enzyme authentication strategies are constructed based on DNA networks'good compatibility and programmability. This study gives proof of concept for the detection and protection of bioinformation about single nucleotide variants and miRNA, highlighting their potential in biosensing and security protection.

Topics & Concepts

Computer scienceDNA computingAuthentication (law)CryptographyDeoxyribozymeComputer securityDNAComputer networkTheoretical computer scienceChemistryAlgorithmBiochemistryComputationAdvanced biosensing and bioanalysis techniquesDNA and Biological ComputingGold and Silver Nanoparticles Synthesis and Applications
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