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Towards practical and robust DNA-based data archiving using the yin-yang codec system.

Zhi Ping1,2,3,4, Shihong Chen2,3,5, Guangyu Zhou6,7

  • 1BGI-Shenzhen, Shenzhen, China.

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|January 4, 2024
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This summary is machine-generated.

We developed the yin-yang codec, a novel DNA data storage method encoding two bits per nucleotide. This robust algorithm ensures high data recovery rates and compatibility with DNA synthesis and sequencing technologies.

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Area of Science:

  • Biotechnology
  • Bioinformatics
  • Data Storage

Background:

  • DNA offers exceptional durability and storage density for data.
  • Existing DNA data storage methods face challenges in biocompatibility and decoding accuracy.
  • Efficient bit-to-base transcoding is crucial for reliable DNA data storage.

Purpose of the Study:

  • To introduce a robust DNA transcoding algorithm, the yin-yang codec.
  • To enhance compatibility with DNA synthesis and sequencing.
  • To demonstrate high-fidelity data storage in vitro and in vivo.

Main Methods:

  • Developed the yin-yang codec, encoding two binary bits into one nucleotide using two rules.
  • Stored diverse file formats in vitro as oligo pools and in vivo as DNA fragments in yeast.
  • Utilized sequencing to assess data recovery rates and storage density.

Main Results:

  • The yin-yang codec achieved an average recovery rate of 99.9% above 10^4 molecule copies.
  • A recovery rate of 87.53% was achieved at low molecule copy numbers (≤10^2).
  • In vivo storage demonstrated a physical density approaching the theoretical maximum.

Conclusions:

  • The yin-yang codec provides a robust and reliable solution for DNA data storage.
  • This method significantly improves compatibility with current DNA technologies.
  • Demonstrated successful in vitro and in vivo data storage with high fidelity.