Low cost DNA data storage using photolithographic synthesis and advanced information reconstruction and error correction

Due to its longevity and enormous information density, DNA is an attractive medium for archival storage. The current hamstring of DNA data storage systems—both in cost and speed—is synthesis. The key idea for breaking this bottleneck pursued in this work is to move beyond the low-error and expensive...

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Vydané v:Nature communications Ročník 11; číslo 1; s. 5345 - 10
Hlavní autori: Antkowiak, Philipp L., Lietard, Jory, Darestani, Mohammad Zalbagi, Somoza, Mark M., Stark, Wendelin J., Heckel, Reinhard, Grass, Robert N.
Médium: Journal Article
Jazyk:English
Vydavateľské údaje: London Nature Publishing Group UK 22.10.2020
Nature Publishing Group
Nature Portfolio
Predmet:
49/23
631/553/2720
631/61/338/552
639/705/117
639/705/258
Algorithms
Base Sequence
Chemistry Techniques, Synthetic - methods
Data recovery
Data storage
Deoxyribonucleic acid
DNA
DNA - chemical synthesis
DNA - chemistry
DNA - genetics
DNA biosynthesis
Error correction
Gene Library
Humanities and Social Sciences
Information storage
Information Storage and Retrieval - methods
Light
Monte Carlo Method
multidisciplinary
Oligonucleotide Array Sequence Analysis - methods
Photochemical Processes
Photolithography
Reconstruction
Science
Science (multidisciplinary)
Sequence Analysis, DNA
Solid phase methods
Solid phase synthesis
Solid phases
Storage systems
ISSN:2041-1723, 2041-1723
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Shrnutí:Due to its longevity and enormous information density, DNA is an attractive medium for archival storage. The current hamstring of DNA data storage systems—both in cost and speed—is synthesis. The key idea for breaking this bottleneck pursued in this work is to move beyond the low-error and expensive synthesis employed almost exclusively in today’s systems, towards cheaper, potentially faster, but high-error synthesis technologies. Here, we demonstrate a DNA storage system that relies on massively parallel light-directed synthesis, which is considerably cheaper than conventional solid-phase synthesis. However, this technology has a high sequence error rate when optimized for speed. We demonstrate that even in this high-error regime, reliable storage of information is possible, by developing a pipeline of algorithms for encoding and reconstruction of the information. In our experiments, we store a file containing sheet music of Mozart, and show perfect data recovery from low synthesis fidelity DNA. The current bottleneck for DNA data storage systems is the cost and speed of synthesis. Here, the authors use inexpensive, massively parallel light-directed synthesis and correct for a high error rate with a pipeline of encoding and reconstruction algorithms.
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ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-020-19148-3