Principles of Information Storage in Small-Molecule Mixtures

Rosenstein, Jacob K.; Rose, Christopher; Reda, Sherief; Weber, Peter M.; Kim, Eunsuk; Sello, Jason K.; Geiser, Joseph D.; Kennedy, Eamonn; Arcadia, Christopher E.; Dombroski, Amanda; Oakley, Kady; Chen, Shui Ling; Tann, Hokchhay; Rubenstein, Brenda M.

doi:10.1109/tnb.2020.2977304

Cited by 20 publications

(23 citation statements)

References 60 publications

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“…To date, demonstrations using DNA have reached about 214 petabytes per gram [32], although this is still orders of magnitude from theoretical limits [33]. An encoded metabolome written using a large small-molecule library could improve on this number [34], but our experiments highlight several limitations and potential benefits that warrant further discussion.…”

Section: Discussionmentioning

confidence: 90%

Encoding Information in Synthetic Metabolomes

Kennedy

Arcadia

Geiser

et al. 2019

Preprint

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Biomolecular information systems o↵er numerous potential advantages over conventional semiconductor technologies. Downstream from DNA, the metabolome is an informationrich molecular system with diverse chemical dimensions which could be harnessed for information storage and processing. As a proof of principle of postgenomic data storage, here we demonstrate a workflow for representing abstract data in synthetic metabolomes. Our approach leverages robotic liquid handling for writing digital information into chemical mixtures, and mass spectrometry for extracting the data. We present several kilobytescale image datasets stored in synthetic metabolomes, which are decoded with accuracy exceeding 98-99% using multi-mass logistic regression. Cumulatively, >100,000 bits of digital image data was written into metabolomes. These early demonstrations provide insight into the benefits and limitations of postgenomic chemical information systems.

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Section: Discussionmentioning

confidence: 90%

Encoding Information in Synthetic Metabolomes

Kennedy

Arcadia

Geiser

et al. 2019

Preprint

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“…Writing data as chemical mixtures. The composition of a chemical sample can represent abstract information, whether the sample consists of a single compound selected from a defined chemical space 17 , a pool of sequence-controlled polymers 4,13 , or a mixture of unique compounds 15 . With small molecule libraries, the most direct way to encode information is to use the presence or absence of each library element in a sample to represent one bit of data 14,39 .…”

Section: Resultsmentioning

confidence: 99%

“…While macromolecules will continue to be important for information systems, complementary small-molecule approaches can offer a number of potential advantages 13,15 . They do not require polymerization or enzymatic steps; they can be designed to resist cellular digestion 16 and extreme environmental conditions; and they can be economical to produce.…”

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confidence: 99%

Multicomponent molecular memory

et al. 2020

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Multicomponent reactions enable the synthesis of large molecular libraries from relatively few inputs. This scalability has led to the broad adoption of these reactions by the pharmaceutical industry. Here, we employ the four-component Ugi reaction to demonstrate that multicomponent reactions can provide a basis for large-scale molecular data storage. Using this combinatorial chemistry we encode more than 1.8 million bits of art historical images, including a Cubist drawing by Picasso. Digital data is written using robotically synthesized libraries of Ugi products, and the files are read back using mass spectrometry. We combine sparse mixture mapping with supervised learning to achieve bit error rates as low as 0.11% for single reads, without library purification. In addition to improved scaling of non-biological molecular data storage, these demonstrations offer an information-centric perspective on the high-throughput synthesis and screening of small-molecule libraries.

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“…The idea of chemical computing has a long history, inspired in part by the power, complexity, and energy efficiency of living systems 10,11 . Recent advances in molecular information storage [12][13][14][15][16][17] have brought these unconventional systems closer to reality and have renewed interest in chemical computing. Much of the research on molecular computing has focused on in vitro gene expression circuits 18,19 and DNA strand-displacement reactions [20][21][22] .…”

Section: Introductionmentioning

confidence: 99%