Towards Optimal DNA-Templated Computing

Jakob L. Andersen; Christoph Flamm; Martin M. Hanczyc; Daniel Merkle

Towards Optimal DNA-Templated Computing

Jakob L. Andersen, Christoph Flamm, Martin M. Hanczyc, Daniel Merkle

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › peer review

Abstract

Using DNA-templated synthesis, reactants are attached to DNA strands and complementary DNA strands are used to control the reaction towards a goal compound. This very general, simple, and still efficient approach has proven to be successful for the design of complex one-pot synthesis for a large variety of compounds. For a given goal compound many different synthesis plans may exist, and all of them can potentially be implemented with many different DNA-templated programs. This raises the issue of how to automatically infer optimal low-level programs based on a high-level synthesis plan or a goal compound only. In this paper we will introduce a computational approach for DNAtemplated synthesis based on graph rewriting approaches and the systematic exploration of chemical spaces. We will use them for verification of correctness of real-world synthesis plans as well as to illustrate the non-triviality of finding an optimal DNA assembler program.

Originalsprog	Engelsk
Tidsskrift	International Journal of Unconventional Computing
Vol/bind	11
Udgave nummer	3-4
Sider (fra-til)	185-203
ISSN	1548-7199
Status	Udgivet - 2015

Dokumenter og links

http://www.oldcitypublishing.com/journals/ijuc-home/ijuc-issue-contents/ijuc-volume-11-number-3-4-2015/ijuc-11-3-4-p-185-203/

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ALife 14
Andersen, J. L. (Deltager)
30. jul. 2014 → 2. aug. 2014
Aktivitet: Deltagelse i faglig begivenhed › Organisering af eller deltagelse i konference

Citationsformater

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title = "Towards Optimal DNA-Templated Computing",

abstract = "Using DNA-templated synthesis, reactants are attached to DNA strands and complementary DNA strands are used to control the reaction towards a goal compound. This very general, simple, and still efficient approach has proven to be successful for the design of complex one-pot synthesis for a large variety of compounds. For a given goal compound many different synthesis plans may exist, and all of them can potentially be implemented with many different DNA-templated programs. This raises the issue of how to automatically infer optimal low-level programs based on a high-level synthesis plan or a goal compound only. In this paper we will introduce a computational approach for DNAtemplated synthesis based on graph rewriting approaches and the systematic exploration of chemical spaces. We will use them for verification of correctness of real-world synthesis plans as well as to illustrate the non-triviality of finding an optimal DNA assembler program.",

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year = "2015",

language = "English",

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pages = "185--203",

journal = "International Journal of Unconventional Computing",

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TY - JOUR

T1 - Towards Optimal DNA-Templated Computing

AU - Andersen, Jakob L.

AU - Flamm, Christoph

AU - Hanczyc, Martin M.

AU - Merkle, Daniel

PY - 2015

Y1 - 2015

N2 - Using DNA-templated synthesis, reactants are attached to DNA strands and complementary DNA strands are used to control the reaction towards a goal compound. This very general, simple, and still efficient approach has proven to be successful for the design of complex one-pot synthesis for a large variety of compounds. For a given goal compound many different synthesis plans may exist, and all of them can potentially be implemented with many different DNA-templated programs. This raises the issue of how to automatically infer optimal low-level programs based on a high-level synthesis plan or a goal compound only. In this paper we will introduce a computational approach for DNAtemplated synthesis based on graph rewriting approaches and the systematic exploration of chemical spaces. We will use them for verification of correctness of real-world synthesis plans as well as to illustrate the non-triviality of finding an optimal DNA assembler program.

AB - Using DNA-templated synthesis, reactants are attached to DNA strands and complementary DNA strands are used to control the reaction towards a goal compound. This very general, simple, and still efficient approach has proven to be successful for the design of complex one-pot synthesis for a large variety of compounds. For a given goal compound many different synthesis plans may exist, and all of them can potentially be implemented with many different DNA-templated programs. This raises the issue of how to automatically infer optimal low-level programs based on a high-level synthesis plan or a goal compound only. In this paper we will introduce a computational approach for DNAtemplated synthesis based on graph rewriting approaches and the systematic exploration of chemical spaces. We will use them for verification of correctness of real-world synthesis plans as well as to illustrate the non-triviality of finding an optimal DNA assembler program.

M3 - Journal article

SN - 1548-7199

VL - 11

SP - 185

EP - 203

JO - International Journal of Unconventional Computing

JF - International Journal of Unconventional Computing

IS - 3-4

ER -

Towards Optimal DNA-Templated Computing

Abstract

Dokumenter og links

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ALife 14

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