Scalable synthesis of sequence-defined, unimolecular macromolecules by Flow-IEG

Leibfarth, Frank A.; Johnson, Jeremiah A.; Jamison, Timothy F.

doi:10.1073/pnas.1508599112

Cited by 162 publications

(120 citation statements)

References 48 publications

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“…Directly inspired by biologically accessible DNA systems—for example, nucleobase-coded chains—sequence-defined macromolecules have been synthesized employing template-based coding strategies26272829 or via the generation of regulated sequence alternating thymine hybrid polymers30, as well as the design of reactions with iterative protection/deprotection steps on supports3132. Further, bulk reactions have been conducted in flow systems based on iterative synthesis33. In addition, iterative exponential growth can lead to sequence-defined macromolecules343536.…”

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confidence: 99%

Coding and decoding libraries of sequence-defined functional copolymers synthesized via photoligation

et al. 2016

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Designing artificial macromolecules with absolute sequence order represents a considerable challenge. Here we report an advanced light-induced avenue to monodisperse sequence-defined functional linear macromolecules up to decamers via a unique photochemical approach. The versatility of the synthetic strategy—combining sequential and modular concepts—enables the synthesis of perfect macromolecules varying in chemical constitution and topology. Specific functions are placed at arbitrary positions along the chain via the successive addition of monomer units and blocks, leading to a library of functional homopolymers, alternating copolymers and block copolymers. The in-depth characterization of each sequence-defined chain confirms the precision nature of the macromolecules. Decoding of the functional information contained in the molecular structure is achieved via tandem mass spectrometry without recourse to their synthetic history, showing that the sequence information can be read. We submit that the presented photochemical strategy is a viable and advanced concept for coding individual monomer units along a macromolecular chain.

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confidence: 99%

Coding and decoding libraries of sequence-defined functional copolymers synthesized via photoligation

et al. 2016

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“…However,t he transition of these syntheses to automated, programmable, and high-throughput operating systemsi s ac hallenging step neededt ot ranslate the vast potential of precision polymers into machine-programmablep olymers for biological and functional applications.C haingrowth polymerizations are particularlya ppealing for their ability to form structurallya nd chemically well-defined macromolecules through living/controlled polymerization techniques. We, ando thers, [7] believe that automation,allowing adegree of programmability,w ill play ak ey role in new material discoverya nd polymer bio-mimicry.We envisaged that for access to the most diverser ange of polymer architecturesa nd molecular structures ac hain-growth polymerization wouldb eb est suited.P articularly,l iving or controlledp olymerizations that retain an active chain-end are appealing owingt ot heir ability to be easily reactivated if am ultistep reaction is required. To develop aproof-of-concept of aframework polymerization technique that is readily amenable to automation requires several key characteristics.I nt his study, an ew approach is described that is believed to meet these requirements, thus openinga venues toward automated polymers ynthesis.…”

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confidence: 99%

Fenton‐RAFT Polymerization: An “On‐Demand” Chain‐Growth Method

Reyhani

McKenzie

Ranji‐Burachaloo

et al. 2017

Chemistry A European J

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Fine control over the architecture and/or microstructure of synthetic polymers is fast becoming a reality owing to the development of efficient and versatile polymerization techniques and conjugation reactions. However, the transition of these syntheses to automated, programmable, and high-throughput operating systems is a challenging step needed to translate the vast potential of precision polymers into machine-programmable polymers for biological and functional applications. Chain-growth polymerizations are particularly appealing for their ability to form structurally and chemically well-defined macromolecules through living/controlled polymerization techniques. Even using the latest polymerization technologies, the macromolecular engineering of complex functional materials often requires multi-step syntheses and purification of intermediates, and results in sub-optimal yields. To develop a proof-of-concept of a framework polymerization technique that is readily amenable to automation requires several key characteristics. In this study, a new approach is described that is believed to meet these requirements, thus opening avenues toward automated polymer synthesis.

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“…Modifying each monomer's chemical side-chains between cycles adds complexity, and a semi-automated system can make the process less laborious 12 .…”

Section: Boutique Polymersmentioning

confidence: 99%

The plastics revolution: how chemists are pushing polymers to new limits

Peplow¹

2016

Nature

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Scalable synthesis of sequence-defined, unimolecular macromolecules by Flow-IEG

Cited by 162 publications

References 48 publications

Coding and decoding libraries of sequence-defined functional copolymers synthesized via photoligation

Coding and decoding libraries of sequence-defined functional copolymers synthesized via photoligation

Fenton‐RAFT Polymerization: An “On‐Demand” Chain‐Growth Method

The plastics revolution: how chemists are pushing polymers to new limits

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