Electrically Fueled Active Supramolecular Materials

Selmani, Serxho; Schwartz, Eric L.; Mulvey, Justin T; Wang, Hong; Grosvirt-Dramen, Adam; Gibson, Wyeth; Hochbaum, Allon I.; Patterson, Joseph P.; Ragan, Regina; Guan, Zhibin

doi:10.1021/jacs.2c01884

Cited by 41 publications

(73 citation statements)

References 43 publications

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“…The ultrasensitive response of the coacervates in our work is attributable to the competition of the reactive radicals between the methacrylate monomer and molecular oxygen. , As described above, molecular oxygen diffused from the air effectively quenches reactive radical species at a lower frequency to generate a threshold, whereas the amount of the radicals produced at a higher frequency becomes higher than that of molecular oxygen to proceed radical polymerization, resulting in the ultrasensitive response. Such an ultrasensitive response based on the competitive mechanism is considered as a new example of light-fueled dissipative systems. ,− To date, it has been reported that coacervates can provide a microenvironment to accelerate catalytic reactions mainly through molecular sequestration ,− and to realize stimulus responses towards reactive molecules ( e.g. , assembly–disassembly). ,,,,,− Compared with these examples, one of the important aspects of our work is to combine the rate enhancement effect with competitive inhibition via continuous supply of diffusing O 2 , which establishes a unique system in response to temporally distinct stimulus patterns.…”

Section: Resultsmentioning

confidence: 99%

Temporal Stimulus Patterns Drive Differentiation of a Synthetic Dipeptide-Based Coacervate

2022

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The fate of living cells often depends on their processing of temporally modulated information, such as the frequency and duration of various signals. Synthetic stimulus-responsive systems have been intensely studied for >50 years, but it is still challenging for chemists to create artificial systems that can decode dynamically oscillating stimuli and alter the systems’ properties/functions because of the lack of sophisticated reaction networks that are comparable with biological signal transduction. Here, we report morphological differentiation of synthetic dipeptide-based coacervates in response to temporally distinct patterns of the light pulse. We designed a simple cationic diphenylalanine peptide derivative to enable the formation of coacervates. The coacervates concentrated an anionic methacrylate monomer and a photoinitiator, which provided a unique reaction environment and facilitated light-triggered radical polymerizationeven in air. Pulsed light irradiation at 9.0 Hz (but not at 0.5 Hz) afforded anionic polymers. This dependence on the light pulse patterns is attributable to the competition of reactive radical intermediates between the methacrylate monomer and molecular oxygen. The temporal pulse pattern-dependent polymer formation enabled the coacervates to differentiate in terms of morphology and internal viscosity, with an ultrasensitive switch-like mode. Our achievements will facilitate the rational design of smart supramolecular soft materials and are insightful regarding the synthesis of sophisticated chemical cells.

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Section: Resultsmentioning

confidence: 99%

Temporal Stimulus Patterns Drive Differentiation of a Synthetic Dipeptide-Based Coacervate

2022

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“…[62,63] Besides molecular machines, the same strategy might be used to operate non-equilibrium supramolecular systems that rely on electrical energy, such as fiber-forming monomers. [37,41] Implementing the autonomous use of electrical energy by supramolecular assemblies to perform molecular motions advances our ability to control matter away from equilibrium. [9,64]…”

Section: Discussionmentioning

confidence: 99%

“…Efforts in this direction were recently reported in relation to the selfassembly of a cysteine derivative, which was modulated by controlling the potential of an electrode in the presence of a homogeneous reducing agent, leading to fibers formation under nonequilibrium conditions. [37] To address the outlined challenge, one possibility is to rely on redox-active oscillating systems, where the origin of the emergent phenomena is rooted in the kinetic control of redox reactions. Albeit prominent examples have been reported, [38][39][40][41] this approach suffers from limited flexibility and it is difficult to generalize since it critically relies on specific kinetic features of the oscillating system.…”

Section: Introductionmentioning

confidence: 99%

“…This goal is particularly relevant for self‐assembling systems, whose operation at the single‐molecule level has significant fundamental and technical limitations. Efforts in this direction were recently reported in relation to the self‐assembly of a cysteine derivative, which was modulated by controlling the potential of an electrode in the presence of a homogeneous reducing agent, leading to fibers formation under nonequilibrium conditions [37] …”

Section: Introductionmentioning

confidence: 99%

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Autonomous Non‐Equilibrium Self‐Assembly and Molecular Movements Powered by Electrical Energy**

et al. 2022

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The ability to exploit energy autonomously is one of the hallmarks of life. Mastering such processes in artificial nanosystems can open technological opportunities. In the last decades, light-and chemically driven autonomous systems have been developed in relation to conformational motion and self-assembly, mostly in relation to molecular motors. In contrast, despite electrical energy being an attractive energy source to power nanosystems, its autonomous harnessing has received little attention. Herein we consider an operation mode that allows the autonomous exploitation of electrical energy by a self-assembling system. Threading and dethreading motions of a pseudorotaxane take place autonomously in solution, powered by the current flowing between the electrodes of a scanning electrochemical microscope. The underlying autonomous energy ratchet mechanism drives the self-assembly steps away from equilibrium with a higher energy efficiency compared to other autonomous systems. The strategy is general and might be extended to other redoxdriven systems.

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“…Efforts in the past decade to mimic such out-of-equilibrium control in constructing molecular assemblies have yielded various forms of synthetic dissipative materials. Pioneering works in this area have demonstrated molecular assemblies driven by chemical reaction networks where the added fuel converts a precursor into an assembling or a disassembling species and a spontaneous chemical process (e.g., hydrolysis) reverts it to the precursor state. − In these systems, the chemical energy in the fuel temporarily produces a transient metastable species, while the fuel is converted into waste. − Other forms of energy to generate metastable states, including light, − and more recently, electricity, have been introduced to construct and control dissipative materials.…”

Section: Introductionmentioning

confidence: 99%

Sugar-Fueled Dissipative Living Materials

Selmani

Guan

et al. 2023

J. Am. Chem. Soc.

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Dissipative behaviors in biology are fuel-driven processes controlled by living cells, and they shape the structural and functional complexities in biological materials. This concept has inspired the development of various forms of synthetic dissipative materials controlled by time-dependent consumption of chemical or physical fuels, such as reactive chemical species, light, and electricity. To date, synthetic living materials featuring dissipative behaviors directly controlled by the fuel consumption of their constituent cells is unprecedented. In this paper, we report a chemical fuel-driven dissipative behavior of living materials comprising Staphylococcus epidermidis and telechelic block copolymers. The macroscopic phase transition is controlled by d-glucose which serves a dual role of a competitive disassembling agent and a biological fuel source for living cells. Our work is a significant step toward constructing a synthetic dissipative living system and provides a new tool and knowledge to design emergent living materials.

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Electrically Fueled Active Supramolecular Materials

Cited by 41 publications

References 43 publications

Temporal Stimulus Patterns Drive Differentiation of a Synthetic Dipeptide-Based Coacervate

Temporal Stimulus Patterns Drive Differentiation of a Synthetic Dipeptide-Based Coacervate

Autonomous Non‐Equilibrium Self‐Assembly and Molecular Movements Powered by Electrical Energy**

Sugar-Fueled Dissipative Living Materials

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