Redox Interfaces for Electrochemically Controlled Protein–Surface Interactions: Bioseparations and Heterogeneous Enzyme Catalysis

Su, Xiao; Hübner, Jonas; Kauke, Monique J.; Dalbosco, Luiza; Thomas, Jonathan C.; Gonzalez, Christopher C.; Zhu, Eric F.; Franzreb, Matthias; Jamison, Timothy F.; Hatton, T. Alan

doi:10.1021/acs.chemmater.7b01699

Cited by 38 publications

(26 citation statements)

References 63 publications

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“…Membrane separation is a frequently used energy-efficient tool in water purification, while other separation techniques such as electrochemical separations of redox-electrodes have been successfully developed. [221][222][223][224] The membrane separation process includes microfiltration (MF), ultrafiltration (UF), nanofiltration (NF), reverse osmosis (RO), and forward osmosis (FO) according to their pore sizes. MF membranes with large surface pores are capable of removing large particles and microorganisms.…”

Section: Membrane Separationmentioning

confidence: 99%

Emerging Functional Porous Polymeric and Carbonaceous Materials for Environmental Treatment and Energy Storage

Zheng

Lin

Zhang

et al. 2019

Adv Funct Materials

196

118

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The demand for practical and cost-effective environmental treatment and energy storage materials is exploding. Porous polymeric and carbonaceous materials have attracted tremendous interest on account of their welldeveloped porosity and tunable surface chemistry. Functionalization of pore structures further enhances their properties for environmental treatment and energy storage. Herein, the procedures for functionalization of porous structures are introduced, including predesign and postsynthetic strategies. Subsequently, the important advancements of emerging porous polymers for environmental treatment in sorption (e.g., organic micropollutant adsorption, heavy metal ion removal, radionuclide extraction, and oil absorption) and membrane separation (e.g., aqueous micropollutant separation, organic solvent nanofiltration, desalination and pervaporation), as well as for energy storage ranging from the electrodes and separators of batteries to supercapacitor electrodes are highlighted. Moreover, given the combined merits of high intrinsic conductivity, porosity, and physicochemical stability, novel polymer-based porous carbons for energy storage are also highlighted. Key functionalization chemistry for each application is discussed and an in-depth understanding of the structure-property relationships of these functional porous materials is provided. Finally, the challenges and perspectives of emerging functional porous polymeric and carbonaceous materials for environmental treatment and energy storage are proposed.

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Section: Membrane Separationmentioning

confidence: 99%

Emerging Functional Porous Polymeric and Carbonaceous Materials for Environmental Treatment and Energy Storage

Zheng

Lin

Zhang

et al. 2019

Adv Funct Materials

196

118

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“…The PVFc metallopolymer has recently been observed to exhibit redox‐mediated hydrogen bonding that imparts it with the ability to electrochemically separate organic carboxylate anions in both aqueous and organic solution with high separation factors of ≈100 in over 100‐fold excess competing electrolyte, [ 17 ] inorganic oxyanions from wastewater [ 18 ] and nuclear waste, [ 19 ] and even proteins. [ 20 ] As the activation of the redox‐species is mediated by an electrochemical stimulus, the process is reversible and desorption of adsorbed compounds can be accomplished via moderate electrochemical potential swings. This framework for targeted and electrochemically reversible separation has been applied to both organic micropollutants such as pharmaceuticals and personal care products and endocrine disruptors, [ 21 ] which are usually present in the ppt to ppb concentration ranges and inefficiently removed to varying degrees in wastewater plants, [ 22 ] as well as inorganic heavy metal contaminants, which are well‐known for their toxicity and carcinogenicity.…”

Section: Introductionmentioning

confidence: 99%

An Asymmetric Iron‐Based Redox‐Active System for Electrochemical Separation of Ions in Aqueous Media

Tan

Hatton

2020

Adv Funct Materials

Self Cite

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Electrochemically mediated redox-active processes are gaining momentum as a promising liquid-phase separation technology. Compared to conventional systems, they offer potential benefits, such as smaller energy footprints, nondestructive operation, reversibility, and tunability for specific analyte removal, with clear applications to societal and industrial challenges like water treatment and chemical synthesis. An asymmetric Faradaic cell heterogeneously functionalized with a metallopolymer at the anode and a hexacyanoferrate material at the cathode is presented for the first time. The redox-active species' iron centers enhance the electrosorption of heavy metal oxyanions with up to 98% removal in the ppb range, and offer tunable operating windows as low as ≈0.1 V at ≈1 A m −2 . By avoiding water splitting, the hexacyanoferrate cathode imparts additional advantages, namely a fourfold reduction in adsorption energy requirements, full suppression of solution pH increase, and the ability to capture redox-active catalytic anions such as polyoxometalates without altering their bulk oxidation state. This hybrid framework of a polymeric ferrocene anode and crystalline hexacyanoferrate cathode allows for simultaneous and synergistic uptake of anions and cations, respectively, creating a new asymmetric scheme for water-based separations, with foreseeable future extension to fields such as ion-sensing, energy storage, and electrocatalysis.

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“…The voltage swings were shown to be as low as 0.6 V with a two‐electrode setup, and current efficiencies >98 % . The strong interaction of oxidized PVFc‐modified electrodes has also been extended for proteins, presumably interacting with the carboxylate functionalities of the proteins . The interactions and selectivity for proteins were shown to be more complex than that for small molecules, with a dependence based on charge distribution and the isoelectric point.…”

Section: Metallopolymers For Ion Capturingmentioning

confidence: 95%

Recent Trends in Metallopolymer Design: Redox‐Controlled Surfaces, Porous Membranes, and Switchable Optical Materials Using Ferrocene‐Containing Polymers

Gallei

Rüttiger

2018

Chemistry A European J

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Metallopolymers with metal functionalities are a unique class of functional materials. Their redox-mediated optoelectronic and catalytic switching capabilities, their outstanding structure formation and separation capabilities have been reported recently. Within this Minireview, the scope and limitations of intriguing ferrocene-containing systems will be discussed. In the first section recent advances in metallopolymer design will be given leading to a plethora of novel metallopolymer architectures. Discussed synthetic pathways comprise controlled and living polymerization protocols as well as surface immobilization strategies. In the following sections, we focus on recent advances and new applications for side-chain and main-chain ferrocene-containing polymers as (i) remote-switchable materials, (ii) smart surfaces, (iii) redox-responsive membranes, and some recent trends in (iv) photonic structures and (v) other optical applications.

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Redox Interfaces for Electrochemically Controlled Protein–Surface Interactions: Bioseparations and Heterogeneous Enzyme Catalysis

Cited by 38 publications

References 63 publications

Emerging Functional Porous Polymeric and Carbonaceous Materials for Environmental Treatment and Energy Storage

Emerging Functional Porous Polymeric and Carbonaceous Materials for Environmental Treatment and Energy Storage

An Asymmetric Iron‐Based Redox‐Active System for Electrochemical Separation of Ions in Aqueous Media

Recent Trends in Metallopolymer Design: Redox‐Controlled Surfaces, Porous Membranes, and Switchable Optical Materials Using Ferrocene‐Containing Polymers

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