Minteer, Shelley D. - The University of Utah

个人简介

Western Illinois University, B.S. in Chemistry 1995 University of Iowa, Ph.D. in Chemistry 2000

研究领域

The Minteer Group focuses on improving the abiotic-biotic interface between biocatalysts and electrode surfaces for enhanced bioelectrocatalysis. These biocatalysts include microbial cells, organelles (mitochondria and thylakoid membranes), redox proteins, and oxidoreductase enzymes. We design electrode structures for enhanced flux at electrode surfaces for biosensor and biofuel cell applications. The group utilizes a variety of electroanalytical techniques (linear polarization, cyclic voltammetry, differential pulse voltammetry, differential pulse amperometry), as well as a variety of biological and spectroscopic techniques to accomplish these goals.

近期论文

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L. Lancaster, D.H. Hickey, M.S. Sigman, S.D. Minteer, and I. Wheeldon, “Bioinspired design of a hybrid bifunctional enzymatic/organic electrocatalyst for site selective alcohol oxidation,” ChemComm, 2018, 54, 491-494. K. Hendriks, S. Robinson, M. Braten, C. Sevov, B. Helms, M. Sigman, S. Minteer, and M. Sanford, “High-Performance Oligomeric Catholytes for Effective Macromolecular Separation in Nonaqueous Redox Flow Batteries,” ACS Central Science, 2018, 4(2), 189-196. S. Abdellaoui, F. Macazo, R. Cai, A. de Lacey, M. Pita, and S.D. Minteer, “Enzymatic Electrosynthesis of Alkanes via Bioelectrocatalytic Decarbonylation of Fatty Aldehydes,” Angewandte Chemie, 2018, 57, 2404-2408. R. Cai, R. Milton, S. Abdellaoui, T. Park, J. Patel, B. Alkotaini, and S.D. Minteer, “Electroenzymatic C-C bond formation from CO2,” Journal of the American Chemical Society, 2018, 140, 5041-5044. M. Yuan, S. Sahin, R. Cai, S. Abdellaoui, D.P. Hickey, S.D. Minteer, and R.D. Milton, “Creating a low-potential redox polymer for efficient electroenzymatic CO2 reduction,” Angewandte Chemie, 2018, 130, 6692-6696. S.L. Foster, S.I. Perez Bakovic, R. Duda, S. Maheshwari, R.D. Minteer, S.D. Minteer, M.J. Janik, J.N. Renner, and L.F. Greenlee, “Catalysts for Nitrogen Reduction to Ammonia,” Nature Catalysis, 2018, 1, 490-500. D.P. Hickey, K. Lim, R. Cai, A. Patterson, M. Yuan, S. Sahin, S. Abdellaoui, and S.D. Minteer, “Pyrene Hydrogel for Promoting Direct Bioelectrochemistry: ATP-Independent Electroenzymatic Reduction of N2,” Chemical Science, 2018, 9, 5172-5177. J. Kitt, D. Bryce, S.D. Minteer, and J. Harris, “Confocal Raman Microscopy for In-situ Measurement of Phospholipid-Water Partitioning into Model Phospholipid Bilayers within Individual Chromatographic Particles,” Analytical Chemistry, 2018, in press. R.D. Milton, R. Cai, S. Sahin, S. Abdellaoui, B. Alkotaini, D. Leech, and S.D. Minteer, “The In Vivo Potential-Regulated Protective Protein of Nitrogenase in Azotobacter vinelandii Supports Aerobic Bioelectrochemical Dinitro-gen Reduction In Vitro,” Journal of the American Chemical Society, 2017, 139, 9044-9052. R.D. Milton and S.D. Minteer, “Direct Enzymatic Bioelectrocatalysis: Differentiating Between Myth and Reality,” Journal of the Royal Society Interface, 2017, 14, 20170253. L. Xia, K. Nguyen, Y. Holade, H. Han, K. Dooley, P. Atanassov, S. Banta, and S.D. Minteer, “Improving the Performance of Methanol Biofuel Cells Utilizing an Enzyme Cascade Bioanode with DNA Bridged Substrate Channeling,” ACS Energy Letters, 2017, 2, 1435-1438. S. Abdellaoui, M. Snow, I. Matanovic, A. Stephens, P. Atanassov, and S.D. Minteer, “Hybrid Molecular/Enzymatic Catalytic Cascade for Complete Electro-oxidation of Glycerol Using a Promiscuous NAD-dependent Formate Dehydrogenase from Candida boidinii,” ChemComm, 2017, 53, 5368 - 5371. Y. Liu, D.P. Hickey, J.Y. Guo, E. Earl, S. Abdellaoui, R. Milton, M.S. Sigman, S.D. Minteer, and S. Calabrese Barton, “Substrate Channeling in an Artificial Metabolon: A Molecular Dynamics Blueprint for an Experimental Peptide Bridge,” ACS Catalysis, 2017, 7, 2486-93. M. Grattieri, N.D. Shivel, I. Sifat, M. Bestetti, and S.D. Minteer, “Sustainable Hypersaline Microbial Fuel Cells: Inexpensive Recyclable Polymer Supports for Carbon Nanotube Conductive Paint Anodes,” ChemSusChem, 2017, 10, 2053-2058. K. Knoche, K. Hasan, E. Aoyama, and S.D. Minteer, “Role of Nitrogenase and Ferredoxin in the Mechanism of Bioelectrocatalytic Nitrogen Fixation by the Cyanobacteria Anabaena variabilis SA-1 Mutant Immobilized on Indium Tin Oxide (ITO) Electrodes,” Electrochimica Acta, 2017, 232, 396-403. J. Kitt, D. Bryce, S.D. Minteer, and J.M. Harris, “Raman Spectroscopy Reveals Selective Interactions of Cytochrome c with Cardiolipin that Correlate with Membrane Permeability,” Journal of the American Chemical Society, 139(10), 3851-3860. K. Hasan, R. Milton, M. Grattieri, T. Wang, M. Stephanz, and S.D. Minteer, “Photobioelectrocatalysis of Intact Chloroplasts for Solar Energy Conversion,” ACS Catalysis, 2017, 7, 2257-2265. C. Serov, D.P. Hickey, M. Cook, S. Robinson, S. Barnett, S.D. Minteer, M.S. Sigman, and M. Sanford, “A Physical Organic Approach to Persistent, Cyclable, Low-Potential Electrolytes for Flow Battery Applications,” Journal of the American Chemical Society, 2017, 139, 2924-2927. R.D. Milton, R. Cai, S. Abdellaoui, D. Leech, A.L. De Lacey, M. Pita, and S.D. Minteer, “Bioelectrochemical Haber-Bosch Process: An Ammonia-Producing H2/N2 Fuel Cell,” Angewandte Chemie, 2017, 56(10), 2680-2683. R.D. Milton, S. Abdellaoui, D. Dean, L. Seefeldt, D. Leech, and S.D. Minteer, “Nitrogenase bioelectrocatalysis: heterogeneous ammonia and hydrogen production by MoFe protein,” Energy and Environmental Science, 2016, 9, 2550-2554. L. Pelster and S.D. Minteer, “Mitochondrial Inner Membrane Biomimic for the Investigation of Electron Transport Chain Supercomplex Bioelectrocatalysis,” ACS Catalysis, 2016, 6, 4995-4999. K. Knoche, D.P. Hickey, R.D. Milton, C. Curchoe, and S.D. Minteer, “Hybrid Glucose/O2 Biobattery and Supercapacitor Utilizing a Pseudocapacitive Dimethylferrocene Redox Polymer at the Bioanode,” ACS Energy Letters, 2016, 1, 380-385. B. Bulutoglu, K.E. Garcia, F. Wu, S.D. Minteer, and S. Banta, “Direct evidence for metabolon formation and substrate channeling in recombinant TCA cycle enzymes,” ACS Chemical Biology, 2016, 11, 2847-2853.