Morgan McKee scite author profile

Morgan McKee

5Publications

43Citation Statements Received

70Citation Statements Given

How they've been cited

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143

Affiliations

Université de Montréal, Swansea University

Publications

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Ultrastructural characterization and immunolocalization of osteopontin in rat calvarial osteoblast primary cultures

Nanci

Zalzal

Gotoh

et al. 1996

Microsc. Res. Tech.

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As part of ongoing studies aimed at clarifying the early events of bone matrix deposition and mineralization, we have characterized primary osteoblast cultures using ultrastructural and immunocytochemical methods. Osteogenic cells were isolated by sequential enzymatic digestion of newborn rat (2-4-day-old) calvariae and grown for periods of 7 to 28 days on polystyrene, Thermanox plastic, or sputtered titanium. Bone-like nodules, showing a stratified organization of cells and collagen, were examined by scanning and transmission electron microscopy, and further characterized for mineral by backscattered electron imaging and X-ray microanalysis. Colloidal gold immunocytochemistry was used to examine the distribution of osteopontin in these nodules. Cells at the surface of the nodules were rounded, while those within the nodules generally appeared more flattened. Both cell types, particularly at early culture intervals, exhibited well-developed protein synthetic organelles. Collagen fibrils were present between the cell layers and some individual fibrils appeared mineralized. Aggregates of needle-shaped crystallites were sometimes apposed to the cell surface, frequently within invaginated regions of the cell membrane, while other mineralized masses of various sizes were present within the collagenous scaffolding. The periphery of the mineralized masses was often delimited by an electron-dense, lamina limitans-like layer. Focal accumulations and/or a more complete layer of afibrillar, mineralized organic matrix were sometimes observed at the interface between the cells and the surface of the culture dish. Osteopontin was immunodetected over the afibrillar and collagenous mineralized matrix throughout the cultures and, in some cases, labeling was concentrated over the peripheral, electron-dense material delimiting the mineralized masses. In conclusion, these data indicate that calvaria-derived osteoblasts produce an extracellular matrix with structural and compositional similarities to bone. Although not a regular observation, the accumulation of osteopontin on the surface of the culture substrate and at the periphery of masses of mineralized matrix may be analogous to what takes place in vivo at naturally occurring bone interfaces.

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Solvent-controlled O₂ diffusion enables air-tolerant solar hydrogen generation

Allan

McKee

Marken

et al. 2021

Energy Environ. Sci.

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Oxy-reductive C-N bond formation via pulsed electrolysis

Zhang

Al‐Mahayni

Aguiar

et al. 2022

Preprint

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Co-electrolysis of CO2 with simple N-species is an appealing route to sustainable fabrication of C-N bond containing products. A prominent challenge in, the area is to promote the C-N coupling step in place of the established CO2 reduction pathways. This can be particularly difficult when relying on solution-based species (e.g., NH3) to intercept intermediates that are continually being reduced on heterogeneous catalyst surfaces. In light of this, we introduce pulsed electrocatalysis as a tool for C-N bond formation. The reaction routes opened through this method involve both partial reduction and partial oxidation of separate reactants on the same catalyst surface in parallel to co-adsorb their activated intermediates proximal to one another. Using the CO2 and NH3 as model reactants, the end result is an enhancement of selectivity and formation rates for C-N bond containing products (urea, formamide, acetamide, methylamine) by factors of 3-20 as compared to static electrolysis in otherwise identical conditions. An array of operando measurements and computational modelling was carried out to pinpoint the key factors behind this performance enhancement. Finally, the oxy-reductive coupling strategy was extended to additional carbon and nitrogen reactants as well as applied to boost electrochemical C-S coupling.

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Hydrophobic molecular assembly at the gas-liquid-solid interface drives highly selective CO2 electromethanation

McKee

Kutter

Lentz

et al. 2023

Preprint

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The modularity of molecular catalysts enables the tuning of both active site and peripheral units to maximize functionality, thus rendering them as ideal model systems to explore fundamental concepts in catalysis. Hydrophobicity is often regarded as an undesirable aspect that hinders their dissolution in aqueous electrolytes. In contrast, we modified established Co terpyridine catalysts with hydrophobic perfluorinated alkyl side chains and took advantage of their hydrophobic character by utilizing them not as dissolved species in an aqueous electrolyte but at the gas-liquid-solid interfaces on a gas diffusion electrode (GDE) applied towards the electrochemical reduction of CO2. We found that the self-assembly of these perfluorinated units on the GDE surface results in a catalytic system selective for CH4 production, whereas every other Co terpyridine catalyst reported before was only selective for CO or formate. An array of mechanistic and operando spectroscopic investigations suggests a mechanism in which the pyridine units function as proton shuttles that deliver protons to the dynamic hydrophobic pocket in which CO2 reduction takes place. Finally, optimizing the system by integrating fluorinated carbon nanotubes as a hydrophobic conductive scaffold leads to a Faradaic efficiency for CH4 production above 80% at rates above 10 mA/cm2, thus far unprecedented for a molecular electrocatalytic system.

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Emerging opportunities with metal-organic framework electrosynthetic platforms

Kuruvinashetti

Zhang

et al. 2022

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The development of electrochemical technologies is becoming increasingly important due to their growing part in renewable energy conversion and storage. Within this context, metal organic frameworks (MOFs) are finding an important role as electrocatalysts. Specifically, their molecularly defined structure across several lengths scales endows them functionality not accessible with conventional heterogeneous catalysts. To this end, this perspective will focus on the unique features within MOFs and their analogs that enable them to carry out electrocatalytic reactions in unique ways to synthesize fuels and value-added chemicals from abundant building blocks like CO2 and N2. We start with a brief overview of the initial advent of MOF electrocatalysts prior to moving to overview the forefront of the field of MOF-based electrosynthesis. The main discussion focuses on three principal directions in MOF-based electrosynthesis: multifunctional active sites, electronic modulation, and catalytic microenvironments. To conclude, we identify several challenges in the next stage of MOF electrocatalyst development and offer several key directions to take as the field matures.

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Morgan McKee

Ultrastructural characterization and immunolocalization of osteopontin in rat calvarial osteoblast primary cultures

Solvent-controlled O₂ diffusion enables air-tolerant solar hydrogen generation

Oxy-reductive C-N bond formation via pulsed electrolysis

Hydrophobic molecular assembly at the gas-liquid-solid interface drives highly selective CO2 electromethanation

Emerging opportunities with metal-organic framework electrosynthetic platforms

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About

Morgan McKee

Ultrastructural characterization and immunolocalization of osteopontin in rat calvarial osteoblast primary cultures

Solvent-controlled O2 diffusion enables air-tolerant solar hydrogen generation

Oxy-reductive C-N bond formation via pulsed electrolysis

Hydrophobic molecular assembly at the gas-liquid-solid interface drives highly selective CO2 electromethanation

Emerging opportunities with metal-organic framework electrosynthetic platforms

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Solvent-controlled O₂ diffusion enables air-tolerant solar hydrogen generation