2 article(s) from Arends, Isabel W C E
- Letter
- Published 26 Mar 2018
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Scheme 1: Enzymatic reaction schemes for the selective oxidation of trans-hex-2-enol. A: Alcohol dehydrogenas...
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Figure 1: Michaelis–Menten kinetics of the PeAAOx-catalysed oxidation of trans-hex-2-enol. Conditions: 50 mM ...
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Figure 2: The influence of the residence time on the conversion of trans-hex-2-enol (red squares) to trans-2-...
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Figure 3: Increasing the PeAAOx turnover numbers (TN) by increasing the residence time. Conditions: 6 mL flow...
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- Review
- Published 20 Feb 2018
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Figure 1: Chemical structure of UDCA.
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Figure 2: Chemical structures of bile acids and salts.
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Figure 3: Comparison between Wolff–Kishner and Mozingo reduction. Notably the overall chemical reaction is th...
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Figure 4: Reaction catalysed by the 12α-HSDH; the 12-OH group of CA or UCA is oxidized yielding 12-oxo-CDCA o...
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Figure 5: Epimerization reaction catalysed by the 7α-HSDH and 7β-HSDH; the 7α-OH group of CA (R = OH) or CDCA...
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Figure 6: Overview of the chemoenzymatic process for the production of UDCA from CA: The oxidation, reduction...
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Figure 7: Schematic representation of the flow reactor for the continuous conversion of CDCA to UDCA [93].
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Figure 8: Chemoenzymatic pathways for the formation of UDCA from CA that profit by the C7 hydroxylation activ...
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