Synthesis and NMR analysis of 13 C and 15 N-labeled long-chain polyamines (LCPAs)
RSC Advances, 2016•pubs.rsc.org
15N, 13C, or both isotope labels were introduced in selected positions of several LCPAs
containing 5, 11, or 13 nitrogens. The number of transformations during chemical synthesis
was minimized by coupling Fmoc-glycine-15N, Fmoc-glycine-1-13C, or Fmoc-β-alanine
simultaneously at both ends of the growing oligoamide chain on resin-linked norspermidine.
LCPAs containing 10–20 nitrogens are the main organic constituent of diatom biosilica.
Preliminary NMR studies of bioinspired silica nanocomposites obtained from double-labeled …
containing 5, 11, or 13 nitrogens. The number of transformations during chemical synthesis
was minimized by coupling Fmoc-glycine-15N, Fmoc-glycine-1-13C, or Fmoc-β-alanine
simultaneously at both ends of the growing oligoamide chain on resin-linked norspermidine.
LCPAs containing 10–20 nitrogens are the main organic constituent of diatom biosilica.
Preliminary NMR studies of bioinspired silica nanocomposites obtained from double-labeled …
15N, 13C, or both isotope labels were introduced in selected positions of several LCPAs containing 5, 11, or 13 nitrogens. The number of transformations during chemical synthesis was minimized by coupling Fmoc-glycine-15N, Fmoc-glycine-1-13C, or Fmoc-β-alanine simultaneously at both ends of the growing oligoamide chain on resin-linked norspermidine. LCPAs containing 10–20 nitrogens are the main organic constituent of diatom biosilica. Preliminary NMR studies of bioinspired silica nanocomposites obtained from double-labeled LCPA 14 and 29Si-enriched orthosilicic acid identified the close spatial arrangement of 29Si and 13C nuclei.
The Royal Society of Chemistry