Munoz-garcia, Juan C. , Moscoso, Francisco G. , Sanchez-fernandez, Elena M. , SANTOS GARCÍA, JENIFER, Angulo, Jesus , Carrillo-Carrion, Carolina
No
Angew Chem Int Ed Engl
Article
Científica
19/01/2026
001664545100001
Understanding and controlling the formation mechanisms of metal-organic gels is crucial for their rational design with well-defined properties for diverse applications. However, rapid methodologies enabling atomic-resolution structural characterization of gel formation are still largely lacking. Here, we report for the first time the molecular-level characterization of the in-situ formation of a Zr-based metal-organic gel by monitoring solvent structuration during gelation using solvent-observed nuclear magnetic resonance (NMR) spectroscopy. UiO-66-type gels were optimized under mild conditions, i.e., 40 degrees C and in the absence of acidic modulators, providing a biocompatible environment suitable for the in-situ encapsulation of sensitive biomolecules during gelation. The combined analysis of saturation transfer difference and spin diffusion transfer difference NMR growth curves enabled real time monitoring of nucleation and gelation stages, revealing an excellent correlation between the progressive structuration of water within the gel network and the resulting macroscopic properties. Furthermore, we demonstrate that this NMR approach allows tracking of the in-situ encapsulation of therapeutic biomolecules within the gel, exemplified by a glycolipid with anti-inflammatory properties.
Carbohydrate-based drugs; Metal-organic gels; NMR spectroscopy; Spin diffusion transfer difference NMR; Water structuration