Polymorphic transient glycolipid assemblies with tunable lifespan and cargo release

Hypothesis: In living systems, dynamic processes like dissipative assembly, polymorph formation, and destabilization of hydrophobic domains play an indispensable role in the biochemical processes. Adaptation of biological self-assembly processes to an amphiphilic molecule leads to the fabrication of intelligent biomaterials with life-like behavior. Experiments: An amphiphilic glycolipid molecule was engineered into various dissipative assemblies (vesicles and supramolecular nanotube-composed hydrogels) by using two activation steps, including heating-cooling and shear force in method-1 or boric acid/glycolipid complexation and shear force in method-2. The influence of number of activation steps on vesicle to nanotube phase transitions and activation method on the properties of hydrogels were investigated, where the morphological transformations and destabilization of hydrophobic domains resulted from a bilayer to a higher-order crystal structure. Findings: Hydrophobic and hydrophilic cargos encapsulated in the dissipative assemblies (vesicles and injectable hydrogels) can be released in a controlled manner via changing the activation method. The reported adaptive materials engineered by dual activation steps are promising self-assembled systems for programmed release of loaded cargos at a tunable rate. (c) 2021 Elsevier Inc. All rights reserved.

Automated summary

In the study, it was found that the adaptation of biological self-assembly processes to an amphiphilic molecule can lead to the fabrication of intelligent biomaterials with life-like behavior. The researchers investigated the influence of activation steps and methods on the properties of dissipative assemblies and found that different activation methods could control the release of hydrophobic and hydrophilic cargos.