ABSTRACT
Constructing biocompatible soft materials via supramolecular approaches remains an important challenge for in vivo applications. Substantial efforts have been made to develop biocompatible non-polymeric materials allowing sustained release of biomolecules and/or drugs in vivo. Herein, we introduce disulfide based low molecular weight gels (LMWGs) allowing the in vitro selective sustained release of proteins containing thiol residues. The novel glycosylated nucleoside based bola-amphiphile (GNBA), which features a disulfide bond inserted in the hydrophobic segment, self-assembles to stabilize the resulting hydrogel. Rheological studies show the dominant elastic character and thixotropic properties of the disulfide LMWG demonstrating its injectability. In vitro and in vivo biodegradation investigations reveal that the disulfide LMWG is stable for several weeks. Importantly, disulfide bonds can be cleaved through the thiol-disulfide exchange reactions with small redox molecules such as dithiothreitol (DTT). The disulfide LMWG loaded with a thiol-containing protein (bovine serum albumin) features sustained release in vitro, whereas a dextran of the same molecular weight, lacking a thiol biomolecule, shows quick release. The disulfide GNBA is the first example of a LMWG allowing selective long term sustained release in vitro via a disulfide reshuffling mechanism.
Subject(s)
Disulfides/administration & dosage , Nucleosides/administration & dosage , Serum Albumin, Bovine/administration & dosage , Animals , Cell Line , Cell Survival/drug effects , Delayed-Action Preparations/administration & dosage , Delayed-Action Preparations/chemistry , Dextrans/chemistry , Disulfides/chemistry , Drug Liberation , Gels , Mice , Molecular Weight , Nucleosides/chemistry , Rheology , Serum Albumin, Bovine/chemistry , Sulfhydryl Compounds/administration & dosage , Sulfhydryl Compounds/chemistryABSTRACT
There is a critical need for soft materials in the field of regenerative medicine and tissue engineering. However, designing injectable hydrogel scaffolds encompassing both adequate mechanical and biological properties remains a key challenge for in vivo applications. Here we use a bottom-up approach for synthesizing supramolecular gels to generate novel biomaterial candidates. We evaluated the low molecular weight gels candidates in vivo and identified one urea-containing molecule, compound 16, that avoid foreign body reactions in mice. The self-assembly of bolaamphiphiles creates a unique hydrogel supramolecular structures featuring fast gelation kinetics, high elastic moduli, thixotropic, and thermal reversibility properties. This soft material, which inhibits recognition by macrophages and fibrous deposition, exhibits long-term stability after in vivo injection.
Subject(s)
Biocompatible Materials/pharmacology , Furans/pharmacology , Hydrogels/pharmacology , Injections , Pyridones/pharmacology , Urea/chemistry , Amides/chemistry , Animals , Biocompatible Materials/chemical synthesis , Biocompatible Materials/chemistry , Female , Furans/chemistry , Hydrogels/chemical synthesis , Hydrogels/chemistry , Mice , Molecular Weight , Pyridones/chemistry , RheologyABSTRACT
Hydrogels formed by the self-assembly of low-molecular-weight gelators (LMWGs) are promising scaffolds for drug-delivery applications. A new biocompatible hydrogel, resulting from the self-assembly of nucleotide-lipid salts can be safely injected in vivo. The resulting hydrogel provides sustained-release of protein for more than a week.