Enzyme-controlled, nutritive hydrogel for mesenchymal stromal cell survival and paracrine functions.

Culture-adapted human mesenchymal stromal cells (hMSCs) are appealing candidates for regenerative medicine applications. However, these cells implanted in lesions as single cells or tissue constructs encounter an ischemic microenvironment responsible for their massive death post-transplantation, a major roadblock to successful clinical therapies. We hereby propose a paradigm shift for enhancing hMSC survival by designing, developing, and testing an enzyme-controlled, nutritive hydrogel with an inbuilt glucose delivery system for the first time.

Properties of interpenetrating polymer networks associating fibrin and silk fibroin networks obtained by a double enzymatic method.

Fibrin gels are of interest as biomaterials for regenerative medicine but present poor mechanical properties, undergo fast degradation and strongly contract in presence of cells. To face these drawbacks, a fibrin network can be associated with another polymer network, in an Interpenetrating Polymer Network (IPN) architecture. In this study, we report the properties of an IPN comprising a fibrin (Fb) network and a silk fibroin (SF) network.

Evaluation of Fibrin-Based Interpenetrating Polymer Networks as Potential Biomaterials for Tissue Engineering.

Interpenetrating polymer networks (IPNs) have gained great attention for a number of biomedical applications due to their improved properties compared to individual components alone. In this study, we investigated the capacity of newly-developed naturally-derived IPNs as potential biomaterials for tissue engineering. These IPNs combine the biologic properties of a fibrous fibrin network polymerized at the nanoscale and the mechanical stability of polyethylene oxide (PEO).

Ephemeral biogels to control anti-biofilm agent delivery: From conception to the construction of an active dressing.

Chronic wound colonization by bacterial biofilms is common and can cause various complications. An anti-biofilm strategy was developed around the co-entrapment of a commercially available antiseptic, PHMB (polyhexamethylene biguanide 4mgmL), with EDTA (Ethylen diamine tetra acetic acid, 20mM) in a gelatin gel. The two active compounds act synergistically against bacterial biofilms, but their efficiency is strongly reduced (16-fold) when entrapped inside the 5% gelatin gel, and they weaken the mechanical properties (50-fold) of the gel.

Time-Controllable Lipophilic-Drug Release System Designed by Loading Lipid Nanoparticles into Polysaccharide Hydrogels.

A hybrid hydrogel composed of solid lipid nanoparticles (LNPs) entrapped within chemically cross-linked carboxymethylcellulose (CMC) is developed to achieve localized and sustained release of lipophilic drugs. The analysis of LNP stability as well as the hydrogel swelling and mechanical properties confirm the successful incorporation of particles up to a concentration of 50% w/w . The initial LNP release rate can be prolonged by increasing the particle diameter from 50 to 120 nm, while the amount of long-term release can be adjusted by tailoring the particle surface charge or the cross-linking density of the polymer.

Synergistic antibiofilm efficacy of various commercial antiseptics, enzymes and EDTA: a study of Pseudomonas aeruginosa and Staphylococcus aureus biofilms.

A multistep strategy was used to generate a combined antibiofilm treatment that could efficiently decrease the biomass of dense biofilms (≥6 × 10(7) CFU/cm(2)). Several compounds that exhibited activity against various targets were tested individually and in combination to search for possible synergistic effects. First, the antibiofilm activity of various commercially available antiseptics was tested on Pseudomonas aeruginosa and Staphylococcus aureus.

Characterization of Breast Implant Surfaces, Shapes, and Biomechanics: A Comparison of High Cohesive Anatomically Shaped Textured Silicone, Breast Implants from Three Different Manufacturers.

Unlabelled: Several companies offer anatomically shaped breast implants but differences among manufacturers are often misunderstood. The shell texture is a crucial parameter for anatomically shaped implants to prevent rotation and to decrease the risk of capsular contracture, even though concerns have recently been raised concerning the complications associated with textured breast implants. The aim of this study was to characterize differences in terms of texture, cell adhesion, shape, and stiffness between some commonly used anatomically shaped implants from three different manufacturers.

Self-supported fibrin-polyvinyl alcohol interpenetrating polymer networks: an easily handled and rehydratable biomaterial.

A fibrin hydrogel at physiological concentration (5 mg/mL) was associated with polyvinyl alcohol (PVA) inside an interpenetrating polymer networks (IPN) architecture. Previously, PVA has been modified with methacrylate functions in order to cross-link it by free-radical polymerization. The fibrin network was synthesized by the enzymatic hydrolysis of fibrinogen by thrombin.

Bacterial floras and biofilms of malignant wounds associated with breast cancers.

The risk of infections and the appearance of symptoms (e.g., odors) represent the main troubles resulting from malignant wounds.

Molecular size characterization and kinetics studies on hydrolysis of pullulan by pullulanase in an entangled alginate medium.

The behavior of a hydrolytic enzyme (pullulanase) toward its substrate (pullulan) in the presence of a nonsubstrate (alginate), both below and above the critical entanglement concentration (C*), was studied. The hydrolysis kinetics were studied with the enzyme and alginate concentrations varied using two main methods: a colorimetric assay of the reducing extremities (RE), which allowed the number-average molar masses (Mn) of the oligosaccharides to be determined, and size exclusion chromatography with on-line, multiangle light scattering, viscometer, and differential refractive index detectors, which allowed the average molar masses, Mn and Mw, of the oligosaccharides during hydrolysis to be determined. Free pullulanase acts via an "endo" process.

Gelatin-alginate gels and their enzymatic modifications: controlling the delivery of small molecules.

The release of molecules entrapped within biogels is dictated by diffusion laws. Innovative biogel architectures are conceived and tested to control small molecule delivery from gelatin gels. The ionic interactions modulate the release of small molecules.

Increase of fibrin gel elasticity by enzymes: a kinetic approach.

Two enzymes, thrombin and transglutaminase, both participate in the formation of fibrin networks and contribute to the mechanical strength of biogels. A theoretical model built from the available kinetic data showed that a competition may take place between the two enzymes for their common substrate, fibrinogen. To evidence this phenomenon experimentally, the concentrations of the reactants were varied and the rheological properties of the resulting fibrin gels explored.

Influence of enzymatic specificity on the behavior of ephemeral gels.

Ephemeral gels, called Enzgels, successively undergo sol-gel and then gel-sol transition under the action of two antagonistic enzymes, transglutaminase and protease. Molecular and macroscopic properties of Enzgels are directly dependent on the enzymatic activities and their ratios. This work studies the characteristics of Enzgels according to the specificity of three different proteases: thermolysin, trypsin, and collagenase.

Enzyme-catalyzed phase transition of alginate gels and gelatin-alginate interpenetrated networks.

The enzyme-catalyzed gel-sol transition of calcium-alginate obtained by internal gelling strategy with the help of an entrapped alginate lyase is described. We show that alginate molecules and enzyme-produced oligoalginates shorten the gel time of physical gelatin gels (5% and 1.5%), probably due to local protein concentration increase.

Antagonistic enzymes may generate alternate phase transitions leading to ephemeral gels.

In some biological processes, two enzymes with antagonistic activities--the one creating a bond, the other destroying it--are involved in a reaction cycle. Several catalysts have the ability to modify the rheological properties of biological media participating in the production of a solid gel phase which later dissolves. Transglutaminase, catalyzing intermolecular protein cross-linking, is considered here as a reverse protease as far as the physical state of a proteic gel is concerned.

Carbamylation differentially alters type I collagen sensitivity to various collagenases.

Carbamylation is a post-translational modification due to nonenzymatic binding of cyanate, a by-product of urea, on free amino groups of proteins. Post-translational modifications are known to induce alterations in structural and functional properties of proteins, thus disturbing protein-protein or cell-protein interactions. We report the impact of carbamylation on type I collagen sensitivity to enzymatic proteolysis.

Removal of surface by-products from sintered hydroxyapatite: effect of a chelation treatment on fibronectin adsorption and cell adhesion.

It was observed that fibronectin precipitates when deposited on hydroxyapatite (HA) ceramics. Fibronectin's known affinity for calcium and the composition of the ceramic itself suggested that calcium release could be the main cause of this aggregation effect. It was then decided to investigate the effect of a surface chelation treatment on fibronectin adsorption, and MG63 cell adhesion, onto porous ceramics of hydroxyapatite (HA), beta-tricalcium phosphate (beta-TCP), and HA/TCP biphasic material (BCP).

Rheological characterization and dissolution kinetics of fibrin gels crosslinked by a microbial transglutaminase.

Various fibrin gels were prepared with a microbial transglutaminase under miscellaneous conditions. The gels were characterized through their rheological properties. The influence of fibronectin addition and that of covalent bonding on the viscoelastic characteristics were evaluated.

Influence of weak and covalent bonds on formation and hydrolysis of gelatin networks.

The relative influence of physical and chemical bonds to overall gel properties are explored in gelatin gels. Physical, chemical, chemical-physical, and physical-chemical gels are obtained by cooling the protein solution and/or by transglutaminase reaction. Each type of network is characterized by rheology and polarimetry.

Modeling extracellular matrix degradation balance with proteinase/transglutaminase cycle.

Extracellular matrix mass balance is implied in many physiological and pathological events, such as metastasis dissemination. Widely studied, its destructive part is mainly catalysed by extracellular proteinases. Conversely, the properties of the constructive part are less obvious, cellular neo-synthesis being usually considered as its only element.