Significant reduction in neural adhesions after administration of the regenerating agent OTR4120, a synthetic glycosaminoglycan mimetic, after peripheral nerve injury in rats.

Object: Extradural and intraneural scar formation after peripheral nerve injury frequently causes tethering and compression of the nerve as well as inhibition of axonal regeneration. Regenerating agents (RGTAs) mimic stabilizing and protective properties of sulphated glycosaminoglycan toward heparin-binding growth factors. The aim of this study was to assess the effect of an RGTA known as OTR4120 on extraneural fibrosis and axonal regeneration after crush injury in a rat sciatic nerve model.

Effects on coagulation of a synthetic heparan mimetic given intraperitoneally or orally.

OTR4120, which belongs to a family of heparan sulfate-mimetic polymers, promotes tissue repair when injected locally in doses of a few micrograms. As OTR4120 is a sulfated polysaccharide, we investigated its possible role on the coagulation cascade. We used both in vitro and in vivo assays.

Heparin-like synthetic polymers, named RGTAs, mimic biological effects of heparin in vitro.

A family of biopolymers engineered to protect and stabilize heparin binding growth factors (HBGFs) show remarkable properties as wound healing agents in several in vivo tissue repair models to the extend that damaged tissues would recover almost its initial aspect and properties. These polymers where named RGTA for regenerating agents and proposed to act in vivo by enhancing the bioavailability of HBGFs at the site of the injury. To provide support for this hypothesis, we studied interaction of RGTA with FGF-2, taken as the paradigm of HBGFs, and its high- and low-affinity receptors as well as its ability to inhibit heparanase activity.

A synthetic glycosaminoglycan mimetic binds vascular endothelial growth factor and modulates angiogenesis.

In a previous study, we showed that in situ injection of glycosaminoglycan mimetics called RGTAs (ReGeneraTing Agents) enhanced neovascularization after skeletal muscular ischemia (Desgranges, P., Barbaud, C., Caruelle, J.

A synthetic glycosaminoglycan mimetic (RGTA) modifies natural glycosaminoglycan species during myogenesis.

Crucial events in myogenesis rely on the highly regulated spatiotemporal distribution of cell surface heparan sulfate proteoglycans to which are associated growth factors, thus creating a specific microenvironment around muscle cells. Most growth factors involved in control of myoblast growth and differentiation are stored in the extracellular matrix through interaction with specific sequences of glycosaminoglycan oligosaccharides, mainly heparan sulfate (HS). Different HS subspecies revealed by specific antibodies, have been shown to provide spatiotemporal regulation during muscle development.

Structurally different RGTAs modulate collagen-type expression by cultured aortic smooth muscle cells via different pathways involving fibroblast growth factor-2 or transforming growth factor-beta1.

We have engineered polymers called ReGeneraTing Agents (RGTAs), which mimic the protecting and potentiating properties of heparan sulfates toward heparin-binding growth factors (HBGF). RGTAs have been shown to optimize cell growth and regulate collagen production in vitro. Here, we studied relationships between RGTA structure and collagen-type expression in aortic smooth muscle cells by using two RGTAs, the carboxylmethylsulfate dextran RG-1503 and the carboxylmethylsulfate dextran with added benzylamide RG-1192.

Controlled sulfatation of natural anionic bacterial polysaccharides can yield agents with specific regenerating activity in vivo.

The regenerating activities of chemically modified anionic bacterial polysaccharides by O-sulfonation were investigated using a in vivo model of rat injured muscle regeneration. Glucuronan (GA), a linear homopolysaccharide of -->4)-beta-D-GlcpA-(1--> residues partially acetylated at the C-3 and/or the C-2 position, and glucoglucuronan (GGA), a linear heteropolysaccharide of -->3)-beta-D-GlcpA-(1-->4)-beta-D-Glcp-(1--> residues were sulfated. SO3-DMF sulfatation complex provided polysaccharides with different sulfur contents, however, a depolymerization occurred because we did not use large excess of pyridine to obtain pure modified polysaccharides.

An engineered biopolymer prevents mucositis induced by 5-fluorouracil in hamsters.

Oral mucositis is a common, treatment-limiting, and costly side effect of cancer treatments whose biological underpinnings remain poorly understood. In this study, mucositis induced in hamsters by 5-fluorouracil (5-FU) was observed after cheek-pouch scarifications, with and without administration of RGTA (RG1503), a polymer engineered to mimic the protective effects of heparan sulfate. RG1503 had no effects on 5-FU-induced decreases in body weight, blood cell counts, or cheek-pouch and jejunum epithelium proliferation rates, suggesting absence of interference with the cytotoxic effects of 5-FU.

Heparin-like dextran derivatives as well as glycosaminoglycans inhibit the enzymatic activity of human cathepsin G.

Some synthetic dextran derivatives that mimic the action of heparin/heparan sulfate were previously shown to inhibit neutrophil elastase and plasmin. Here we report that these derivatized dextrans also inhibit cathepsin G (CatG). Dextran containing carboxymethyl and benzylamide groups (RG1150) as well as those containing carboxymethyl, sulfate and benzylamide groups (RG1192), were the most efficient inhibitors of CatG activity.

RGTA modulates the healing pattern of a defect in a monolayer of osteoblastic cells by acting on both proliferation and migration.

A family of heparan-like polymers, RGTAs, was shown to promote repair of various tissues. Like heparin and heparan-sulfates, RGTAs potentiate in vitro the biological activities of heparin-binding growth factors (HBGFs) and protect them against proteolytic degradation. It was postulated that RGTAs stimulate bone healing by interacting with HBGFs released in the wound site and, subsequently, by promoting the proliferation of cells implicated in this process.

Pharmacological studies of RGTA(11), a heparan sulfate mimetic polymer, efficient on muscle regeneration.

RGTA is a family of chemically modified polymers that have been engineered to mimic the properties of heparan sulfates towards heparin binding growth factors. In vivo, RGTA stimulated tissue repair and protection when injected at the site of an injury. These properties have been reported in various models, suggesting a potential interest for therapeutic uses as a general tissue repair agent.

Glycosaminoglycan mimetics (RGTA) modulate adult skeletal muscle satellite cell proliferation in vitro.

Muscle regeneration occurs through the activation of satellite cells, which are stimulated to proliferate and to fuse into myofibers that will reconstitute the damaged muscle. We have previously reported that a family of new compounds called "regenerating agents" (RGTAs), which are polymers engineered to mimic heparan sulfates, stimulate in vivo tissue repair. One of these agents, RG1192, a dextran derivative substituted by CarboxyMethyl, Benzylamide, and Sulfate (noted CMBS, RGTA type), was shown to improve greatly the regeneration of rat skeletal muscle after severe crushing, denervation, and acute ischemia.

Heparin-like polymer improved healing of gastric and colic ulceration.

A family of chemically substituted biopolymers has been developed to protect and stabilize heparin binding growth factors and was shown to enhance tissue repair in various in vivo models. One of these compounds, a dextran derivative named RGTA11, was tested for its ability to treat acute gastritis and colic ulceration models induced by ethanol and acid. RGTA was not efficient in reducing nor in protecting against gastric acidic secretion compared to EGF.