Comparative long-term preclinical safety evaluation of two glatiramoid compounds (glatiramer Acetate, Copaxone(R), and TV-5010, protiramer) in rats and monkeys.

Glatiramer acetate (GA), the active ingredient in Copaxone®, is a complex mixture of polypeptides used for the treatment of relapsing remitting multiple sclerosis. Glatiramoids are related mixtures that may differ in some characteristics of the prototype molecule. Our aim is to describe the long-term toxicity studies with protiramer (TV-5010), a new glatiramoid, in comparison with similar studies conducted with GA. The toxicity of twice-weekly subcutaneous injections of protiramer to Sprague-Dawley rats (twenty-six weeks) and cynomolgus monkeys (fifty-two weeks) was compared with similar studies done with daily subcutaneous injections of GA. Daily treatment with GA was safe and well tolerated, without systemic effects or death. Protiramer administration was not as well tolerated as GA and led to dose- and time-related mortalities, probably mediated through severe injection-site lesions both in rats and in monkeys. Bridging fibrosis in the liver and severe progressive nephropathy were seen in rats. A dose-related increase in eosinophils was observed in monkeys. The protiramer toxicity studies show that minor variations in the manufacturing of glatiramoids may lead to significant toxic effects. It is therefore essential that the safety of any new glatiramoid be studied in long-term preclinical studies before exposing humans.

The therapeutic equivalence of complex drugs.

When the patent of a small molecule drug expires generics may be introduced. They are considered therapeutically equivalent once pharmaceutical equivalence (i.e. identical active substances) and bioequivalence (i.e. comparable pharmacokinetics) have been established in a cross-over volunteer study. However this generic paradigm cannot be applied to complex drugs as biologics and a number of other therapeutic modalities. For copies of biologics the European Medicine Agency and other regulatory agencies have introduced a new regulatory biosimilar pathway which mandates clinical trials to show therapeutic equivalence. However for other complex drugs such as the iron-carbohydrate drugs, low molecular weight heparins (LMWHs), liposomal drugs and the glatiramoids regulatory guidance is still mostly lacking. In this paper we will discuss (therapeutic) experience obtained so far with these different classes of 'complex drugs' and their specifics to provide scientific arguments and criteria for consideration for a regulatory framework for the market authorization for these type of drugs.

The glatiramoid class of immunomodulator drugs.

Glatiramer acetate (GA) is a complex heterogenous mixture of polypeptides with immunomodulatory activity approved for treatment of relapsing-remitting multiple sclerosis. GA is the first, and was until recently, the only member of the glatiramoids, a family of synthetic copolymer mixtures comprising the four amino acids, L-glutamic acid, L-alanine, L-lysine and L-tyrosine, in a defined molar ratio. Another glatiramoid, protiramer, was recently evaluated in preclinical studies and in two small Phase II clinical trials with relapsing-remitting multiple sclerosis patients. Due to the complexity and heterogeneity of GA and other glatiramoids, the clinically active epitopes within the mixture cannot be identified and the consistency of polypeptide sequences within the mixture is dependent on a tightly controlled manufacturing process. Although no two glatiramoids can be proved identical, it is possible to differentiate among members of the glatiramoid class using analytical methods and immunological and biological markers. Even slight differences in the distribution of molecular masses or in the composition of antigenic polypeptide sequences among glatiramoids can significantly influence their efficacy, toxicity and immunogenicity profiles. Experience with GA may be instructive regarding important safety and efficacy considerations for new glatiramoid mixtures now in development.

Oral glatiramer acetate in experimental autoimmune encephalomyelitis: clinical and immunological studies.

Glatiramer acetate (GA, Copaxone, copolymer 1) for injection is an approved drug for relapsing-remitting multiple sclerosis. The clinical and immunological effects of GA were extensively studied in experimental autoimmune encephalomyelitis (EAE), the experimental animal model for MS. The effect of oral administration of GA was tested in both rodents and primates in acute as well as in chronic relapsing (CR) models of EAE. Oral GA was found to suppress acute EAE induced in rats, mice, and rhesus monkeys. The effect of GA was also tested in several models of CR-EAE: proteolipid protein and myelin oligodendrocyte glycoprotein induced CR-EAE in mice, CR-EAE in Biozzi mice, and CR-EAE in cynomolgus monkeys. In all the murine models, oral treatment with GA initiated at the peak of first relapse reduced the severity of disease and suppressed further relapses. Suppression of EAE with oral GA was associated with marked inhibition of spleen cell proliferation and Th1 cytokine (IL-2 and IFN-gamma) response to the respective autoantigens. GA-specific T cell lines of the Th2/3 type that inhibit EAE induction in vivo, similarly to those induced by injection of GA, could be isolated from spleens of GA-fed mice and rats. Furthermore, as demonstrated previously for GA-specific cells induced by the parenteral route, the orally induced GA-specific cells accumulate in the CNS and secrete in situ Th2 cytokines in response to both GA and MBP as well as brain-derived neurotrophic factor (BDNF). Although a clinical trial in MS with two doses of oral GA in enteric-coated tablets did not show a significant effect either at the clinical or immunological level, the results presented here suggest that oral GA may still be developed into a therapeutic modality in MS.

Regional peptide uptake study in the rat intestinal mucosa: glatiramer acetate as a model drug.

PURPOSE: To identify regions of the rat intestine that are able to internalize from the lumen oligopeptides, using the model drug glatiramer acetate (GA). METHODS: GA was introduced into rat intestinal sacs and the integrity of GA during uptake was monitored using antibody detection. Sodium docecyl sulphate polyacrylamide gel electrophoresis (SDS-PAGE) and immunoblotting of intestinal homogenates that had been exposed to GA were performed to identify GA presence. An enzyme-linked immunosorbent assay (ELISA) protocol was adapted for GA quantification. Immunohistochemistry was undertaken to examine the rat colonic wall for GA uptake, and confocal microscopy was used to differentiate adsorbed and internalized peptide in cultured colorectal adenocarcinoma cells. RESULTS: The colon and the ileum, respectively, were identified to be the intestinal regions in which GA was maximally preserved during uptake from the lumen. GA was identified to cross the colonic wall from the epithelium to the serosa. Internalization of GA into cultured colonic epithelial cells was demonstrated. CONCLUSIONS: The rat colonic wall was identified to be less proteolytically active toward GA compared to the wall of the more proximal regions of the small intestine. GA has the capacity to penetrate from the lumen into the colonic wall. The maintenance of GA integrity within the wall of the colon offers the potential for local biological activity of the drug.