An oral antisense oligonucleotide for PCSK9 inhibition.

Inhibitors of proprotein convertase subtilisin/kexin type 9 (PCSK9) reduce low-density lipoprotein (LDL) cholesterol and are used for treatment of dyslipidemia. Current PCSK9 inhibitors are administered via subcutaneous injection. We present a highly potent, chemically modified PCSK9 antisense oligonucleotide (ASO) with potential for oral delivery. Past attempts at oral delivery using earlier-generation ASO chemistries and transient permeation enhancers provided encouraging data, suggesting that improving potency of the ASO could make oral delivery a reality. The constrained ethyl chemistry and liver targeting enabled by N-acetylgalactosamine conjugation make this ASO highly potent. A single subcutaneous dose of 90 mg reduced PCSK9 by >90% in humans with elevated LDL cholesterol and a monthly subcutaneous dose of around 25 mg is predicted to reduce PCSK9 by 80% at steady state. To investigate the feasibility of oral administration, the ASO was coformulated in a tablet with sodium caprate as permeation enhancer. Repeated oral daily dosing in dogs resulted in a bioavailability of 7% in the liver (target organ), about fivefold greater than the plasma bioavailability. Target engagement after oral administration was confirmed by intrajejunal administration of a rat-specific surrogate ASO in solution with the enhancer to rats and by plasma PCSK9 and LDL cholesterol lowering in cynomolgus monkey after tablet administration. On the basis of an assumption of 5% liver bioavailability after oral administration in humans, a daily dose of 15 mg is predicted to reduce circulating PCSK9 by 80% at steady state, supporting the development of the compound for oral administration to treat dyslipidemia.

Systematic studies on the paracellular permeation of model permeants and oligonucleotides in the rat small intestine with chenodeoxycholate as enhancer.

The objective of this study was to mechanistically and quantitatively analyze chenodeoxycholate-enhanced paracellular transport of polar permeants and oligonucleotides in the rat jejunum and ileum. Micellar chenodeoxycholate solutions were used to perturbate the tight junctions. Supporting studies included assessment of the aqueous boundary layer (ABL) with ABL-controlled permeants, measurements of the permeability coefficients and fluxes of the bile acid in dilute and micellar concentrations, and determinations of pore sizes with paracellular probes (urea, mannitol, and raffinose). The paracellular permeability coefficients, P(para), of two model oligonucleotides (ON3 and ON6; 12- and 24-mers with 11 and 23 negative charges, respectively) were determined. The enhanced permeabilities paralleled the increased fluxes of micellar bile salt solutions into mesenteric blood and the opening of the tight junctions as compared to controls. As the pore radius increased from 0.7 nm to a maximum of 2.4 nm in the jejunum and ileum, the absorption of ON3 was enhanced up to sixfold in the jejunum and about 14-fold in the ileum with P(para) values between 0.5 x 10(-6) and 6 x 10(-6) cm/s, whereas ON6 was enhanced up to twofold in the jejunum and fivefold in the ileum with permeabilities between 0.3 x 10(-6) and 2 x 10(-6) cm/s.

Oral delivery of antisense oligonucleotides in man.

Treatment of systemic disease with phosphorothioate antisense oligonucleotides (PS ASOs) has been accomplished using local or parenteral routes of administration to date. This report describes, for the first time, the effective oral delivery of a second generation oligonucleotide where significant milligram amounts of intact drug are absorbed in human subjects. In this study, a variety of oral solid dosage formulations were evaluated and it was determined that pulsing the delivery of sodium caprate (C10), a well-known permeation enhancer, in a novel manner may provide optimal ASO plasma bioavailability. Further, these dosage forms, containing C10 and ASO, were well tolerated in both fasted and fed volunteers. Oral absorption of the 2'-O-(2-methoxyethyl) modified antisense oligonucleotide (2'-MOE ASO), ISIS 104838, was demonstrated in healthy volunteers with an average 9.5% plasma bioavailability across four formulations tested. The greatest average performance achieved in this study for a single formulation was 12.0% bioavailability within an individual dose and subject range of 1.96-27.5%. The totality of the data suggests that formulations can be devised that allow oral administration of oligonucleotides that maintain systemic concentrations associated with inhibition of targeted human mRNA.

Stability of polycationic complexes of an antisense oligonucleotide in rat small intestine homogenates.

Presystemic degradation in the gastrointestinal tract is one of the major problems contributing to the poor oral absorption of antisense oligonucleotides. Complexes between the antisense phosphorothioate oligodeoxynucleotide ISIS 2302 and the polycationic carriers protamine sulfate grade X, protamine chloride grade V, protamine phosphate grade X, poly-L-lysine hydrobromide (PLL), spermidine phosphate salt, spermine diphosphate salt, and Protasan G113 and CL113 were formulated in order to increase stability against intestinal nucleolytic degradation. Specific conductivity measurements were carried out to determine the charge ratio of the complex systems. Nuclease stability assays were performed in a rat small intestine homogenate model, which displayed significant exo- and endonuclease activity. Full-length oligonucleotide and metabolites were analyzed by capillary gel electrophoresis with UV detection at 260 nm. Most of the complexes of ISIS 2302 and the polycationic materials, except PLL-based systems, showed a better protection against enzymatic metabolism than free oligonucleotide. Protamine sulfate and protamine chloride considerably enhanced the nuclease stability of the phosphorothioate antisense oligonucleotide. The association of oligonucleotides with several polycationic substances proved to be an alternative to chemical modification in order to stabilize oligonucleotides in the gastrointestinal tract against nucleolytic degradation.

Alginate/poly-L-lysine microparticles for the intestinal delivery of antisense oligonucleotides.

PURPOSE: A microparticle carrier based on alginate and poly-L-lysine was developed and evaluated for the delivery of antisense oligonucleotides at the intestinal site. Formulations of oligonucleotide-loaded microparticles having differences in the carrier molecular weight and composition were characterized in vitro and in vivo. METHODS: Polymeric microparticles were prepared by ionotropic gelation and crosslinking of alginate with calcium ions and poly-L-lysine. The loading of the antisense oligonucleotide into the microparticles was achieved by absorption in aqueous medium. The association capacity, loading and particle size of the microparticles were characterized. The in vivo performances of various formulations after intrajejunal administration were studied in rat and in dog models. RESULTS: Microparticles had a sponge-like structure and an oligonucleotide loading of 27-35%. The composition of the medium affected the particle size and the in vitro release profiles. The oligonucleotide bioavailability after intrajejunal administration to rats in the presence of permeation enhancers was good for most of the tested systems. The application of microparticles in powder form compared to an equivalent suspension improved the intrajejunal bioavailability of the oligonucleotide (25% and 10% respectively) in rats. On the contrary, the intrajejunal administration to dogs resulted in poor oligonucleotide bioavailability (0.42%). CONCLUSIONS: The formulation of antisense oligonucleotides within alginate and poly-L-lysine microparticles is a promising strategy for the oral application.