Intervention with selution SLR™ Agent Balloon for Endovascular Latent Limus therapy for failing AV Fistulas (ISABELLA) Trial: Protocol for a pilot clinical study and pre-clinical results

BACKGROUND

The aim of this pilot clinical study is to evaluate the safety and efficacy of the Selution Sustained Limus Release (SLR)™ sirolimus-coated balloon (M.A. MedAlliance SA, Nyon, Switzerland) for improving the patency of failing arterio-venous fistulas (AVF) in hemodialysis patients. We also present herein a pre-clinical pharmacokinetic and safety evaluation of Selution™ to justify its first use in hemodialysis patients for endovascular access salvage.

METHODS AND RESULTS

This is an investigator-initiated prospective single-center, non-blinded single-arm trial. Forty patients with clinically significant de novo or recurrent stenoses in a mature AVF circuit will be recruited. All stenotic lesions will be prepared with high pressure non-compliant conventional balloon angioplasty (CBA) prior to deployment of the Sustained-Release Selution™ sirolimus drug-eluting balloon. The primary efficacy endpoint is 6-month target lesion primary patency and the primary safety endpoint is freedom from localized or systemic serious adverse events through 30 days. Secondary endpoints of interest include technical and clinical success rates and circuit access patency at 3 and 6 months. Follow-up will occur for 2 years for those patients whose AVFs remain patent. Pharmacokinetic and histological animal safety studies performed with the Selution™ coating formulation showed prolonged arterial tissue retention of sirolimus with therapeutic levels up to 60 days and non-toxic and rapidly declining blood levels. Histological results in animal models demonstrated safety, freedom from intraluminal thrombus, reduction in restenosis by sirolimus elution compared to CBA, and no evidence of embolic phenomena indicative of adverse particulate effects.

DISCUSSION

Long release sirolimus coated balloons may serve as a promising novel alternative therapy to paclitaxel-based technology for treating conduit stenosis secondary to neointimal hyperplasia. Pre-clinical pharmacokinetic and histological animal data are encouraging and provide suggestion of safety and efficacy in this setting. This single-center trial will provide a first step toward demonstration of efficacy and safety of this device for treatment of stenotic fistulas.

Determination of Carrier-Mediated Transport of 2 ,3 -Dideoxypurine Nucleosides in the Rat Ileum Using a Bidirectional Perfusion Technique

PURPOSE

Previous attempts to ascertain the role of uptake and efflux transporters in the oral absorption of anti-HIV dideoxypurine nucleosides have been inconclusive. A novel in situ intestinal perfusion technique with complete mesenteric arterial/venous cannulation was used to examine the asymmetry of ileal dideoxynucleoside permeability under near in vivo conditions.

METHODS

Intestinal perfusions were performed in the rat ileum, with cannulation of the artery and vein immediately entering and leaving the segment. Urea and mannitol were used as passive permeability markers, and the directional transport of 2',3'-dideoxyinosine (ddI), 2'-beta-fluoro-2',3'-dideoxyinosine (F-ddI), and 2'-beta-fluoro-2',3'-dideoxyadenosine (F-ddA) were examined.

RESULTS

Urea and mannitol exhibited symmetric permeability (PLtoB = PBtoL), whereas F-ddI and ddI showed significantly higher permeability in blood-to-lumen transport (PBtoL > PLtoB). PBtoL for F-ddA exceeded PLtoB, but the difference did not reach significance at p < 0.05. PBtoL for ddI was demonstrated to be saturable with increasing ddI concentrations, but PLtoB was independent of ddI concentration. PBtoL for ddI was shown to be dependent on sodium concentration and inhibited by probenecid.

CONCLUSIONS

Symmetric transport was demonstrated for urea and mannitol as expected for these passive permeability markers. F-ddI and ddI were shown to be preferentially transported from blood to lumen. The basolateral to luminal transport of ddI is saturable, inhibited by probenecid, and sodium ion dependent. These results are consistent with carrier-mediated uptake on the basolateral membrane.

Enhanced oral bioavailability of 2'- beta-fluoro-2',3'-dideoxyadenosine (F-ddA) through local inhibition of intestinal adenosine deaminase

PURPOSE

Intestinal enzyme inhibition may be an effective tool to increase the oral bioavailability of compounds that undergo first-pass intestinal metabolism. However, systemic enzyme inhibition may be undesirable and therefore should be minimized. 2-Beta-fluoro-2',3'-dideoxyadenosine (F-ddA) is an adenosine deaminase (ADA) activated prodrug of 2-beta-fluoro-2',3'-dideoxyinosine (F-ddI) with enhanced delivery to the central nervous system (CNS) that has been tested clinically for the treatment of AIDS. Unfortunately, intestinally localized ADA constitutes a formidable enzymatic barrier to the oral absorption of F-ddA. This study explores various factors involved in inhibitor selection and dosage regimen design to achieve local ADA inhibition with minimal systemic inhibition.

METHODS

In situ intestinal perfusions with mesenteric vein cannulation were performed in the rat ileum to determine the lumenal disappearance and venous blood appearance of F-ddA and F-ddI. Coperfusions with the ADA inhibitor erythro9-(2-hydroxy-3-nonyl)adenine [(+)-EHNA] over a range of concentrations were used to monitor inhibitor effects on F-ddA absorption and metabolism.

RESULTS

High concentrations of EHNA in coperfusions with F-ddA completely inhibited intestinal ADA, increasing the permeability coefficient of F-ddA by nearly threefold but producing high systemic inhibition of ADA. Mathematical models were utilized to show that in full-length intestinal perfusions an optimal log mean lumenal EHNA perfusate concentration of 0.5 microg/ml could achieve an intestinal bioavailability of 80% with <20% systemic inhibition.

CONCLUSIONS

Optimizing local enzyme inhibition may require careful selection of a suitable inhibitor, the dose of the inhibitor, and the inhibitor vs. drug absorption profiles.