Brain Tumor Tandem Targeting Using a Combination of Monoclonal Antibodies Attached to Biopoly(beta-L-malic Acid)

Overview

Journal J Control Release

Specialty Pharmacology

Date 2007 Jul 17

PMID 17630012

Citations 25

Authors

Manabu Fujita

Bong-Seop Lee

Natalya M Khazenzon

Manuel L Penichet

Kolja A Wawrowsky

Rameshwar Patil

Hui Ding

Eggehard Holler

Keith L Black

Julia Y Ljubimova

Affiliations

Soon will be listed here.

Abstract

Tumor-specific targeting using achievements of nanotechnology is a mainstay of increasing efficacy of anti-tumor drugs. To improve drug targeting we covalently conjugated for the first time two different monoclonal antibodies, an anti-mouse transferrin receptor antibody and a mouse autoimmune anti-nucleosome antibody 2C5, onto the drug delivery nanoplatform, poly(beta-L-malic acid). The active anti-tumor drug components attached to the same carrier molecule were antisense oligonucleotides to vascular protein laminin-8. The resulting drug, a new Polycefin variant, was administered intravenously into glioma-bearing xenogeneic animals. The drug delivery system was targeted across mouse endothelial system by the anti-mouse transferring receptor antibody and to the tumor cell surface by the anti-nucleosome antibody 2C5. The targeting efficacies of the Polycefin variants bearing either two antibodies or each single antibody were compared in vitro and in vivo. ELISA confirmed the co-existence of two antibodies on the same nanoplatform molecule and their functional activities. Fluorescence imaging analysis after 24 h of intravenous injection demonstrated significantly higher tumor accumulation of Polycefin variants with the tandem configuration of antibodies than with single antibodies. The results suggest improved efficacy for tandem configuration of antibodies than for single configurations carried by a drug delivery vehicle.

Citing Articles

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Targeting Malignant Brain Tumors with Antibodies.

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