Nanotubes Functionalized with Lipids and Natural Amino Acid Dendrimers: a New Strategy to Create Nanomaterials for Delivering Systemic RNAi

Overview

Journal Bioconjug Chem

Publisher American Chemical Society

Specialty Biochemistry

Date 2009 Dec 5

PMID 19957956

Citations 14

Authors

Joshua McCarroll

Huricha Baigude

Chao-Shun Yang

Tariq M Rana

Affiliations

Soon will be listed here.

Abstract

Single-walled carbon nanotubes (SWNT) have unique electronic, mechanical, and structural properties as well as chemical stability that make them ideal nanomaterials for applications in materials science and medicine. Here, we report the design and creation of a novel strategy for functionalizing SWNT to systemically silence a target gene in mice by delivering siRNA at doses of <1 mg/kg. SWNT were functionalized with lipids and natural amino acid-based dendrimers (TOT) and complexed to siRNA. Our model study of the silencing efficiency of the TOT-siRNA complex showed that, in mice injected at 0.96 mg/kg, an endogenous gene for apoliproprotein B (ApoB) was silenced in liver, plasma levels of ApoB decreased, and total plasma cholesterol decreased. TOT-siRNA treatment was nontoxic and did not induce an immune response. Most (80%) of the RNA trigger molecules assembled with TOT were cleared from the body 48 h after injection, suggesting that the nanotubes did not cause siRNA aggregation or inhibit biodegradation and drug clearance in vivo. These results provide the first evidence that nanotubes can be functionalized with lipids and amino acids to systemically deliver siRNA. This new technology not only can be used for systemic RNAi, but may also be used to deliver other drugs in vivo.

Citing Articles

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siRNA Design and Delivery Based on Carbon Nanotubes.

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Dendrimer-coated carbon nanotubes deliver dsRNA and increase the efficacy of gene knockdown in the red flour beetle Tribolium castaneum.

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