Improving Cell Penetration of Gold Nanorods by Using an Amphipathic Arginine Rich Peptide.

INTRODUCTION: Gold nanorods are highly reactive, have a large surface-to-volume ratio, and can be functionalized with biomolecules. Gold nanorods can absorb infrared electromagnetic radiation, which is subsequently dispersed as local heat. Gold nanoparticles can be used as powerful tools for the diagnosis and therapy of different diseases. To improve the biological barrier permeation of nanoparticles with low cytotoxicity, in this study, we conjugated gold nanorods with cell-penetrating peptides (oligoarginines) and with the amphipathic peptide CLPFFD. METHODS: We studied the interaction of the functionalized gold nanorods with biological membrane models (liposomes) by dynamic light scattering, transmission electron microscopy and the Langmuir balance. Furthermore, we evaluated the effects on cell viability and permeability with an MTS assay and TEM. RESULTS AND DISCUSSION: The interaction study by DLS, the Langmuir balance and cryo-TEM support that GNR-Arg7CLPFFD enhances the interactions between GNRs and biological membranes. In addition, cells treated with GNR-Arg7CLPFFD internalized 80% more nanoparticles than cells treated with GNR alone and did not induce cell damage. CONCLUSION: Our results indicate that incorporation of an amphipathic sequence into oligoarginines for the functionalization of gold nanorods enhances biological membrane nanoparticle interactions and nanoparticle cell permeability with respect to nanorods functionalized with oligoarginine. Overall, functionalized gold nanorods with amphipathic arginine rich peptides might be candidates for improving drug delivery by facilitating biological barrier permeation.

Stable conjugates of peptides with gold nanorods for biomedical applications with reduced effects on cell viability.

Gold nanorods used in therapy and diagnosis must be nontoxic and stable in biological media and should be specific for the target. The complete combination of these three factors has hindered the use of gold nanorods as carriers in biological and biomedical applications. In this study, we produced a conjugate of gold nanorods with the peptide CLPFFD that recognizes toxic ß-amyloid aggregates present in Alzheimer's disease, demonstrates colloidal stability, maintains plasmonic properties, and shows no effects on cell viability in the SH-SY5Y cell line. Furthermore, the irradiation of ß-amyloid in the presence of the conjugate with near-infrared region irradiation energy reduces the amyloidogenic process reducing also its cytotoxicity. The nanorods were synthesized following the seed-mediated method in cetyltrimethylammonium bromide (CTAB) and were conjugated with the N-terminal cysteine peptide, CLPFFD. The conjugate was exhaustively characterized using different techniques (Absorption spectroscopy, X-ray photoelectron spectroscopy, electron energy loss spectroscopy, and zeta potential). The effects on cell viability and cell penetration by transmission electron microscopy of the conjugate were evaluated. The chemisorption of the peptide on the surface of gold nanorods increases their stability and reduces their effects on cell viability.

Selective nanodecoration of modified cyclodextrin crystals with gold nanorods.

Gold nanorods (AuNRs) stabilized by cetyltrimethylammonium bromide (CTAB) were deposited onto crystals of α-cyclodextrin (α-CD) inclusion compounds (ICs) that contained octanethiol (OT) as guest molecules. The nanodecoration was produced specifically at the {001} crystal planes through interaction between the -SH groups of the ICs and the AuNRs.

Improving the brain delivery of gold nanoparticles by conjugation with an amphipathic peptide.

BACKGROUND & AIMS: Gold nanoparticles (GNPs) have promising applications for drug delivery as well as for the diagnosis and treatment of several pathologies, such as those related to the CNS. However, GNPs are retained in a number of organs, such as the liver and spleen. Owing to their negative charge and/or processes of opsonization, GNPs are retained by the reticuloendothelial system, thereby decreasing their delivery to the brain. It is therefore crucial to modify the nanoparticle surface in order to increase its lipophilicity and reduce its negative charge, thus achieving enhanced delivery to the brain. RESULTS: In this article, we have shown that conjugation of 12 nm GNPs with the amphipathic peptide CLPFFD increases the in vivo penetration of these particles to the rat brain. The C(GNP)-LPFFD conjugates showed a smaller negative charge and a greater hydrophobic character than citrate-capped GNPs of the same size. We administered intraperitoneal injections of citrate GNPs and C(GNP)-LPFFD in rats, and determined the gold content in the tissues by neutron activation. Compared with citrate GNPs, the C(GNP)-LPFFD conjugate improved the delivery to the brain, increasing the concentration of gold by fourfold, while simultaneously reducing its retention by the spleen 1 and 2 h after injection. At 24 h, the conjugate was partially cleared from the brain, and mainly accumulated in the liver. The C(GNP)-LPFFD did not alter the integrity of the blood-brain barrier, and had no effect on cell viability.