Cyclic peptide-poly(HPMA) nanotubes as drug delivery vectors: In vitro assessment, pharmacokinetics and biodistribution

Size and shape have progressively appeared as some of the key factors influencing the properties of nanosized drug delivery systems. In particular, elongated materials are thought to interact differently with cells and therefore may allow alterations of in vivo fate without changes in chemical compo...

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Veröffentlicht in:	Biomaterials 2018-09, Vol.178, p.570-582
Hauptverfasser:	Larnaudie, Sophie C., Sanchis, Joaquin, Nguyen, Tri-Hung, Peltier, Raoul, Catrouillet, Sylvain, Brendel, Johannes C., Porter, Christopher J.H., Jolliffe, Katrina A., Perrier, Sébastien
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Schlagworte:	Animals Biodistribution Cell Line, Tumor Chemical Sciences Drug Delivery Systems Humans Male Methacrylates - chemistry Methacrylates - pharmacokinetics Nanotubes - chemistry Neutron Diffraction Peptide-polymer conjugates Peptides, Cyclic - blood Peptides, Cyclic - chemistry Peptides, Cyclic - pharmacokinetics Pharmacokinetics Polymers Polymers - chemical synthesis Polymers - chemistry Radiolabelling Rats, Sprague-Dawley Scattering, Radiation Supramolecular nanotubes Tissue Distribution
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creator	Larnaudie, Sophie C. Sanchis, Joaquin Nguyen, Tri-Hung Peltier, Raoul Catrouillet, Sylvain Brendel, Johannes C. Porter, Christopher J.H. Jolliffe, Katrina A. Perrier, Sébastien
description	Size and shape have progressively appeared as some of the key factors influencing the properties of nanosized drug delivery systems. In particular, elongated materials are thought to interact differently with cells and therefore may allow alterations of in vivo fate without changes in chemical composition. A challenge, however, remains the creation of stable self-assembled materials with anisotropic shape for delivery applications that still feature the ability to disassemble, avoiding organ accumulation and facilitating clearance from the system. In this context, we report on cyclic peptide-polymer conjugates that self-assemble into supramolecular nanotubes, as confirmed by SANS and SLS. Their behaviour ex and in vivo was studied: the nanostructures are non-toxic up to a concentration of 0.5 g L−1 and cell uptake studies revealed that the pathway of entry was energy-dependent. Pharmacokinetic studies following intravenous injection of the peptide-polymer conjugates and a control polymer to rats showed that the larger size of the nanotubes formed by the conjugates reduced renal clearance and elongated systemic circulation. Importantly, the ability to slowly disassemble into small units allowed effective clearance of the conjugates and reduced organ accumulation, making these materials interesting candidates in the search for effective drug carriers.
doi_str_mv	10.1016/j.biomaterials.2018.03.047
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In particular, elongated materials are thought to interact differently with cells and therefore may allow alterations of in vivo fate without changes in chemical composition. A challenge, however, remains the creation of stable self-assembled materials with anisotropic shape for delivery applications that still feature the ability to disassemble, avoiding organ accumulation and facilitating clearance from the system. In this context, we report on cyclic peptide-polymer conjugates that self-assemble into supramolecular nanotubes, as confirmed by SANS and SLS. Their behaviour ex and in vivo was studied: the nanostructures are non-toxic up to a concentration of 0.5 g L−1 and cell uptake studies revealed that the pathway of entry was energy-dependent. Pharmacokinetic studies following intravenous injection of the peptide-polymer conjugates and a control polymer to rats showed that the larger size of the nanotubes formed by the conjugates reduced renal clearance and elongated systemic circulation. 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Pharmacokinetic studies following intravenous injection of the peptide-polymer conjugates and a control polymer to rats showed that the larger size of the nanotubes formed by the conjugates reduced renal clearance and elongated systemic circulation. 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subjects	Animals Biodistribution Cell Line, Tumor Chemical Sciences Drug Delivery Systems Humans Male Methacrylates - chemistry Methacrylates - pharmacokinetics Nanotubes - chemistry Neutron Diffraction Peptide-polymer conjugates Peptides, Cyclic - blood Peptides, Cyclic - chemistry Peptides, Cyclic - pharmacokinetics Pharmacokinetics Polymers Polymers - chemical synthesis Polymers - chemistry Radiolabelling Rats, Sprague-Dawley Scattering, Radiation Supramolecular nanotubes Tissue Distribution
title	Cyclic peptide-poly(HPMA) nanotubes as drug delivery vectors: In vitro assessment, pharmacokinetics and biodistribution
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