Correction to "Luminescent Gold Nanocluster-Decorated Polymeric Hybrid Particles with Assembly-Induced Emission"

Correction to “Luminescent Gold Nanocluster-Decorated Polymeric Hybrid Particles with Assembly-Induced Emission

Liposomal formulations of mistletoe produced by centrifugal technologies and cell proliferation analysis of both mistletoe extracts and isolated mistletoe lectin I = Liposomale Formulierung von Mistelextrakten durch Zentrifugationsverfahren und Analyse der Zellproliferation von Gesamtextrakten und isoliertem Mistellektin I

Um Liposomen aus Nanoemulsionen herzustellen, wird ein Zentrifugationsverfahren entwickelt, das eine hohe Einkapselungseffizienz und asymmetrische Membranen ermöglicht. Heparin-Komplexe werden für die Bildung einer stabilen Schutzschicht verwendet. Um die Erprobung der liposomalen Formulierungen in vitro und in vivo zu ermöglichen, wurden Mistelpräparate mit unterschiedlicher Viscotoxin-(VT) und Mistellektin-(ML) Zusammensetzung sowie isoliertes ML°I an Maus-Zelllinien erprobt. Ein Proliferationstest wurde durchgeführt, um die inhibierenden Konzentrationen (IC50) zu ermitteln und sensitive Zelllinien für in vivo Experimente auszuwählen. abnobaVISCUM (AV) Pini Präparate, die den geringsten Gesamtgehalt an ML und eine Dominanz von ML III aufweisen, zeigten bei B16-F10 Melanomzellen eine stärkere Inhibierung der Proliferation im Vergleich zu den ML I reichen Präparaten AV Fraxini und Quercus. Für AV Fraxnini und AV Quercus wurde gezeigt, dass die Zytotoxizität überwiegend auf ML I zurückzuführen ist und ML I daher als potentieller Wirkstoff zur Verkapselung in Liposomen geeignet ist. Auf isoliertes ML I reagiert die getestete Kolonkarzinomzelllinie C26 deutlich empfindlicher als die aggressive B16-F10 Melanomzelllinie. Diese Ergebnisse erlauben den Vergleich eines sensitiven mit einem aggressiven Tumormodell in vivo. Im Vergleich zu C26 ist die Makrophagenzelllinie RAW264.7 relativ unempfindlich gegenüber isoliertem ML I. Die Ergebnisse deuten auf die Möglichkeit einer gezielten Therapie von z.B. Kolontumoren hin, bei der die Immunfunktionen intakt bleiben

Biotin-decorated all-HPMA polymeric micelles for paclitaxel delivery

To avoid poly(ethylene glycol)-related issues of nanomedicines such as accelerated blood clearance, fully N-2-hydroxypropyl methacrylamide (HPMAm)-based polymeric micelles decorated with biotin for drug delivery were designed. To this end, a biotin-functionalized chain transfer agent (CTA), 4-cyano-4-[(dodecylsulfanylthiocarbonyl)-sulfanyl]pentanoic acid (biotin-CDTPA), was synthesized for reversible addition-fragmentation chain-transfer (RAFT) polymerization. Amphiphilic poly(N-2-hydroxypropyl methacrylamide)-block-poly(N-2-benzoyloxypropyl methacrylamide) (p(HPMAm)-b-p(HPMAm-Bz)) with molecular weights ranging from 8 to 24 kDa were synthesized using CDTPA or biotin-CDTPA as CTA and 2,2'-azobis(2-methylpropionitrile) as initiator. The copolymers self-assembled in aqueous media into micelles with sizes of 40-90 nm which positively correlated to the chain length of the hydrophobic block in the polymers, whereas the critical micelle concentrations decreased with increasing hydrophobic block length. The polymer with a molecular weight of 22.1 kDa was used to prepare paclitaxel-loaded micelles which had sizes between 61 and 70 nm, and a maximum loading capacity of around 10 wt%. A549 lung cancer cells overexpressing the biotin receptor, internalized the biotin-decorated micelles more efficiently than non-targeted micelles, while very low internalization of both types of micelles by HEK293 human embryonic kidney cells lacking the biotin receptor was observed. As a consequence, the paclitaxel-loaded micelles with biotin decoration exhibited stronger cytotoxicity in A549 cells than non-targeted micelles. Overall, a synthetic pathway to obtain actively targeted poly(ethylene glycol)-free micelles fully based on a poly(HPMAm) backbone was established. These polymeric micelles are promising systems for the delivery of hydrophobic anticancer drugs

Dérivés amphiphiles de la riboflavine pour le développement de nanosystèmes à ciblage tumoral

Riboflavin (RF) is an essential vitamin for cell growth and development. It possesses interesting physicochemical properties and is internalized by the cells through specific transporters. The first aim of this study was to prepare amphiphile derivatives of RF (RFA) and study their auto-assembly. The second aim was to insert RFA into established drug delivery systems and test their tumour-targeting potential in vitro and in vivo. RFA were prepared by the molecule functionalization with lipid moieties in different positions. One of them, a phospholipid-like derivative (RfdiC14) was able to self-assembly in aqueous solutions into μm-sized 3D objects constituted from slightly curved multilayer lamellas. The bilayer architecture and dynamics were very different from ordinary phospholipids. In contrast, the insertion of small amount of RfdiC14 in a liposome did not influence membrane dynamics and physicochemical characteristics. RfdiC14-functionalised liposomes displayed high and specific uptake in vitro in A431, PC3 cells and HUVECs. The efficiency of RF targeting was also tested in vivo. For that purpose, liposome composition was optimized and a new RF amphiphile with a PEG spacer between RF and lipid was prepared. The tumour accumulation of the liposomes labelled with ICG was studied by photoacoustic imaging in A431 tumour model. The biodistribution of DiR labelled liposomes was accessed by combined μCT/FMT imaging in PC3 tumour model. The results show slight improvement of the tumour accumulation in A431 xenographts and the enhancement of vascular targeting in PC3 tumour model. The overall biodistribution of the RF-targeted liposomes was comparable to control.La riboflavine (RF) est une vitamine essentielle pour la croissance et le développement cellulaire. Elle possède des propriétés physico-chimiques intéressantes et est internalisée dans les cellules par des transporteurs spécifiques. Le premier objectif de ce projet était de synthétiser des dérivés amphiphiles de la RF (RFA) et d'étudier leurs capacités d'auto-assemblages. Le second objectif était d'insérer les RFA dans des liposomes et d'évaluer leur efficacité de ciblage tumoral in vitro et in vivo. La préparation des différents RFA repose sur l'ajout d'un lipide en différentes positions de la RF. L’un d'eux, de type phospholipide (RfdiC14) a été capable de former des objets tridimensionnels de taille μm constitués de lamelles multicouches dont l’architecture et la dynamique sont très différentes de celles des phospholipides classiques. L’insertion de RfdiC14 dans des liposomes est efficace et n’influence pas leurs propriétés physico-chimiques. Les liposomes fonctionnalisés ont montré une internalisation cellulaire spécifique dans les lignées A431, PC3 et HUVECs. Afin de tester l’efficacité du ciblage tumoral in vivo, un analogue de RfdiC14 portant un espaceur PEG a été préparé puis inséré dans des liposomes péguylés. Grâce à un marquage adéquat (ICG et DiR), leur accumulation tumorale a été suivie par imagerie photoacoustique dans un modèle A431 et leur biodistribution évaluée par imagerie μCT/FMT dans un modèle PC3. Les résultats montrent une légère amélioration de l’accumulation tumorale dans les xénogreffes A431 et une augmentation du ciblage vasculaire dans le modèle tumoral PC3. La biodistribution globale des liposomes marqués est comparable à celle des contrôles

Riboflavin-based amphiphiles for tumour-targeted nanosystems

La riboflavine (RF) est une vitamine essentielle pour la croissance et le développement cellulaire. Elle possède des propriétés physico-chimiques intéressantes et est internalisée dans les cellules par des transporteurs spécifiques. Le premier objectif de ce projet était de synthétiser des dérivés amphiphiles de la RF (RFA) et d'étudier leurs capacités d'auto-assemblages. Le second objectif était d'insérer les RFA dans des liposomes et d'évaluer leur efficacité de ciblage tumoral in vitro et in vivo. La préparation des différents RFA repose sur l'ajout d'un lipide en différentes positions de la RF. L’un d'eux, de type phospholipide (RfdiC14) a été capable de former des objets tridimensionnels de taille μm constitués de lamelles multicouches dont l’architecture et la dynamique sont très différentes de celles des phospholipides classiques. L’insertion de RfdiC14 dans des liposomes est efficace et n’influence pas leurs propriétés physico-chimiques. Les liposomes fonctionnalisés ont montré une internalisation cellulaire spécifique dans les lignées A431, PC3 et HUVECs. Afin de tester l’efficacité du ciblage tumoral in vivo, un analogue de RfdiC14 portant un espaceur PEG a été préparé puis inséré dans des liposomes péguylés. Grâce à un marquage adéquat (ICG et DiR), leur accumulation tumorale a été suivie par imagerie photoacoustique dans un modèle A431 et leur biodistribution évaluée par imagerie μCT/FMT dans un modèle PC3. Les résultats montrent une légère amélioration de l’accumulation tumorale dans les xénogreffes A431 et une augmentation du ciblage vasculaire dans le modèle tumoral PC3. La biodistribution globale des liposomes marqués est comparable à celle des contrôles.Riboflavin (RF) is an essential vitamin for cell growth and development. It possesses interesting physicochemical properties and is internalized by the cells through specific transporters. The first aim of this study was to prepare amphiphile derivatives of RF (RFA) and study their auto-assembly. The second aim was to insert RFA into established drug delivery systems and test their tumour-targeting potential in vitro and in vivo. RFA were prepared by the molecule functionalization with lipid moieties in different positions. One of them, a phospholipid-like derivative (RfdiC14) was able to self-assembly in aqueous solutions into μm-sized 3D objects constituted from slightly curved multilayer lamellas. The bilayer architecture and dynamics were very different from ordinary phospholipids. In contrast, the insertion of small amount of RfdiC14 in a liposome did not influence membrane dynamics and physicochemical characteristics. RfdiC14-functionalised liposomes displayed high and specific uptake in vitro in A431, PC3 cells and HUVECs. The efficiency of RF targeting was also tested in vivo. For that purpose, liposome composition was optimized and a new RF amphiphile with a PEG spacer between RF and lipid was prepared. The tumour accumulation of the liposomes labelled with ICG was studied by photoacoustic imaging in A431 tumour model. The biodistribution of DiR labelled liposomes was accessed by combined μCT/FMT imaging in PC3 tumour model. The results show slight improvement of the tumour accumulation in A431 xenographts and the enhancement of vascular targeting in PC3 tumour model. The overall biodistribution of the RF-targeted liposomes was comparable to control

Amphiphilic Phospholipid-Based Riboflavin Derivatives for Tumor Targeting Nanomedicines

Riboflavin (RF) is an essential vitamin for cellular metabolism. Recent studies have shown that RF is internalized through RF transporters, which are highly overexpressed by prostate and breast cancer cells, as well as by angiogenic endothelium. Here, we present an optimized synthesis protocol for preparing tailor-made amphiphilic phospholipid-based RF derivatives using phosphoramidite chemistry. The prepared RF amphiphile-RfdiC14-can be inserted into liposome formulations for targeted drug delivery. The obtained liposomes had a hydrodynamic size of 115 ± 5 nm with narrow size distribution (PDI 0.06) and a zeta potential of -52 ± 3 mV. In vitro uptake studies showed that RfdiC14-containing liposomes were strongly internalized in HUVEC, PC3, and A431 cells, in a specific and transporter-mediated manner. To assess the RF targeting potential in vivo, an amphiphile containing PEG spacer between RF and a lipid was prepared-DSPE-PEG-RF. The latter was successfully incorporated into long-circulating near-infrared-labeled liposomes (141 ± 1 nm in diameter, PDI 0.07, zeta potential of -33 ± 1 mV). The longitudinal μCT/FMT biodistribution studies in PC3 xenograft bearing mice demonstrated similar pharmacokinetics profile of DSPE-PEG-RF-functionalized liposomes compared to control. The subsequent histological evaluation of resected tumors revealed higher degree of tumor retention as well as colocalization of targeted liposomes with endothelial cells emphasizing the targeting potential of RF amphiphiles and their utility for the lipid-containing drug delivery systems

Selective Cytotoxicity to HER2 Positive Breast Cancer Cells by Saporin-Loaded Nanobody-Targeted Polymeric Nanoparticles in Combination With Photochemical Internalization

In cancer treatment, polymeric nanoparticles (NPs) can serve as a vehicle for the delivery of cytotoxic proteins that have intracellular targets but that lack well-defined mechanisms for cellular internalization, such as saporin. In this work we have prepared PEGylated poly(lactic acid-co-glycolic acid-co-hydroxymethyl glycolic acid) (PLGHMGA) NPs for the selective delivery of saporin in the cytosol of HER2 positive cancer cells. This selective uptake was achieved by decorating the surface of the NPs with the 11A4 nanobody that is specific for the HER2 receptor. Confocal microscopy observations showed rapid and extensive uptake of the targeted NPs (11A4-NPs) by HER2 positive cells (SkBr3), but not by HER2 negative cells (MDA-MB-231). This selective uptake was blocked upon pre-incubation of the cells with an excess of nanobody. Non-targeted NPs (Cys-NPs) were not taken up by either type of cells. Importantly, a dose-dependent cytotoxic effect was only observed on SkBr3 cells when these were treated with saporin-loaded 11A4-NPs in combination with photochemical internalization (PCI), a technique that uses a photosensitizer and local light exposure to facilitate endosomal escape of entrapped nanocarriers and biomolecules. The combined use of saporin-loaded 11A4-NPs and PCI strongly inhibited cell proliferation and decreased cell viability through induction of apoptosis. Also the cytotoxic effect could be reduced by an excess of nanobody, reinforcing the selectivity of this system. These results suggest that the combination of the targeting nanobody on the NPs with PCI are effective means to achieve selective uptake and cytotoxicity of saporin-loaded NPs

Selective Cytotoxicity to HER2 Positive Breast Cancer Cells by Saporin-Loaded Nanobody-Targeted Polymeric Nanoparticles in Combination With Photochemical Internalization

In cancer treatment, polymeric nanoparticles (NPs) can serve as a vehicle for the delivery of cytotoxic proteins that have intracellular targets but that lack well-defined mechanisms for cellular internalization, such as saporin. In this work we have prepared PEGylated poly(lactic acid-co-glycolic acid-co-hydroxymethyl glycolic acid) (PLGHMGA) NPs for the selective delivery of saporin in the cytosol of HER2 positive cancer cells. This selective uptake was achieved by decorating the surface of the NPs with the 11A4 nanobody that is specific for the HER2 receptor. Confocal microscopy observations showed rapid and extensive uptake of the targeted NPs (11A4-NPs) by HER2 positive cells (SkBr3), but not by HER2 negative cells (MDA-MB-231). This selective uptake was blocked upon pre-incubation of the cells with an excess of nanobody. Non-targeted NPs (Cys-NPs) were not taken up by either type of cells. Importantly, a dose-dependent cytotoxic effect was only observed on SkBr3 cells when these were treated with saporin-loaded 11A4-NPs in combination with photochemical internalization (PCI), a technique that uses a photosensitizer and local light exposure to facilitate endosomal escape of entrapped nanocarriers and biomolecules. The combined use of saporin-loaded 11A4-NPs and PCI strongly inhibited cell proliferation and decreased cell viability through induction of apoptosis. Also the cytotoxic effect could be reduced by an excess of nanobody, reinforcing the selectivity of this system. These results suggest that the combination of the targeting nanobody on the NPs with PCI are effective means to achieve selective uptake and cytotoxicity of saporin-loaded NPs

Small nanosized poly(vinyl benzyl trimethylammonium chloride) based polyplexes for siRNA delivery

The success of siRNA gene therapy requires the availability of safe and efficient delivery systems. In the present study, we investigated poly(vinyl benzyl trimethylammonium chloride) (PVTC) and its block copolymer with poly(oligo(ethyleneglycol) methacrylate) (POEGMA) as delivery vector for siRNA. Small polyplexes ranging from 8 to 25 nm in diameter were formed in aqueous solution by spontaneous self-assembly of both the homopolymer and block copolymer with siRNA and the formed particles were stable at physiological ionic strength. It was shown that when human ovarian adenocarcinoma cells were transfected, siRNA polyplexes based on PVTC (40 kDa) and PVTC-POEGMA-4 (PP4, 34 kDa) efficiently induced luciferase gene silencing to the same extent as the formulation based on a commercial lipid (Lipofectamine®) (∼80%), and showed higher gene silencing than the linear polyethylenimine formulation linear polyethylenimine (∼35%). Importantly, the POEGMA block polymers displayed a significantly lower cytotoxicity as compared to L-pEI. siRNA polyplexes based on the block polymers displayed high cellular uptake resulting in ∼50% silencing of luciferase expression also in the presence of serum. These results demonstrate that PVTC-based polymers are promising siRNA delivery vectors