Your search keyword '"Davies, Catharina de Lange"' showing total 8 results

1. Tumor Targeting by αvβ3‑Integrin-Specific Lipid Nanoparticles Occurs via Phagocyte Hitchhiking.

Author

Sofias, Alexandros Marios, Toner, Yohana C., Meerwaldt, Anu E., van Leent, Mandy M. T., Soultanidis, Georgios, Elschot, Mattijs, Gonai, Haruki, Grendstad, Kristin, Flobak, Åsmund, Neckmann, Ulrike, Wolowczyk, Camilla, Fisher, Elizabeth L., Reiner, Thomas, Davies, Catharina de Lange, Bjørkøy, Geir, Teunissen, Abraham J. P., Ochando, Jordi, Pérez-Medina, Carlos, Mulder, Willem J. M., and Hak, Sjoerd

Published

2020

2. Tumor Targeting by αvβ3-Integrin-Specific Lipid Nanoparticles Occurs viaPhagocyte Hitchhiking

Author

Sofias, Alexandros Marios, Toner, Yohana C., Meerwaldt, Anu E., van Leent, Mandy M. T., Soultanidis, Georgios, Elschot, Mattijs, Gonai, Haruki, Grendstad, Kristin, Flobak, Åsmund, Neckmann, Ulrike, Wolowczyk, Camilla, Fisher, Elizabeth L., Reiner, Thomas, Davies, Catharina de Lange, Bjørkøy, Geir, Teunissen, Abraham J. P., Ochando, Jordi, Pérez-Medina, Carlos, Mulder, Willem J. M., and Hak, Sjoerd

Abstract

Although the first nanomedicine was clinically approved more than two decades ago, nanoparticles’ (NP) in vivobehavior is complex and the immune system’s role in their application remains elusive. At present, only passive-targeting nanoformulations have been clinically approved, while more complicated active-targeting strategies typically fail to advance from the early clinical phase stage. This absence of clinical translation is, among others, due to the very limited understanding for in vivotargeting mechanisms. Dynamic in vivophenomena such as NPs’ real-time targeting kinetics and phagocytes’ contribution to active NP targeting remain largely unexplored. To better understand in vivotargeting, monitoring NP accumulation and distribution at complementary levels of spatial and temporal resolution is imperative. Here, we integrate in vivopositron emission tomography/computed tomography imaging with intravital microscopy and flow cytometric analyses to study αvβ3-integrin-targeted cyclic arginine-glycine-aspartate decorated liposomes and oil-in-water nanoemulsions in tumor mouse models. We observed that ligand-mediated accumulation in cancerous lesions is multifaceted and identified “NP hitchhiking” with phagocytes to contribute considerably to this intricate process. We anticipate that this understanding can facilitate rational improvement of nanomedicine applications and that immune cell–NP interactions can be harnessed to develop clinically viable nanomedicine-based immunotherapies.

Published

2020

3. Near-Infrared Fluorescence Energy Transfer Imaging of Nanoparticle Accumulation and Dissociation Kinetics in Tumor-Bearing Mice

Author

Zhao, Yiming, van Rooy, Inge, Hak, Sjoerd, Fay, Francois, Tang, Jun, Davies, Catharina de Lange, Skobe, Mihaela, Fisher, Edward Allen, Radu, Aurelian, Fayad, Zahi. A., de Mello Donegá, Celso, Meijerink, Andries, and Mulder, Willem J. M.

Abstract

In the current study we show the dissociation and tumor accumulation dynamics of dual-labeled near-infrared quantum dot core self-assembled lipidic nanoparticles (SALNPs) in a mouse model upon intravenous administration. Using advanced in vivofluorescence energy transfer imaging techniques, we observed swift exchange with plasma protein components in the blood and progressive SALNP dissociation and subsequent trafficking of individual SALNP components following tumor accumulation. Our results suggest that upon intravenous administration SALNPs quickly transform, which may affect their functionality. The presented technology provides a modular in vivotool to visualize SALNP behavior in real time and may contribute to improving the therapeutic outcome or molecular imaging signature of SALNPs.

Published

2024

4. Quantification and Qualitative Effects of Different PEGylations on Poly(butyl cyanoacrylate) Nanoparticles

Author

Åslund, Andreas K. O., Sulheim, Einar, Snipstad, Sofie, von Haartman, Eva, Baghirov, Habib, Starr, Nichola, Kvåle Løvmo, Mia, Lelú, Sylvie, Scurr, David, Davies, Catharina de Lange, Schmid, Ruth, and Mørch, Ýrr

Abstract

Protein adsorption on nanoparticles (NPs) used in nanomedicine leads to opsonization and activation of the complement system in blood, which substantially reduces the blood circulation time of NPs. The most commonly used method to avoid protein adsorption is to coat the NPs with polyethylene glycol, so-called PEGylation. Although PEGylation is of utmost importance for designing the in vivobehavior of the NP, there is still a considerable lack of methods for characterization and fundamental understanding related to the PEGylation of NPs. In this work we have studied four different poly(butyl cyanoacrylate) (PBCA) NPs, PEGylated with different types of PEG-based nonionic surfactantsJeffamine M-2070, Brij L23, Kolliphor HS 15, Pluronic F68or combinations thereof. We evaluated the PEGylation, both quantitatively by nuclear magnetic resonance (NMR), thermogravimetric analysis (TGA), and time-of-flight secondary ion mass spectrometry (ToF-SIMS) and qualitatively by studying ζ-potential, protein adsorption, diffusion, cellular interactions, and blood circulation half-life. We found that NMR and ToF-SIMS are complementary methods, while TGA is less suitable to quantitate PEG on polymeric NPs. It was found that longer PEG increases both blood circulation time and diffusion of NPs in collagen gels.

Published

2017

5. Intraperitoneal administration of cabazitaxel-loaded nanoparticles in peritoneal metastasis models.

Author

Hyldbakk, Astrid, Fleten, Karianne Giller, Snipstad, Sofie, Åslund, Andreas K.O., Davies, Catharina de Lange, Flatmark, Kjersti, and Mørch, Yrr

Subjects

RADIOACTIVE tracers, NANOPARTICLES, INTRAPERITONEAL injections, CABAZITAXEL, IRINOTECAN, METASTASIS, TREATMENT effectiveness

Abstract

Colorectal and ovarian cancers frequently develop peritoneal metastases with few treatment options. Intraperitoneal chemotherapy has shown promising therapeutic effects, but is limited by rapid drug clearance and systemic toxicity. We therefore encapsulated the cabazitaxel taxane in poly(alkyl cyanoacrylate) (PACA) nanoparticles (NPs), designed to improve intraperitoneal delivery. Toxicity of free and encapsulated cabazitaxel was investigated in rats by monitoring clinical signs, organ weight and blood hematological and biochemical parameters. Pharmacokinetics, biodistribution and treatment response were evaluated in mice. Biodistribution was investigated by measuring both cabazitaxel and the 2-ethylbutanol NP degradation product. Drug encapsulation was shown to increase intraperitoneal drug retention, leading to prolonged intraperitoneal drug residence time and higher drug concentrations in peritoneal tumors. As a result, encapsulation of cabazitaxel improved the treatment response in two in vivo models bearing intraperitoneal tumors. Together, these observations indicate a strong therapeutic potential of NP-based cabazitaxel encapsulation as a novel treatment for peritoneal metastases. The schematic illustration demonstrates that intraperitoneal treatment of cabazitaxel-loaded PACA nanoparticles (PACAB) leads to peritoneal drug retention, causing high local drug concentrations and increased survival in a murine tumor xenograft model. [Display omitted] • PACA drug encapsulation improves treatment response in peritoneal metastases models. • Intraperitoneal injection of PACA nanoparticles provides a beneficial drug biodistribution. • Drug encapsulation in PACA nanoparticles improves intraperitoneal drug retention. • The taxane cabazitaxel is a promising chemotherapy option for peritoneal metastases. [ABSTRACT FROM AUTHOR]

Published

2023

6. The Effect of Nanoparticle Polyethylene Glycol Surface Density on Ligand-Directed Tumor Targeting Studied in Vivoby Dual Modality Imaging

Author

Hak, Sjoerd, Helgesen, Emily, Hektoen, Helga H., Huuse, Else Marie, Jarzyna, Peter A., Mulder, Willem J.M., Haraldseth, Olav, and Davies, Catharina de Lange

Abstract

The development and application of nanoparticles as in vivodelivery vehicles for therapeutic and/or diagnostic agents has seen a drastic growth over the last decades. Novel imaging techniques allow real-time in vivostudy of nanoparticle accumulation kinetics at the level of the cell and targeted tissue. Successful intravenous application of such nanocarriers requires a hydrophilic particle surface coating, of which polyethylene glycol (PEG) has become the most widely studied and applied. In the current study, the effect of nanoparticle PEG surface density on the targeting efficiency of ligand-functionalized nanoemulsions was investigated. We synthesized 100 nm nanoemulsions with a PEG surface density varying from 5 to 50 mol %. Fluorescent and paramagnetic lipids were included to allow their multimodal detection, while RGD peptides were conjugated to the PEG coating to obtain specificity for the αvβ3-integrin. The development of a unique experimental imaging setup allowed us to study, in real time, nanoparticle accumulation kinetics at (sub)-cellular resolution in tumors that were grown in a window chamber model with confocal microscopy imaging, and at the macroscopic tumor level in subcutaneously grown xenografts with magnetic resonance imaging. Accumulation in the tumor occurred more rapidly for the targeted nanoemulsions than for the nontargeted versions, and the PEG surface density had a strong effect on nanoparticle targeting efficiency. Counterintuitively, yet consistent with the PEG density conformation models, the highest specificity and targeting efficiency was observed at a low PEG surface density.

Published

2012

7. Decorin Inhibits Endothelial Migration and Tube-like Structure Formation: Role of Thrombospondin-1

Author

Davies, Catharina de Lange, Melder, Robert J., Munn, Lance L., Mouta-Carreira, Carla, Jain, Rakesh K., and Boucher, Yves

Abstract

Interactions between endothelial cell receptors and the extracellular matrix (ECM) play a critical, yet poorly understood role in angiogenesis. Based on the anti-adhesive role of decorin, we hypothesized that decorin binding to ECM molecules such as thrombospondin-1 (TSP-1) plays a regulatory role in endothelial tube-like structure (TLS) formation. To test this hypothesis, endothelial cells were plated on TSP-1, decorin, or mixed substrates of TSP-1 plus decorin. TLS formation was induced by applying type I collagen on the confluent endothelial monolayer. Cartilage decorin inhibited the formation of TLSs in a concentration-dependent manner. On substrates of high decorin concentrations (2.5 and 5.0 μg/cm2) the reduction in TLSs was due either to a reduction in the number of adhering cells or to decreased cell migration. At low decorin concentrations (0.05 and 0.25 μg/cm2) the reduction in TLSs was independent of the number of attached cells. Time-lapse video microscopy revealed that decorin substrates facilitated homotypic aggregation and isolated cord formation at the expense of endothelial migration and TLS formation. Consistent with the reduced migration, endothelial cells formed fewer vinculin-positive focal adhesions and actin-stress fibers on decorin substrates. Endothelial migration and TLS formation were also significantly inhibited by skin decorin and the protein core of cartilage decorin. The inhibition of TLS formation by the protein core of cartilage decorin was potentiated by TSP-1. These findings suggest that decorin alone or in combination with TSP-1 interferes with the activation of endothelial cell receptors by ECM molecules, thus blocking intracellular signals that induce cytoskeletal reorganization, migration, and TLS formation.

Published

2001

8. Enhancing carrier flux for efficient drug delivery in cancer tissues

Author

Arango-Restrepo, Andrés, Rubi, J. Miguel, Kjelstrup, Signe, Angelsen, Bjørn Atle J., and Davies, Catharina de Lange

Abstract

Ultrasound focused toward tumors in the presence of circulating microbubbles improves the delivery of drug-loaded nanoparticles and therapeutic outcomes; however, the efficacy varies among the different properties and conditions of the tumors. Therefore, there is a need to optimize the ultrasound parameters and determine the properties of the tumor tissue important for the successful delivery of nanoparticles. Here, we propose a mesoscopic model considering the presence of entropic forces to explain the ultrasound-enhanced transport of nanoparticles across the capillary wall and through the interstitium of tumors. The nanoparticles move through channels of variable shape whose irregularities can be assimilated to barriers of entropic nature that the nanoparticles must overcome to reach their targets. The model assumes that focused ultrasound and circulating microbubbles cause the capillary wall to oscillate, thereby changing the width of transcapillary and interstitial channels. Our analysis provides values for the penetration distances of nanoparticles into the interstitium that are in agreement with experimental results. We found that the penetration increased significantly with increasing acoustic intensity as well as tissue elasticity, which means softer and more deformable tissue (Young modulus lower than 50 kPa), whereas porosity of the tissue and pulse repetition frequency of the ultrasound had less impact on the penetration length. We also considered that nanoparticles can be absorbed into cells and to extracellular matrix constituents, finding that the penetration length is increased when there is a low absorbance coefficient of the nanoparticles compared with their diffusion coefficient (close to 0.2). The model can be used to predict which tumor types, in terms of elasticity, will successfully deliver nanoparticles into the interstitium. It can also be used to predict the penetration distance into the interstitium of nanoparticles with various sizes and the ultrasound intensity needed for the efficient distribution of the nanoparticles.

Published

2021