The Effect of Ligand Mobility on the Cellular Interaction of Multivalent Nanoparticles

Figueroa, Sara Maslanka; Fleischmann, Daniel; Beck, Sebastian; Goepferich, Achim

doi:10.1002/mabi.201900427

Cited by 19 publications

(18 citation statements)

References 47 publications

(64 reference statements)

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“…The conjugated PEG allows to minimize the use of formulation stabilizers and importantly, it decreases the formation of protein corona after administration and results in extended systemic circulation of the NPs [33][34][35][36]. Furthermore, the PEG chain terminated with targeting ligands, demonstrated positive results in in vitro studies [22,37].…”

Section: Introductionmentioning

confidence: 99%

Formulation of tunable size PLGA-PEG nanoparticles for drug delivery using microfluidic technology

et al. 2021

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Amphiphilic block co-polymer nanoparticles are interesting candidates for drug delivery as a result of their unique properties such as the size, modularity, biocompatibility and drug loading capacity. They can be rapidly formulated in a nanoprecipitation process based on self-assembly, resulting in kinetically locked nanostructures. The control over this step allows us to obtain nanoparticles with tailor-made properties without modification of the co-polymer building blocks. Furthermore, a reproducible and controlled formulation supports better predictability of a batch effectiveness in preclinical tests. Herein, we compared the formulation of PLGA-PEG nanoparticles using the typical manual bulk mixing and a microfluidic chip-assisted nanoprecipitation. The particle size tunability and controllability in a hydrodynamic flow focusing device was demonstrated to be greater than in the manual dropwise addition method. We also analyzed particle size and encapsulation of fluorescent compounds, using the common bulk analysis and advanced microscopy techniques: Transmission Electron Microscopy and Total Internal Reflection Microscopy, to reveal the heterogeneities occurred in the formulated nanoparticles. Finally, we performed in vitro evaluation of obtained NPs using MCF-7 cell line. Our results show how the microfluidic formulation improves the fine control over the resulting nanoparticles, without compromising any appealing property of PLGA nanoparticle. The combination of microfluidic formulation with advanced analysis methods, looking at the single particle level, can improve the understanding of the NP properties, heterogeneities and performance.

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Section: Introductionmentioning

confidence: 99%

Formulation of tunable size PLGA-PEG nanoparticles for drug delivery using microfluidic technology

et al. 2021

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“…In a bid to examine the role of ligand mobility, cellular uptake of PLA-PEG nanoparticles bound to angiotensin-II was investigated using rat mesangial cells. It was found that a lower ligand density (20%) allowed more ligand mobility and enhanced binding to specific receptors, increasing it to 80%, and decreased cellular uptake, which may be associated with lower free movement of NPs [105].…”

Section: Ligand Bindingmentioning

confidence: 99%

Effect of Physico-Chemical Properties of Nanoparticles on Their Intracellular Uptake

Sabourian

Yazdani

Ashraf

et al. 2020

IJMS

123

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Cellular internalization of inorganic, lipidic and polymeric nanoparticles is of great significance in the quest to develop effective formulations for the treatment of high morbidity rate diseases. Understanding nanoparticle–cell interactions plays a key role in therapeutic interventions, and it continues to be a topic of great interest to both chemists and biologists. The mechanistic evaluation of cellular uptake is quite complex and is continuously being aided by the design of nanocarriers with desired physico-chemical properties. The progress in biomedicine, including enhancing the rate of uptake by the cells, is being made through the development of structure–property relationships in nanoparticles. We summarize here investigations related to transport pathways through active and passive mechanisms, and the role played by physico-chemical properties of nanoparticles, including size, geometry or shape, core-corona structure, surface chemistry, ligand binding and mechanical effects, in influencing intracellular delivery. It is becoming clear that designing nanoparticles with specific surface composition, and engineered physical and mechanical characteristics, can facilitate their internalization more efficiently into the targeted cells, as well as enhance the rate of cellular uptake.

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“… NP Ligands Targets Optimal ligand density/structure In vivo Therapy/Cargo Ref. Quantum dots Peptide NPY 1 receptor – – – [ 73 ] PAMAM dendrimers/Branched PEG Small molecule AT1R – – – [ 103 ] PEG-PLA/PLGA NPs “-” “-” 20% (+ high mobility) – – [ 113 ] PEG-PLGA NPs Folate Folate receptor >10% – DNA [ 110 ] Linear dendritic polymer NPs “-” “-” 20% KB/A375 tumors (mouse) – [ 114 ] Polystyrene/Ovalbumin NPs “-” “-” clustered – – [ 121 ] PLGA NPs Peptide ICAM-1 50% – – [ 111 ] Iron oxide NPs Antibody HER2/neu 23 ligands/NP (medium density) – – [ 112 ] PEG-Au NPs RGD αvβ3 integrin high – – [ 115 ] PEG-PLA/PLGA NPs c(RGDfK) “-” “-” – ...…”

Section: Ligand Display and Cell Recognitionmentioning

confidence: 99%

“…Similarly, Elias et al [ 112 ] found that an intermediate ligand density was optimal for targeting purposes using antibodies against HER2/neu, overexpressed in cancer cells. Generally, decreases in targeting with higher grafting densities are explained by a steric hindrance of the ligands and decreased ligand mobility [ 113 ]. This may disrupt interaction with the receptors to a point where their internalization is impeded.…”

Section: Ligand Display and Cell Recognitionmentioning

confidence: 99%

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Biomedical nanoparticle design: What we can learn from viruses

Figueroa

Fleischmann

Goepferich

2021

Journal of Controlled Release

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Viruses are nanomaterials with a number of properties that surpass those of many synthetic nanoparticles (NPs) for biomedical applications. They possess a rigorously ordered structure, come in a variety of shapes, and present unique surface elements, such as spikes. These attributes facilitate propitious biodistribution, the crossing of complex biological barriers and a minutely coordinated interaction with cells. Due to the orchestrated sequence of interactions of their stringently arranged particle corona with cellular surface receptors they effectively identify and infect their host cells with utmost specificity, while evading the immune system at the same time. Furthermore, their efficacy is enhanced by their response to stimuli and the ability to spread from cell to cell. Over the years, great efforts have been made to mimic distinct viral traits to improve biomedical nanomaterial performance. However, a closer look at the literature reveals that no comprehensive evaluation of the benefit of virus-mimetic material design on the targeting efficiency of nanomaterials exists. In this review we, therefore, elucidate the impact that viral properties had on fundamental advances in outfitting nanomaterials with the ability to interact specifically with their target cells. We give a comprehensive overview of the diverse design strategies and identify critical steps on the way to reducing them to practice. More so, we discuss the advantages and future perspectives of a virus-mimetic nanomaterial design and try to elucidate if viral mimicry holds the key for better NP targeting.

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The Effect of Ligand Mobility on the Cellular Interaction of Multivalent Nanoparticles

Cited by 19 publications

References 47 publications

Formulation of tunable size PLGA-PEG nanoparticles for drug delivery using microfluidic technology

Formulation of tunable size PLGA-PEG nanoparticles for drug delivery using microfluidic technology

Effect of Physico-Chemical Properties of Nanoparticles on Their Intracellular Uptake

Biomedical nanoparticle design: What we can learn from viruses

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