Lipophilicity of Cationic Ligands Promotes Irreversible Adsorption of Nanoparticles to Lipid Bilayers

Lochbaum, Christian A.; Chew, Alex K.; Zhang, Xianzhi; Rotello, Vincent M.; Lehn, Reid C. Van; Pedersen, Joel A.

doi:10.1021/acsnano.0c09732

Cited by 31 publications

(66 citation statements)

References 54 publications

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“…21,22 Additionally, QCM has been extensively employed to study discrete adsorbates such as abiotic and biological macromolecules and nanoparticles (NPs). These studies included investigations of biomolecular interactions of proteins 23,24 and viruses; 25,26 structure, 27,28 confirmation 29,30 and orientation changes 31 of biomacromolecules; spatial distribution, 32 size, 33−35 deformation 36,37 and dissolution 38 of NPs; protein corona formation on amyloids; 39 interactions between NPs and biomimetic membranes; 40,41 as well as bioanalytical sensor development. 42−46 Yet, the inseparable nature of the adsorbate and liquid contributions to the measured response puts a significant limitation on quantitative interpretation of adsorption measurements in a liquid environment.…”

Section: ■ Introductionmentioning

confidence: 99%

“…Still, the rich information contained in combined Δ f n and Δ D n measurements, especially when complemented with theoretical models representing the response for viscoelastic films, − has turned out to be very valuable in multiple research areas, including hydration analysis of organic polymers, , proteins, and biological membranes. , QCM has also been widely applied to monitor and characterize thin films, including porosity determination, , monitoring the growth of mesoporous materials, probing responsiveness of polymeric coatings, and characterization of biomimetic membranes. , Additionally, QCM has been extensively employed to study discrete adsorbates such as abiotic and biological macromolecules and nanoparticles (NPs). These studies included investigations of biomolecular interactions of proteins , and viruses; , structure, , confirmation , and orientation changes of biomacromolecules; spatial distribution, size, − deformation , and dissolution of NPs; protein corona formation on amyloids; interactions between NPs and biomimetic membranes; , as well as bioanalytical sensor development. − …”

Section: Introductionmentioning

confidence: 99%

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Determination of Nanosized Adsorbate Mass in Solution Using Mechanical Resonators: Elimination of the So Far Inseparable Liquid Contribution

et al. 2021

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Assumption-free mass quantification of nanofilms, nanoparticles, and (supra)molecular adsorbates in a liquid environment remains a key challenge in many branches of science. Mechanical resonators can uniquely determine the mass of essentially any adsorbate; yet, when operating in a liquid environment, the liquid dynamically coupled to the adsorbate contributes significantly to the measured response, which complicates data interpretation and impairs quantitative adsorbate mass determination. Employing the Navier−Stokes equation for liquid velocity in contact with an oscillating surface, we show that the liquid contribution for rigid systems can be eliminated by measuring the response in solutions with identical kinematic viscosity but different densities. Guided by this insight, we used the quartz crystal microbalance (QCM), one of the most widely employed mechanical resonators, to experimentally demonstrate that the kinematic-viscosity matching can be utilized to quantify the dry mass of rigid and in many cases also nonrigid adsorbate systems, including, e.g., rigid nanoparticles, tethered biological nanoparticles (lipid vesicles), as well as highly hydrated polymeric films. For all the adsorbates, the dry mass determined using the kinematic-viscosity matching was within the uncertainty limits of the corresponding mass determined using complementary methods, i.e., QCM in air, scanning electron microscopy, surface plasmon resonance, and theoretical estimations. The same approach applied to the simultaneously measured energy dissipation made it possible to quantify the mechanical properties of the adsorbate and its attachment to the surface, as demonstrated by, for example, probing the hydrodynamic stabilization induced by nanoparticle crowding. In addition to a unique means to quantify the liquid contribution to the measured response of mechanical resonators, we also envision that the kinematic-viscosity-matching approach will open up applications beyond mass determination, including a new means to investigate orientation, spatial distribution, and binding strength of adsorbates without the need for complementary techniques.

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Section: ■ Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Determination of Nanosized Adsorbate Mass in Solution Using Mechanical Resonators: Elimination of the So Far Inseparable Liquid Contribution

et al. 2021

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“…15 The cascading effect of engineered NP properties on membrane attachment through dictating protein assemblage was elucidated by Melby et al 16 Recently, Lochbaum et al tuned the lipophilicity of cationic ligands on NPs and demonstrated its promotion to irreversible NP binding to supported lipid bilayers. 17 Using a complementary experimental and computational method, Tollefson et al determined the relative orientation of peripheral membrane proteins on functionalized NPs, 18 and proved its facilitating role in nanoparticle binding to model cell membranes. 19 Other properties, such as surface charge and chirality, were also found to modulate protein adsorption and conformation.…”

Section: ■ Introductionmentioning

confidence: 99%

“…Due to the large surface-to-volume ratio, nanoparticles (NPs) acquire coatings of biomolecules, such as proteins and natural organic matter (NOM), upon entering an aquatic environment. − Often referred to as the ecocorona, such molecular coating endows NPs with a new surface identity influencing NP behaviors at environmental and biological interfaces. − Continuous efforts have been made to understand biomolecular adsorption on various NPs and its downstream impacts on NP attachment to cell membranes, often using solid-supported lipid bilayers as model systems. − One previous study showed a lower amount of fullerene accumulated in supported lipid bilayers when adsorbed with humic acid (HA) due to surface modification of fullerene and the steric repulsion with the membrane . Mensch et al found effective binding of functionalized diamond NPs to the supported lipid bilayer only at lower NOM-to-NP ratios, as ascribed to changes in the hydrodynamic and electrokinetic properties by forming coronas .…”

Section: Introductionmentioning

confidence: 99%

Surface Properties of Nanoparticles Dictate Their Toxicity by Regulating Adsorption of Humic Acid Molecules

Wang

Yan

et al. 2021

ACS Sustainable Chem. Eng.

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In an aquatic environment, nanoparticles (NPs) acquire coatings of natural organic matter (NOM) that alter the fate and toxicity of NPs. However, the essential relationship between engineered NP properties and NOM assemblage that determines how NPs are modified and behave at biological interfaces remains unclear. Herein, we use a complementary experimental and molecular dynamics approach to elucidate the mechanisms underlying adsorption of humic acid (HA) on NPs of different surface properties and effects on NP interactions with bacteria. Our results demonstrate that hydrophobic and positively charged NPs are more capable of adsorbing HAs in unique standing or lying conformations that expose particular groups to modify NP properties. In particular, HA adsorption increases effective NP size, reduces NP’s hydrophobicity, and reverses NP’s surface charge. As a consequence of HA adsorption, the binding of NPs to bacteria is sterically hindered and suppressed by electrostatic repulsion between negatively charged groups in adsorbed HAs and lipopolysaccharide on the bacterial membrane. The toxicity of NPs is mitigated as seen by reductions of NP association with bacteria and NP-induced membrane damage. These findings provide compelling explanations on the cascading events from dictation of HA adsorption by engineered NP properties to how the modified NP surfaces change their toxicity.

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“…Therefore, it is proposed that a drug delivery system that can transport DOX to the tumor site should be developed to achieve better antitumor effect and reduce adverse reactions. Due to the advantages that traditional delivery systems do not have, nano-drug delivery systems have been widely studied as drug carriers, and many nano-drug delivery systems have been developed, such as magnetic nanoparticles ( Hosseinpour Moghadam et al, 2019 ), microemulsion ( Lv et al, 2018 ; Wang et al, 2019 ), liposomes ( Antimisiaris et al, 2021 ), gold nanoparticles ( Lochbaum et al, 2021 ), platinum nanoparticles ( Kawawaki et al, 2021 ), polymer micelles ( Yang et al, 2021 ), etc. In these drug delivery systems, polymeric micelles are considered to be effective nanocarriers because they can encapsulate hydrophobic agents into their “core-shell” structures and deliver them to tumor regions through enhanced permeability and retention (EPR) effect.…”

Section: Introductionmentioning

confidence: 99%

CD44/Folate Dual Targeting Receptor Reductive Response PLGA-Based Micelles for Cancer Therapy

et al. 2022

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In this study, a novel poly (lactic-co-glycolic acid) (PLGA)-based micelle was synthesized, which could improve the therapeutic effect of the antitumor drug doxorubicin hydrochloride (DOX) and reduce its toxic and side effects. The efficient delivery of DOX was achieved by active targeting mediated by double receptors and stimulating the reduction potential in tumor cells. FA-HA-SS-PLGA polymer was synthesized by amidation reaction, and then DOX-loaded micelles were prepared by dialysis method. The corresponding surface method was used to optimize the experimental design. DOX/FA-HA-SS-PLGA micelles with high drug loading rate and encapsulation efficiency were prepared. The results of hydrophilic experiment, critical micelle concentration determination, and hemolysis test all showed that DOX/FA-HA-SS-PLGA micelles had good physicochemical properties and biocompatibility. In addition, both in vitro reduction stimulus response experiment and in vitro release experiment showed that DOX/FA-HA-SS-PLGA micelles had reduction sensitivity. Molecular docking experiments showed that it can bind to the target protein. More importantly, in vitro cytology studies, human breast cancer cells (MCF-7), human non-small cell lung cancer cells (A549), and mouse colon cancer cells (CT26) were used to demonstrate that the dual receptor-mediated endocytosis pathway resulted in stronger cytotoxicity to tumor cells and more significant apoptosis. In and in vivo antitumor experiment, tumor-bearing nude mice were used to further confirm that the micelles with double targeting ligands had better antitumor effect and lower toxicity. These experimental results showed that DOX/FA-HA-SS-PLGA micelles have the potential to be used as chemotherapeutic drugs for precise tumor treatment.

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Lipophilicity of Cationic Ligands Promotes Irreversible Adsorption of Nanoparticles to Lipid Bilayers

Cited by 31 publications

References 54 publications

Determination of Nanosized Adsorbate Mass in Solution Using Mechanical Resonators: Elimination of the So Far Inseparable Liquid Contribution

Determination of Nanosized Adsorbate Mass in Solution Using Mechanical Resonators: Elimination of the So Far Inseparable Liquid Contribution

Surface Properties of Nanoparticles Dictate Their Toxicity by Regulating Adsorption of Humic Acid Molecules

CD44/Folate Dual Targeting Receptor Reductive Response PLGA-Based Micelles for Cancer Therapy

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