Mechanochemical Cellular Membrane Internalization of Nanohydrogels: A Large-Scale Mesoscopic Simulation

Song, Xianyu; Ma, Jule; Long, Ting; Xu, Xiaofei; Zhao, Teng; Liu, Honglai

doi:10.1021/acsami.0c16688

Cited by 21 publications

(7 citation statements)

References 68 publications

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“…To confirm our hypothesis about the behavior of soft and hard NGs, the mesoscopic computer simulations of the adsorption of single particles onto the lipid membrane were performed. [25] We simulated the PEG NGs, which have the same hydrodynamic radii in the swollen state ( � 15 nm) and differ in the cross-linking density (5 % for the soft network and 10 % for the hard network). In turn, the membrane is modeled as a bilayer composed of lipids of a single sort.…”

Section: Resultsmentioning

confidence: 99%

Tuning the Elasticity of Nanogels Improves Their Circulation Time by Evading Immune Cells

et al. 2022

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Peptide receptor radionuclide therapy is used to treat solid tumors by locally delivering radiation. However, due to nephro‐ and hepato‐toxicity, it is limited by its dosage. To amplify radiation damage to tumor cells, radiolabeled nanogels can be used. We show that by tuning the mechanical properties of nanogels significant enhancement in circulation half‐life of the gel could be achieved. We demonstrate why and how small changes in the mechanical properties of the nanogels influence its cellular fate. Nanogels with a storage modulus of 37 kPa were minimally phagocytosed by monocytes and macrophages compared to nanogels with 93 kPa modulus. Using PET/CT a significant difference in the blood circulation time of the nanogels was shown. Computer simulations affirmed the results and predicted the mechanism of cellular uptake of the nanogels. Altogether, this work emphasizes the important role of elasticity even for particles that are inherently soft such as nano‐ or microgels.

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Section: Resultsmentioning

confidence: 99%

Tuning the Elasticity of Nanogels Improves Their Circulation Time by Evading Immune Cells

et al. 2022

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“…Thus, the engulfing behavior of the inhomogeneous cross-linked microgel may differ from the regular cross-linked one. More realistic cross-linked models for microgels, such as inhomogeneous or disorder network architecture should be considered in future work. , …”

Section: Results and Discussionmentioning

confidence: 99%

“…More realistic cross-linked models for microgels, such as inhomogeneous or disorder network architecture should be considered in future work. 23,65 The typical trajectories for a mobile microgel and nanoparticle are illustrated in Figure 5. Though different temperatures are considered, the three-dimensional trajectories of the microgel and nanoparticle are approximately paralleled, as displayed in Figure 5, parts A and B, respectively.…”

Section: Interfacial Elastocapillarity Evaluationmentioning

confidence: 99%

Engulfing Behavior of Nanoparticles into Thermoresponsive Microgels: A Mesoscopic Simulation Study

et al. 2021

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The engulfing of nanoparticles into microgels provides a versatile platform to design nano- and microstructured materials with various shape anisotropies and multifunctional properties. Manipulating the spontaneous engulfment process remains elusive. Herein, we report a mesoscopic simulation study on the engulfing behavior of nanoparticles into thermoresponsive microgels. The effects of the multiple parameters, including binding strength, temperature, and nanoparticle size, are examined systematically. Our simulation results disclose three engulfing states at different temperatures, namely full-engulfing, half-engulfing, and surface contact. The engulfing depth is determined by the complementary balance of interfacial elastocapillarity. Specifically, the van der Waals interaction of hybrid microgel–nanoparticle offers the capillary force while the internally networked structure of microgel reinforces the elasticity repulsion. Our study, validated by relevant experimental results, provides a mechanistic understanding of the interfacial elastocapillarity for nanoparticle–microgels.

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“…A complex network structure is formed in the curing process through reactions between polymers, functional additives, and particle surfaces. Network-forming dynamics in the curing process thus play an important role in determining the overall performance of materials …”

Section: Introductionmentioning

confidence: 99%

Promoting Cross-Link Reaction of Polymers by the Matrix–Filler Interface Effect: Role of Coupling Agents and Intermediate Linkers

Huang,

Wang,

Wang

et al. 2024

J. Phys. Chem. B

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The matrix−filler interface effect plays an important role in determining the structural stability and mechanical properties of polymer composite materials, which remain ambiguous and need to be studied. The network-forming dynamics of poly(3,3-bis (azidomethyl) oxetane−tetrahydrofuran) (PBT) at the ammonium perchlorate (AP) surface was studied by using atomistic molecular dynamics simulation, considering the additives of curing agent toluene diisocyanate (TDI), cross-linker trimethylolpropane (TMP), and coupling agent triethanolamine (TEA). The presence of the AP surface promotes chain cross-link reaction, which is attributed to the increased production of intermediate linkers formed by TDI, TMP, and TEA. The intermediate linker has three reactive sites that can react with PBT main chains to form a cross-linked structure. Owing to the strong interaction with the AP surface, the coupling agent TEA plays a dominant role in forming the intermediate linker. At the early stage of network forming (reaction ratio r < 30%), the AP surface adsorbs TEA, which leads to a maximum contact density to PBT. As r increases to 60%, the density of intermediate linkers near the AP surface reaches a maximum value. Consequently, the chain cross-link reactions between the intermediate linker and PBT main chains are enhanced as r > 60%. This work explains the micromechanism of the promotion of chain cross-link reaction by the interface effect and provides important insights on designing polymer materials with high mechanical properties.

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Mechanochemical Cellular Membrane Internalization of Nanohydrogels: A Large-Scale Mesoscopic Simulation

Cited by 21 publications

References 68 publications

Tuning the Elasticity of Nanogels Improves Their Circulation Time by Evading Immune Cells

Tuning the Elasticity of Nanogels Improves Their Circulation Time by Evading Immune Cells

Engulfing Behavior of Nanoparticles into Thermoresponsive Microgels: A Mesoscopic Simulation Study

Promoting Cross-Link Reaction of Polymers by the Matrix–Filler Interface Effect: Role of Coupling Agents and Intermediate Linkers

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