Physical Principles of Nanoparticle Cellular Endocytosis

Zhang, Sulin; Gao, Huajian; Bao, Gang

doi:10.1021/acsnano.5b03184

Cited by 875 publications

(814 citation statements)

References 122 publications

(287 reference statements)

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“…For example, for a cell membrane tension in the order of 0.05 mNÁm ¡1 and bending modulus values of 15 k B T, the length scale is approximately 50 nm [48]. Simulation [59] and experiment [60] suggest a bending modulus of k » 23 k B T (»10 ¡19 J at 300 K for DPPC gives »60 nm.…”

Section: Nanoparticle-membrane Interactions: Elastic Theorymentioning

confidence: 97%

“…These mechanisms are in most cases controlled by the cell membrane via specific receptor-mediated interactions (eg clathrin, caveolin, flotollin mediated endocytosis) [42,44,45]. However, it has been demonstrated that NPs can also traverse the cell membrane via endocytosis (or exocytosis) without being involved in any specific receptor-mediated interaction [46][47][48][49]. Lipid membranes are highly flexible and the bilayer can be deformed due to NP adhesion on its surface leading to a full NP engulfment and its final uptake.…”

Section: Nanoparticle-membrane Interactions: Elastic Theorymentioning

confidence: 99%

“…Assuming a tensionless membrane and that the non-specific adhesion interaction is driving the process, NP engulfment occurs when the adhesion energy is sufficient to overcome the energy cost associated with bending the membrane around the particle surface. For this tensionless case, two parameters, adhesion energy and membrane bending modulus, define a critical radius, r c , representing the minimum particle size for which the NP engulfment occurs [47,48,53,54]:…”

Section: Nanoparticle-membrane Interactions: Elastic Theorymentioning

confidence: 99%

See 2 more Smart Citations

Nanoparticle–membrane interactions

Contini

Schneemilch

Gaisford

et al. 2017

Journal of Experimental Nanoscience

144

109

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Engineered nanomaterials have a wide range of applications and as a result, are increasingly present in the environment. While they offer new technological opportunities, there is also the potential for adverse impact, in particular through possible toxicity. In this review, we discuss the current state of the art in the experimental characterisation of nanoparticle-membrane interactions relevant to the prediction of toxicity arising from disruption of biological systems. One key point of discussion is the urgent need for more quantitative studies of nano-bio interactions in experimental models of lipid system that mimic in vivo membranes.

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Section: Nanoparticle-membrane Interactions: Elastic Theorymentioning

confidence: 97%

Section: Nanoparticle-membrane Interactions: Elastic Theorymentioning

confidence: 99%

Section: Nanoparticle-membrane Interactions: Elastic Theorymentioning

confidence: 99%

See 1 more Smart Citation

Nanoparticle–membrane interactions

Contini

Schneemilch

Gaisford

et al. 2017

Journal of Experimental Nanoscience

144

109

View full text Add to dashboard Cite

show abstract

“…Filament growth and membrane deformation generate forces that promote invagination of the virus 6. Many simulation studies have focused on this process of endocytosis, and provided useful information for understanding this process 7. Cell membranes are considered as the first barrier to defend cells from external harms 8.…”

Section: Introductionmentioning

confidence: 99%

The Process of Wrapping Virus Revealed by a Force Tracing Technique and Simulations

Pan

Zhang

et al. 2017

Advanced Science

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Viral entry into the host cell is the first step of virus infection; however, its dynamic process via endocytosis remains largely elusive. Here, the force tracing technique and single particle simulation are combined to investigate the invagination of single human enterovirus 71 (HEV71, a positive single‐stranded RNA virus that is associated with hand, foot, and mouth disease) via cell membranes during its host cell entry. The experimental results reveal that the HEV71 invaginates in membrane vesicles at a force of 58 ± 16 pN, a duration time of 278 ± 68 ms. The simulation further shows that the virus can reach a partially wrapped state very fast, then the upper surface of the virus is covered by the membrane traveling over a long period of time. Combining the experiment with the simulation, the mechanism of membrane wrapping of virus is uncovered, which provides new insights into how the cell is operated to initiate the endocytosis of virus.

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“…Recently, self‐powered motor,11 jumper,12 oscillator,13 soft actuators,14, 15, 16 and 2D semiconductor skin17 demonstrated with this class of material shed light on their new possibilities toward more diverse applications. Here, we report a particle‐eating phenomenon of gallium‐based LMs, which mimics the biological phagocytosis process (also known as cellular‐eating, a basic cell behavior referring to the transportation of external particles into cells from across the membranes18, 19, 20, 21), and thus we call it LM‐Phagocytosis. Such phenomenon represents a wet‐processing strategy to achieve particle internalization.…”

mentioning

confidence: 98%

Liquid Metal Phagocytosis: Intermetallic Wetting Induced Particle Internalization

et al. 2017

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A biomimetic cellular‐eating phenomenon in gallium‐based liquid metal to realize particle internalization in full‐pH‐range solutions is reported. The effect, which is called liquid metal phagocytosis, represents a wet‐processing strategy to prepare various metallic liquid metal‐particle mixtures through introducing excitations such as an electrical polarization, a dissolving medium, or a sacrificial metal. A nonwetting‐to‐wetting transition resulting from surface transition and the reactive nature of the intermetallic wetting between the two metallic phases are found to be primarily responsible for such particle‐eating behavior. Theoretical study brings forward a physical picture to the problem, together with a generalized interpretation. The model developed here, which uses the macroscopic contact angle between the two metallic phases as a criterion to predict the particle internalization behavior, shows good consistency with experimental results.

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Physical Principles of Nanoparticle Cellular Endocytosis

Cited by 875 publications

References 122 publications

Nanoparticle–membrane interactions

Nanoparticle–membrane interactions

The Process of Wrapping Virus Revealed by a Force Tracing Technique and Simulations

Liquid Metal Phagocytosis: Intermetallic Wetting Induced Particle Internalization

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