Manipulating nanoparticle transport within blood flow through external forces: an exemplar of mechanics in nanomedicine

Ye, Huilin; Shen, Zhiqiang; Yu, Le; Wei, Mei; Liu, Ying

doi:10.1098/rspa.2017.0845

Cited by 85 publications

(57 citation statements)

References 143 publications

(217 reference statements)

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“…29 Particles being rstly rotated by the magnetic torque as a function of the eld direction, the non-zero magnetic eld gradient then guides the motion of particles. 26,28 2.2 TMMEP parameters…”

Section: Presentation Of Cancer Treatment By Magneto-mechanical Effecmentioning

confidence: 99%

“…24 These studies show that the particle shapenot only the sizeclearly plays a key-role in the particle's ability to travel in the blood circulation. 24,28,66,67 Non-spherical particles, such as rods or discs, driven in the blood ow, exhibit a propensity to be more efficiently deected towards the vessel wall, once they have escaped the macrophage uptake. This so-called phenomenon of margination, which consists in the particle lateral dri across the streamlines towards the endothelium, is favoured by an anisotropic shape of the particle, owing to inertial and hydrodynamical forces, 68 potentially enhanced by the magnetic actuation.…”

Section: Particle Composition Concerning the Particles Compositionprmentioning

confidence: 99%

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Cancer treatment by magneto-mechanical effect of particles, a review

et al. 2020

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Section: Presentation Of Cancer Treatment By Magneto-mechanical Effecmentioning

confidence: 99%

Section: Particle Composition Concerning the Particles Compositionprmentioning

confidence: 99%

Cancer treatment by magneto-mechanical effect of particles, a review

et al. 2020

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“…There are three essential parameters governing the vascular dynamics of these drug carriers: pair collision force, deformation-induced lift force, and shear gradient force, all of which are determined by its size, shape, stiffness, and surface functionality. These “4S” properties are strongly correlated with the “passive tumor-targeting” characteristics of a nanoparticle [ 13 ].…”

Section: Introductionmentioning

confidence: 99%

Therapeutic Apheresis, Circulating PLD, and Mucocutaneous Toxicity: Our Clinical Experience through Four Years

et al. 2020

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Cancer treatment has been greatly improved by the combined use of targeted therapies and novel biotechnological methods. Regarding the former, pegylated liposomal doxorubicin (PLD) has a preferential accumulation within cancer tumors, thus having lower toxicity on healthy cells. PLD has been implemented in the targeted treatment of sarcoma, ovarian, breast, and lung cancer. In comparison with conventional doxorubicin, PLD has lower cardiotoxicity and hematotoxicity; however, PLD can induce mucositis and palmo-plantar erythrodysesthesia (PPE, hand-foot syndrome), which limits its use. Therapeutical apheresis is a clinically proven solution against early PLD toxicity without hindering the efficacy of the treatment. The present review summarizes the pharmacokinetics and pharmacodynamics of PLD and the beneficial effects of extracorporeal apheresis on the incidence of PPE during chemoradiotherapy in cancer patients.

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“…FEM and LBM were coupled by the immersed boundary method (Peskin, 2002). The volume-of-fluid (VOF) method (Yokoi, 2007) and front-tracking method (Unverdi and Tryggvason, 1992) were also employed to update the viscosity in the fluid mesh. A volume constraint was implemented to counteract the accumulation of small errors in the volume of individual cells (Freund 2007).…”

Section: Numerical Simulationsmentioning

confidence: 99%

Capture event of platelets by bolus flow of red blood cells in capillaries

Takeishi

Imai

Wada

2019

JBSE

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Studies on platelet margination have shown that the platelets can effectively marginate at the microvessel wall in a multi-file flow of red blood cells (RBCs), whereas axially migrated RBCs push platelets toward the wall. However, it is unclear whether these results can be extended to capillaries, which potentially cause a single-file line of RBCs, or a so-called bolus flow. Our previous numerical results (Takeishi and Imai, 2017) showed that microparticles with a diameter of 1 µm (1-µm-MPs) were captured by a bolus flow of RBCs, instead of being marginated in capillaries. Herein we perform numerical simulations to clarify whether platelets are captured or escape from the vortex-like flow structures between RBCs. We demonstrate that platelets are also captured in a capillary whose diameter is 25% larger than that of RBCs at a physiologically-relevant hematocrit (Hct ∼ 0.2), but the number of captured platelets is smaller than that of 1-µm-MPs. When the capillary diameter is comparable to that of RBCs, however, many platelets flow near the wall due to an unstable bolus flow resulting in a less number of captured platelets. These results suggest that the size effect reduces platelet capture events compared to 1-µm-MPs. We also investigate the effect of Hct and the non-dimensional shear rate (capillary number) on capture events. These findings may help not only to understand platelet adhesion in capillaries but also to develop therapeutic drug carriers.

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Manipulating nanoparticle transport within blood flow through external forces: an exemplar of mechanics in nanomedicine

Cited by 85 publications

References 143 publications

Cancer treatment by magneto-mechanical effect of particles, a review

Cancer treatment by magneto-mechanical effect of particles, a review

Therapeutic Apheresis, Circulating PLD, and Mucocutaneous Toxicity: Our Clinical Experience through Four Years

Capture event of platelets by bolus flow of red blood cells in capillaries

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