Durotaxis of Passive Nanoparticles on Elastic Membranes

Ivan Palaia; Alexandru Paraschiv; Vincent E. Debets; Cornelis Storm; Andela Šarić

doi:10.1021/acsnano.1c02777

Durotaxis of Passive Nanoparticles on Elastic Membranes

Ivan Palaia
, Alexandru Paraschiv
, Vincent E. Debets
, Cornelis Storm
, Andela Šarić (Corresponding author)

Onderzoeksoutput: Bijdrage aan tijdschrift › Tijdschriftartikel › Academic › peer review

12 Citaten (Scopus)

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The transport of macromolecules and nanoscopic particles to a target cellular site is a crucial aspect in many physiological processes. This directional motion is generally controlled via active mechanical and chemical processes. Here we show, by means of molecular dynamics simulations and an analytical theory, that completely passive nanoparticles can exhibit directional motion when embedded in nonuniform mechanical environments. Specifically, we study the motion of a passive nanoparticle adhering to a mechanically nonuniform elastic membrane. We observe a nonmonotonic affinity of the particle to the membrane as a function of the membrane's rigidity, which results in the particle transport. This transport can be both up or down the rigidity gradient, depending on the absolute values of the rigidities that the gradient spans across. We conclude that rigidity gradients can be used to direct average motion of passive macromolecules and nanoparticles on deformable membranes, resulting in the preferential accumulation of the macromolecules in regions of certain mechanical properties.

Originele taal-2	Engels
Pagina's (van-tot)	15794-15802
Aantal pagina's	9
Tijdschrift	ACS Nano
Volume	15
Nummer van het tijdschrift	10
DOI's	https://doi.org/10.1021/acsnano.1c02777
Status	Gepubliceerd - 26 okt. 2021

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We acknowledge support from the European Research Council (I.P. and A.Š., Starting Grant No. 802960), the Royal Society (A.Š., Grant No. UF160266), and the Dutch Research Council (V.E.D., START-UP Grant No. 740.018.002).

Financiers	Financiernummer
European Union’s Horizon Europe research and innovation programme	802960
Royal Society	UF160266
European Union’s Horizon Europe research and innovation programme
Nederlandse Organisatie voor Wetenschappelijk Onderzoek	740.018.002

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10.1021/acsnano.1c02777

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title = "Durotaxis of Passive Nanoparticles on Elastic Membranes",

abstract = "The transport of macromolecules and nanoscopic particles to a target cellular site is a crucial aspect in many physiological processes. This directional motion is generally controlled via active mechanical and chemical processes. Here we show, by means of molecular dynamics simulations and an analytical theory, that completely passive nanoparticles can exhibit directional motion when embedded in nonuniform mechanical environments. Specifically, we study the motion of a passive nanoparticle adhering to a mechanically nonuniform elastic membrane. We observe a nonmonotonic affinity of the particle to the membrane as a function of the membrane's rigidity, which results in the particle transport. This transport can be both up or down the rigidity gradient, depending on the absolute values of the rigidities that the gradient spans across. We conclude that rigidity gradients can be used to direct average motion of passive macromolecules and nanoparticles on deformable membranes, resulting in the preferential accumulation of the macromolecules in regions of certain mechanical properties. ",

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author = "Ivan Palaia and Alexandru Paraschiv and Debets, \{Vincent E.\} and Cornelis Storm and Andela {\v S}ari{\'c}",

note = "Funding Information: We acknowledge support from the European Research Council (I.P. and A.{\v S}., Starting Grant No. 802960), the Royal Society (A.{\v S}., Grant No. UF160266), and the Dutch Research Council (V.E.D., START-UP Grant No. 740.018.002). ",

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AU - Palaia, Ivan

AU - Paraschiv, Alexandru

AU - Debets, Vincent E.

AU - Storm, Cornelis

AU - Šarić, Andela

N1 - Funding Information: We acknowledge support from the European Research Council (I.P. and A.Š., Starting Grant No. 802960), the Royal Society (A.Š., Grant No. UF160266), and the Dutch Research Council (V.E.D., START-UP Grant No. 740.018.002).

PY - 2021/10/26

Y1 - 2021/10/26

N2 - The transport of macromolecules and nanoscopic particles to a target cellular site is a crucial aspect in many physiological processes. This directional motion is generally controlled via active mechanical and chemical processes. Here we show, by means of molecular dynamics simulations and an analytical theory, that completely passive nanoparticles can exhibit directional motion when embedded in nonuniform mechanical environments. Specifically, we study the motion of a passive nanoparticle adhering to a mechanically nonuniform elastic membrane. We observe a nonmonotonic affinity of the particle to the membrane as a function of the membrane's rigidity, which results in the particle transport. This transport can be both up or down the rigidity gradient, depending on the absolute values of the rigidities that the gradient spans across. We conclude that rigidity gradients can be used to direct average motion of passive macromolecules and nanoparticles on deformable membranes, resulting in the preferential accumulation of the macromolecules in regions of certain mechanical properties.

AB - The transport of macromolecules and nanoscopic particles to a target cellular site is a crucial aspect in many physiological processes. This directional motion is generally controlled via active mechanical and chemical processes. Here we show, by means of molecular dynamics simulations and an analytical theory, that completely passive nanoparticles can exhibit directional motion when embedded in nonuniform mechanical environments. Specifically, we study the motion of a passive nanoparticle adhering to a mechanically nonuniform elastic membrane. We observe a nonmonotonic affinity of the particle to the membrane as a function of the membrane's rigidity, which results in the particle transport. This transport can be both up or down the rigidity gradient, depending on the absolute values of the rigidities that the gradient spans across. We conclude that rigidity gradients can be used to direct average motion of passive macromolecules and nanoparticles on deformable membranes, resulting in the preferential accumulation of the macromolecules in regions of certain mechanical properties.

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KW - molecular dynamics

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KW - rigidity gradients

KW - soft matter

KW - stiffness

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Durotaxis of Passive Nanoparticles on Elastic Membranes

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