Red blood cells affect the margination of microparticles in synthetic microcapillaries and intravital microcirculation as a function of their size and shape

Rosa D'Apolito; Giovanna Tomaiuolo; Francesca Taraballi; Silvia Minardi; Dickson Kirui; Xuewu Liu; Armando Cevenini; Roberto Palomba; Mauro Ferrari; Francesco Salvatore; Ennio Tasciotti; Stefano Guido

doi:10.1016/j.jconrel.2015.09.013

Red blood cells affect the margination of microparticles in synthetic microcapillaries and intravital microcirculation as a function of their size and shape

Rosa D'Apolito, Giovanna Tomaiuolo, Francesca Taraballi, Silvia Minardi, Dickson Kirui, Xuewu Liu, Armando Cevenini, Roberto Palomba, Mauro Ferrari, Francesco Salvatore, Ennio Tasciotti, Stefano Guido

Research output: Contribution to journal › Article › peer-review

71 Scopus citations

Abstract

A key step in particle-based drug delivery through microcirculation is particle migration from blood flow to vessel walls, also known as "margination", which promotes particle contact and adhesion to the vesselwall. Margination and adhesion should be independently addressed as two distinct phenomena, considering that the former is a fundamental prerequisite to achieve particle adhesion and subsequent extravasation. Although margination has been modeled by numerical simulations and investigated in model systems in vitro, experimental studies including red blood cells (RBCs) are lacking. Here, we evaluate the effect of RBCs on margination through microfluidic studies in vitro and by intravital microscopy in vivo. We showthat margination,which is almost absent when particles are suspended in a cell-free medium, is drastically enhanced by RBCs. This effect is size- and shape-dependent, larger spherical/discoid particles being more effectively marginated both in vitro and in vivo. Our findings can be explained by the collision of particles with RBCs that induces the drifting of the particles towards the vessel walls where they become trapped in the cell-free layer. These results are relevant for the design of drug delivery strategies based on systemically administered carriers.

Original language	English (US)
Pages (from-to)	263-272
Number of pages	10
Journal	Journal of Controlled Release
Volume	217
DOIs	https://doi.org/10.1016/j.jconrel.2015.09.013
State	Published - Nov 10 2015

Keywords

Drug delivery
Margination
Micro-particles
Microcirculation
Red blood cells
Shape
Size

ASJC Scopus subject areas

Pharmaceutical Science

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10.1016/j.jconrel.2015.09.013

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D'Apolito, R., Tomaiuolo, G., Taraballi, F., Minardi, S., Kirui, D., Liu, X., Cevenini, A., Palomba, R., Ferrari, M., Salvatore, F., Tasciotti, E., & Guido, S. (2015). Red blood cells affect the margination of microparticles in synthetic microcapillaries and intravital microcirculation as a function of their size and shape. Journal of Controlled Release, 217, 263-272. https://doi.org/10.1016/j.jconrel.2015.09.013

D'Apolito, R, Tomaiuolo, G, Taraballi, F, Minardi, S, Kirui, D, Liu, X, Cevenini, A, Palomba, R, Ferrari, M, Salvatore, F, Tasciotti, E & Guido, S 2015, 'Red blood cells affect the margination of microparticles in synthetic microcapillaries and intravital microcirculation as a function of their size and shape', Journal of Controlled Release, vol. 217, pp. 263-272. https://doi.org/10.1016/j.jconrel.2015.09.013

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title = "Red blood cells affect the margination of microparticles in synthetic microcapillaries and intravital microcirculation as a function of their size and shape",

abstract = "A key step in particle-based drug delivery through microcirculation is particle migration from blood flow to vessel walls, also known as {"}margination{"}, which promotes particle contact and adhesion to the vesselwall. Margination and adhesion should be independently addressed as two distinct phenomena, considering that the former is a fundamental prerequisite to achieve particle adhesion and subsequent extravasation. Although margination has been modeled by numerical simulations and investigated in model systems in vitro, experimental studies including red blood cells (RBCs) are lacking. Here, we evaluate the effect of RBCs on margination through microfluidic studies in vitro and by intravital microscopy in vivo. We showthat margination,which is almost absent when particles are suspended in a cell-free medium, is drastically enhanced by RBCs. This effect is size- and shape-dependent, larger spherical/discoid particles being more effectively marginated both in vitro and in vivo. Our findings can be explained by the collision of particles with RBCs that induces the drifting of the particles towards the vessel walls where they become trapped in the cell-free layer. These results are relevant for the design of drug delivery strategies based on systemically administered carriers.",

keywords = "Drug delivery, Margination, Micro-particles, Microcirculation, Red blood cells, Shape, Size",

author = "Rosa D'Apolito and Giovanna Tomaiuolo and Francesca Taraballi and Silvia Minardi and Dickson Kirui and Xuewu Liu and Armando Cevenini and Roberto Palomba and Mauro Ferrari and Francesco Salvatore and Ennio Tasciotti and Stefano Guido",

note = "Funding Information: This study is related to the activity of the European network action COST MP1106 “Smart and green interfaces—from single bubbles and drops to industrial, environmental, and biomedical applications.” The authors acknowledge Dr. YeonJu Lee for the figure design. The authors gratefully acknowledge funding support from the following sources: Department of Defense grants W81XWH-09-1-0212 and W81XWH-12-1-0414 , National Institute of Health grants U54CA143837 and U54CA151668 , the CPRIT grant RP121071 from the State of Texas, and the Ernest Cockrell Jr. Distinguished Endowed Chair . This study was also supported by the Brown Foundation (Project ID: 18130011 ) and by the Cullen Trust for Health Care Foundation (Project ID: 18130014 ). We thank Jean Ann Gilder (Scientific Communication srl, Naples, Italy) for the text editing. Funding Information: Funding from the Italian Ministry of University and Research ( PRIN Program 2010–2011, Project No. 20109PLMH2 ), and from the Regione Campania ( MICROEMA Project , 220 APQRT02 2008 ) is acknowledged. This work has been also supported by POR CAMPANIA FSE 2007–2013 Project DIAINTECH ( B25C13000270007 ), Italy (to F.S.) and by Grant PON01_02589 ( MICROMAP ) — 2012 from the Ministry of University and Research, Italy (to F.S.) Publisher Copyright: {\textcopyright} 2015 Elsevier B.V. All rights reserved.",

year = "2015",

month = nov,

day = "10",

doi = "10.1016/j.jconrel.2015.09.013",

language = "English (US)",

volume = "217",

pages = "263--272",

journal = "Journal of Controlled Release",

issn = "0168-3659",

publisher = "Elsevier B.V.",

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TY - JOUR

T1 - Red blood cells affect the margination of microparticles in synthetic microcapillaries and intravital microcirculation as a function of their size and shape

AU - D'Apolito, Rosa

AU - Tomaiuolo, Giovanna

AU - Taraballi, Francesca

AU - Minardi, Silvia

AU - Kirui, Dickson

AU - Liu, Xuewu

AU - Cevenini, Armando

AU - Palomba, Roberto

AU - Ferrari, Mauro

AU - Salvatore, Francesco

AU - Tasciotti, Ennio

AU - Guido, Stefano

N1 - Funding Information: This study is related to the activity of the European network action COST MP1106 “Smart and green interfaces—from single bubbles and drops to industrial, environmental, and biomedical applications.” The authors acknowledge Dr. YeonJu Lee for the figure design. The authors gratefully acknowledge funding support from the following sources: Department of Defense grants W81XWH-09-1-0212 and W81XWH-12-1-0414 , National Institute of Health grants U54CA143837 and U54CA151668 , the CPRIT grant RP121071 from the State of Texas, and the Ernest Cockrell Jr. Distinguished Endowed Chair . This study was also supported by the Brown Foundation (Project ID: 18130011 ) and by the Cullen Trust for Health Care Foundation (Project ID: 18130014 ). We thank Jean Ann Gilder (Scientific Communication srl, Naples, Italy) for the text editing. Funding Information: Funding from the Italian Ministry of University and Research ( PRIN Program 2010–2011, Project No. 20109PLMH2 ), and from the Regione Campania ( MICROEMA Project , 220 APQRT02 2008 ) is acknowledged. This work has been also supported by POR CAMPANIA FSE 2007–2013 Project DIAINTECH ( B25C13000270007 ), Italy (to F.S.) and by Grant PON01_02589 ( MICROMAP ) — 2012 from the Ministry of University and Research, Italy (to F.S.) Publisher Copyright: © 2015 Elsevier B.V. All rights reserved.

PY - 2015/11/10

Y1 - 2015/11/10

N2 - A key step in particle-based drug delivery through microcirculation is particle migration from blood flow to vessel walls, also known as "margination", which promotes particle contact and adhesion to the vesselwall. Margination and adhesion should be independently addressed as two distinct phenomena, considering that the former is a fundamental prerequisite to achieve particle adhesion and subsequent extravasation. Although margination has been modeled by numerical simulations and investigated in model systems in vitro, experimental studies including red blood cells (RBCs) are lacking. Here, we evaluate the effect of RBCs on margination through microfluidic studies in vitro and by intravital microscopy in vivo. We showthat margination,which is almost absent when particles are suspended in a cell-free medium, is drastically enhanced by RBCs. This effect is size- and shape-dependent, larger spherical/discoid particles being more effectively marginated both in vitro and in vivo. Our findings can be explained by the collision of particles with RBCs that induces the drifting of the particles towards the vessel walls where they become trapped in the cell-free layer. These results are relevant for the design of drug delivery strategies based on systemically administered carriers.

AB - A key step in particle-based drug delivery through microcirculation is particle migration from blood flow to vessel walls, also known as "margination", which promotes particle contact and adhesion to the vesselwall. Margination and adhesion should be independently addressed as two distinct phenomena, considering that the former is a fundamental prerequisite to achieve particle adhesion and subsequent extravasation. Although margination has been modeled by numerical simulations and investigated in model systems in vitro, experimental studies including red blood cells (RBCs) are lacking. Here, we evaluate the effect of RBCs on margination through microfluidic studies in vitro and by intravital microscopy in vivo. We showthat margination,which is almost absent when particles are suspended in a cell-free medium, is drastically enhanced by RBCs. This effect is size- and shape-dependent, larger spherical/discoid particles being more effectively marginated both in vitro and in vivo. Our findings can be explained by the collision of particles with RBCs that induces the drifting of the particles towards the vessel walls where they become trapped in the cell-free layer. These results are relevant for the design of drug delivery strategies based on systemically administered carriers.

KW - Drug delivery

KW - Margination

KW - Micro-particles

KW - Microcirculation

KW - Red blood cells

KW - Shape

KW - Size

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UR - http://www.scopus.com/inward/citedby.url?scp=84942872040&partnerID=8YFLogxK

U2 - 10.1016/j.jconrel.2015.09.013

DO - 10.1016/j.jconrel.2015.09.013

M3 - Article

C2 - 26381900

AN - SCOPUS:84942872040

SN - 0168-3659

VL - 217

SP - 263

EP - 272

JO - Journal of Controlled Release

JF - Journal of Controlled Release

ER -

Red blood cells affect the margination of microparticles in synthetic microcapillaries and intravital microcirculation as a function of their size and shape

Abstract

Keywords

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