Vascular tropism models of blood-borne microbial dissemination

Ae, Boczula; A, Ly; Ebady, Rhodaba; J, Cho; Anjum, Zoha; Zlotnikov, Nataliya; Persson, Henrik; Odisho, Tanya; Simmons, Craig A.; Moriarty, Tara J.

doi:10.1101/2021.05.05.442761

Cited by 4 publications

(5 citation statements)

References 53 publications

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“…Investigation of the potential contributions of endothelial activation and junction rearrangement to transmigration mechanisms using a microfluidic transmembrane model will require the ability to cocultivate primary endothelial cells and B. burgdorferi for periods longer than 4 hours, which we have unfortunately not yet been able to technically achieve. In addition, leukocyte molecular transmigration mechanisms differ in distinct vascular beds, and genetically diverse Borrelia strains also exhibit distinct interaction affinities for endothelia from the vascular beds of different tissues under physiological shear stress [44]. Thus, factors specific to endothelia in different tissues likely also influence B. burgdorferi transendothelial migration kinetics and mechanisms.…”

Section: Discussionmentioning

confidence: 99%

“…The HUVEC flow chamber model recapitulates all major molecular and biophysical properties of B. burgdorferi interactions with the walls of postcapillary venules in the skin of mice [25][26][27]44]. Interaction of genetically diverse Borrelia strains with distinct tissue dissemination patterns with postconfluent HUVEC cultured under static conditions under postcapillary shear stress conditions also robustly predicts strain-specific dissemination to skin in intravenous (IV) perfusion infection models [44].…”

Section: Transmembrane Microfluidic System For Studyingmentioning

confidence: 90%

“…HUVECs were used in these proof-of-principle experiments to enable direct comparison to previous studies investigating B. burgdorferi-endothelial transmigration in Transwell devices under static conditions [42,43], as well as B. burgdorferi-endothelial interaction mechanisms under postcapillary venule shear stress [25][26][27][28]. The HUVEC flow chamber model recapitulates all major molecular and biophysical properties of B. burgdorferi interactions with the walls of postcapillary venules in the skin of mice [25][26][27]44]. Interaction of genetically diverse Borrelia strains with distinct tissue dissemination patterns with postconfluent HUVEC cultured under static conditions under postcapillary shear stress conditions also robustly predicts strain-specific dissemination to skin in intravenous (IV) perfusion infection models [44].…”

Section: Transmembrane Microfluidic System For Studyingmentioning

confidence: 99%

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A Live Cell Imaging Microfluidic Model for Studying Extravasation of Bloodborne Bacterial Pathogens

Bergevin

Boczula

Caruso

et al. 2022

Cellular Microbiology

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Bacteria that migrate (extravasate) out of the bloodstream during vascular dissemination can cause secondary infections in many tissues and organs, including the brain, heart, liver, joints, and bone with clinically serious and sometimes fatal outcomes. The mechanisms by which bacteria extravasate through endothelial barriers in the face of blood flow-induced shear stress are poorly understood, in part because individual bacteria are rarely observed traversing endothelia in vivo, and in vitro model systems inadequately mimic the vascular environment. To enable the study of bacterial extravasation mechanisms, we developed a transmembrane microfluidics device mimicking human blood vessels. Fast, quantitative, three-dimensional live cell imaging in this system permitted single-cell resolution measurement of the Lyme disease bacterium Borrelia burgdorferi transmigrating through monolayers of primary human endothelial cells under physiological shear stress. This cost-effective, flexible method was 10,000 times more sensitive than conventional plate reader-based methods for measuring transendothelial migration. Validation studies confirmed that B. burgdorferi transmigrate actively and strikingly do so at similar rates under static and physiological flow conditions. This method has significant potential for future studies of B. burgdorferi extravasation mechanisms, as well as the transendothelial migration mechanisms of other disseminating bloodborne pathogens.

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Section: Discussionmentioning

confidence: 99%

Section: Transmembrane Microfluidic System For Studyingmentioning

confidence: 90%

Section: Transmembrane Microfluidic System For Studyingmentioning

confidence: 99%

See 1 more Smart Citation

A Live Cell Imaging Microfluidic Model for Studying Extravasation of Bloodborne Bacterial Pathogens

Bergevin

Boczula

Caruso

et al. 2022

Cellular Microbiology

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“…Cells were cultured at 37 °C and 5% CO 2 in cell-specific media: primary human umbilical vascular endothelial cells (HUVECs, Lonza; up to passage 6) in EGM-2 (Lonza) culture medium kit; primary human brain microvascular endothelial cells (HBMVECs, Cell Systems - ACBRI 376) in complete classic medium (4Z0–500, Cell Systems) supplemented with CultureBoost (Cell Systems); immortalized HBMVECs in EGM-2MV microvascular endothelial cell growth medium (Lonza) supplemented with hygromycin-B (20 μg/mL); hCMEC/D3 BBB endothelial line (CELLutions Biosystems, Inc. CLU512) cultured according to supplier’s directions in supplemented EBM-2 endothelial basal medium (Lonza); and normal human astrocytes (NHAs, Lonza) in Dulbecco’s minimum essential medium (DMEM), supplemented with N2 supplement (1%) and fetal bovine serum (10%). Media was changed every 48 h in cell culture flasks and every 24–48 h in PM-ECIS devices.…”

Section: Methodsmentioning

confidence: 99%

Porous Membrane Electrical Cell–Substrate Impedance Spectroscopy for Versatile Assessment of Biological Barriers In Vitro

Chebotarev,

Ugodnikov,

Simmons

2024

ACS Appl. Bio Mater.

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Cell culture models of endothelial and epithelial barriers typically use porous membrane inserts (e.g., Transwell inserts) as a permeable substrate on which barrier cells are grown, often in coculture with other cell types on the opposite side of the membrane. Current methods to characterize barrier function in porous membrane inserts can disrupt the barrier or provide bulk measurements that cannot isolate barrier cell resistance alone. Electrical cell–substrate impedance sensing (ECIS) addresses these limitations, but its implementation on porous membrane inserts has been limited by costly manufacturing, low sensitivity, and lack of validation for barrier assessment. Here, we present porous membrane ECIS (PM-ECIS), a cost-effective method to adapt ECIS technology to porous substrate-based in vitro models. We demonstrate high fidelity patterning of electrodes on porous membranes that can be incorporated into well plates of a variety of sizes with excellent cell biocompatibility with mono- and coculture set ups. PM-ECIS provided sensitive, real-time measurement of isolated changes in endothelial cell barrier impedance with cell growth and barrier disruption. Barrier function characterized by PM-ECIS resistance correlated well with permeability coefficients obtained from simultaneous molecular tracer permeability assays performed on the same cultures, validating the device. Integration of ECIS into conventional porous cell culture inserts provides a versatile, sensitive, and automated alternative to current methods to measure barrier function in vitro, including molecular tracer assays and transepithelial/endothelial electrical resistance.

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“…Immortalized human brain microvascular endothelial cells (HBMEC) (provided by Tara Moriarty, University of Toronto) 35 , were cultured using the EGM™-2 MV Microvascular Endothelial Cell Growth Medium BulletKit™ (Lonza, CC-3202), which contains hydrocortisone, and was supplemented with 20 µg/mL Hygromycin B Biobasic Canada (Cat #BS725) to select for transfected cells. Primary human astrocytes (Thermo Fisher, N7805100) were used for the co-culture conditions and grown in DMEM supplemented with 10% FBS, 1% penicillin-streptomycin and N-2 supplement (17502-048).…”

Section: Methodsmentioning

confidence: 99%

A microfluidic platform with integrated porous membrane cell-substrate impedance spectroscopy (PM-ECIS) for biological barrier assessment

Ugodnikov,

Lu,

Chebotarev

et al. 2023

Preprint

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Traditionally, biological barriers are assessed in vitro by measuring trans-endothelial/epithelial electrical resistance (TEER) across a monolayer using handheld chopstick electrodes. Implementation of TEER into organ-on-chip (OOC) setups is a challenge however, due to non-uniform current distribution and interference from biomaterials typically found in such systems. In this work, we address the pitfalls of standard TEER measurement through the application of porous membrane electrical cell-substrate impedance sensing (PM-ECIS) to an OOC setup. Gold leaf electrodes (working electrode diameters = 250, 500, 750 µm) were incorporated onto porous membranes and combined with biocompatible tape to assemble microfluidic devices. PM-ECIS resistance at 4 kHz was not influenced by presence of collagen hydrogel in bottom channels, compared to TEER measurements in same devices, which showed a difference of 1723 ± 381.8 Ω (p=0.006) between control and hydrogel conditions. A proof of concept, multi-day co-culture model of the blood-brain barrier was also demonstrated in these devices. PM-ECIS measurements were robust to fluid shear (5 dyn/cm2) in cell-free devices, yet were highly sensitive to flow-induced changes in an endothelial barrier model. Initiation of perfusion (0.06 dyn/cm2) in HUVEC-seeded devices corresponded to significant decreases in impedance at 40 kHz (p<0.01 for 750 and 500 µm electrodes) and resistance at 4 kHz (p<0.05 for all electrode sizes) relative to static control cultures, with minimum values reached at 6.5 to 9.5 hours after induction of flow. Our microfluidic PM-ECIS platform enables sensitive, non-invasive, real-time measurements of barrier function in setups integrating critical OOC features like 3D co-culture, biomaterials and shear stress.

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Vascular tropism models of blood-borne microbial dissemination

Cited by 4 publications

References 53 publications

A Live Cell Imaging Microfluidic Model for Studying Extravasation of Bloodborne Bacterial Pathogens

A Live Cell Imaging Microfluidic Model for Studying Extravasation of Bloodborne Bacterial Pathogens

Porous Membrane Electrical Cell–Substrate Impedance Spectroscopy for Versatile Assessment of Biological Barriers In Vitro

A microfluidic platform with integrated porous membrane cell-substrate impedance spectroscopy (PM-ECIS) for biological barrier assessment

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