A modular approach to create a neurovascular unit-on-a-chip

Achyuta, Anil Kumar H.; Conway, Amy J.; Crouse, Richard B.; Bannister, Emilee C.; Lee, Robin N.; Katnik, Christopher; Behensky, Adam; Cuevas, Javier; Sundaram, S.

doi:10.1039/c2lc41033h

Cited by 175 publications

(136 citation statements)

References 81 publications

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“…Still, a comprehensive study on a human brain endothelial cell line in a microdevice, with a complex characterization of barrier properties including microscopy, has so far been missing. Previously, the rat cell line RBE4 was studied for a similar purpose [17,36]. Biochips modeling the vascular system also widely use peripheral endothelial cells [37][38][39][40].…”

Section: 2mentioning

confidence: 99%

A versatile lab-on-a-chip tool for modeling biological barriers

Walter

Valkai

Kincses

et al. 2016

Sensors and Actuators B: Chemical

148

156

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Keywords: Microfluidics Lung and intestinal epithelial cells Endothelial cells Blood-brain barrier PermeabilityTrans-epithelial/endothelial electric resistance a b s t r a c t Models of biological barriers are important to study physiological functions, transport mechanisms, drug delivery and pathologies. However, there are only a few integrated biochips which are able to monitor several of the crucial parameters of cell-culture-based barrier models. The aim of this study was to design and manufacture a simple but versatile device, which allows a complex investigation of barrier functions. The following functions and measurements are enabled simultaneously: co-culture of 2 or 3 types of cells; flow of culture medium; visualization of the entire cell layer by microscopy; real-time transcellular electrical resistance monitoring; permeability measurements. To this end, a poly(dimethylsiloxane)-based biochip with integrated transparent gold electrodes and with a possibility to connect to a peristaltic pump was built. Unlike previous systems, the structure of the device allowed a constant visual observation of cell growth over the whole membrane surface. Morphological characterization of the layers was also accomplished by immunohistochemical staining. The chip was applied to monitor and characterize models of the intestinal and lung epithelial barriers, and the blood-brain barrier. The models were established using human Caco-2 intestinal and A549 lung epithelial cell lines, hCMEC/D3 human brain endothelial cell line and primary rat brain endothelial cells co-cultured with primary astrocytes and brain pericytes. This triple primary co-culture blood-brain barrier model was assembled on a lab-on-a-chip device and investigated under fluid flow for the first time. Such a versatile tool is expected to facilitate the kinetic investigation of various biological barriers.

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Section: 2mentioning

confidence: 99%

A versatile lab-on-a-chip tool for modeling biological barriers

Walter

Valkai

Kincses

et al. 2016

Sensors and Actuators B: Chemical

148

156

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“…Additionally, signalling of the 'neurovascular unit', the functional module comprised of the neural parenchyma and blood-brain barrier, has been investigated by Achyuta and colleagues. [ 48 ] Their platform mimicked in-vivo conditions by vertically stacking a vascular channel on top of a neural parenchymal chamber, with a microporous polycarbonate membrane to separate the two chambers. Both the endothelial cell barriers of the vascular channel and the capacity of the neural cells to fi re action potentials were demonstrated to be functional.…”

Section: Paracrine Signallingmentioning

confidence: 99%

Microfluidic Platforms for the Investigation of Intercellular Signalling Mechanisms

Nahavandi

Tang

Baratchi

et al. 2014

Small

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Intercellular signalling has been identified as a highly complex process, responsible for orchestrating many physiological functions. While conventional methods of investigation have been useful, their limitations are impeding further development. Microfluidics offers an opportunity to overcome some of these limitations. Most notably, microfluidic systems can emulate the in-vivo environments. Further, they enable exceptionally precise control of the microenvironment, allowing complex mechanisms to be selectively isolated and studied in detail. There has thus been a growing adoption of microfluidic platforms for investigation of cell signalling mechanisms. This review provides an overview of the different signalling mechanisms and discusses the methods used to study them, with a focus on the microfluidic devices developed for this purpose.

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“…1A,B; Huh et al, 2010). Since this study was published, multi-channel design approaches have been used by multiple research groups to build microfluidic organ-chip models of the human lung small airway, skin, kidney, intestine, placenta, blood-retinal barrier, blood-brain barrier, neurovascular unit and neuromuscular unit, among others (Kim et al, 2012;Achyuta et al, 2013;Abaci et al, 2015;Benam et al, 2016a;Lee et al, 2016;Musah et al, 2017;Yeste et al, 2017;Wang et al, 2017;Workman et al, 2018;Kasendra et al, 2018;Sances et al, 2018; reviewed by Bhatia and Ingber, 2014).…”

Section: Introductionmentioning

confidence: 99%

Developmentally inspired human ‘organs on chips’

Ingber

2018

Development

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Although initially developed to replace animal testing in drug development, human 'organ on a chip' (organ chip) microfluidic culture technology offers a new tool for studying tissue development and pathophysiology, which has brought us one step closer to carrying out human experimentation in vitro. In this Spotlight article, I discuss the central role that developmental biology played in the early stages of organ-chip technology, and how these models have led to new insights into human physiology and disease mechanisms. Advantages and disadvantages of the organ-chip approach relative to organoids and other human cell cultures are also discussed.

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A modular approach to create a neurovascular unit-on-a-chip

Cited by 175 publications

References 81 publications

A versatile lab-on-a-chip tool for modeling biological barriers

A versatile lab-on-a-chip tool for modeling biological barriers

Microfluidic Platforms for the Investigation of Intercellular Signalling Mechanisms

Developmentally inspired human ‘organs on chips’

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