A Low Permeability Microfluidic Blood-Brain Barrier Platform with Direct Contact between Perfusable Vascular Network and Astrocytes

Chung

Biotech & Bioengineering

2019

Self Cite

The human central nervous system (CNS) vasculature expresses a distinctive barrier phenotype, the blood-brain barrier (BBB). As the BBB contributes to low efficiency in CNS pharmacotherapy by restricting drug transport, the development of an in vitro human BBB model has been in demand. Here, we present a microfluidic model of CNS angiogenesis having three-dimensional (3D) lumenized vasculature in concert with perivascular cells. We confirmed the necessity of the angiogenic tri-culture system (brain endothelium in direct interaction with pericytes and astrocytes) to attain essential phenotypes of BBB vasculature, such as minimized vessel diameter and maximized junction expression. In addition, lower vascular permeability is achieved in the tri-culture condition compared to the monoculture condition.Notably, we focussed on reconstituting the functional efflux transporter system, including p-glycoprotein (p-gp), which is highly responsible for restrictive drug transport. By conducting the calcein-AM efflux assay on our 3D perfusable vasculature after treatment of efflux transporter inhibitors, we confirmed the higher efflux property and prominent effect of inhibitors in the tri-culture model. Taken together, we designed a 3D human BBB model with functional barrier properties based on a developmentally inspired CNS angiogenesis protocol. We expect the model to contribute to a deeper understanding of pathological CNS angiogenesis and the development of effective CNS medications. K E Y W O R D S3D vascular model, blood-brain barrier, CNS angiogenesis, efflux transporter, organ-on-chip

Section: Discussioncontrasting

confidence: 77%

Section: Introductionmentioning

confidence: 99%

3D brain angiogenesis model to reconstitute functional human blood–brain barrier in vitro

Chung

Biotech & Bioengineering

2019

Self Cite

“…[ 33–36 ] Among the many 2D and 3D vascular models, only few 3D in vitro models of functional brain vasculature have been described. [ 37–39 ] However, they typically show larger diameters (600–800 µm) compared to brain vessels (arterioles and venules: 1–100 µm; capillaries: 5–10 µm), which results in altered transport properties. To address such limitations, a 3D in vitro microfluidic model of the human BBB microvasculature has been recently developed by the authors, by the triculture of human induced pluripotent stem cell‐derived ECs (iPSC‐ECs), primary human pericytes, and astrocytes in 3D fibrin hydrogel ( Figure ; Figures S1 and S2, Supporting Information).…”

Section: Introductionmentioning

confidence: 99%

Modeling Nanocarrier Transport across a 3D In Vitro Human Blood‐Brain–Barrier Microvasculature

Adv Healthcare Materials

Campisi

Osaki

et al. 2020

Polymer nanoparticles (NPs), due to their small size and surface functionalization potential have demonstrated effective drug transport across the blood–brain–barrier (BBB). Currently, the lack of in vitro BBB models that closely recapitulate complex human brain microenvironments contributes to high failure rates of neuropharmaceutical clinical trials. In this work, a previously established microfluidic 3D in vitro human BBB model, formed by the self‐assembly of human‐induced pluripotent stem cell‐derived endothelial cells, primary brain pericytes, and astrocytes in triculture within a 3D fibrin hydrogel is exploited to quantify polymer NP permeability, as a function of size and surface chemistry. Microvasculature are perfused with commercially available 100–400 nm fluorescent polystyrene (PS) NPs, and newly synthesized 100 nm rhodamine‐labeled polyurethane (PU) NPs. Confocal images are taken at different timepoints and computationally analyzed to quantify fluorescence intensity inside/outside the microvasculature, to determine NP spatial distribution and permeability in 3D. Results show similar permeability of PS and PU NPs, which increases after surface‐functionalization with brain‐associated ligand holo‐transferrin. Compared to conventional transwell models, the method enables rapid analysis of NP permeability in a physiologically relevant human BBB set‐up. Therefore, this work demonstrates a new methodology to preclinically assess NP ability to cross the human BBB.

“…This results in the formation of a functional and perfusable vascular network. Through this method, Kim et al generated the vascular network to mimic vasculogenesis and angiogenesis processes, and with this platform, they further created the pericytes‐covered vasculature, vascularized bone and blood–brain barrier microenvironment by coculturing the relevant type of cells to better mimic the physiological state as well as the organ‐specific vasculature.…”

Section: Design Consideration: How Simple Is Complex Enough?mentioning

confidence: 99%

Recreating Physiological Environments In Vitro: Design Rules for Microfluidic‐Based Vascularized Tissue Constructs

Tan

Leung

2020

Small

Vascularization of engineered tissue constructs remains one of the greatest unmet challenges to mimicking the native tissue microenvironment in vitro. The main obstacle is recapitulating the complexity of the physiological environment while providing simplicity in operation and manipulation of the model. Microfluidic technology has emerged as a promising tool that enables perfusion of the tissue constructs through engineered vasculatures and precise control of the vascular microenvironment cues in vitro. The tunable microenvironment includes i) biochemical cues such as coculture, supporting matrix, and growth factors and ii) engineering aspects such as vasculature engineering methods, fluid flow, and shear stress. In this systematic review, the design considerations of the microfluidic‐based in vitro model are discussed, with an emphasis on microenvironment control to enhance the development of next‐generation vascularized engineered tissues.