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Abstract
Introduction
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Bioengineering

Use of the MicroSiM (µSiM) Barrier Tissue Platform for Modeling the Blood-Brain Barrier

Published: January 12, 2024
doi:
10.3791/65258
, , , , , , , ,
1Department of Biomedical Engineering,University of Rochester, 2Theodor Kocher Institute,University of Bern, 3Department of Biomedical Engineering,Rochester Institute of Technology

Summary

This report provides protocols for assembly, cell culture, and assays on the µSiM platform for the construction of blood-brain barrier models.

Abstract

The microSiM (µSiM) is a membrane-based culture platform for modeling the blood-brain barrier (BBB). Unlike conventional membrane-based platforms, the µSiM provides experimentalists with new capabilities, including live cell imaging, unhindered paracrine signaling between 'blood' and 'brain' chambers, and the ability to directly image immunofluorescence without the need for the extraction/remounting of membranes. Here we demonstrate the basic use of the platform to establish monoculture (endothelial cells) and co-culture (endothelial cells and pericytes) models of the BBB using ultrathin nanoporous silicon-nitride membranes. We demonstrate compatibility with both primary cell cultures and human induced pluripotent stem cell (hiPSC) cultures. We provide methods for qualitative analysis of BBB models via immunofluorescence staining and demonstrate the use of the µSiM for the quantitative assessment of barrier function in a small molecule permeability assay. The methods provided should enable users to establish their barrier models on the platform, advancing the use of tissue chip technology for studying human tissues.

Introduction

Living tissues are compartmentalized by specialized cells that create and maintain barriers and regulate which cells and molecules are transported from one compartment to another. The improper regulation of barrier functions can be the source of both acute illnesses and chronic disease. The blood-brain barrier (BBB) is the most restrictive tissue barrier in the human body1. Dysfunction of the BBB underlies a wide range of diseases of the central nervous system (CNS), including Alzheimer's disease2, Parkinson's disease3,4, and multiple sclerosis5,6. Injury to the BBB is also linked to long-term cognitive impairment as an outcome of acute disorders, such as sepsis7, COVID-198, and postoperative delirium9. The development of drugs with the potential to treat brain disorders has been frustratingly difficult because of the challenge of intentionally breaching the BBB to deliver bioactive molecules to targets in the brain10. For these reasons, methods to study BBB function in vitro are of paramount importance to the understanding and treatment of diseases of the CNS.

The basic methods for measuring barrier function in vitro involve the establishment of a monolayer or co-culture on a semi-permeable membrane and measuring the resistance imparted by cells to either small molecule diffusion or small electrical currents11,12,13,14. While the emergence of microphysiological systems (MPS) has produced an abundance of choices for modeling the BBB in 3D15,16, the diversity of system geometries makes it difficult to compare permeability measurements between MPS or to established literature values. The establishment of trusted baseline values is particularly important in BBB research where, because of the extensive barrier regulation by brain vascular endothelial cells, in vitro permeability values are highly scrutinized12,17,18. For these reasons, permeability measurements across monolayers established on 2D membranes will remain a staple in BBB studies for years to come. This holds true for other tissue barriers, including epithelial barriers, where absolute values of baseline permeability are used to validate and compare in vitro models19,20,21.

With the goal of establishing a valuable new tool for the BBB research community, we have introduced22 and advanced23,24,25,26 the microdevice featuring a silicon membrane (µSiM) platform for use in barrier tissue modeling over the last 5 years. The enabling feature of the platform is an ultrathin (<100 nm thick) membrane with hundreds of millions of nanopores27,28 or a mix of nanopores and micropores29. The free-standing membrane chips are produced on a 300 µm silicon 'chip' that stabilizes the ultrathin structures30 and allows them to be handled by tweezers for device assembly. Because of their ultrathin nature, the membranes have a permeability that is two orders of magnitude higher than that of conventional track-etched membranes used in commercial membrane culture devices31,32. In practice, this means that the membrane's hindrance to the diffusion of molecules smaller than the nanopores (<60 nm) is negligible33. Thus, for cellular barriers, only the cells and the matrices they deposit will determine the rate of small molecule transport from the apical to basal compartments that are separated by the membrane34. The device design and the ultrathin nature of the membranes also provide many advantages for optical microscopy. These include 1) the ability to follow live cultures using phase contrast or bright field imaging, 2) the ability to fluorescently stain and image in situ without the need to extract and transfer the membrane to a cover glass, and 3) the fact that the membranes are thinner than confocal 'slices' so that direct co-cultures have a more natural spacing between cell types than can be achieved with 6-10 µm-thick track-etched membranes.

Most recently, we advanced the platform to a modular format to facilitate rapid assembly34 and customization35,36. We leveraged the modular format to distribute device components between our bioengineering and collaborating brain barrier laboratories. We then jointly developed protocols for device assembly, monoculture and co-culture, immunofluorescent staining, and small molecule permeability and showed that these methods were reproducible between labs. Using these protocols, we also showed that the modular platform supports a validated BBB developed using the extended endothelial culture method (EECM) for creating brain microvascular-like endothelial cells (BMEC) from human induced pluripotent stem cells (hiPSCs)37. The purpose of the current report is to review these methods in greater detail and, with the aid of the accompanying video, facilitate broader adoption of the platform in the BBB community.

Protocol

1. µSiM device assembly

NOTE: This method describes the assembly of the devices. The membrane chip has a trench-side and flat-side, which can be assembled trench-up or trench-down. Trench-down devices are most commonly used for cell culture.

  1. In a sterile environment (i.e., a biosafety hood), prepare all the materials for assembly, including the assembly fixtures, components, membrane chips, and tweezers.
  2. Place the membrane chip onto the center of fixture A1 using chip tweezers. The flat surface of the chip faces down and the trench area faces up for trench-down devices, and vice versa for trench-up devices.
    NOTE: The following assembly steps are illustrated by using the trench-down device as an example, which allows a flat growth area in the top chamber.
  3. Bond component 1 to the chip. First, peel off the blue protective layers on both sides of component 1 using straight tweezers and place it in fixture A1, top chamber down. Gently press component 1 down until the pressure-sensitive adhesive (PSA) touches the chip.
  4. Put fixture A2 onto fixture A1 and apply firm pressure at different corners to ensure a tight fit of the chip and component.
    NOTE: Be sure to not take the PSA layer off. It is a transparent and stiffer layer compared to the blue protective layers.
  5. Bond component 2 to component 1 with the chip. First, prepare component 2 by grabbing one corner of component 2 with straight tweezers and peeling it off from the sheet. Then, grab the non-PSA "triangle" region of component 2 and together remove the thick, transparent protective layer and blue layer of component 2, exposing the PSA surface. Place component 2 in fixture B1, PSA side up.
  6. Place component 1 with the membrane chip in fixture B1, top chamber facing up.
  7. Put fixture B2 onto component 1 and apply firm pressure at different corners of fixture B2.
  8. Take the assembled device out of the fixture and use straight tweezers to press out any air bubbles on the underside of the device and seal the edges of the channelx`, avoiding contact with the membrane region. Prior to using for cell culture, ultraviolet (UV)-sterilize newly assembled devices for 20 min.

2. Cell culture

NOTE: This method describes protocols for primary and hiPSC-derived cultures on the platform. The methods describe endothelial cell monoculture in the top chamber of the device and pericyte and endothelial cell co-culture with pericytes in the bottom chamber and endothelial cells in the top chamber of trench-down assembled devices. For chamber dimensions and volumes, see Table 1. These are the most common formats; however, other cell culture layouts can be used depending on user needs.

  1. Cell culture chamber preparation
    1. Assemble the devices per the protocol detailed in section 1.
    2. Place the devices in sterile hose clamps. Prior to cell culture, sterilize the clamps by soaking them in ethanol for ≥20 min. Resterilize after each experiment for reuse.
    3. Culture the devices in a large sterile Petri dish. For extra humidity, add a small Petri dish or 50 mL conical tube lid filled with sterile water.
    4. Wash the top chamber of the devices twice with 100 µL of sterile water. For bottom chamber cell culture, wash the bottom chamber with 20 µL of sterile water.
  2. hCMEC/D3 cell line (BBB) monoculture
    1. Prepare the cell culture chamber according to section 2.1.
    2. Coat the top chambers with 25 µg/cm2 of collagen I and 5 µg/cm2 of human fibronectin mixed in phosphate-buffered saline (PBS). Let it sit for 1-2 h at 37 °C or overnight at 4 °C.
    3. Remove the coating solution and add 100 µL of prewarmed growth-factor-depleted endothelial medium (Assay medium) to the top chamber and 20 µL to the lower chamber. To prepare the assay medium, mix 100 mL of endothelial basal medium + 400 µL of human fibroblastic growth factor + 40 µL of hydrocortisone + 100 µL of gentamicin sulfate + 2 mL of fetal bovine serum.
    4. Passage hCMEC/D3 cells according to the manufacturer's protocol; trypsinize the cells in a 37 °C incubator for 3-5 min and then stop trypsinization by the addition of prewarmed endothelial medium. Transfer the cell suspension to a centrifuge tube and centrifuge at 200 × g for 5 min at room temperature. Resuspend the cell pellet in assay media and seed the cells in the top chambers at a density of 40,000-60,000 cells/cm2. Incubate the devices at 37 °C with 5% carbon dioxide (CO2) for 2-4 h to facilitate cell adhesion. For example, to achieve 40,000 cells/cm2 on the 0.37 cm2 chip, add 100 µL of a cell solution with a concentration of 150,000 cells/mL to the top chamber.
      NOTE: We culture and passage hCMEC/D3 according to Hudecz et al.38, using a modified formulation of endothelial growth media-2 (EGM-2) for cell maintenance and a growth factor-reduced "assay medium" after subculture for assays. Other media formulations should be compatible with the devices, though we recommend the media formulations from Hudecz et al.38 if users experience issues with hCMEC/D3 survival.
    5. After 2-4 h for cell adhesion, exchange with fresh assay medium in both chambers to remove dead or unattached cells.
    6. Maintain the devices at 37 °C with 5% CO2, exchanging the assay medium in both chambers every 2-3 days until experimentation. Assays are typically performed after 2 weeks of culture.
  3. hiPSC-derived EECM-BMEC-like cell monoculture
    1. Prepare the cell culture chamber according to section 2.1.
    2. Prepare collagen IV from human placenta solution by adding 5 mL of 0.5 mg/mL acetic acid to 5 mg of collagen IV to create a 1 mg/mL solution. Let the solution sit for ≥4 h at 4 °C to fully reconstitute. The solution is stable at 4 °C for 2 weeks.
    3. Coat the top chambers with 100 µL of a 4:1:5 ratio of collagen IV, bovine fibronectin, and sterile water. Coat at 37 °C for 2-4 h.
    4. Remove the coating solution and add 100 µL of room temperature hECSR to the top chamber and 20 µL to the lower chamber.
    5. Passage EECM-BMEC-like cells according to Nishihara et al.37; add a cell detachment enzyme mixture to the cells and transfer to a 37 °C incubator for 5-8 min. Pipet the cell solution to singularize and add to 4x the volume of endothelial medium in a centrifuge tube. Centrifuge at 200 × g for 5 min at room temperature; resuspend the cells in hECSR and seed in the top chambers at a density of 40,000 cells/cm2. Incubate the devices at 37 °C with 5% CO2 for 2-4 h to facilitate cell adhesion. For example, to achieve 40,000 cells/cm2, add 100 µL of a cell solution at 150,000 cells/mL.
    6. After 2-4 h for cell adhesion, exchange with fresh hECSR in both chambers to remove dead or unattached cells.
    7. Maintain the devices at 37 °C with 5% CO2, exchanging hECSR in both chambers every 1-2 days until experimentation. Assays are typically performed on day 6 of culture.
  4. hCMEC/D3 and primary human brain vascular pericyte (HBVP) co-culture
    1. Prior to the device assembly, coat the membrane chips with 2 µg/cm2 of poly-L-lysine (PLL) mixed in PBS. Apply 50-80 μL PLL in a droplet only to the side that will be facing down in the final device assembly. Complete the coating process in either 1-2 h at 37 °C or overnight at 4 °C.
    2. Remove the coating solution. Wash the membrane chips with sterile ultrapure water and allow them to dry.
    3. Assemble the devices per the protocol detailed in section 1 above, with the PLL-coated side facing down, and prepare the cell culture chamber according to section 2.1.
    4. Coat the top chambers according to section 2.2.2.
    5. Add 50 µL of prewarmed pericyte medium to the top chambers and add 20 µL to the lower channels.
    6. Passage HBVPs according to the manufacturer's protocol; trypsinize the cells in a 37 °C incubator for 3-5 min, then stop trypsinization by addition of prewarmed pericyte medium. Transfer the cell suspension to a centrifuge tube and centrifuge at 200 × g for 5 min at room temperature. Resuspend the cell pellet in pericyte medium and seed the cells in the bottom chambers at a density of 14,000-25,000 cells/cm2. Invert the devices but maintain an air interface with the top chambers to facilitate gas exchange.
      NOTE: The air interface required during inversion can be achieved by flipping the devices after placing them inside hose clamps and pushing down on all corners prior to flipping, or by placing the devices upside down on parallel strips of acrylic or silicone spaced far enough apart to keep the top chambers unobstructed. Seeding density may need to be optimized for each user. To achieve 14,000 cells/cm2, add 20 µL of a cell suspension at ~590,000 cells/mL. Note that 20 µL is pipetted into the bottom chamber to avoid bubbles, but the density is calculated using the bottom chamber volume of 10 µL.
    7. Incubate the cells at 37 °C with 5% CO2 for 2-4 h in the inverted position to facilitate cell adhesion.
    8. After 2-4 h for cell adhesion, flip the devices upright and exchange them with fresh pericyte medium in both chambers to remove dead or unattached cells.
    9. After pericyte seeding, seed hCMEC/D3s in the top chamber, following steps 2.2.4-2.2.5. Switch both chambers to the assay medium.
    10. Maintain the devices at 37 °C with 5% CO2, exchanging assay medium in both chambers every 1-2 days until experimentation. Primary cell co-culture is usually maintained for 6-8 days prior to the assays.
      NOTE: If the HBVP monocultures will be compared to hCMEC/D3 monocultures or hCMEC/D3 and HBVP co-cultures, then exchange pericyte medium with assay medium 2-3 days after seeding the HBVPs.
  5. hiPSC-derived EECM-BMEC-like cell and brain pericyte-like cell (BPLC) co-culture
    1. Prepare the cell culture chamber according to section 2.1 and coat the top chambers according to steps 2.3.2-2.3.3.
    2. Remove the coating solution and add 50 µL of room temperature Essential 6 Medium + 10% Fetal Bovine Serum (E6 + 10% FBS) to the top chamber.
    3. Passage the BPLCs according to Gastfriend et al.39; add a cell detachment enzyme mixture to the cells and transfer to a 37 °C incubator for 5-15 min, until ~90% of the cells are rounded. Pipet the cell solution to singularize and add 4x the volume of DMEM/F12 in a 50 mL centrifuge tube, using a 40 µm cell strainer to filter and fully singularize the cells. Transfer to a 15 mL centrifuge tube, centrifuge at 200 × g for 5 min at room temperature, resuspend the cell pellet in E6 + 10% FBS, and seed the cells in the bottom chambers at a density of 14,000-25,000 cells/cm2. Invert the devices but maintain an air interface with the top chamber to facilitate gas exchange.
      NOTE: The air interface required during inversion can be achieved by flipping the devices after placing them inside the hose clamps and pushing down on all corners prior to flipping, or by placing the devices upside down on parallel strips of acrylic or silicone spaced far enough apart to keep the top chambers unobstructed. Seeding density may need to be optimized for each user. To achieve 14,000 cells/cm2, add 20 µL of a cell suspension at ~590,000 cells/mL. Note that 20 µL is pipetted into the bottom chamber to avoid bubbles, but the density is calculated using the bottom chamber volume of 10 µL.
    4. Incubate the cells at 37 °C with 5% CO2 for 2-4 h in the inverted position to facilitate cell adhesion.
    5. After 2-4 h for cell adhesion, flip the devices upright and exchange with fresh E6 + 10% FBS in both chambers to remove dead or unattached cells.
    6. One day after pericyte seeding, seed EECM-BMEC-like cells in the top chamber, following steps 2.3.5-2.3.6. Switch both chambers to hECSR.
    7. Maintain the devices at 37 °C with 5% CO2, exchanging the assay medium in both chambers every 1-2 days until experimentation. hiPSC-derived co-culture is usually maintained for 7 days for BPLCs and 6 days for EECM-BMEC-like cells prior to assays.
      ​NOTE: If the BPLC monocultures will be compared to EECM-BMEC monocultures or EECM-BMEC and BPLC co-cultures, then exchange E6 + 10% FBS with hECSR 1 day after seeding the BPLCs.

3. Immunocytochemistry

NOTE: This method describes a protocol for immunocytochemical staining and imaging of cells cultured in the top and/or bottom side of the membrane. The aim of this experiment is to determine the presence and location of key proteins that should be found in the BBB such as adherens and tight junction proteins, and cell identity proteins. Alternate and live staining methods are also compatible with the platform.

  1. Fixation and staining on the devices
    1. Place the primary antibodies on ice to thaw.
    2. Prepare a 4% paraformaldehyde (PFA) solution at room temperature (e.g., dilute 16% PFA in 3x its volume of PBS) or chill 100% methanol at -20 °C.
    3. Create an appropriate blocking solution according to Table 2. Store on ice.
      NOTE: Vortexing the solution may be necessary to fully dissolve Triton X-100.
    4. Fix the cells by pipetting 20 µL of fixative (e.g., PFA or methanol) into the bottom chamber and 50 µL into the top chamber. Incubate the devices for 10 min (PFA) or 2 min (methanol) at room temperature.
    5. Wash for 3 x 5 min by pipetting 20 µL of PBS through the bottom chamber and 100 µL into the top chamber.
    6. Block for 30 min at room temperature by adding 20 µL of the blocking solution to the bottom chamber and 50 µL of blocking solution into the top chamber. Check for bubbles in the bottom chamber.
    7. Prepare the primary antibody solution by diluting the antibody(ies) in the blocking solution according to Table 2. Store on ice.
    8. Stain with the primary antibodies by adding 20 µL of the primary antibody solution to the bottom chamber and replacing the volume of the top chamber with 50 µL of the primary antibody solution. Check for bubbles in the bottom chamber. Incubate for 1 h at room temperature or overnight at 4 °C.
    9. Wash for 3 x 5 min by pipetting 20 µL of PBS through the bottom chamber and 100 µL into the top chamber.
    10. Prepare the secondary antibody solution by diluting the antibody(ies) in the blocking solution according to Table 2. Store on ice protected from light.
    11. Stain with secondary antibodies by adding 20 µL of secondary antibody solution to the bottom chamber and replacing the volume of the top chamber with 50 µL of the secondary antibody solution. Check for bubbles in the bottom chamber. Incubate for 1 h at room temperature protected from light.
    12. Wash for 3 x 5 min by pipetting 20 µL of PBS through the bottom chamber and 100 µL into the top chamber.
    13. Make a nuclear stain solution. Dilute Hoechst 1:10,000 in PBS. Add 20 µL of the nuclear stain solution to the bottom chamber and replace the volume of the top chamber with 50 µL of the nuclear stain solution. Check for bubbles in the bottom chamber. Incubate for 3 min at room temperature protected from light.
    14. Remove the stain by adding 20 µL of PBS to the bottom chamber and replacing the volume of the top chamber with 100 µL of PBS. Image the devices immediately or store them at 4 °C with the petri dish wrapped in parafilm and protected from light until ready for imaging.
  2. Confocal imaging
    NOTE: This section describes imaging the devices using an inverted spinning disc confocal microscope with a long working distance (LWD) 40x objective (water, WD 590-610, numerical aperture 1.15) as an example. For working distances and lens compatibility, refer to supplemental material in McCloskey et al.34. Images of the entire membrane area are also taken using a 10x objective to ensure that the 40x images are representative of the entire field. These are usually taken in widefield.
    1. Turn on the microscope and open the imaging software.
    2. Set the channels according to the properties of the secondary antibody and the nuclear stain, using Confocal Imaging Mode. Optimize the laser power and exposure time to ensure that the signal is above the background and reduces imaging artifacts.
      1. For Hoechst nuclear staining, use excitation 405, emission 450/50 Bandpass (BP), 500 ms exposure time, 50% laser power. For labels using a secondary antibody conjugated to Alexa Fluor (AF) 488, use excitation 488, emission 525/50BP, 500 ms exposure time, and 50% laser power. For labels using a secondary antibody conjugated to AF568, use excitation 561, emission 600/50BP, 500 ms exposure time, and 100% laser power.
    3. Place the device in the microscope slide device holder, top chamber facing up and set in the microscope using a microscope slide holder. Turn on Live and select the channel for the nuclear stain. Find the membrane using a low objective, making sure that the transparent silicon-nitride membrane region is centered, as light will not transmit through the blue, solid silicone region. Once the device is properly centered and the cell layer is found, switch to the 40x objective, wet the objective, and focus on the membrane region using the nuclear stain as a guide.
    4. Turn on z-stack imaging and set Scan Mode to Start/End. Set step size or count. Using the coarse adjustment knob on the microscope, set the scan start to the top of the endothelial cell layer, using the nuclear stain as a guide, and scan end at the bottom of the pericyte layer, using the nuclear stain as a guide. Check all channels to ensure that everything will be captured in the imaging field.
      ​NOTE: We usually use auto step, which is ~0.2 µm slices.
    5. Set the Image Name and press Acquire to start imaging. Repeat on different regions as needed.
    6. Process the confocal images using ImageJ40 or Imaris.
      1. To process in Imaris, drag the image file into the program to open. Select Section on the top menu bar to see a 2D image of the x-y plane with corresponding views of the x-z and y-z planes. Select 3D View on the top menu bar to see a 3D image. Click on the image and drag it to rotate. Select Snapshot on the top menu bar to take an image.

4. Sampling assay of small molecule permeability

NOTE: This section describes a methodology for quantitative measurements of barrier properties of the cell cultures. The aim of this experiment is to detect the concentration of a fluorescent small molecule that passes through the cell layers and enters the bottom chamber of the platform. These data are then used to calculate cellular permeability.

  1. Sampling technique
    1. Assemble the devices per the protocol detailed in section 1 and culture the desired cell lines as described in section 2. Include an additional device to serve as a cell-free, coated control device to measure the system permeability.
      NOTE: Minimum three technical replicates per condition are recommended; however, only one replicate of the coated control is required.
    2. Prior to starting the sampling assay, replace the medium at the bottom chamber with fresh medium. Check the confluency of the endothelial monolayer in each device under the microscope. Note any gaps in cell monolayers, as this will impact the diffusion of dye into the bottom chamber.
      NOTE: A healthy endothelial culture should be 100% confluent.
    3. Prepare the fluorescent small molecule solution (e.g., 150 µg/mL Lucifer Yellow, 457 Da) in cell culture medium. Prepare excess volume of the fluorescent small molecule solution to be used for the preparation of the standard solutions that serve as references to calculate the concentration of the fluorescent small molecule sampled from the bottom channel.
      NOTE: We recommend the preparation of 400 µL of excess solution to be used as the standard solution with the highest concentration of the fluorescent small molecule.
    4. Replace the medium in the top well with 100 µL of the fluorescent small molecule solution.
      NOTE: We recommend using a hydrophobic pen to draw circles around the sampling ports and wait until the hydrophobic ink dries completely before the addition of fluorescent dye solution. This prevents the spread of the medium from the bottom channel around the sampling port at step 4.1.7. We recommend staggering the addition of the fluorescent small molecule solution into the top well-wait 2 min before adding the fluorescent solution to the next device, or work in groups of 3 (add the solution into three devices at the same time and wait 5 min to add the next three devices).
    5. Incubate the devices at 37 °C, 5% CO2 for 1 h.
    6. During 1 h-long incubation at the previous step, prepare standard solutions by performing 2-fold serial dilutions from the fluorescent small molecule solution prepared at step 4.1.3. Pipet 50 µL of each solution into the flat-bottom black 96-well plate in triplicates. Use blank cell culture medium as the baseline standard solution.
      NOTE: To prepare standard solutions, we recommend 11 serial dilutions at a final volume of 200 µL and the use of cell culture medium as blank to measure the baseline fluorescent intensity.
      1. Transfer 200 µL of 400 µL of the excess fluorescent small molecule solution prepared at step 4.1.3 into a tube containing 200 µL of medium, mix well, and transfer 200 µL of this solution into the next tube containing 200 µL of medium. Repeat 1:2 dilutions until there are a total of 10 tubes. Pipet 50 µL of the most concentrated standard solution into column 1 in triplicates in the 96-well plate (B1, C1, D1), the 2nd most concentrated solution into column 2 (B2, C2, D2), and so on. For the 12th column in the plate, pipet 50 µL of blank media in triplicates (B12, C12, D12).
    7. Perform the following steps to sample the fluorescent small molecule solution from the bottom channel.
      1. Remove the fluorescent small molecule solution from the well to stop the process of diffusion.
      2. Place a tip containing 50 µL of medium into the upper port to serve as a reservoir by inserting the tip with 50 µL into the port, lifting the device, and gently ejecting the tip while holding on to the top for stabilization. Set down the device. Make sure there are no bubbles in the pipet tip or air at the tip of the pipet to avoid adding bubbles into the bottom chamber during sampling.
      3. Add 50 µL of medium into the top well to prevent the disruption of the cell monolayer during sampling.
      4. For sampling the solution from the bottom channel, push a pipetter with an empty pipet tip to its first resistance, insert the tip into the sampling port, and reverse pipet out 50 µL of the solution from the bottom channel. Transfer directly into the flat-bottom black 96-well plate  containing the standard solutions. 
        NOTE: We recommend checking the cell monolayer under the microscope immediately after sampling. Drawing media from the bottom channel can occasionally result in disruption of the cell layer in the top well, which might cause inconsistent permeability measurements. Working quickly throughout steps in 4.1.7 will help prevent this.
    8. Measure the fluorescence intensity in a microplate reader using the proper excitation and emission wavelength parameters for the fluorescent small molecule used. For Lucifer Yellow, use 428 nm excitation and 536 nm emission, with optimal gain. Fluorescence is measured from the top of the plate. Add the plate into the plate reader, highlight the wells with sample (including the standard curve) and select Start to read the plate.
  2. Calculation of the permeability value (see Supplemental File 1 for template)
    1. Subtract the averaged fluorescence intensity value of the blank medium from all fluorescence intensity values measured.
    2. Use equation (1) to calculate the system permeability Ps:
      Equation 1     (1)
      Where [A]A is the concentration of the fluorescent small molecule collected from the bottom channel, V is the volume sampled and added to the plate (0.050 mL), [A]L is the concentration of the fluorescent small molecule added into the top well  (e.g. 0.15 mg/mL), t is the time of incubation (in s or min depending on the desired units), and S is the membrane surface area (0.014 cm2).
      1. Calculate [A]A using the equation obtained by plotting a standard curve from the fluorescence intensity outputs and the known concentrations of the standard solutions. Calculate concentrations (x) of the experimental samples by inserting their fluorescence intensity values (y) into the equation.
        NOTE: Use the portion of the standard curve that is linear. We recommend measuring the membrane surface area from an image of the membrane taken under the microscope as membrane area could vary depending on the lot number and may significantly affect the calculated permeability values if they differ from the coated control.
    3. Use equation (2) to calculate the permeability of the cell monolayer Pe:
      Equation 2     (2)
      Where PS is the system permeability as calculated at step 4.2.2 and PC is the system permeability value of the cell-free, coated control device.

Representative Results

The assembly of a trench-down device is shown in Figure 1. The fixtures guide the assembly of the components and the membrane chip. Component 1 is primarily acrylic with a PSA surface for bonding to the chip and an opening to the bottom chamber and ports for pipet access to the bottom chamber. Component 2 is the channel layer and contains a non-adhesive, PSA-free "triangle" in the top right for gripping. Trench-down devices provide a flat cell culture growth area in the top chamber, whereas trench-up devices have a flat surface for cell culture in the bottom chamber.

We performed endothelial monocultures and co-cultures of hCMEC/D3 and HBVPs and of hiPSC IMR90-4-derived EECM-BMEC-like cells and BPLCs and acquired phase images using a Nikon Eclipse Ts2 phase contrast microscope and 10x objective (Figure 2). Optimal seeding densities for primary cell culture are shown (images taken 1 day after seeding), as well as under-seeded HBVPs (Figure 2A). Final coculture and monoculture phase images (6 days endothelial cell culture) can be difficult to distinguish (Figure 2C), and confirmation of successful primary cell co-culture may require immunofluorescence staining (see protocol section 3). Low, high, and optimal hiPSC-derived BPLC seeding densities are also illustrated (Figure 2B). hiPSC-derived co-culture is clearer to distinguish in phase contrast imaging compared to primary co-cultures (Figure 2D). Low BPLC seeding results in poor pericyte coverage and pericyte clumping, whereas overseeding results in the pericyte layer peeling off the membrane. Further, exchanging the medium in the bottom chamber too quickly may result in pericyte loss, as these cells are very sensitive to shear. Optimal coverage by pericytes is ~90% for a BBB model, with no gaps in the endothelial layer.

Representative images of immunostained hiPSC-derived co-culture are illustrated in Figure 3 (6 days endothelial cell culture). IMR90-4-derived BPLCs were stained for the pericyte marker PDGFRβ, and IMR90-4-derived EECM-BMEC-like cells were stained for the adherens junction marker VE-cadherin. Hoechst was used to stain the nuclei. Images were acquired on a Spinning Disc confocal microscope using a 40x LWD objective with 0.2 µm slices and processed with Imaris. Both cell layers can be visualized even though the thin nanomembrane is not seen.

We performed the sampling-based small molecule permeability assay using the same experimental conditions in two physically distant laboratories at the University of Bern, Switzerland, and the University of Rochester, NY, USA to demonstrate interlaboratory reproducibility of results (Figure 4)34. hiPSC IMR90-4-derived EECM-BMEC-like cells were cultured in the µSiM device for 2, 4, or 6 days and on transwell filters for 6 days. The assay was performed using 150 µg/mL Lucifer Yellow (457 Da) in both laboratories. High variability in the permeability of the endothelial cells cultured for 2 days in the device indicates that 2 days of culture was insufficient for barrier maturation. There were no significant differences in permeability between the labs upon barrier maturation-from 4 days on. We also showed that the permeability of the endothelial cells cultured in µSiM and transwell filters for 6 days matched those previously published40.

Figure 1
Figure 1: Steps of µSiM assembly. (A) Prepare the chip by placing it on fixture A1. Place the chip trench up for a final trench-down device. Place the chip trench down for a final trench-up device. (B) Bond component 1 to the chip by removing the protective masks from component 1 and placing it face-down into FA1. Bond by applying pressure with fixture A2. (C) Bond component 2 and component 1 by removing component 2 from its sheet and peeling off the top protective layers. Place the channel up into fixture B1 and place component 1 on top of component 2 face-up. Bond by applying pressure with fixture B2. Abbreviations: FAn = fixture An; FBn = fixture Bn. Please click here to view a larger version of this figure.

Figure 2
Figure 2: Schematic of coculture and representative phase contrast images of cell culture in devices. (A) Location of pericyte and endothelial cell seeding. (B) Side view schematic of cell locations across the trench of the membrane chip. (C) Representative images of low and optimal seeding densities for primary HBVP and hCMEC/D3 brain endothelial cell line. Images were acquired 1 day after seeding (HBVP) and 2 h after seeding (hCMEC/D3). (D) Representative images of low, high, and optimal seeding densities for hiPSC-derived brain pericyte-like cells. Images were acquired 1 day after seeding. (E) Representative images of final HBVP and hCMEC/D3 co-culture and hCMEC/D3 monoculture. Images were acquired 8 days following HBVP seeding and 7 days following hCMEC/D3 seeding. (F) Representative images of failed and successful BPLC and EECM-BMEC-like cell co-culture and EECM-BMEC-like cell monoculture. Images were acquired 7 days following BPLC seeding and 6 days following EECM-BMEC seeding. Underseeded BPLC cultures fail to have sufficient coverage, whereas overseeding BPLC cultures will grow overconfluent and start clumping/receding. Scale bars = 100 µm (CF). Abbreviations: HBVPs = human brain vascular pericytes; hiPSC = human induced pluripotent stem cell; BPLCs = hiPSC-derived brain pericyte-like cells. Please click here to view a larger version of this figure.

Figure 3
Figure 3: Representative images of immuno-stained hiPSC-derived cell co-culture in devices. Cells were stained for endothelial cell marker VE-cadherin (green), pericyte marker PDGFRβ (red), and nuclear stain (blue). Two layers of cells can be seen in close proximity, separated only by a thin silicon-nitride nanomembrane (white arrow marks membrane location on left image). Scale bar = 50 µm. Abbreviations: hiPSC = human induced pluripotent stem cell; PDGFRβ = platelet-derived growth factor receptor beta. Please click here to view a larger version of this figure.

Figure 4
Figure 4: Sampling-based small molecule permeability assay. (A) Schematic of the experimental workflow. (B) Demonstration of the interlaboratory reproducibility between two physically distant laboratories at the University of Bern (UniBe), Switzerland, and the University of Rochester (UR), NY, USA: hiPSC-derived endothelial cells were cultured in the µSiM device for 2, 4, or 6 days and in transwell filters for 6 days. Permeability assay was performed using 150 µg/mL Lucifer Yellow (457 Da). The red bar indicates the previously published sodium fluorescein (376 Da) permeability data of the same hiPSC-derived endothelial cells cultured for 6 days in transwell filters40. N = 4-16 per group. Two-way ANOVA with Tukey's post hoc test was used, and comparisons were only displayed for relevant p < 0.05. (C) Demonstration of cytokine response using hiPSC-derived EECM-BMEC-like cells cultured in the µSiM for 2 days; 0.1 ng/mL TNFα + 2 IU/mL IFNγ) or media control (non-stimulated, NS) was added to the top chamber for 20 hr prior to permeability assay using 150 µg/mL Lucifer Yellow. N = 3 per group. Students t-test, p < 0.05. Please click here to view a larger version of this figure.

Top Chamber Seeding Surface Area Top Well Volume Bottom Chamber Seeding Surface Area Bottom Channel Volume
~37 mm2 100 µL (can hold ≥115 µL) ~42 mm2 10 µL (pipet 20 µL to avoid bubbles)

Table 1: Critical µSiM surface area and volumes.

Target Fixative Blocking Solution Dilution
VE-cadherin 4% PFA or 100% MeOH 5% GS + 0.4% Tx-100 or 10% GS + 0.3% Triton X-100 1:50
CD31 4% PFA or 100% MeOH 5% GS + 0.3-0.4% Triton X-100 1:100
Claudin-5 100% MeOH 5-10% GS + 0.3% Triton X-100 1:200
ZO-1 100% MeOH 5-10% GS + 0.3% Triton X-100 1:200
Occludin 100% MeOH 5-10% GS + 0.3% Triton X-100 1:50
PDGFRβ 4% PFA 5% GS + 0.4% Triton X-100 1:100
NG2 4% PFA 5% GS + 0.4% Triton X-100 1:100
Goat α-Mouse IgG Alexa Fluor 488 1:200
Goat α-Mouse IgG Alexa Fluor 568 1:200

Table 2: Antibodies and staining methods validated for co-culture immunocytochemistry in µSiM devices. Abbreviations: PFA = paraformaldehyde; MeOH = methanol; GS = goat serum.

Supplemental File 1: Template for calculation of permeability value. Please click here to download this File.

Discussion

While membrane chips have been designed for stability, they can crack or break if handled incorrectly during assembly. Thus, it is critical to grip the chip in the chip tweezer notches and gently place it in the fixture. When handling the devices in general, extra precaution must be taken not to bump or drop the devices. During the bonding of the membrane chip to fixture A1, the chip must be laid flat and centered on the pillar of fixture A1 to avoid membrane cracking during the bonding to component 1. Further, any contact with the exposed PSA layers must be avoided after removing protective masks. When handling component 2 following the removal of the protective masks, it is advisable to hold it along the component's edge and use tweezers to grab the triangle corner that is PSA-free.

While cell culture protocols were described for possible BBB models, the BMEC/pericyte co-culture model of the BBB described here may be sufficient or insufficient depending on the physiological context and questions of interest. For example, immune cell trafficking largely occurs in the postcapillary venules of the brain41,42. In these regions, a perivascular space separates the BMEC/pericyte barrier from the glial limitans established by astrocytes. Thus, in postcapillary venules, the neurovascular unit (NVU) comprises two physically separated barriers in series, and astrocytic end-feet do not directly contact the BMEC/pericyte blood barrier, which is well represented by the current model. If the goal is an NVU model that accounts for the impact of astrocyte-secreted factors on the blood barrier, an astrocyte compartment could be added to the device that allows soluble factor exchange through the perivascular space. This example was illustrated previously34 and could be extended to include other cells such as microglia and neurons in a 3D 'brain' compartment. The modular architecture of the platform enables simple assembly strategies to be used to achieve these reconfigurations so that the platform is as simple or complex as needed to address the hypotheses at hand. Each cell culture setup; however, must be optimized for new cell lines and multi-cultures. For example, due to the properties of the silicon-nitride membranes, coating solutions may need to be adjusted compared to tissue culture plates. The inclusion of fibronectin typically aids in cell attachment and survival. Further, users could culture endothelial cells and pericytes in opposite directions. In this case, it may be necessary to modify, for example, the way the permeability measurements are made and interpreted. Providing steps for this type of culture, however, is beyond the scope of this paper.

Another challenge one may encounter during cell culture is the quick evaporation of media since the devices can be more sensitive to alterations in the environment compared to standard tissue culture plates and flasks. If excess evaporation is seen or cell growth is slowed, all critical incubator parameters must be measured to ensure accurate settings. More water can be added to the tissue cap or small Petri dish placed inside the cell culture chamber, or media must be exchanged more frequently. Further, bubbles can enter the bottom channel and get stuck in the trench for trench-down devices. While they can be removed, it is easiest to avoid adding bubbles in the first place. To do this, it is important to check that there are no bubbles in the pipette tip or air at the end of the pipette tip prior to pipetting media into the bottom chamber. Further, media evaporation in the channel can lead to a gap between the media surface and the port top. A small volume of media can be pipetted into one port until the media reaches the surface of the opposite port, after which the media can be exchanged in that opposite port. While hECSR and E6 + 10% FBS media should not be warmed in the water bath, other media can be prewarmed to reduce bubble formation. If a bubble does get into the bottom chamber, it can be removed by quickly pipetting 100 µL through the channel. However, this method can lead to contamination between chambers or media spilled across the device's surface. It may also disrupt cell layers. Alternatively, the media can be removed from the channel first and then reintroduced with a 50 µL volume. Removing the media first, however, can result in more bubble formation in the channel. If a bubble is not directly under the membrane area, it can be left in the channel with no effects on cell culture.

Pericyte attachment and growth, as demonstrated in Figure 2, can be challenging. Using an optimized seeding density is essential for the formation of a layer with a physiologically relevant pericyte-to-endothelial cell ratio. Further, as the pericytes are sensitive to shear, all media exchanges in the channel should be done very slowly to protect the cells. For BPLC culture, improved attachment can be achieved by coating the bottom chamber with 800 µg/mL collagen type IV or 100 µg/mL fibronectin.

Immunocytochemistry in devices described here enables qualitative analysis of cell health and function. Methods for staining in tissue culture plates or other platforms should be directly translatable into the platform. For cell culture in only the top chamber, following fixation, PBS can be added into the bottom chamber and left for the remaining steps, with blocking and staining done in the top chamber only. This minimizes the risks of breaking the membranes or getting bubbles into the bottom chamber. For co-culture staining, we recommend using both chambers in all steps. It is important to note that the viscosity of the fixative and PBS is different from that of media. Thus, it can be easier to add bubbles into the bottom chamber, and extra care should be taken to check pipette tips for air at the end of the tip prior to pipetting into the bottom chamber.

The protocol described for the small molecule permeability assay allows functional and quantitative assessment of the barrier function of the endothelial cells cultured in the µSiM device. One issue that may be encountered during this assay is drawing air bubbles into the pipette during sample collection from the bottom channel at protocol step 4.1.7.4. To avoid this issue, it is important to make sure that the tip is sealed into the port before starting sample collection and the sample should not be drawn too fast. If that does not solve the problem, the size of the tips used might be too small or too large to fit into the ports; use the tips listed in the Table of Materials. If unexpectedly high permeability values are measured in spite of a healthy-looking confluent monolayer, the integrity of the monolayer must be checked for disruption during sample collection. We recommend always checking the monolayer under the microscope immediately after sample collection. If the monolayer still seems intact and healthy, the sample can be fixed and biological markers of barrier function can be assessed, for instance, via immunostaining of the junctional proteins. Conversely, if unexpectedly low permeability values are measured, it is important to ensure that 50 µL of media is sampled from the bottom channel without any air bubbles. If medium comes out from the sampling port as soon as the reservoir tip is placed, that media must be collected before fitting the pipette into the sampling port as most of the fluorescent small molecule will be present in the initial 10 µL volume sampled from the bottom channel. Drawing circles around the ports using a hydrophobic pen or placing a hydrophobic tape with a hole around the port prevents any passively pumped media from spreading. If bubbles are withdrawn during sampling or the full 50 µL sample is not removed, the sample must not be used. Alternatively, the exact volume can be determined and used in the permeability calculation; however, this should only be done if the volume removed is ≥40 µL, which corresponds to ~98-99% dye recovery34.

Disclosures

The authors have nothing to disclose.

Acknowledgements

J.L.M., B.E., T.R.G., M.C.M., P.K., M.T., K.C., and L.W. were funded by NIH grant R33 HL154249. J.L.M. was funded by R44 GM137651. M.M. was funded by the Schmidt Program Award Del Monte Institute for Neuroscience, University of Rochester. M.T. was funded by RF1 AG079138. K.C. was funded by International Foundation for Ethical Research.

Materials

Antibodies
CD31 Polyclonal antibody Thermo Fisher Scientific PA5-32321
Claudin-5 mouse IgG antibody, 4C3C2 Thermo Fisher Scientific 35-2500
Goat α-Mouse IgG Alexa Fluor 488 Thermo Fisher Scientific A11001
Goat α-Rabbit IgG Alexa Fluor 568 Thermo Fisher Scientific A11011
Hoechst 33342 Life Technologies H3570
NG2, mouse IgG2a, 9.2.27 Millipore  MAB2029
Occludin mouse IgG antibody, OC-3F10 Thermo Fisher Scientific 33-1500
PDGFRβ, rabbit IgG antibody, 28E1 Cell Signaling Technology 3169
VE-cadherin mouse IgG2B Clone # 123413 R&D Systems MAB9381
ZO-1 rabbit IgG antibody, polyclonal Thermo Fisher Scientific 40-2200
Chemicals, peptides, and recombinant proteins
100% Methanol VWR 101443-718 Can be substituted with similar products
16% Paraformaldehyde Thermo Fisher Scientific 28908 Can be substituted with similar products
Accutase Thermo Fisher Scientific A1110501
Acetic acid Sigma-Aldrich 695092
B27 supplement Thermo Fischer Scientific 17504044
bFGF R&D Systems 233-FB-025
Collagen IV from human placenta Sigma-Aldrich C5533
Collagen, Type I solution from rat tail Sigma-Aldrich C3867-1VL Can be substituted with similar products
DMEM/Ham’s F12 Thermo Fisher Scientific 11320033
EGM-2 Endothelial Cell Growth Medium-2 BulletKit Lonza CC-3162
Essential 6 medium Thermo Fisher Scientific A1516401
Fetal bovine serum (FBS) Peak Serum PS-FB1
Fibronectin from bovine plasma Sigma-Aldrich F1141
Fibronectin human protein, plasma ThermoFisher Scientific 33016015 Can be substituted with similar products
hESFM Thermo Fisher Scientific 11111044
Lucifer Yellow CH dilithium salt Sigma-Aldrich 861502
Normal goat serum Thermo Fisher Scientific 500627 Can be substituted with similar products
PBS without calcium, magnesium Cytiva SH30256.01 Can be substituted with similar products
Pericyte Medium ScienCell 1201 Use complete kit (includes supplements)
Poly-L-Lysine, 10 mg/mL ScienCell 0413
Triton X-100 JT Baker X198-05 Can be substituted with similar products
UltraPure DNase/RNase-Free Distilled Water Invitrogen™ 10977015 Can be substituted with similar products
Experimental models: Cell lines
Blood-brain barrier hCMEC/D3 cell line Sigma-Aldrich SCC066
Human brain vascular pericytes ScienCell 1200
iPS(IMR90)-4 human induced pluripotent stem cells WiCell RRID:CVCL_C437
Glassware and Plasticware
150 mm TC-treated Cell Culture Dish with 20 mm Grid Falcon 353025
Clamps VWR MFLX06832-10
Corning tissue culture plates (6-well) Corning 3506
Flat 96-well non-binding microplates Greiner Bio-One 655900
Microscope Slide Device Holder  SiMPore USIM-SB Dimensions compatible with micropscope slide holders
Nunc 15 mL Conical Sterile Polypropylene Centrifuge Tubes Thermo Fischer Scientific 339651
Nunc 50 mL Conical Sterile Polypropylene Centrifuge Tubes Thermo Fischer Scientific 339653 Tube caps can be filled with water for cell culture
P20-200 pipette tips VWR 76322-516 Alternate brands may not seal as effectively into ports
Transwell filters (12 well, 12 mm, 0.4 μm pore size, PC) CoStar 3401
Instruments
10X Objective (For Andor) Nikon Instruments Inc. MRD00105 Air; WD: 4 mm; NA 0.45
10X Objective (For Nikon) Nikon Instruments Inc. MRP40102 Air; WD: 6.2 mm; NA 0.25
40X Objective (LWD) (For Andor) Nikon Instruments Inc. MRD77410 Water immersion; WD: 590-610 mm; NA 1.15
Andor Spinning Disc Confocal microscope Oxford Instruments, Andor
Nikon Eclipse Ts2 Phase Contrast Microscope Nikon Instruments Inc. Can be substituted with similar products
TECAN Infinite M200 TECAN Can be substituted with similar products
Other
Advanced PAP Pen Millipore Sigma Z672548 2 mm tip is recommended
Assembly kit with fixtures SiMPore USIM-JIGSET Including fixure A1, A2, B1, and B2
Camera Adapter for Microscopes AmScope CA-CAN-SLR Canon SLR / D-SLR Φ23.2 – Φ30 adapter fits Nikon Eclipse Ts2
Canon EOS Rebel SL3 DSLR Camera Canon EOS 250D, BH #CAEDRSL3B, MFR #3453C001 Can be substituted with similar products
Cell strainer, 40 µm Millipore Sigma (Corning) CLS431750
Component 1 SiMPore USIM-C1
Component 2 SiMPore USIM-C2
Membrane chips SiMPore NPSN100-1L Other chips formats are available
SMD handling tweezer double angle Techni-Tool 758TW003 "Chip Tweezers"
Stainless steel precision type GG tweezer Techni-Tool 758TW534 "Straight Tweezers"
Software
Fiji ImageJ For image processing
Fusion Oxford Instruments, Andor Instructions for version 2.3.0.44
i-control TECAN Instructions for version 2.0
Imaris Oxford Instruments For image processing. Instructions for version 9.9.0
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References

  1. Villabona-Rueda, A., Erice, C., Pardo, C. A., Stins, M. F. The evolving concept of the blood brain barrier (BBB): from a single static barrier to a heterogeneous and dynamic relay center. Frontiers in Cellular Neuroscience. 13, 405 (2019).
  2. Nation, D. A., et al. Blood-brain barrier breakdown is an early biomarker of human cognitive dysfunction. Nature Medicine. 25 (2), 270-276 (2019).
  3. Ferrari, C. C., Tarelli, R. Parkinson’s disease and systemic inflammation. Parkinsons Disease. 116 (3), 436813 (2011).
  4. Koch, E. V., Ledwig, V., Bendas, S., Reichl, S., Dietzel, A. Tissue barrier-on-chip: a technology for reproducible practice in drug testing. Pharmaceutics. 14 (7), 1451 (2022).
  5. Nishihara, H., et al. Intrinsic blood-brain barrier dysfunction contributes to multiple sclerosis pathogenesis. Brain. 145 (12), 4334-4348 (2022).
  6. Ortiz, G. G., et al. Role of the blood-brain barrier in multiple sclerosis. Archives of Medical Research. 45 (8), 687-697 (2014).
  7. Orhun, G., et al. Association between inflammatory markers and cognitive outcome in patients with acute brain dysfunction due to sepsis. Archives of Neuropsychiatry. 56 (1), 63-70 (2019).
  8. Chen, Y., Yang, W., Chen, F., Cui, L. COVID-19 and cognitive impairment: neuroinvasive and blood-brain barrier dysfunction. Journal of Neuroinflammation. 19 (1), 222 (2022).
  9. Hughes, C. G., et al. Endothelial activation and blood-brain barrier injury as risk factors for delirium in critically ill patients. Critical Care Medicine. 44 (9), e809-e817 (2016).
  10. Saraiva, C., et al. Nanoparticle-mediated brain drug delivery: Overcoming blood-brain barrier to treat neurodegenerative diseases. Journal of Control Release. 235 (10), 34-47 (2016).
  11. Jolliet-Riant, P., Tillement, J. P. Drug transfer across the blood-brain barrier and improvement of brain delivery. Fundamental & Clinical Pharmacology. 13 (1), 16-26 (1999).
  12. Abbott, N. J., et al. Structure and function of the blood-brain barrier. Neurobiology of Disease. 37 (1), 13-25 (2009).
  13. Siflinger-Birnboim, A., et al. Molecular sieving characteristics of the cultured endothelial monolayer. Journal of Cellular Physiology. 132 (1), 111-117 (1987).
  14. Bischoff, I., et al. Pitfalls in assessing microvascular endothelial barrier function: impedance-based devices versus the classic macromolecular tracer assay. Scientific Reports. 6, 23671 (2016).
  15. van der Helm, M. W., van der Meer, A. D., Eijkel, J. C., van den Berg, A., Segerink, L. I. Microfluidic organ-on-chip technology for blood-brain barrier research. Tissue Barriers. 4 (1), e1142493 (2016).
  16. Osaki, T., Shin, Y., Sivathanu, V., Campisi, M., Kamm, R. D. In vitro microfluidic models for neurodegenerative disorders. Advanced Healthcare Materials. 7 (2), (2018).
  17. Girard, S. D., et al. High and low permeability of human pluripotent stem cell-derived blood-brain barrier models depend on epithelial or endothelial features. FASEB Journal. 37 (2), e22770 (2023).
  18. Vigh, J. P., et al. Transendothelial electrical resistance measurement across the blood-brain barrier: a critical review of methods. Micromachines. 12 (6), 685 (2021).
  19. Lea, T., et al., Verhoeckx, K., et al. Caco-2 cell line. The Impact of Food Bioactives on Health: in vitro and ex vivo models. , (2015).
  20. Felix, K., Tobias, S., Jan, H., Nicolas, S., Michael, M. Measurements of transepithelial electrical resistance (TEER) are affected by junctional length in immature epithelial monolayers. Histochemistry and Cell Biology. 156 (6), 609-616 (2021).
  21. Srinivasan, B., et al. TEER measurement techniques for in vitro barrier model systems. Journal of Laboratory Automation. 20 (2), 107-126 (2015).
  22. Mossu, A., et al. A silicon nanomembrane platform for the visualization of immune cell trafficking across the human blood-brain barrier under flow. Journal of Cerebral Blood Flow and Metabolism. 39 (3), 395-410 (2019).
  23. Castro Dias, M., et al. Brain endothelial tricellular junctions as novel sites for T-cell diapedesis across the blood-brain barrier. Journal of Cell Science. 134 (8), jcs253880 (2021).
  24. Hudecz, D., et al. Ultrathin silicon membranes for in situ optical analysis of nanoparticle translocation across a human blood-brain barrier model. ACS Nano. 14 (1), 1111-1122 (2020).
  25. Khire, T. S., et al. Microvascular mimetics for the study of lukocyte-endothelial interactions. Cellular and Molecular Bioengineering. 13 (2), 125-139 (2020).
  26. Salminen, A. T., et al. Endothelial cell apicobasal polarity coordinates distinct responses to luminally versus abluminally delivered TNF-alpha in a microvascular mimetic. Integrative Biology: Quantitative Biosciences from Nano to Macro. 12 (11), 275-289 (2020).
  27. DesOrmeaux, J. P. S., et al. Nanoporous silicon nitride membranes fabricated from porous nanocrystalline silicon templates. Nanoscale. 6 (18), 10798-10805 (2014).
  28. Hill, K., et al. Second generation nanoporous silicon nitride membranes for high toxin clearance and small format hemodialysis. Advanced Healthcare Materials. 9 (4), e1900750 (2020).
  29. Salminen, A. T., et al. Ultrathin dual-scale nano- and microporous membranes for vascular transmigration models. Small. 15 (6), e1804111 (2019).
  30. Gillmer, S. R., et al. Predicting the failure of ultrathin porous membranes in bulge tests. Thin Solid Films. 631, 152-160 (2017).
  31. Ishimatsu, R., et al. Ion-selective permeability of ultrathin nanopore silicon membrane as studied using nanofabricated micropipet probes. Analytical Chemistry. 82 (17), 7127-7134 (2010).
  32. Kim, E., et al. A structure-permeability relationship of ultrathin nanoporous silicon membrane: a comparison with the nuclear envelope. Journal of American Chemical Society. 130 (13), 4230-4231 (2008).
  33. Snyder, J. L., et al. An experimental and theoretical analysis of molecular separations by diffusion through ultrathin nanoporous membranes. Journal of Membrane Science. 369 (1-2), 119-129 (2011).
  34. McCloskey, M. C., et al. The modular µSiM: a mass produced, rapidly assembled, and reconfigurable platform for the study of barrier tissue models in vitro. Advanced Healthcare Materials. 11 (18), e2200804 (2022).
  35. Mansouri, M., et al. The modular microSiM reconfigured: integration of microfluidic capabilities to study in vitro barrier tissue models under flow. Advanced Healthcare Materials. 11 (21), e2200802 (2022).
  36. Su, S. -. H., et al. A tissue chip with integrated digital immunosensors: In situ brain endothelial barrier cytokine secretion monitoring. Biosensors and Bioelectronics. 224, 115030 (2023).
  37. Nishihara, H., et al. Differentiation of human pluripotent stem cells to brain microvascular endothelial cell-like cells suitable to study immune cell interactions. STAR Protocols. 2 (2), 100563 (2021).
  38. Hudecz, D., et al. Ultrathin silicon membranes for in situ optical analysis of nanoparticle translocation across a human blood-brain barrier model. ACS Nano. 14 (1), 1111-1122 (2020).
  39. Gastfriend, B. D., Stebbins, M. J., Du, F., Shusta, E. V., Palecek, S. P. Differentiation of brain pericyte-like cells from human pluripotent stem cell-derived neural crest. Current Protocols. 1 (1), e21 (2021).
  40. Nishihara, H., et al. Advancing human induced pluripotent stem cell-derived blood-brain barrier models for studying immune cell interactions. FASEB Journal. 34 (12), 16693-16715 (2020).
  41. Engelhardt, B., Vajkoczy, P., Weller, R. O. The movers and shapers in immune privilege of the CNS. Nature Immunology. 18 (2), 123-131 (2017).
  42. Bechmann, I., Galea, I., Perry, V. H. What is the blood-brain barrier (not). Trends in Immunology. 28 (1), 5-11 (2007).

Tags

Blood-brain BarrierMicroSiMμSiMInduced Pluripotent Stem CellsSepsisInflammationBlood-borne FactorsGenetic FactorsReproducibilityFunctional AssaysHigh-resolution Live ImagingPermeability AssaysExtracellular MatrixAstrocytesMicrogliaPostoperative DeliriumDementia

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McCloskey, M. C., Kasap, P., Trempel, M., Widom, L. P., Kuebel, J., Chen, K., Gaborski, T. R., Engelhardt, B., McGrath, J. L. Use of the MicroSiM (µSiM) Barrier Tissue Platform for Modeling the Blood-Brain Barrier. J. Vis. Exp. (203), e65258, doi:10.3791/65258 (2024).
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