Human Pseudoislet System for Synchronous Assessment of Fluorescent Biosensor Dynamics and Hormone Secretory Profiles

Summary

This protocol describes a method for the synchronous acquisition and co-registration of intracellular signaling events and the secretion of insulin and glucagon by primary human pseudoislets using the adenoviral delivery of a cyclic adenosine monophosphate (cAMP) biosensor, a cAMP difference detector in situ (cADDis), and a microperifusion system.

Abstract

The pancreatic islets of Langerhans, which are small 3D collections of specialized endocrine and supporting cells interspersed throughout the pancreas, have a central role in the control of glucose homeostasis through the secretion of insulin by beta cells, which lowers blood glucose, and glucagon by alpha cells, which raises blood glucose. Intracellular signaling pathways, including those mediated by cAMP, are key for regulated alpha and beta cell hormone secretion. The 3D islet structure, while essential for coordinated islet function, presents experimental challenges for mechanistic studies of the intracellular signaling pathways in primary human islet cells. To overcome these challenges and limitations, this protocol describes an integrated live-cell imaging and microfluidic platform using primary human pseudoislets generated from donors without diabetes that resemble native islets in their morphology, composition, and function. These pseudoislets are size-controlled through the dispersion and reaggregation process of primary human islet cells. In the dispersed state, islet cell gene expression can be manipulated; for example, biosensors such as the genetically encoded cAMP biosensor, cADDis, can be introduced. Once formed, pseudoislets expressing a genetically encoded biosensor, in combination with confocal microscopy and a microperifusion platform, allow for the synchronous assessment of fluorescent biosensor dynamics and alpha and beta cell hormone secretory profiles to provide more insight into cellular processes and function.

Introduction

The islets of Langerhans are mini organs scattered throughout the pancreas whose function is crucial for the maintenance of glucose homeostasis. Insulin is secreted from beta cells following the metabolism of glucose, an increase in the ATP/ADP ratio, the closure of ATP-sensitive potassium channels, depolarization of the plasma membrane, and the influx of extracellular calcium¹. Glucagon secretion from alpha cells is less understood, but it has been postulated that intracellular and paracrine pathways contribute to glucagon granule exocytosis^2,3,4. Both type 1 and type 2 diabetes are associated with islet cell dysfunction^5,6,7. Therefore, elucidating the intracellular signaling pathways mediating islet hormone secretion is essential for understanding physiologic and pathologic mechanisms in pancreatic islets.

The spherical architecture of islets presents certain obstacles to experimentation. These challenges include islet size variation and the 3D nature of islets, which reduces viral transduction within the islet core^8,9. To overcome these challenges, a pseudoislet system was developed, in which primary human islets are dispersed into single cells, adenovirally transduced with constructs encoding targets of interest, and reaggregated to form size-controlled, islet-like structures termed pseudoislets⁷. Compared to native islets from the same donor that have been cultured in parallel, these pseudoislets are similar in morphology, endocrine cell composition, and hormone secretion⁷. This method allows for the expression of constructs throughout the pseudoislet, meaning it overcomes a previous barrier to the uniform genetic manipulation of primary human islets^7,8,9.

In this protocol, the pseudoislet system is integrated with a microfluidic device to express biosensors in primary human islet cells and gain temporal resolution of pseudoislet hormone secretion during dynamic perifusion^10,11,12. The pseudoislets are placed in a microchip and exposed to a steady flow of different secretagogues via a peristaltic pump¹². The microchip has a transparent glass bottom and is mounted on a confocal microscope to record the intracellular signaling dynamics via changes in the biosensor fluorescence intensity. Biosensor imaging is synchronized with the collection of microperifusion effluent for the subsequent analysis of insulin and glucagon secretion⁷. Compared to macroperifusion, this microperifusion approach allows for fewer pseudoislets to be used due to the smaller volume of the microfluidic device compared to the macroperifusion chamber⁷.

To harness the utility of this system, the cyclic adenosine monophosphate (cAMP) difference detector in situ (cADDis) biosensor was expressed in human pseudoislets to assess cAMP dynamics and hormone secretion. The cADDis biosensor is composed of a circularly permuted green fluorescent protein (cpGFP) positioned in the hinge region of an exchange protein activated by cAMP 2 (EPAC2), connecting its regulatory and catalytic regions. The binding of cAMP to the regulatory region of EPAC2 elicits a conformational change in the hinge region that increases fluorescence from the cpGFP¹³. Intracellular messengers such as cAMP elicit insulin and glucagon secretion after the upstream activation of G-protein coupled receptors¹⁴. Live-cell imaging coupled with microperifusion helps to connect the intracellular cAMP dynamics with islet hormone secretion. Specifically, in this protocol, cADDis-expressing pseudoislets are generated to monitor cAMP responses in alpha and beta cells to various stimuli: low glucose (2 mM glucose; G 2), high glucose plus isobutylmethylxanthine (IBMX; 20 mM glucose + 100 µM IBMX; G 20 + IBMX), and low glucose plus epinephrine (Epi; 2 mM glucose + 1 µM Epi; G 2 + Epi). This treatment workflow allows for the assessment of the intracellular cAMP dynamics directly via 1) IBMX-mediated phosphodiesterase inhibition, which enhances intracellular cAMP levels by preventing its degradation, and 2) epinephrine, a known cAMP-dependent stimulator of alpha cell glucagon secretion mediated by β-adrenergic receptor activation. The steps for setting up the microperifusion apparatus for live-cell imaging experiments, the loading of the pseudoislets into the microchip, synchronous live-cell imaging and microperifusion, and the analysis of the biosensor traces and hormone secretion by microplate-based hormone assays are detailed below.

Protocol

Human islets (N = 4 preparations) were obtained through partnerships with the Integrated Islet Distribution Program, Human Pancreas Analysis Program, Prodo Laboratories, Inc., and Imagine Pharma. The Vanderbilt University Institutional Review Board does not consider deidentified human pancreatic specimens as human subjects research. This work would not be possible without organ donors, their families, and organ procurement organizations. See Table 1 for donor demographic information. Human islets from pancreas donors without diabetes were isolated with less than 15 h of cold ischemia time.

1. Pseudoislet formation (detailed in Walker et al.⁷)

1. Obtain and hand-pick primary human islets using a P200 pipette and benchtop microscope, paying close attention not to contaminate the pipette tip on any surfaces outside of the islet culture medium (10% FBS, 100 µg/mL streptomycin, 100 U/mL penicillin, 2 mM L-glutamine in CMRL 1066).
2. Transfer primary islets into a 15 mL tube, and perform all of the following pseudoislet formation steps under a tissue culture hood to prevent contamination. Slowly dissociate the primary islets for 7 min at room temperature with a P1000 pipette in 0.025% trypsin. The solution will become opaque as the islets begin to break apart.
   1. For these studies, 200-300 hand-picked primary islets with diameters of approximately 200 µm dispersed in 500 µL of 0.025% trypsin yields one to two 96-well plates of pseudoislets; the exact number may vary depending on the average islet size and viability. For >500 primary islets, scale up the volume of 0.025% trypsin used in a 1:1 ratio (e.g., 600 µL of 0.025% trypsin for 600 hand-picked islets).
3. Quench the dispersion by adding a volume of Vanderbilt Pseudoislet Media (VPM) equivalent to the volume of trypsin used. Then, wash two times with 1 mL of VPM. For the washes, centrifuge the dispersed cells at 485 x g for 2-3 min at 4 °C in a benchtop centrifuge. Resuspend the cells in a defined volume of VPM (typically 1 mL) for counting.
   ​NOTE: The pseudoislet generation and VPM composition are detailed in a prior publication⁷. Briefly, VPM contains equal volumes of enriched-CMRL media (20% FBS, 100 µg/mL streptomycin, 100 U/mL penicillin, 1 mM sodium pyruvate, 2 mM Glutamax, 2 mM HEPES in CMRL 1066) and iEC-media (VEGF Medium Complete Kit minus FBS + 1 bottle of Endothelial Cells Medium Supplement). A summary schematic of pseudoislet generation is included in Figure 1A.
4. Determine the cell count and viability using an automated cell counter by combining 10 µL of Trypan Blue with 10 µL of the cell suspension. Mix the cell suspension well to ensure an accurate cell count.
5. Calculate the volume of cell suspension, virus, and VPM required for the desired number of pseudoislets. Base all the calculations on the live cell count obtained in step 1.4.
   1. For these studies, transduce dispersed human islet cells at MOI 500 (N = 1) or 1,000 (N = 2) with Ad-CMV-cADDis in a total volume of 500 µL. One plate of transduced pseudoislets (2,000 cells/pseudoislet) yields three technical replicates per donor (32 pseudoislets/experiment). The adenovirus was commercially obtained in this work.
6. Combine the calculated amounts of cell suspension, virus, and VPM into a 1.5 mL tube. Gently mix the contents by pipetting up and down.
7. During transduction, incubate the tubes with open caps, and cover them with a sterile Petri dish for 2 h in a tissue culture incubator at 37 °C and 5% CO₂/95% air.
8. Add 500 µL of VPM to each tube, and wash the cells by centrifuging them at 500 x g for 3 min at 4 °C. Complete two more washes for a total of three washes. Aspirate off supernatant, and resuspend the cells in 1 mL of VPM.
9. Calculate the total cell seeding volume (200 µL/pseudoislet). Add the VPM (the calculated cell seeding volume minus 2 mL) to an appropriately sized conical tube. Add the transduced cell suspension from step 1.7 to the conical tube. Keep the conical tube slightly closed but not tightly closed to allow air exchange for the cells.
10. Rinse the 1.5 mL tube (from step 1.7) with 1 mL of VPM, and transfer the contents to the conical tube, at which point the conical tube should contain the total cell seeding volume.
11. Mix the contents of the conical tube well by pipetting up and down with a motorized serological pipette, and then transfer the contents to a sterile reagent reservoir. If the reservoir does not hold the entire cell seeding volume, perform serial transfers, and ensure that suspension is well mixed at each step.
12. Using a multichannel P200 pipette, pipet the cell suspension in the reagent reservoir up and down 3-4 times to ensure homogeneity, and then pipet 200 µL of the cell suspension into each well of the microwell plates.
13. Incubate the pseudoislets in a tissue culture incubator at 37 °C and 5% CO₂/95% air for 6 days without medium changes. By day 6, the pseudoislets should be fully formed and ready for experiments (Figure 1B-D).

2. Preparation for live-cell imaging and microperifusion (1 day prior to the experiment)

NOTE: Information on the microperifusion medium preparation is available through the protocols.io resource (https://www.protocols.io/view/analysis-of-islet-function-in-dynamic-cell-perifus-bt9knr4w.html).

1. Harvest the pseudoislets using a multichannel pipette by transferring them from the 96-well plate into a sterile Petri dish. Then, hand-pick the pseudoislets, and transfer them into another sterile Petri dish containing fresh VPM. Allow the pseudoislets to incubate in a tissue culture incubator at 37 °C and 5% CO₂/95% air overnight.
2. Prepare 1 L of DMEM by adding 1 g of BSA (radioimmunoassay-grade), 0.11 g of sodium pyruvate, 0.58 g of L-glutamine, 3.2 g of sodium bicarbonate, 1.11 g of HEPES, and 1 bottle of DMEM to 1 L of ultra-purified water. Prepare a 1 M glucose stock solution in DMEM. Keep both solutions at 4 °C overnight.
3. Check the flow of the microperifusion system the day prior to the experiment. Connect all the tubing to a chip holder containing an empty microchip, as outlined in Figure 2A-B. Utilize ultra-purified water as the effluent to confirm a flow rate of 100 µL/min at the fraction collector.

3. Addition of secretagogues to the DMEM (day of the experiment)

1. Add 0.07 mg/mL ascorbate to the DMEM, and prepare the secretagogues in DMEM + ascorbate buffer using a 1 M glucose stock for the glucose-containing buffers.
   NOTE: Ascorbate is used to stabilize epinephrine by preventing its oxidation. If epinephrine is not being used, ascorbate can be omitted from the DMEM.
2. Filter the secretagogues twice through a 0.22 µm pore filter, using a fresh filter each time. Warm the solutions to 37 °C, and measure the glucose via a glucometer to confirm the desired concentration.

4. Microperifusion apparatus setup

1. Warm the environmental chamber of a confocal laser scanning microscope to 37 °C, ensuring all the doors are closed and the chamber maintains a stable temperature. Place the chip holder containing the microchip in the chamber to warm up. Verify the chip temperature with an infrared gun.
   NOTE: In this case, the environmental chamber is set to 38.5 °C, which allows for the chip to reach 37 °C.
2. Connect all the tubing to the chip holder (as outlined in Figure 2A-B). Flush-line with baseline secretagogue for 5 min. In this study, the line was flushed with 2 mM glucose (G 2). Change the bubble trap membrane of the de-bubbler every 8-10 experiments.

5. Loading of the pseudoislets into the microchip

1. Prior to loading the microchip, take a brightfield and darkfield image (10x magnification) of the pseudoislets that will be used in the experiment for the subsequent quantification of islet equivalents (IEQ).
   NOTE: The IEQ is used to normalize the hormone secretion to variations in the islet number across the experiments. This step can also be done the day prior to the experiment.
2. Aspirate any extra fluid from the bottom and top halves of the microchip. The top half of the microchip contains gaskets that ensure an adequate seal of each well, while the bottom half of the microchip contains the wells with a glass coverslip attached. Pre-wet one well in the microchip with 5 µL of DMEM. Make sure to pipet around the outer edges of the well to wet the crevices.
3. Use a pre-wetted pipette to collect 30-32 pseudoislets in a 23 µL volume, and slowly dispense the pseudoislets into the center of the well in the bottom piece of the microchip. Check the tip of the pipette for any pseudoislets that may have been attached.
4. Use a gel loading tip to gently maneuver the pseudoislets into the center of the well. This ensures that the maximum number of pseudoislets will be captured in a field of view.
5. Take an image of the pseudoislets in the microchip on the stereoscope. This count will be used to adjust the calculated IEQ for any pseudoislet loss during this process.
   1. If all the pseudoislets from step 5.3 are not loaded into the microchip, adjust the IEQ accordingly. For example, if 30 pseudoislets are visualized now but 32 were visualized in step 5.1, calculate the IEQ on the images from step 5.1 and then multiply by 30/32.
6. Place the bottom of the microchip into the microchip holder. Carefully place the top of the microchip on with the green gasket side down.
7. While holding the microchip in place, gently close the microchip holder to clamp the microchip together. Try not to apply excessive pressure onto the microchip during this process, as doing so will displace the fluid contained in the well and may lead to pseudoislet loss. Avoid introducing air bubbles into the well.

6. Synchronous live-cell imaging and microperifusion

1. Transfer the secretagogues, pump, and microchip in the holder into the environmental chamber fitted to the confocal microscope. Direct the efflux tubing out of the chamber to the fraction collector.
   1. Place the buffers into 15 mL conical tubes with openings drilled into their caps. These holes prevent the collection tubing from drifting out of the tube.
   2. When screwing the tubing into the de-bubbler, separate the nut and ferrule, and then screw into the de-bubbler. This prevents the twisting of the line.
2. Set the fraction collector to rotate every 2 min. Load the appropriate number of tubes into the fraction collector, accounting for the washes and experimental fractions. For these experiments, 15 wash tubes (30 min total washing) and 28 tubes for fraction collection were utilized.
3. Start the pump to deliver the baseline medium (containing the baseline glucose concentration) at 100 µL/min (a 2 min collection at a 100 µL/min flow rate results in 200 µL of effluent per each fraction tube). This flow rate was chosen to limit the sheer stress on the pseudoislets and prevent significant pseudoislet movement during the live imaging.
   1. While the fluid is running through the apparatus, watch for the following:
      1. Watch for droplets at the end of the fraction collector spout, which indicate flow through the system.
      2. Watch for decreases in the efflux from the system; if there is <200 µL in the collection tubes, this indicates that there might be a blockage or leak in the system. See Table 2 for a list of the potential causes of decreased effluent volume, solutions, and prevention tips.
4. Once there is a steady medium flow from the efflux tubing, rotate the fraction collector head to dispense into the tubes, and start the fraction collector. Collect the first 15 fractions (30 min) as wash to allow the pseudoislets to equilibrate. Use these first 15 fractions to ensure continual and accurate medium flow through the system. Discard these fractions afterward.
5. During the 30 min wash, set up the microscope for live-cell imaging according to these parameters: objective lens: U Plan Fluorite 20x with 1x zoom; fluorescence channels: EGFP (emission = 510 nm, laser wavelength = 488, detection wavelength = 500-600 nm); time series: image acquired every 2 s for the entirety of the experiment (i.e., 56 min); sampling speed: 2 µs/pixel.
   1. Identify the bottom of the pseudoislets in the field of view and adjust the focal plane to 15 µm above this position. This is the frame that will be used throughout the imaging experiment.
6. Once the 30 min wash is complete, begin fraction collection and image acquisition.
   NOTE: All efforts should be made to identify and correct any issues before this step. Once data collection begins, any pauses in the experiment or excess exposure to secretagogues may adversely affect the results.
7. Continue perifusing the pseudoislets with baseline medium for the duration of the first baseline collection, collecting the effluent into 1.5 mL tubes. Switch the tubing from the baseline buffer by hand to the new stimulus buffer tube when the time is appropriate for the experiment.
   1. A standard microperifusion sequence is shown in Table 3.
   2. After collecting ~10 fractions, place all the fractions into a 4 °C refrigerator until the end of the experiment to prevent the degradation of the hormones, especially glucagon.
   3. Continue to monitor the system flow throughout the experiment by checking the effluent volume in each tube.
8. When the experiment is complete, switch back to the baseline medium, and allow the pump to continue running for 5 min to wash out the stimulus with baseline medium (in this case, 2 mM glucose).
9. Stop the pump, and disconnect the microchip holder tubing at the de-bubbler and fraction collector to remove the microchip holder from the environmental chamber. Close all the doors after removing the microchip to maintain the temperature.
10. Store the perifusates at −80 °C for subsequent hormone analysis.

7. Pseudoislet acid ethanol extraction

1. Carefully open the microchip holder and lift off the top of the microchip. Use a pipette and benchtop microscope to pick pseudoislets out of the well and transfer them to a 1.5 mL tube. Ensure the collection of all the pseudoislets using a benchtop microscope if needed.
   1. Take a final image of the pseudoislets in the microchip prior to removal from the well to adjust the islet extract IEQ, similar to in step 5.5.
2. Wash two times with 500 µL of PBS. Spin down the pseudoislets for 1 min at 94 x g between each wash, and aspirate off the supernatant.
3. After removing the last wash, add 200 µL of acid ethanol (5.5 mL of 95% ethanol + 50 µL of 12 N HCl). Store at 4 °C overnight.
4. On the next day, spin down the extracts for 10 min at 15,989 x g, and 4 °C. Aliquot 45 µL into three new tubes. Store at −80 °C for hormone content analysis. As an alternative to normalizing the hormone secretion to the IEQ, the hormone secretion may also be normalized to the pseudoislet hormone content measured from the extracts.

8. Additional experiments and clean-up

1. Repeat steps 5-7 with subsequent groups of pseudoislets to obtain additional technical replicates.
2. After finishing all the microperifusion experiments, run 10% bleach through the microchip and tubing for 5 min and then ultra-purified water for 30 min to sanitize the tubing.

9. Data analysis

NOTE: Live-cell imaging was performed using a laser-scanning confocal microscope. The images were analyzed using the microscope-associated imaging software package. The following are general guidelines but may differ depending on the microscope manufacturer and image acquisition software.

1. Determining the total islet equivalents (IEQ) for data normalization
   1. Open the software program, and click on the Acquisition tab at the top right of the window. Batch-burn in all the dark field images by selecting the Batch burn in function in the Macro Manager (View > Tool Windows > Macro Manager).
      1. To burn multiple images at once, click on the Toggle Batch Mode button prior to clicking on the Run button within the Macro Manager. Follow the on-screen instructions for selecting the source image location and destination location for the burned images. For the image file type, choose Tagged Imagine File Format (*.tif).
   2. For the IEQ measurement, open the burned version of the 10x darkfield image taken in step 5.1. Click on the Count and Measure tab at the top, and choose the Manual HSV Threshold button on the left.
      1. Use the dropper function to add/remove the positive area (in red) until each pseudoislet is highlighted in red, without extending past the pseudoislet border. Click on Count and Measure.
   3. Use the auto-split or manual-split functions to split the pseudoislets that were joined together.
      1. To manually split the pseudoislets, choose the manual-split function, left-click to draw a line separating the pseudoislets, and then right-click to complete the line. To auto-split, choose the auto-split function, and click on the grouped pseudoislets of interest. Confirm the correct auto-split afterward.
   4. In batch-burned images, the scale bar and magnification text may be marked as positive. Delete these objects for an accurate count by highlighting the text and scale bar using the mouse and pressing the Delete keyboard key.
   5. Toggle the filter on and off to confirm that all the pseudoislets are being counted. The file can also be opened outside of the program for cross-referencing. When finished, click on Export to Excel.
   6. Open the spreadsheet, and modify it as follows.
      1. Delete the count, mean, and sort information at the bottom. Sort the objects based on their mean diameter. Insert a column after the mean diameter, and name the column "Pseudoislet count".
      2. The islet count is determined by the number of pseudoislets with mean diameters that fall within each index below. Multiply the number of pseudoislets per index by the respective IEQ conversion factor, and sum these values to determine the total IEQ. Perform the IEQ calculations on the images acquired before each experiment. Use the following indexes and IEQ conversion factors:
         1-49 µm: × 0.167
         50-100 µm: × 0.667
         101-150 µm: × 1.685
         151-200 µm: × 3.500
         201-300 µm: × 6.315
         301-350 ​µm: × 10.352
      3. For an example spreadsheet for determining the IEQ counts, see Supplementary File 1.
2. Live-cell imaging quantification in software
   1. Open the desired file (.oir) in cellSens.
   2. Designate the regions of interest (ROIs) as follows.
      1. Use the drawing tools to designate the ROIs (i.e., each pseudoislet). If using the freehand drawing option, right-click to close the shape.
      2. Highlight all the ROIs by using the arrow hand and dragging it to encompass all the ROIs in the image. With all the ROIs highlighted, right-click, and select Convert to Dynamic ROI Over Time
      3. Play the XYT file to confirm that the ROIs are accurate over time. If the ROI is not accurate at a specific period, correct its size/location at that period. The software will gradually adjust the ROI's size/location over time to match these changes. Repeat these steps until the ROI is accurate throughout the imaging experiment.
   3. Perform intensity measurements on each ROI as follows.
      1. In the toolbar, click on Measure Intensity Profile. Highlight the ROIs to analyze; use shift + click to select multiple ROIs.
         NOTE: While multiple files may be open at a time in the software, only analyze the ROIs from one file at a time.
      2. To account for background noise, select a constant value to subtract from each intensity value, or designate one ROI as background. Click on Execute.
      3. Within the Intensity Profile toolbar, click on Export to Excel to export the data.
      4. Normalize all the data points to the average of the intensities measured from 7-8 min (i.e., the last min of the first baseline medium perifusion). These normalized values at each time point are defined as the relative cADDis intensity. For an example spreadsheet of imaging data analysis and normalization, see Supplementary File 2.
3. Measure the hormone secretion in each fraction and islet extract. In these experiments, insulin and glucagon concentrations were measured by ELISA. Normalize the hormone secretion in each fraction to the pseudoislet volume using the IEQ measurements determined in step 9.1 or by the extract hormone content.

Results

Biosensor-expressing human pseudoislets were created via the adenoviral delivery of constructs encoding the cAMP biosensor cADDis (Figure 1A). Figure 1B shows the reaggregation of the transduced human islet cells over time, with fully formed pseudoislets observed after 6 days of culture. The cells began to show visible cADDis fluorescence within 48 h, and there was high biosensor expression in transduced cells by the end of the culture period. Using thi...

Discussion

The integration of a microperifusion system, biosensor-expressing pseudoislets, and laser-scanning confocal microscopy allows for the synchronous assessment of intracellular signaling events and dynamic hormone secretory profiles. The dynamic microperifusion system can deliver a series of well-defined stimuli to the pseudoislets and allows for the collection of the effluent, in which the insulin and glucagon concentrations can be measured by commercially available ELISA. Concurrently, live-cell imaging of the biosensor-e...

Materials

Name	Company	Catalog Number	Comments
Ad-CMV-cADDis	Welgen	Not applicable
0.01” FEP tubing	IDEX	1527L
1 M HEPES	Gibco	15630-080	Enriched-CMRL Media Component
1.5 mL and conical tubes	Any	Any
10 μm PTFE filter	Cole-Parmer	SK-21940-41	Change every 8-10 runs
100 mM Sodium Pyruvate	Thermo Scientific	11360070	Enriched-CMRL Media Component
190 proof Ethanol	Decon labs	2816	Acid Ethanol Component
200 mM GlutaMAX-I Supplement	Gibco	35050061	Enriched-CMRL Media Component
Ascorbate	Sigma	A5960	DMEM Perifusion Buffer Component
Bovine Serum Albumin	Sigma	A7888	DMEM Perifusion Buffer Component
Bubble trap	Omnifit	006BT
CellCarrier ULA 96-well Microplates	Perkin Elmer	6055330
cellSens analysis software	Olympus	v3.1	Software used for data analysis
CMRL 1066	MediaTech	15-110-CV	Enriched-CMRL Media Component
Conical adapter (IDEX, P-794)	IDEX	P-794
D-(+)-Glucose	Sigma	G7528	Glucose Buffer Component
DMEM	Sigma	D5030	DMEM Perifusion Buffer Component
Environmental chamber	okolab	IX83
Epinepherine (Epi)	Sigma	E4250	Stimulation Buffer Component
Fetal Bovine Serum (FBS), Heat Inactivated	Sigma	12306C	Enriched-CMRL Media Component
Glucagon ELISA	Mercodia	10-1281-01
Glucagon Kit HTRF	Cisbio	62CGLPEH
HCl (12N)	Any	Any	Acid Ethanol Component
HEPES	Sigma	H7523	DMEM Perifusion Buffer Component
iCell Endothelial Cells Medium Supplement	Cell Dynamics	M1019	iEC Media Component
Idex Derlin nut & ferrule 1/4-24	Cole-Parmer	EW-00414-LW
Insulin ELISA	Mercodia	10-1113-01
Isobutylmethylonine (IBMX)	Sigma	I5879	Stimulation Buffer Component
Laser scanning confocal microscope	Olympus	FV3000
L-Glutamine	Sigma	G8540	DMEM Perifusion Buffer Component
Microchip (University of Miami, FP-3W)	University of Miami	FP-3W
Microchip holder	Micronit Microfluidics	FC_PRO_CH4525
Model 2110 Fraction Collector	Biorad	7318122
P10, P200, and P1000 pipets and tips	Any	Any
Penicillin/Streptomycin	Gibco	15140-122	Enriched-CMRL Media Component
Peristaltic pump	Instech	P720
Phosphate Buffered Saline	Gibco	14190-144	Wash Islets
Sarstedt dishes	Sarstedt	depends on dish diameter
Sodium Bicarbonate	Sigma	S6014	DMEM Perifusion Buffer Component
Sodium Pyruvate	Sigma	P2256	DMEM Perifusion Buffer Component
Stereoscope	Olympus	SZX12
Steriflip Filter (0.22 μm)	Millipore	SCGP00525	Filter all buffers twice
VascuLife VEGF Medium Complete Kit	LifeLine Cell Technology	LL-0003	iEC Media Component