eoe sub articles

EoE Sub Articles

All procedures involving sample collection have been performed in accordance with the institute's IRB guidelines.1. Preparation and sterilization of equipment and supplies<ol><li>Refer to the&#160;Table of Materials for a complete list of supplies required as well as supplier and catalogue numbers.</li><li>Prior to use, sterilize all equipment and instruments by autoclaving or using ethylene oxide ampules.</li></ol>2. Preparation of perfusion medium<ol><li>Add 1% penicillin-streptomycin (10,000 U/mL penicillin, 10,000 &#956;g/mL streptomycin in 0.85% NaCl) and 1% L-glutamine (200 mM) to 1,000 mL high glucose Dulbecco&#8217;s modified Eagle&#8217;s medium (DMEM).</li><li>Sterilize the perfusion medium by passing through a 0.22 &#956;m filter.</li></ol>3. Translaminar autonomous system (TAS) setup<ol><li>Set up inflow syringes (intraocular pressure (IOP) and intracranial pressure (ICP) reservoirs).<ol style='list-style-type:decimal;'><li>Add 30 mL of the perfusion medium (section 2) to a 30 mL syringe. Attach a 3-way stopcock to the 30 mL syringe. Attach a 0.22 &#956;m hydrophilic filter to the 3-way stopcock. Attach a 15 G Luer stub adapter to the 0.22 &#956;m hydrophilic filter.</li><li>Remove air bubbles from the syringe setup. Attach tubing to the 15 G Luer stub adapter. Close the side port of the stopcock with an unvented universal lock cap. Repeat for a total of two setups.</li><li>Label one syringe as channel 1 intracranial pressure (CH1 ICP) and the other syringe as channel 2 intraocular pressure (CH2 IOP).</li></ol></li><li>Set up outflow syringes (IOP and ICP reservoirs).<ol style='list-style-type:decimal;'><li>Attach a 3-way stopcock to a 30 mL syringe. Attach a 15 G Luer stub adapter to the 3-way stopcock. Attach tubing to the 15 G Luer stub adapter.</li><li>Close the side port of the stopcock with an unvented universal lock cap. Repeat for a total of two setups. Label one syringe as CH1 ICP and the other syringe as CH2 IOP.</li></ol></li></ol>4. Preparation of human whole eye globeNOTE:&#160;If whole eyes are received, follow the procedure below to separate the anterior segment from the posterior segment of the eye. If the eyes are received bisected, start at step 4.4.<ol><li>Place a whole eye into the povidone-iodine solution for 2 min.</li><li>Rinse the eye in a sterile phosphate-buffered solution (PBS) to remove the povidone-iodine. Repeat two times.</li><li>Remove the adnexa from the whole eye globe using forceps and scissors. Bisect the eye at the equator to separate the anterior and posterior segments of the eye.</li><li>Remove the optic nerve sheath. Remove the vitreous humor from the posterior segment.</li><li>Trim additional sclera from the posterior segment, if needed, to ensure a good fit on the round dome of the IOP (bottom) chamber. Using forceps, ensure that the retina is spread evenly over the posterior of the segment.</li><li>IOP (bottom) chamber setup<ol style='list-style-type:decimal;'><li>Place the human posterior segment into the IOP (bottom) chamber of the TAS over the round dome with the optic nerve facing the top.</li><li>Seal the posterior segment using the epoxy resin O-ring with four screws, ensuring a tight seal.</li><li>Insert the tubing into the IN and OUT ports of the IOP (bottom) chamber. The IOP inflow syringe with tubing containing medium is inserted into the IN port and the empty IOP outflow syringe with tubing is inserted into the OUT port.</li><li>Use the push/pull method to slowly infuse the perfusion medium into the inflow port to fill the posterior eye cup while simultaneously slowly pulling the perfusion medium out through the outflow syringe to remove any air bubbles from the lines. Stop infusing the medium once both the IN and OUT tubes are void of air bubbles.</li><li>Lock the stopcocks in the off position. Remove the 30 mL syringe from the IOP IN port filter assembly and refill it with 30 mL of medium. Then, replace the syringe with the filter assembly.</li></ol></li><li>ICP (top) chamber setup<ol style='list-style-type:decimal;'><li>Place the ICP (top) chamber/lid over the back of the posterior segment. Make certain that the optic nerve is within the top chamber. Seal the top chamber with four screws.</li><li>Insert the tubing into the IN and OUT ports of the ICP (top) chamber. The ICP inflow syringe with tubing containing medium is inserted into the IN port and the empty ICP outflow syringe with tubing is inserted into the OUT port.</li><li>Gently and slowly infuse the medium into the IN port to fill the ICP chamber and remove air bubbles from the lines using the push/pull method. Stop infusing the medium once the ICP chamber and both the IN and OUT tubing are void of air bubbles.</li><li>Lock the stopcocks in the off position. Remove the 30 mL syringe from the ICP in port filter assembly and refill it with 30 mL of medium. Then, replace the syringe with the filter assembly.</li></ol></li></ol>

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 developing a translaminar pressure model using a translaminar autonomous system

<a href='https://app-jove-com.remotexs.ntu.edu.sg/v/61006/translaminar-autonomous-system-model-for-modulation-intraocular'>Source: Sharma, T. P., et al.,&#160;Translaminar Autonomous System Model for the Modulation of Intraocular and Intracranial Pressure in Human Donor Posterior Segments. J. Vis. Exp.&#160;(2020).</a>This video demonstrates the procedure of preparing a human eye to study the effects of translaminar pressure on retinal ganglion cell signaling by simulating intraocular and intracranial pressures in a translaminar autonomous system.

 Developing a Translaminar Pressure Model Using a Translaminar Autonomous System

Source: Sharma, T. P., et al.,&#160;Translaminar Autonomous System Model for the Modulation of Intraocular and Intracranial Pressure in Human Donor ...

developing-translaminar-pressure-model-using-translaminar-autonomous

Nanyang Technological University

Research

JoVE Encyclopedia of Experiments

Neuroscience

Neuropathology

Cerebrovascular Diseases

22 Views. Source: Sharma, T. P., et al., Translaminar Autonomous System Model for the Modulation of Intraocular and Intracranial Pressure in Human Donor Posterior Segments. J. Vis. Exp. (2020). This video demonstrates the procedure of preparing a human eye to study the effects of translaminar pressure on retinal ganglion cell signaling by simulating intraocular and intracranial pressures in a translaminar autonomous system. 

Video:  Developing a Translaminar Pressure Model Using a Translaminar Autonomous System - Concept

Dissection of Human Retina and RPE-Choroid for Proteomic Analysis

The human retina is composed of the sensory neuroretina and the underlying retinal pigmented epithelium (RPE), which is firmly complexed to the vascular choroid layer. Different regions of the retina are anatomically and molecularly distinct, facilitating unique functions and demonstrating differential susceptibility to disease. Proteomic analysis of each of these regions and layers can provide vital insights into the molecular process of many diseases, including Age-Related Macular Degeneration (AMD), diabetes mellitus, and glaucoma. However, separation of retinal regions and layers is essential before quantitative proteomic analysis can be accomplished. Here, we describe a method for dissection and collection of the foveal, macular, and peripheral retinal regions and underlying RPE-choroid complex, involving regional punch biopsies and manual removal of tissue layers from a human eye.One-dimensional SDS-PAGE as well as downstream proteomic analysis, such as liquid chromatography-tandem mass spectrometry (LC-MS/MS), can be used to identify proteins in each dissected retinal layer, revealing molecular biomarkers for retinal disease.

The human retina is composed of functionally and molecularly distinct regions, including the fovea, macula, and peripheral retina. Here, we describe a method using punch biopsies and manual removal of tissue layers from a human eye to dissect and collect these distinct retinal regions for downstream proteomic analysis.

The human retina is composed of the sensory neuroretina and the underlying retinal pigmented epithelium (RPE), which is firmly complexed to the vascular ...

JoVE Journal

Biochemistry

Trabecular Meshwork Response to Pressure Elevation in the Living Human Eye

The mechanical characteristics of the trabecular meshwork (TM) are linked to outflow resistance and intraocular pressure (IOP) regulation. The rationale behind this technique is the direct observation of the mechanical response of the TM to acute IOP elevation. Prior to scanning, IOP is measured at baseline and during IOP elevation. The limbus is scanned by spectral-domain optical coherence tomography at baseline and during IOP elevation (ophthalmodynamometer (ODM) applied at 30 g force). Scans are processed to enhance visualization of the aqueous humor outflow pathway using ImageJ. Vascular landmarks are used to identify corresponding locations in baseline and IOP elevation scan volumes. Schlemm canal (SC) cross-sectional area (SC-CSA) and SC length from anterior to posterior along its long axis are measured manually at 10 locations within a 1 mm segment of SC. Mean inner to outer wall distance (short axis length) is calculated as the area of SC divided by its long axis length. To examine the contribution of adjacent tissues to the effect IOP elevations, measurements are repeated without and with smooth muscle relaxation with instillation of tropicamide. TM migration into SC is resisted by TM stiffness, but is enhanced by the support of its attachment to adjacent smooth muscle within the ciliary body. This technique is the first to measure the living human TM response to pressure elevation in situ under physiological conditions within the human eye.

Trabecular meshwork (TM) migration into Schlemm&#8217;s canal space can be induced by acute pressure elevation by ophthalmodynamometer, and observed by spectral domain optical coherence tomography. The goal of this method is to quantify the morphometric response of the living outflow tract to acute pressure elevation in living tissues in situ.

The mechanical characteristics of the trabecular meshwork (TM) are linked to outflow resistance and intraocular pressure (IOP) regulation. The rationale ...

Medicine

Biobanking of Human Aqueous and Vitreous Liquid Biopsies for Molecular Analyses

A critical challenge in translational research is establishing a viable and efficient interface between patient care in the operating room (OR) and the research laboratory. Here, we developed a protocol for acquiring high-quality liquid biopsies for molecular analyses from the aqueous humor and the vitreous from patients undergoing eye surgery. In this workflow, a Mobile Operating Room Lab Interface (MORLI) cart equipped with a computer, a barcode scanner, and lab instruments, including onboard cold storage, is used to obtain and archive human biological samples. A web-based data privacy-compliant database enables annotating each sample over its lifetime, and a cartesian coordinate system allows tracking each barcoded specimen in storage, enabling quick and accurate retrieval of samples for downstream analyses. Molecular characterization of human tissue samples not only serves as a diagnostic tool (e.g., to distinguish between infectious endophthalmitis and other non-infectious intraocular inflammation) but also represents an important component of translational research, allowing the identification of new drug targets, development of new diagnostic tools, and personalized therapeutics.

This protocol presents an integrated biorepository platform for the standardized collection, annotation, and biobanking of high-quality human aqueous humor and vitreous liquid biopsies for molecular downstream analyses, including proteomics, metabolomics, and glycomics.

A critical challenge in translational research is establishing a viable and efficient interface between patient care in the operating room (OR) and the ...

Developing a Translaminar Pressure Model Using a Translaminar Autonomous System

Transcript

Developing a Translaminar Pressure Model Using a Translaminar Autonomous System

Dissection of Human Retina and RPE-Choroid for Proteomic Analysis

Trabecular Meshwork Response to Pressure Elevation in the Living Human Eye

Biobanking of Human Aqueous and Vitreous Liquid Biopsies for Molecular Analyses