A Mouse Model of Retinal Ischemia-Reperfusion Injury Through Elevation of Intraocular Pressure

Podsumowanie

This article describes a procedure for inducing retinal ischemia-reperfusion injury by elevated intraocular pressure in mice. Retinal ischemia-reperfusion injury by elevated intraocular pressure serves to model human pathologies characterized by compromised oxygen and nutrient delivery in the retina, enabling researchers to examine potential cellular mechanisms and treatments for human diseases of the retinal neurovascular unit.

Streszczenie

Retinal ischemia-reperfusion (I/R) is a pathophysiological process contributing to cellular damage in multiple ocular conditions, including glaucoma, diabetic retinopathy, and retinal vascular occlusions. Rodent models of I/R injury are providing significant insights into mechanisms and treatment strategies for human I/R injury, especially with regard to neurodegenerative damage in the retinal neurovascular unit. Presented here is a protocol for inducing retinal I/R injury in mice through elevation of intraocular pressure (IOP). In this protocol, the ocular anterior chamber is cannulated with a needle, through which flows the drip of an elevated saline reservoir. Using this drip to raise IOP above systolic arterial blood pressure, a practitioner temporarily halts inner retinal blood flow (ischemia). When circulation is reinstated (reperfusion) by removal of the cannula, severe cellular damage ensues, resulting ultimately in retinal neurodegeneration. Recent studies demonstrate inflammation, vascular permeability, and capillary degeneration as additional elements of this model. Compared to alternative retinal I/R methodologies, such as retinal arterial ligation, retinal I/R injury by elevated IOP offers advantages in its anatomical specificity, experimental tractability, and technical accessibility, presenting itself as a valuable tool for examining neuronal pathogenesis and therapy in the retinal neurovascular unit.

Wprowadzenie

Retinal ischemia-reperfusion (I/R) characterizes many human retinal pathologies, including glaucoma, diabetic retinopathy, and retinal vascular occlusions¹. In retinal I/R, reduced blood flow (ischemia) in the retinal vasculature creates a state of retinal hypersensitivity to oxygen and other nutrients, precipitating severe oxidative and inflammatory damage when circulation is subsequently reinstated (reperfusion)². The neural retina appears particularly vulnerable to these changes, with retinal neurodegeneration being perhaps the most salient feature of I/R-induced damage. Presented here is a protocol for modeling retinal I/R injury in the mouse. This technique enables researchers to examine potential mechanisms and treatment strategies for human diseases of the retinal neurovascular unit.

Pioneered in 1952 by surgeons seeking to understand the neurodegenerative consequences of surgical anemia³, rodent retinal I/R by elevated intraocular pressure (IOP) was reestablished in 1991 for the purpose of standardizing neurodegenerative endpoints after ischemic insult⁴. Using the drip of a saline reservoir to raise IOP above systolic blood pressure, these studies demonstrated that pressurized ocular cannulation was sufficient to suspend the retinal circulation and thereby initiate neuronal degeneration. More recent efforts using retinal I/R by elevated IOP have begun to elaborate the mechanisms underlying I/R-induced retinal neurodegeneration^5-12. Multiple groups have reported additional pathologic changes including inflammation^13,14, vascular permeability^15,16, and capillary degeneration^14,17. Taken together, these studies have established retinal I/R injury by elevated IOP as a model of retinal neurovascular disease more generally.

Characterizing the mechanisms of I/R injury is essential for the study of vascular disease. Retinal I/R injury by elevated IOP is one of many hypoxia-induced injury models, including I/R injuries in lung¹⁸, heart¹⁹, brain²⁰, liver²¹, kidney²², and intestine²³. These models have been paramount in advancing our understanding of vascular illness and its clinical remedies. By extending the investigation of I/R processes to ocular tissues, retinal I/R injury by elevated IOP helps to paint a more comprehensive picture of these related conditions.

Corresponding closely with clinical neurodegenerative conditions in retina, retinal I/R injury by elevated IOP presents a valuable tool for researchers interested in exploring ischemic pathogenesis. The protocol described herein is targeted, tractable, and accessible. It is complemented well by endpoints in neuronal degeneration, such as quantification of retinal neurons, measurement of retinal thickness, and electrophysiological recording of retinal neuron function. This model has proven its utility in advancing neurovascular inquiry, and it shows promise in earning status as a foundational protocol in visual medicine research.

Protokół

Ethics Statement: All procedures were performed in accordance with the guidelines set forth by the Johns Hopkins University Institutional Animal Care and Use Committee.

Note: Mice used during filming are C57BL/6 mice from Jackson, although other rodent strains or species may also be used. When using other strains or species, be aware that anesthesia dosages and injury timeline may vary. It is important to adapt I/R conditions to accommodate strain, species, and experimental variations.

1. Prepare the Anesthesia Cocktail

1. Combine 1.25 ml Ketamine, 0.625 ml Xylazine, 0.375 ml Acepromazine, and 22.75 ml phosphate buffered saline in a 50 ml centrifuge tube.
   NOTE: For the remainder of the manuscript, this solution will be referred to as the cocktail.
2. Filter the cocktail into a new sterile 50 ml centrifuge tube using a 60 ml syringe and a 0.20 µm filter. Label and date this new tube.
3. Fully wrap the cocktail tube in aluminum foil to prevent light-induced degradation of the anesthetic. 
   NOTE: The cocktail may be stored at room temperature and reused until the expiration date of its earliest-expiring ingredient.

2. Prepare the Anesthesia Booster

1. In a 50 ml centrifuge tube, combine 4 ml Ketamine and 16 ml phosphate buffered saline.
   NOTE: This solution will henceforth be referred to as the booster.
2. Filter the booster into a new sterile 50 ml centrifuge tube using a 60 ml syringe and a 0.20 µm filter. Label and date this new tube. 
   NOTE: The booster may be stored at room temperature and reused until the expiration date of its earliest-expiring ingredient.

3. Prepare the Surgical Suite

1. Set the room temperature between 18 °C and 21 °C.
2. Turn on the surgery table, and adjust its surface heat to the highest temperature.
3. Cover all work surfaces with surgical underpads.
4. Arrange an empty cage or other container on the surgical table to warm.
5. Arrange a scale and an ear tagger on the worktop.

4. Prepare the Balanced Salt Solution with Heparin Sodium

1. Add 0.5 ml of heparin sodium to a 500 ml IV bottle of balanced salt solution (HBSS).
2. Insert the sharp end of the primary set prepierced Y-site tubing into the bottle of 0.1% heparin sodium.

5. Set up the IV Pole

1. Hang the bottle of 0.1% heparin sodium from the IV pole extension, and snap open the air filter cap on the primary set prepierced Y-site tubing.
2. Elevate the 0.1% heparin sodium bottle to 163 cm (120 mm Hg). Measure the height from the tabletop to the peak of the sodium heparin drip.
3. Remove any air bubbles in the IV tubing by manually flicking the primary set prepierced Y-site tubing.

6. Set up the Sodium Heparin Drip

1. Connect the primary set prepierced Y-site tubing to the five-valve manifold.
2. Connect 30-gauge ½ inch needles to the five-port manifold using Luer male to Luer male tube fittings.
3. Insert each of the 30-gauge ½ inch needles into its own 10-inch segment of 30-gauge tubing.
4. Using hemostats, break the needle tips from new 30-gauge ½ inch needles and insert their blunt ends into the 30-gauge tubing. Sterility or disinfection of the needle tips will be necessary for Step 8.3.
5. Using tape, arrange the 30-gauge tubes with needles such that the tubes connected to the inner ports are positioned on top of the tubes connected to the outer ports. This arrangement will prevent tangling of tubing during anterior chamber cannulation.
6. Turn on the 0.1% heparin sodium flow to the five-valve manifold and to each individual port.
   1. Ensure that the 0.1% heparin sodium is flowing strongly for each port. If a port is flowing weakly, replace the port or clear it with air from a sterile syringe.
   2. Allow the 0.1% heparin sodium to flow for 2 - 3 min to remove air bubbles from the 30-gauge tubes and 5-valve manifold.
7. Turn off all the ports on the 5-valve manifold.

7. Prepare the Mice for Surgery

1. Bring the mice to the surgical suite. Supply water bottles for each cage in order to prevent animal dehydration during surgery.
2. Record the weight of each mouse.
3. Inject each mouse intraperitoneally with 0.02 ml cocktail per gram bodyweight.
4. Tag and record the number of each mouse.
5. Place all the mice into the empty container on the surgery table. Allow 5-10 min for all the mice to achieve deep anesthetization as confirmed by absence of the pedal withdrawal response to toe pinch.
6. For each mouse, administer one drop of Tropicamide into each eye for pupil dilation and short-term lubrication.
7. For each mouse, administer one drop of Proparacaine into each eye for local anesthesia and short-term lubrication.
8. Arrange the mice in the order of anesthetization so that the first mouse to be anesthetized will be the first mouse to be cannulated.
9. Allow approximately 2 min for the eye drops to take effect.
10. Prepare straight 4-inch pieces of tape by pulling tightly on the tape. Set aside one piece of tape for each mouse.    
    NOTE: Failing to pull tightly on the tape will result in curling of the tape.

8. Cannulate the Anterior Chamber

1. Arrange the first mouse under the surgical microscope, and focus the microscope on the preferred cornea.            
   NOTE: Cannulation may be performed on either eye. Right-hand dominant surgeons may find it easiest to cannulate the left eye, while left-hand dominant surgeons may prefer the right.
2. Turn on the first 0.1% heparin sodium port on the five-valve manifold.
3. Under the surgical microscope, use a pair of forceps to gently proptose the eye. Insert the 30-gauge cannula needle into the anterior chamber approximately halfway between the zonule fibers and the apex of the cornea.
   1. Take care to avoid scratching or puncturing the iris, lens, or inner corneal surface.
   2. Avoid penetrating the cornea a second time.
   3. Using a gentle twisting motion to overcome friction between the cannula and the cornea, insert the cannula deeply in the anterior chamber.
4. Use a strip of tape to secure the 30-gauge tubing to the table. To minimize movement of the inserted cannula, press the 30-gauge tubing against the tabletop while reaching for the tape.
5. Record the start time of the surgery.
6. Using the microscope, verify that no leakage is apparent. If leakage is present, the movement of fluid will be visible near the eye.
7. Visually confirm ocular distention by observing that the I/R eye is larger than the contralateral eye. Together, the absence of leakage and the presence of ocular distention demonstrate a successful elevation of intraocular pressure.
8. Apply hypromellose to both eyes. Hypromellose serves to lubricate the cornea and seal microleaks. Reapply hypromellose as needed (approximately every 30 min) for sustained lubrication.
9. Repeat Step 8 until all animals have been cannulated.

9. Monitor Anesthesia

1. Use the toe pinch, visual observation of the whiskers, or visual observation of the tail to verify that each mouse remains anesthetized. Should a mouse demonstrate a pedal withdrawal response, whisker twitching, or tail movement, proceed immediately to Step 9.2.
2. If a mouse begins to awaken during surgery, lift the tail to inject 0.05 ml booster intraperitoneally into the lower abdomen from behind the mouse. Allow 1 - 2 min for the booster to take effect.
3. Should a mouse require additional sedation, repeat Step 9 as necessary.

10. Remove the Cannula from the Anterior Chamber

1. For each animal, after 90 min have elapsed, gently pull the cannula from the anterior chamber.
2. Untape the mouse from the surgical table, taking care not to disturb the cannula tubing of adjacent animals.
3. Lubricate both eyes with lubricating jelly.
4. As subsequent cannulae are removed, arrange the mice in the empty container on the surgical table to recover from surgery. Do not turn off the heat of the surgical table.
5. Allow, at minimum, 2 - 3 hr for recovery on the heated surgical table. Observe the mice frequently until they have fully recovered from the anesthesia.

11. Clean the Equipment

1. Disinfect the cannulae using alcohol wipes. 
   NOTE: Other methods for disinfection or sterilization, such as autoclaving, may be substituted.
2. Expel 0.1% heparin sodium from the 5-valve manifold, 30-gauge needles, 30-gauge tubing, and cannulae using a 60 ml syringe filled with air.
3. Rinse the 5-valve manifold, 30-gauge needles, 30-gauge tubing, and cannulae using a 60 ml syringe filled with distilled water.
4. Expel distilled water from the 5-port manifold, 30-gauge needles, 30-gauge tubing, and cannulae using a 60 ml syringe filled with air.
5. After disinfecting the cannulae and rinsing the tubing apparatus, store this equipment for reuse.
6. Store, discard, or turn off all other equipment. Leave the heat of the surgical table on.

12. Return All Mice to Their Home Cages

1. After the mice awaken from surgery (after 2 - 3 hr), return each animal to its home cage. Provide gel food for each cage. Return all cages to their designated rooms.
2. Turn off the heat of the surgical table. Discard all waste, and wipe down the surgical suite.

13. Perform Retinal Assessment

1. As appropriate, collect retinas for histological analysis or dark adapt mice for electroretinogram recording.

Wyniki

The neurodegenerative effects of retinal I/R by elevated IOP are commonly evaluated using two standard approaches. NeuN immunolabeling of neuronal nuclei has revealed significant neuronal cell loss following I/R insult (Figure 1). Briefly, eyes enucleated 7 days after I/R were fixed in paraformaldehyde, labeled with the neuronal cell marker NeuN, and whole-mounted. Images were captured using confocal microscopy, and cells labeled with NeuN were quantified by counting^...

Dyskusje

Retinal I/R injury by elevated IOP has proven its utility in modeling cellular damage and dysfunction, particularly neurodegeneration, in the rodent retinal neurovascular unit. This procedure provides a robust control tissue and is easily accessible in terms of technical sophistication. It has been noted in this and other I/R injury models that increasing the pressure and duration of ischemia may increase injury severity²⁴. For this reason, some practitioners have elected to use ischemic pressures and dur...

Materiały

Name	Company	Catalog Number	Comments
Heparin Sodium Injection, USP	Abraxis Pharmaceutical Products		1,000 USP/ml
BSS Sterile Irrigating Solution	Alcon Laboratories, Inc.	9007754-0212	500 ml
SC-2 kg Digital Pocket Scale	American Weigh Scales, Inc.	SC-2 kg
Tropicamide Ophthalmic Solution USP 1%	Bausch + Lomb		1% (10 mg/ml)
Proparacaine Hydrochloride Ophthalmic Solution USP, 0.5%	Bausch + Lomb		0.5% (5 mg/ml)
INTRAMEDIC Polyethylene Tubing	Becton Dickinson and Company	427400	Inner diameter: 427400
30 G 1/2 PrecisionGlide Needles	Benton Dickinson and Company	305106
BC 1 ml TB Syringe, Slim Tip with Intradermal Bevel Needle, 26 G x 3/8	Benton Dickinson and Company	309625
BD 60 ml Syringe Luer-Lok Tip	Benton Dickinson and Company	309653
Zeiss OPMI Visu 200/S8 Microscope	Carl Zeiss AG	000000-1179-101
Sterile Syringe Filter	Corning Inc.	CLS431224	0.20 µm
Durasorb Underpads	Covidien	1038	23 x 24 inches
Alcohol Prep	Covidien	6818	2 Ply, Medium
Student Dumont #5 Forceps	Fine Science Tools	91150-20
Hartman Hemostats	Fine Science Tools	13002-10
Primary Set, Macrobore, Prepierced Y-Site, 80 Inch	Hospira	12672-28
Phosphate Buffered Saline pH 7.4 (1x)	Invitrogen	10010-049	500 ml
Distilled water	Invitrogen	15230-204	500 ml
C57BL/6J Mice	The Jackson Laboratory	664
AnaSed Injection: Xylazine Sterile Solution	LLOYD, Inc.		20 mg/ml
Lubricating Jelly, Water Soluble Bacteriostatic	MediChoice		3-Gram Packet
NAMIC Angiographic Pressure Monitoring Manifold	Navilyst Medical, Inc.	70039355	5-Valve Manifold with Seven Female Ports
Goniosoft, Hypromellose 2.5% Ophthalmic Demulcent Solution: Hydroxypropyl Methylcellulose	OCuSOFT, Inc.		2.5% (25 mg/ml)
Ketaset CIII: Ketamine Hydrochloride	Pfizer, Inc.		100 mg/ml
Trans-Pal I.V. Stand	Pryor Products	372	Furnished with a home-constructed 60-cm stainless steel extension
Acepromazine: Acepromazine Maleate Injection, USP	Vet One		10 mg/ml
V-Top Surgery Table/Adjustable Hydraulic	VSSI	100-4041-21
Tube Fitting Luer Male to Luer Male	Warner Instruments	64-1579