Demonstration of the Rat Ischemic Skin Wound Model

Summary

The rat, due to its size, availability, and rather docile behavior, has been utilized as a research model for many years. The goal of this protocol is to utilize the rat as an ischemic skin wound healing model to provide valuable insight into the pathophysiology of chronic wounds.

Abstract

The propensity for chronic wounds in humans increases with ageing, disease conditions such as diabetes and impaired cardiovascular function, and unrelieved pressure due to immobility. Animal models have been developed that attempt to mimic these conditions for the purpose of furthering our understanding of the complexity of chronic wounds. The model described herein is a rat ischemic skin flap model that permits a prolonged reduction of blood flow resulting in wounds that become ischemic and resemble a chronic wound phenotype (reduced vascularization, increased inflammation and delayed wound closure). It consists of a bipedicled dorsal flap with 2 ischemic wounds placed centrally and 2 non-ischemic wounds lateral to the flap as controls. A novel addition to this ischemic skin flap model is the placement of a silicone sheet beneath the flap that functions as a barrier and a splint to prevent revascularization and reduce contraction as the wounds heal. Despite the debate of using rats for wound healing studies due to their quite distinct anatomic and physiologic differences compared to humans (i.e., the presence of a panniculus carnosus muscle, short life-span, increased number of hair follicles, and their ability to heal infected wounds) the modifications employed in this model make it a valuable alternative to previously developed ischemic skin flap models.

Introduction

Effective drug development and other wound healing therapeutics require appropriate in vivo models, despite known problems in translating findings in animal models to human therapies¹. What follows is a description of a detailed protocol for the use of a rat model of ischemic skin wound healing to investigate mechanisms that further the understanding of pathological wound healing. The rat species, often employed due to its wide availability, size and docile nature is used for wound healing studies as it is large enough to provide a suitable skin area for incisional and excisional wounding, imaging and tissue collection². However it should be taken into careful consideration that the skin of a rat and a human are different anatomically, with rats being referred to as loose-skinned animals. This distinct characteristic allows for wound contraction, rather than epithelialization to contribute significantly to the closing of rat skin wounds². Additionally, the presence of a subcutaneous panniculus carnosus muscle in rats, contributes to healing by both contraction and collagen formation^3,4. These very important anatomical distinctions were considered in the development of the rat ischemic skin wound model and specific modifications were implemented to decrease wound contraction and reduce the influence of the panniculus carnosus muscle⁵.

In diabetic foot ulcers, venous leg ulcers, and pressure ulcers, healing is delayed and these wounds are considered chronic. The wounds are characterized by excessive inflammation, which prevents the wound from progressing to the next phases of wound repair⁶. One of the main factors in the development of a chronic wound is localized tissue ischemia (reduced blood flow)⁵ contributing to the inability to clear inflammation. At the time during which this model was being developed and validated (in 2003-4), there were no standardized animal models that could provide enough tissue to test induction of angiogenesis in the wound bed, a key stage during normal wound healing and the motivation for developing this model⁵. That said, the model presented here is a modification of the ischemic wound model originally described by Schwartz et al.⁷ and subsequently used in modified form by Chen et al.⁸

In the modified ischemic wound model, changes have been made to circumvent the above mentioned anatomical characteristics of the rat that lead to healing by contraction rather than epithelialization: (1) Two full-thickness excisional wounds are created within a bipedicled dorsal skin flap and the panniculus carnosus muscle is removed from the wound bed by dissecting just above the muscle fascia. (2) The flap itself has more narrow dimensions, ensuring that blood supply is random and the wounds located at the midpoint of the flap are ischemic. (3) A silicone sheet is inserted beneath the flap, preventing readherence and reperfusion of the flap from underlying tissue. Wound contraction is limited (not eliminated) by anchoring or suturing the flap to the silicone sheet⁵.

The model has recently been used in studies ranging from hyperbaric oxygen effects on ischemic wound healing^9,10 to ischemic wound healing in young versus aged rats¹¹ and has proven to be a reliable model of prolonged tissue ischemia. The dimensions of the bipedicled flap have also been adapted to different rat strains, including Sprague Dawley (11 cm long by 2 cm wide) and F344 rats (10.5 cm long by 3.0-3.5 cm wide) and other species, including swine¹² and mice^13,14 . This video utilizes the F344 inbred rat strain in the demonstration of the ischemic skin wound model.

Approval for all animal procedures presented below was obtained from the University of South Florida’s Animal Care Committee (IACUC) and abide by all requirements of the Animal Welfare Act and the Guide for Care and Use of Laboratory Animals.

Protocol

NOTE: Approval for all animal procedures presented below was obtained from the University of South Florida’s Animal Care Committee (IACUC) and abide by all requirements of the Animal Welfare Act and the Guide for Care and Use of Laboratory Animals.

1. Preparation of Silicone Sheets and Surgical Instruments

1. Precut strips (10.5 cm x 3.0 cm) of non-reinforced 0.01 thickness, medical grade silicone sheeting and sterilize using an autoclave.
2. Clean and sterilize suitable surgical instruments (scissors, forceps and drapes or towels to create a sterile field during surgery).

2. Experimental Animals

1. Use adult male or female rats weighing in range from 250-350 g obtained from a commercial breeder. If aged rats are utilized, they should be ≥350 g in order to ensure better survival post-surgery. Prior to the start of any experiments acclimate all animals for at least 7 days under standard conditions of a 12 hr light-dark cycle with food and water ad libitum.

3. Anesthesia, Pre-operative Analgesia and Operative Preparation

1. Induce general anesthesia by using isoflurane at 3%-4% via an induction chamber and maintain (via use of a nose cone) at 1%-2% with O₂ during skin preparation and surgery. Monitor the depth of anesthesia by observation of the rate and depth of respiration, interdigital pinch or palpebral blink reflex.
   NOTE: At this time, a vet ointment can be placed on the eyes to prevent dryness while the animal is under anesthesia.
2. In a location remote from the sterile surgical area, place the rat in the prone position and shave the dorsum with clippers from the base of the neck down approximately 11 cm. Stencil with permanent marker, the outline for the 3.0 cm x 10.5 cm flap (see Figure 1A).
3. Move the rat to a clean, designated surgical area equipped with an approved heating pad and sterile surgical drapes or towels. Inject 5 mg/kg Ketoprofen subcutaneously prior to the first surgical incisions for pain management. Additional fluids (saline) can be given (up to 5 cc) subcutaneously as needed.
4. Prepare the skin further by swabbing first with 70% isopropyl alcohol and second with 0.2% chlorhexidine, then apply sterile drapes to create a sterile field. 10% povidone-iodine (Betadine) can also be used.
   NOTE: An antibiotic (ampicillin at 15 mg/kg) can be administered subcutaneously, but if good aseptic techniques are used it is not required.

4. Creating Excisional Wounds and Bipedicled Flap

1. Using a sterile, disposable 6 mm biopsy punch tool, create two circular “ischemic” wounds in the center of the designated flap area (Figure 1B). The depth of the wound should be down to (not through) the underlying fascia of the panniculus carnosus muscle (Figure 1B inset).
2. Using forceps lift the skin in the middle of the wound outline created by the punch biopsy and then use iris scissors (with curved tips) to excise the circular piece of tissue (including the panniculus carnosus muscle). The result will be a full-thickness wound with the fascia as the base of the wound.
   NOTE: The excised tissue (wound plugs) can be snap frozen in liquid nitrogen or fixed in 10% buffered-formalin O/N for later processing as control, normal skin.
3. Create a bipedicled flap by making incisions with a sterile scalpel on each side of the ischemic wounds along the pre-drawn lines (Figure 1C) that are 10.5 cm in length and 3.0 cm apart. The depth of the incisions should be down to the paraspinous muscles. Using iris scissors, separate the panniculus carnosus fascia from the paraspinous muscles, being careful to keep the fascia intact as the “base” of the 6 mm punches (Figure 1D).
4. Take 1 sterile pre-cut silicone sheet and place it in between the panniculus carnosus fascia and the paraspinous muscles (Figure 1E) ensuring that the sheet does not buckle or fold. Using black, non-absorbable sutures (size 4.0) close both incisions by anchoring the silicone sheet to the skin with at least 8 interrupted stitches on each side, along the length of the flap (Figure 1F and 1G).
5. Using a sterile, disposable biopsy punch tool, create two internal control “non-ischemic” wounds (down to the anterior fascia of the panniculus carnosus muscle) 1 cm lateral to the ischemic wounds on either side of the flap (Figure 1G).
6. Place a ruler below the wounds and take digital photos for wound measurement purposes (see Figure 3A). At this time, blood flow (perfusion) can be monitored by use of laser Doppler or other manipulations (topical drug placement) performed.
7. Apply an approved liquid adhesive both cranial and caudal to the wounds and a transparent film dressing to keep the wound environment moist and clean (sterile). An additional dressing may be placed at the caudal end of the flap to prevent the animal from removing the most caudal sutures.

5. Post-operative Procedures

1. Place animals in cages (singly housed) equipped with shallow feeders so as to prevent the surgical site from rubbing against the feeder. Animals should not be left unattended or returned to the company of other animals until they regain sufficient consciousness to maintain sternal recumbency and exhibit purposeful movement. Heating mats should be placed under half of the cage for up to 2 days during recovery.
2. To manage pain post-operatively, administer Ketoprofen (5 mg/kg) subcutaneously to animals the following morning and 1x per day for up to 48 hr post-surgery. Animals should also be monitored daily for prolonged signs of pain, weight loss or surgical site infections.

6. Subsequent Wound Measurements and Dressing Changes

1. Measure ischemic and non-ischemic wounds frequently under general anesthesia using isoflurane at 3%-4% via an induction chamber and maintained (via a nose cone) at 1%-2% with O₂ as in step 3.1.
2. Remove the dressing gently as to not pull the adhesive from the skin. At this time additional digital photos are taken for wound measurements, topical treatments re-applied, laser Doppler imaging (LDI) or other manipulations performed to suit the investigator’s needs.
3. Apply adhesive and a clean dressing and allow the animal to recover as in step 5.1.

7. Wound Collection and Euthanasia

1. Harvest ischemic and non-ischemic wounds (on days the investigator deems appropriate) while the animal is under general anesthesia using isoflurane at 3%-4% via an induction chamber and maintained (via a nose cone) at 1%-2% with O₂ as in step 3.1.
2. Using a scalpel, make a square shaped excision around the wound to include some healthy tissue around the wound. Place the excision into a 1.5 ml snap cap tube and snap freeze in liquid nitrogen (store at -80 °C) for future molecular analysis or incubate in 10% buffered formalin O/N at RT for histological processing.
   NOTE: The wound excisions can also be cut in half to provide more samples for analysis.
3. After wound tissue removal, euthanize the animal using the approved method of CO₂ inhalation.

Results

The rat ischemic wound healing model protocol should take approximately 20 min per animal if performed efficiently. Prior to application of a dressing the model should appear as represented in Figure 1G. It will be important to verify that the bipedicled flap and wounds therein are ischemic. Subcutaneous oxygen tension (PscO₂) at the level of the wounds has been measured during validation of this model⁵ by placing a polarographic electrode in the subcutaneous tissue between the...

Discussion

Wound healing in rats has often been the subject of debate due to their ability to heal infected wounds and high rate of interanimal variability⁵. One of the original goals of the model during its development was to decrease this variation. Modifications to the width of the flap, reducing the number of wounds with specific placement (centered on the flap with consistent cranio-caudal location) and introduction of a silicone sheet has accomplished this goal. Wound healing by contraction has also been reduced an...

Materials

Name	Company	Catalog Number	Comments
Sil-Tec medical grade sheeting	Technical Products Inc.	500-3	nonreinforced, 0.01 inches in thickness
Mini Iris scissors, 8 cm, curved, SS	World Precision Instruments	#503671
Ethilon Nylon Sutures	Ethicon	1964G	black, size 4.0, PC-3 16 mm needles (3/8 circle)
Laser Doppler Imager	Moor Instruments	moorLDI2-IR	Standard blood flow imager: http://us.moor.co.uk/product/moorldi2-laser-doppler-imager/8
ImageJ	NIH	free download	http://rsb.info.nih.gov/ij/
Mastisol	Henry Schein	Cat # 7289210	Fisher Scientific NC9774929
Tegaderm	Medical Specialties	3M1624W	Fisher Scientific NC9922128