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Real-time Digital Imaging of Leukocyte-endothelial Interaction in Ischemia-reperfusion Injury (IRI) of the Rat Cremaster Muscle

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Summary

Digital intravital epifluorescence microscopy of postcapillary venules in the cremasteric microcirculation is a convenient method to gain insights into leukocyte-endothelial interaction in vivo in ischemia-reperfusion injury (IRI) of striated muscle tissue. We here provide a detailed protocol to safely perform the technique and discuss its applications and limitations.

Cite this Article

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Thiele, J. R., Goerendt, K., Stark, G. B., Eisenhardt, S. U. Real-time Digital Imaging of Leukocyte-endothelial Interaction in Ischemia-reperfusion Injury (IRI) of the Rat Cremaster Muscle. J. Vis. Exp. (66), e3973, doi:10.3791/3973 (2012).

Abstract

Ischemia-reperfusion injury (IRI) has been implicated in a large array of pathological conditions such as cerebral stroke, myocardial infarction, intestinal ischemia as well as following transplant and cardiovascular surgery.1 Reperfusion of previously ischemic tissue, while essential for the prevention of irreversible tissue injury, elicits excessive inflammation of the affected tissue. Adjacent to the production of reactive oxygen species, activation of the complement system and increased microvascular permeability, the activation of leukocytes is one of the principle actors in the pathological cascade of inflammatory tissue damage during reperfusion.2, 3 Leukocyte activation is a multistep process consisting of rolling, firm adhesion and transmigration and is mediated by a complex interaction between adhesion molecules in response to chemoattractants such as complement factors, chemokines, or platelet-activating factor.4

While leukocyte rolling in postcapillary venules is predominantly mediated by the interaction of selectins5 with their counter ligands, firm adhesion of leukocytes to the endothelium is selectin-controlled via binding to intercellular adhesion molecules (ICAM) and vascular cellular adhesion molecules (VCAM).6, 7

Gold standard for the in vivo observation of leukocyte-endothelial interaction is the technique of intravital microscopy, first described in 1968.8

Though various models of IRI (ischemia-reperfusion injury) have been described for various organs, 9-12 only few are suitable for direct visualization of leukocyte recruitment in the microvascular bed on a high level of image quality.8

We here promote the digital intravital epifluorescence microscopy of the postcapillary venule in the cremasteric microcirculation of the rat 13 as a convenient method to qualitatively and quantitatively analyze leukocyte recruitment for IRI-research in striated muscle tissue and provide a detailed manual for accomplishing the technique. We further illustrate common pitfalls and provide useful tips which should enable the reader to truly appreciate, and safely perform the method.

In a step by step protocol we depict how to get started with respiration controlled anesthesia under sufficient monitoring to keep the animal firmly anesthetized for longer periods of time. We then describe the cremasteric preparation as a thin flat sheet for outstanding optical resolution and provide a protocol for leukocyte imaging in IRI that has been well established in our laboratories.

Protocol

1. Anesthesia and Monitoring

  1. Appropriate national and institutional ethics should be in place before performing animal experiments. Following approval from the ethics committee anesthetize male Sprague Dawley rats with a body weight from 120 - 180 g. Deliver 2 - 3 vol% isoflurane to a Plexiglas box via isoflurane vaporizer and place the rat inside.
  2. As soon as the appropriate level of anesthesia is achieved (lack of reaction to toe or tail pinch) the rat is weighted and shaved on the ventral cervical area.
  3. Place the rat in dorsal recumbency on a heating pad to maintain body temperature at 37 °C and apply isoflurane at 2 vol% using a silicone mask.

The following preparation steps are best accomplished using a surgical microscope.

  1. For the preparation of the trachea, the carotid artery and the jugular vein, perform a 2 cm horizontal skin incision in the area of the suprasternal notch and mobilize the salivary glands laterally.
  2. You now face the ventral neck muscles. Carefully separate them in the midline and find the trachea. Expose 1 - 2 cm of the trachea and place a micro forceps under it so as to raise it up.
  3. Now slit about halfway through the ventral side of the trachea. Be careful not to cut all the way through, if you do, the cut end of the trachea will slip back into the chest and be very difficult to work with.
  4. Insert an Abbocath tube (14G) used as tracheal tube into the lower part of the trachea, which has previously been connected to an animal ventilator. Tip: Firm fixation on magnet clamps as well as suturing of the trachea around the tube is essential to keep the tracheal tube in place. Generally we use Terylene 5/0 suture, however similar suture material can be used.
  5. Respiration can then be volume controlled (frequency, 35 - 45 breaths/minute; tidal volume, 4.5 - 5 ml; FiO2, 0.35 - 0.50; Isoflurane 1.5 - 2 vol%).14 Atelectasis can be prevented by maintaining a positive end-expiratory pressure of 5 to 10 mm of H2O.15
  6. For the carotid canulation, the right sternohyoid muscle is separated by blunt dissection to locate the carotid artery.
  7. Separate the vagus nerve carefully from the carotid artery and mount the artery on an angled micro forceps to stop blood flowing from the heart.
  8. Pass two pieces of equal length of suture beneath the carotid artery. In reference to the heart, the more distal suture is tied tightly to occlude blood flowing from the head region whereas the proximal suture is tied loosely around the carotid artery.
  9. Using micro scissors a small cut is made into the carotid artery between the two ligatures.
  10. Insert a polyethylene catheter (0.28 mm inner diameter) filled with normal saline solution that is connected to a pressure transducer.
  11. Remove the micro forceps and thread the catheter further into the artery. Then tighten the proximal ligature around the artery and catheter. Tip: Application of a second proximal suture prevents bleeding after removing the micro forceps.
  12. Tie the distal ligature around the carotid and the catheter for additional anchorage.
  13. Monitor anesthesia continuously by monitoring heart rate and arterial pressure. Perform intermittent arterial blood gas analyses using a blood gas analyzer.16 A heart rate lower than 300 bpm or exceeding 360 bpm as well as a mean arterial pressure dropping below 80 mmHg for longer than 5 minutes are criteria for exclusion.17, 18 Maintain blood pH within physiological limits (7.35 - 7.45). In case the experiment has to be terminated due to abnormal monitoring rates, scarify the animal by neck dislocation or exanguation.

For the intravenous application of fluorescent dyes or other drugs of interest, perform the following:

  1. Focus the area of the left jugular vein with the surgical microscope.
  2. With forceps in each hand, tear the thin fascia to reveal the jugular vein. Mount the vein on an angled micro forceps. Blood flow will then stop.
  3. Using forceps, two pieces of equal length of suture are passed under the jugular vein concordant to the carotid canulation. Tie the distal suture tightly and the proximal suture loosely around the jugular vein.
  4. Make a small cut into the jugular vein and insert a polyethylene catheter (0.28 mm inner diameter) that has been flushed with saline. Mark that incision and canulation can be more demanding and time consuming than that of the carotid.
  5. Thread the catheter toward the heart and tighten the ligature closest to the heart around the vein and the catheter.
  6. After conforming patency, tie distal ligature around the catheter. Tip: Additional fixation of both catheters with tape may prevent dislodgment.
  7. Rinse catheters frequently to prevent intraluminal clotting.

2. Preparation of the Cremaster Muscle

  1. We use an aluminium stage of 1.5 - 2 cm thickness for cremasteric imaging. The stage rapidly adopts the desired temperature of the heating pad thus alleviating thermal control of the cremasteric tissue. This is crucial for inflammation studies. Alternatively a Plexiglas platform may be used though regulation of cremasteric temperature is more difficult. Place the scrotum in the centre of the stage.
  2. The initial incision is made in the skin and external spermatic fascia above the scrotum in the very distal end followed by cautious dilatation of the subdermal space using fine scissors. Avoid touching the underlying tissue with the instruments.
  3. As soon as the tissue is exposed it is moistened with pre-heated (37 °C) phosphate buffered saline solution with calcium and magnesium. Apply the solution regularly to any exposed tissue.
  4. Connective tissue between the external spermatic fascia and the cremaster muscle is carefully removed to free the cremaster muscle from surrounding tissue.
  5. The exterior surface of the cremaster muscle is then cautiously cleared of connective tissue. Continuous superfusion during dissection hydrates the connective tissue, facilitating visibility and removal.
  6. Suture the distal end of the cremaster sack to hold down and slightly extend the end of the sack.
  7. Incise the distal end of the sack on the ventral aspect and elongate the incision proximally using micro scissors. Carefully cauterize bleeding vessels along the incision lines utilizing a thermal cautery. Avoid unnecessary cauterization to limit additional inflammatory stimuli. Tip: Blood flow dynamics near the periphery of the preparation are altered by this tissue damage.19 Therefore, to minimize these affects on data collection, blood vessels near the center of the preparation should be used for imaging.
  8. The open cremaster lies flat on the aluminum pedestal though still connected by a thin ligament to the epididymis underneath the testicle. Reflecting the testicle to one side exposes this ligament including a small artery and vein which connect to the epididymis. Use the cautery to seal the vessels and employ the micro scissors to cut the connective ligament between testicle and cremasteric tissue.
  9. Gently push back the isolated testicle into the inguinal canal. Other authors resect the testicle after proximal ligature (orchiectomy) along with the associated inguinal fad pad.20 In a sensitive model as IRI induced leukocyte activation we try to avoid all additional surgical stimuli, therefore we refrain from resecting the testis, which is usually not necessary to get sufficient exposure of the cremaster muscle.
  10. In addition to the first fixation suture four edges of tissue (two on each side) and attach the threads to tapes to cautiously spread the cremasteric tissue radially on the aluminum stage. Leaving a gap between the aluminum stage and the external entrance of the inguinal canal simplifies subsequent cremasteric clipping for ischemia.
  11. Place two ends of polyethylene catheter (0.28 mm inner diameter) close to the cremasteric tissue for the superfusion setup. Make sure that the lumen is free of air to avoid air bubbles in the eventual fluid chamber.
  12. Draw a line of petroleum jelly (Vaseline) around the cremaster muscle using a syringe. The line must extend the size of the cover slip that is used for coverage.
  13. To create a fluid chamber, place a square cover slip (32×32 mm) over the cremasteric tissue and firmly attach the edges to the Vaseline line.
  14. In case the cremasteric tissue is not superfused with a specific drug, continuous replacement of the surrounding fluid is nonessential. A single application of phosphate buffered saline solution with calcium and magnesium into the created chamber may then be sufficient. Local stimulation with drugs however should be performed continuously via micro-perfusion pump at a rate of 3 ml per hour.
  15. The cremasteric tissue is now ready for microscopic imaging.

3. Intravital Setup

The basic intravital setup may vary. For epifluorescence imaging the experiments should be executed in a dark room.

  1. The animal is transferred to the stage of an intravital epifluorescence microscope equipped with a 470 nm LED luminous source for epi-illumination. Use a water immersion objective (20×/1.0) to achieve magnification of approximately 800×. Record observations by means of a high resolution digital camera and store records on a personal computer for offline evaluation.
  2. For leukocyte labeling, inject rhodamine 6G intravenously via the jugular catheter at concentrations of 0.4 mg/kg body weight.
  3. Choose a postcapillary venule for observation. Vessel size should range between 20-60 μm and blood flow should be sufficient. To minimize the influence of pre-activation of the tissue, only vessels in which leukocyte rolling is <20 cells/30 seconds and the number of adherent cells <10 cells/200μm of venular endothelium may be utilized for further analysis.
  4. If possible, up to three postcapillary venules can be used for observation; however they should be located in a corresponding section of the cremasteric tissue to avoid confusing the vessels at different time points.

4. Ischemia-reperfusion Injury (IIR)

  1. Let tissue stabilize for 30 minutes.
  2. Perform a recording of 30 seconds to establish basal values for leukocyte rolling and adherence. Ideally, generate in total three basal recordings to verify cell numbers and to obtain standard deviations.
  3. Gently place a Biemer vessel clip around the very proximal end of the exposed cremasteric tissue by using the application forceps. Stasis should occur immediately and can be visualized by epifluorescence microscopy in the observed vessel section.
  4. A variety of time courses can be utilized depending on the level of damage required. We apply 30 minutes of ischemia time as described by other authors.21-23 Remove the vessel clamp afterwards. Allow blood stream to stabilize for another 15 minutes.
  5. Subsequent recordings of 30 seconds duration can be made throughout the reperfusion period (e.g. 30 seconds every 15 minutes). Save recordings digitally for offline analysis.
  6. For the termination of the experiment, the rat is euthanized by cervical dislocation under sufficient anesthesia by pressing a blunt instrument such as the dull edge of a scissor blade at the base of the skull. With the other hand, the base of the tail is quickly pulled, causing separation of the cervical vertebrae from the skull.

5. Offline Video Playback Analysis

  1. For offline video playback analysis it is helpful to use software that allows selection of distinct pictures and observation of the video sequence in slow motion. Adjust contrast and brightness appropriately. We use software provided by the manufacturer of the microscope that allows length measurements and digital magnification.
  2. For the quantification of leukocyte rolling, define a virtual line that intersects the vessel vertically that is consistent in all records. Count the number of rolling leukocytes that pass the line within 30 seconds manually.
  3. For the quantification of adherent leukocytes, define a 200 μm vessel section that is consistent in all records.23 Count the number of clearly visible leukocytes that remain static during 30 seconds - thus defined as adherent.24

6. Representative Results

IRI of the cremaster muscle has no effect on mean arterial pressure (MAP), heart rate and blood pH

Using the aforementioned setup (Figure 1), we investigated the microcirculation in IRI over a two hours protocol; however a much longer observation time up to 6 hours is possible. As shown in Figure 2, IRI of the cremaster muscle has no significant macrohemodynamic effects on the rat circulation as mean arterial pressure and heart rate remain stable throughout the investigation period. Furthermore we monitored homeostasis by frequent measurements of the arterial blood-pH that ranged within physiological limits and showed no significant inter-group differences.

IRI induces leukocyte rolling in the cremasteric circulation

Leukocyte endothelial interaction is a key event in the acute inflammation. By means of intravital microscopy we found a time-dependent increase in the number of rolling leukocytes in IRI of the cremaster muscle (Figure 3A) concordant to previous data 21, 25. Rolling mounted over the two hours observation time to a maximum of 137.63 ± 22.55 % of the baseline value after 120 minutes of reperfusion time and then reached statistical significance compared to sham operated animals (137.63 ± 22.55 vs 99.43 ± 14.04 % of baseline value).

IRI induces leukocyte adhesion in the cremasteric circulation

For further evaluation of leukocyte-endothelial interaction we analyzed leukocyte adhesion in a 200 μm vessel section. IRI induced an increase in the number of adherent leukocytes that significantly exceeded values of sham operated animals after 60 minutes (118.33 ± 6.83 vs. 96.27 ± 5.78 % of baseline value) and further ascended by 120 minutes of reperfusion (Figure 3B).

In summary the described in vivo model supplies consistent data of acute leukocyte activation in IRI whilst animal survival and circulation stability is warranted.

Figure 1
Figure 1. A. Flow chart for intravital epifluorescence microscopy performance in ischemia-reperfusion injury of the rat cremaster muscle. Following required preparations for anesthesia and monitoring, the rat cremaster muscle is exposed for imaging. Records of leukocyte activation are taken before and after tissue ischemia. Subsequent video analysis is best performed offline. B. Schematic figure on the proposed intravital setup. Click here to view larger figure.

Figure 2
Figure 2. IRI of the cremaster muscle has no effect on mean arterial pressure (MAP), heart rate and blood pH. Mean arterial pressure (A) and heart rate (B) were monitored every 30 minutes throughout the experiment via pressure transducer after canulation of the right carotid artery. Measurement of the arterial blood-pH (C) was performed after 0, 60, and 120 minutes. Values are mean ±SEM of 6 different rats and ranged on physiological levels without significant inter-group differences. Click here to view larger figure.

Figure 3
Figure 3. IRI increases leukocyte-endothelial interaction in the cremasteric circulation. After labeling of leukocytes with rhodamine 6G (0.4 mg/kg body weight) intravital epifluorescence microscopy was used to determine leukocyte-endothelial interaction in reperfusion injury over a 120 minutes protocol after 30 minutes of tissue ischemia. Records were taken at magnification of approximately ×800. A. IRI significantly increases the number of rolling leukocytes in postcapillary venules of the cremaster muscle by 120 minutes of reperfusion whereas leukocyte rolling remains stable throughout the experiment in cremasteric tissue that did not undergo ischemia. Values are mean ± SEM of 6 observed rats. # p<0.05 using the unpaired t test. B. The number of adherent leukocytes is significantly increased in a randomly chosen 200μm postcapillary vessel section after 30 minutes of cremasteric ischemia and subsequent 60 minutes of tissue reperfusion. Results get even more pronounced after a two hours reperfusion period. Values are mean ± SEM of 6 observed rats. # p<0.05 using the unpaired t test. C. Representative pictures of a postcapillary venule prior to ischemia (left) and 120 minutes after IRI (right). Click here to view larger figure.

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Discussion

Leukocyte-endothelial interaction, production of reactive oxygen species and activation of the complement system are the key features of IRI-induced tissue dysfunction.26 The microcirculation of the affected tissue is considered as the integral site for the inflammatory onset. Apart from ex vivo experiments such as flow chamber assays27, 28 it is mandatory to provide well-established models of intravital imaging to further evaluate the in vivo relevance. Though IRI has been implicated in various organ systems, we here describe a method to systematically examine leukocyte-endothelial interaction in reperfusion injury of striated muscle tissue that was first described by Baez et al 13, thus particularly relevant in flap surgery (Figure 1).29 As it is assumed that post-ischemic tissue injury of other organs involves the same inflammatory mechanisms, the described model can be used to gain principle insights into pathophysiological mechanisms of IRI, relevant in conditions such as myocardial infarction, cerebral stroke or intestinal ischemia.

Animals used

The model presented here is suitable for most rodents including rats and mice. For the long period of imaging that is necessary in this model we generally prefer rats as tracheotomy and volume controlled respiration can be easily performed. In combination with cardiovascular imaging via arterial canulation, rats can be kept circulatory and homeostatically stable for hours (Figure 2). Furthermore cremasteric tissue is more extensive in rats than it is in mice leaving more options for postcapillary imaging. Although tissue preparation might be easier preformed in lager rats, one should consider that cremasteric tissue and especially the cremasteric fascia is thinner in young rats (100 -150 g) thus reducing background fluorescence and overlay of additional fascial tissue. However an advantage of using mice for intravital microscopy is the availability of transgenic animals, invaluable to elucidate the role of individual genes in modulating microcirculatory events.

Tissue types

Since first described, intravital microscopy has been used in a variety of microcirculatory preparations including the master cheek pouch, rabbit ear, rodent mesentery, and cremaster. One main drawback associated with most of these preparations is the potential activation of cells by surgical manipulation accompanied with a transient increase in rolling and adherent leukocytes that has been well described for the mesentery.30 Cremasteric preparation has therefore to be carried out with extreme care. To our experience, frequent moistening of the exposed tissue and restrictive cauterization as well as a sufficient tissue stabilization period of at least 30 minutes helps to avoid or reduce leukocyte stimulation.

A major advantage of cremasteric imaging over mesenteric imaging is the easy accessibility that spares opening of the abdominal cavity. Overall surgical trauma is reduced and mounting on either a Plexiglas viewing stage for transmitted illumination or, as utilized our protocol, a thermal controlled aluminum platform for epi-illumintaion is easily performed. Furthermore, fat that collects around postcapillary venules in older animals limiting mesenteric imaging is absent around the cremasteric tissue.

Leukocyte labeling

Reagents such as rhodamine 6G31, acridine orange or acridine red which stain nuclei and/or intracellular organelles that are not found in red blood cells accumulate selectively in leukocytes (and to some degree in platelets and endothelial cells).32 We prefer using rhodamine 6G for leukocyte detection at concentrations of 0.4 mg/kg body weight, which has previously been shown to have no significant effect on activation of neutrophils.33 Acridine orange showed much more background stain and phototoxicity by means of arteriolar vasoconstriction (unpublished observations). The utilization of LEDs for fluorescence imaging provides precise excitation spectra and allows more complex applications such as the combination of different wavelengths e.g. for the detection of leukocyte activation and capillary leakage at the same time and should therefore be the method of choice in the future of in vivo imaging.

IRI in cremasteric tissue

Applying ischemia to the cremaster muscle can be easily performed and perfectly reflects clinically relevant conditions such as free flap surgery. Moreover, modifications such as cold ischemia, warm ischemia or cremasteric superfusion with substances influencing inflammation can be easily applied. Intrascrotal injection may be the method of choice when treatment of the cremasteric tissue is needed hours or days before recording.

A variety of time courses for IRI can be utilized depending on the level of damage required. We here describe a model of 30 minutes ischemia to produce significant levels of rolling after two hours of reperfusion (Figure 3) by counting white blood cells passing a fixed point across the vessel. As increase in rolling is moderate it leaves enough potential to stimulate leukocytes in IRI through other drugs of interest. However, a variety of time courses can be utilized depending on the level of leukocyte activation required.21, 25 Leukocyte adhesion is most often measured by counting cells clearly visible in the vessel wall in a 100 - 200 μm stretch that remain stationary for 30 s, although this time can vary among laboratories. We observed a marked increase in the number of adherent leukocytes in IRI that got significant after 60 minutes.

In conclusion intravital epifluorescence microscopy in IRI of striated muscle tissue can be well performed in rat cremasteric tissue as it provides reproducible data of in vivo leukocyte activation for inflammation research.

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Disclosures

No conflicts of interest declared.

Acknowledgments

This work was supported by a grant of the “Deutsche Forschungsgemeinschaft” to S.U. Eisenhardt (EI 866/1-1).

Materials

Name Company Catalog Number Comments
Name of the equipment: Company: Catalogue No.: Comments:
Forene 100% (V/V) Abbot B506 API isoflurane
Terylene Suture Serag Weissner OC108000
Portex Fine Bore Polythene Tubing Smiths Medical 800/100/100 0.28 mm inner Diameter
0,9% saline solution Fresinus Kabi 808771
Change-A-tip deluxe cautery kit Bovie Medical DEL1
Abbocath -T 14G Venisystems G713 - A01 used as lens tube
Servo Ventilator 900C Maquet used as animal ventialtor
Logical pressure transducer Smiths Medical MX1960
Sirecust 404 Monitor Siemens
ABL 700 Benchtop Analyzer Radiometer for blood gas measurement
Heating pad Effenberger 8319
Aluminum stage Alfun AW7022
Surgical microscope OPMI 6-SDFC Carl Zeiss
Microsurgical instruments lab set S&T 767
Biemer vessel clip Diener 64.562
Applying forceps Diener 64.568 for Biemer vessel clip
Rhodamine 6G Sigma-Aldrich R4127
Vaseline white DAB Winthrop 2726853
Cover glasses 32x32 mm
Intravital setup
Zeis Axio Scope A-1 MAT Carl Zeis 490036 epifluorescence microscope
470 nm LED Carl Zeis 423052 fluorescence light source
Colibri 2 System Carl Zeis 423052
W Plan-Apochromat 20x/1,0 DIC Carl Zeis 421452 water immersion objective
AxioCam MRm Rev. 3 FireWire Carl Zeis 426509 high resolution digital camera
Axio vision LE software Carl Zeis 410130 use for offline analysis

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References

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