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This paper presents a protocol to assess the dysfunction of the cardiac endothelial barrier after being exposed to MIRI. It should be noted that there are several crucial steps in this protocol that determine the reliability and accuracy of the results. All steps involving FITC-dextran are to be performed in a dark room. The FITC-dextran/saline solutions must be stored at 4 °C and wrapped with tin foil. Additionally, coronary arteries must be ligated, as illustrated in Figure 1, so that the myocardium can be reperfused immediately after the loop is loosened. Researchers can choose 5-0 or 6-0 polyethylene sutures because thinner strings under 7-0 are more likely to cut myocardial fibers and vessels. Importantly, the tracer solution should be injected into the femoral veins and not the tail veins. Each heart should be well-perfused and well-rinsed with ice-cold saline before and after being sacrificed, respectively.
Many researchers specializing in MIRI are inclined to study the disrupted subcellular structure of the endothelium in the earlier stage of myocardial reperfusion-the formation of apoptotic bodies, swelling mitochondria, and abnormal intercellular junctions-to prove the hyperpermeability of the endothelium via electron microscopic examination. Immunoblotting has also been used to measure microvascular permeability because the decrease in levels of tight conjunction proteins is regarded as the core mechanism of endothelial injury and malfunction of endothelial barrier over time. For instance, VE-cadherin20 and β-catenin21 are key elements of endothelial cell-to-cell adhesion junctions, and these connections contribute to the maintenance of vascular integrity22. Tight junctions, such as JAM-A23,24 and occludin25, also cooperatively participate in the construction of the endothelial barrier in the circulatory system.
Currently, an increasing number of studies suggest that mitochondrial function and mitochondrial homeostasis could be key targets of protective pathways against reperfusion injury. As reported in pathophysiological and pharmacological studies, mitophagy can play an important role in the cellular death of the endothelium and myocardium induced by IR26. In addition, mitochondrial fission, mitochondrial proteostasis, and mitochondrial quality control may protect high-risk myocardium in reperfused areas27,28. The above methods focus more on demonstrating different mechanisms or causes of hyperpermeability than on displaying endothelial permeability directly and visually. Moreover, sample preparation for electron microscopic examination is complicated and dangerous. Glutaraldehyde, acetone, and osmic acid solutions used in electron microscopy probably volatilize and erode the mucosa, conjunctiva, and skin, even threatening lives if used in uncontrolled environments.
Compared to these indirect and life-threatening methods, this method, which measures the fluorescence intensity emitted by FITC-dextran extravasation, is ideal for assessing cardiac microvascular permeability. First, 70,000 Da FITC-dextran cannot penetrate through the endothelium under normal physiological conditions but can enter the myocardial interstitial space under IR, which allows a clear differentiation between rats under different treatments. Additionally, the FITC-dextran solution is injected into the blood via the femoral veins, which guarantees that all of the fluid is injected into the rat's circulation. In contrast, tail vein injection is more difficult in rats because the tail vein is indistinct and covered with a thick stratum. Further, unlike regular paraformaldehyde fixation and paraffin embedding, myocardial tissue treatment is simplified and optimized using the quick-freeze pathological section technique used in this study. Short storage time, light-proof environment, and cryopreservation may together alleviate fluorescence quenching of FITC.
More importantly, this method can minimize selection bias during statistical analysis. We perform sufficient heart perfusion with saline to ensure that nearly all the blood mixed with FITC-dextran is douched out from the myocardium and the heart chambers, which can eliminate the fluorescence emitted by any FITC remaining in the vessels. If this is not the case, fluorescence merged with capillaries should be excluded and trimmed artificially. While collecting tissue from areas of interest, no visual boundary was observed between the ischemic myocardium and the remote myocardium, especially after EB dye staining. This hindered the collection of samples from these representative areas. Using the method described herein, researchers can obtain images of whole sections and analyze the fluorescence intensity using a quantitative slider scanner.
Interestingly, EB dye can be an alternative, albeit suboptimal, to FITC-dextran. Compared with the relatively harsh storage conditions of FITC-dextran, EB powder or its solution can remain stable at room temperature for a long time. Additionally, EB is relatively inexpensive for most institutions. Nonetheless, certain disadvantages could limit its application. First, EB staining shows lower sensitivity than FITC-dextran, which may underestimate the differences among groups and increase the sample size of each group. Besides, EB shows stronger adhesion to proteins. The endocardium and epicardium are more easily stained by EB, which can influence the results of fluorescence density. Further, obvious filling defects in the reperfusion area remarkedly reduce the image quality, which can limit the use of EB.
To extend the application of this method in an MI model, the method was tested in an MI model. First, FITC-dextran was injected into blood vessels after LAD ligation. As expected, a low level of fluorescence was emitted from the slice because FITC-dextran in blood flow cannot pass through the ligated site, and no FITC-dextran entered the ischemic area. FITC-dextran was also applied 5 min before ligation to ensure the passage of FITC-dextran into all organs. Consequently, FITC-dextran failed to penetrate the microvascular endothelium probably because no perfusion pressure in ligated blood vessels can drive FITC-dextran through the endothelium. Generally, this method probably requires significantly more modification to satisfy its application in the MI model.
Despite the above advantages, there are limitations to this method. First, this protocol was not tested in IR models of other animals, which may limit its application in preclinical and clinical studies. Second, FITC-labeled dyes are more expensive than other common dyes such as EB. However, unlike EB, as 10% w/v FITC-dextran solution, diluted with serum, rarely changes the color of the myocardium, FITC-dextran staining and EB/2,3,5-triphenyltetrazole chloride (TTC) dual staining may be conducted in the same heart, which can trim the budget with respect to the number of animals and the dyes used. Last, the slide scanner used in this study-the Quantitative Slide Scanner and similar instruments-may not be available in some laboratories. In summary, this protocol presents a simplified, reliable, and visual method for the detection of cardiac microvascular endothelial permeability in an IR model in rats using a fluorescence assay based on an automated quantitative pathology imaging system. This protocol demonstrates that 70,000 Da FITC-dextran performs better than EB in the functional assessment of the endothelial barrier of cardiac microvessels after IR injury.