Molecular Vision 2020; 26:731-741
Received 19 February 2020 | Accepted 13 October 2020 | Published 15 October 2020
Gottfried Martin, Kira L. Wefelmeyer, Felicitas Bucher, Günther Schlunck, Hansjürgen T. Agostini
Eye Center, Medical Center, Medical Faculty, University of Freiburg, Freiburg, Germany
Correspondence to: Gottfried Martin, Universitätsklinikum Freiburg, Klinik für Augenheilkunde, Killianstr. 5, 79106 Freiburg, Germany; Phone: ++49-76127040010; email: email@example.com
Purpose: Retinal vein occlusions (RVOs) are a common disease, but there are no animal models for spontaneous RVO formation. The critical sites of predilection, especially for branch RVO (BRVO), are the arteriovenous crossing sites in the inner retina. To gain more insight into possible animal models, the anatomic structure of retinal arteriovenous crossings was investigated in mice, rats, and pigs and compared to the human situation.
Methods: Retinal flat mounts and paraffin sections of eyes from mice, rats, pigs, and humans were stained with GS lectin, Masson’s trichrome, or immunohistochemistry for ACTA2 and GFAP. Serial sections of arteriovenous crossing sites were investigated.
Results: Mice usually do not show retinal arteriovenous crossings. Rats have a mean of 2.8±1.4 crossings per eye at a mean distance from the optic nerve head of 2.79±0.53 mm, though the diameters of the crossing vessels are small. The situation in pigs is similar to that in humans, with many arteriovenous crossings of vessels and with similar diameters as found in humans. A mean of 28.4±3.5 crossings per retina was found, and 23% of these were arterial overcrossings. Serial paraffin sections showed that the tunica media of the artery touched that of the vein, but they did not fuse.
Conclusions: While the retinal arteriovenous crossings of mice and rats are absent or comprised of rather thin vessels, those in the porcine retina are similar to adult humans. Therefore, the porcine retinal vascular bed may serve as a model to assess early steps in the formation of RVOs.
Retinal vein occlusion (RVO) is a common disease in industrialized countries. Though there are several opinions on how the occlusion develops [1,2], there are only sparse experimental data. As RVO is not usually treated surgically, tissue specimens for laboratory investigations are rare. Therefore, animal models are essential to understand the conditions and the process of RVO formation.
Fundus observations in patients show that branch RVO (BRVO) typically occurs at arteriovenous crossings [3,4], while central RVO (CRVO) occurs within the optical nerve head [5,6]. In human BRVO, the arteriovenous crossing sites were investigated in serial sections showing a close convergence of both vessels with a common adventitia at the crossing site [1,7,8]. In almost all cases of BRVO, the vein resides between the retina and the crossing artery, i.e., the artery is located on top of the vein toward the vitreous. The vein is depressed into the retinal tissue, and its cross section is flattened and broadened to a certain extent. This vascular conformation is a likely cause of turbulent blood flow, which favors thrombus formation. However, surgical separation of the artery and vein after vitrectomy in patients with BRVO did not lead to a significant functional improvement, especially in comparison to intravitreal anti-vascular endothelial growth factor (VEGF) treatment, and it is not recommended anymore .
Current animal models of BRVO depend on experimental occlusion of the vein, either by mechanical means or by robust laser treatment [10,11]. They allow an investigation of the consequences of an RVO, such as hypoxia, microglial activation, and inflammation. They also allow the testing of chirurgical or therapeutic strategies in porcine models [12-14]. In contrast, they do not allow observation of RVO formation. For this purpose, an animal model is favorable where the occlusion is induced by food, pharmacological treatment, or genetic conditions. To select such an appropriate model organism, it is important to characterize the anatomic and histological structure of the arteriovenous crossing sites in the respective species. Whereas vascular corrosion casts were studied in rats and pigs [15,16], in this study, we investigated the histology of arteriovenous crossings in the retina of rats and pigs by serial paraffin sections and compared to those of a human specimen.
Six eight-week-old C57BL/6J mice and Sprague-Dawley rats of the same age were used. They were housed at 24 °C with a 12 h:12 h light-dark rhythm. The eyes were gifts from collaborating groups working with different organs (brain or lung). Eyes from pigs were freshly obtained from a local abattoir. Mice were perfused with PBS (9.1 mM Na2HPO4, 1.7 mM NaH2PO4, 150 mM NaCl, pH 6.8) after death, while rats were not. All animal procedures adhered to the animal care guidelines of the Institute for Laboratory Animal Research (Guide for the Care and Use of Laboratory Animals) in accordance with the ARVO Statement for the Use of Animals in Ophthalmic and Vision Research, and they were approved by the local animal welfare committee (Tierschutzkommission).
A human retinal specimen from an eye that was enucleated due to a uveal carcinoma was used for comparison (female, 72 years). Institutional Review Board (IRB)/Ethics Committee approval had been obtained for specimen acquisition and use and data generation.
Eyes from mice or rats were fixed in 4% formalin for 1–2 h and then transferred to PBS. After a circumferential cut, the anterior part of the eye was removed and the retina was immersed in PBlec (1 mM CaCl2, 1 mM MgCl2, 10 g/l BSA in PBS). GSL1-Lectin labeled with TRITC was added to a final concentration of 5 µg/ml, and the retinas were incubated at 4 °C overnight. After washing, the retinas were mounted on slides.
Eyes from rats were fixed in 4% formalin for 1–2 h and then transferred to PBS. After removing the anterior part including the lens, five sclera and retina cups were arranged as a stack in a small reaction tube in 2% agarose in PBS liquefied at 60 °C. First, some agarose was filled into the tube. Then, a cup was put at the top of the agarose and embedded with additional agarose. This procedure was repeated five times. The agarose block was then embedded in paraffin.
Porcine eyes were freed from adherent tissue and opened by a circumferential cut to remove the anterior part of the eye, including the lens and vitreous. The optic nerve head was cut out by a 6 mm punch. The rest of the posterior part of the eye, including the retina and sclera, was cut into three parts for easier handling. The retina was carefully removed and submerged in PBS. Sites of arteriovenous crossings were cut out using a scalpel under a dissecting microscope and fixed in 4% formalin. After transfer to PBS, the crossing sites were arranged in parallel in 2% agarose in PBS liquefied at 60 °C by the following procedure. In a small syringe from which the tip was cut off, some agarose was filled in. Then, a crossing site was arranged at the agarose surface and covered with agarose. This procedure was repeated for nine additional crossing sites. After cooling, the agarose block was embedded in paraffin. Serial paraffin sections were stained with Masson’s trichrome. The human specimen was treated similarly.
Paraffin sections from pieces of porcine or human retina were pre-selected for the presence of arteriovenous crossings. Staining was performed by standard procedures. After demasking the sections in boiling Tris-EDTA buffer, primary antibodies (monoclonal mouse anti-vascular smooth muscle actin [ACTA2], clone 1A4, A2547, Sigma, Taufkirchen, Germany, 1:2,000; or polyclonal rabbit anti-glial fibrillary acidic protein [GFAP], RB-087-A0, Thermo Fisher Scientific, Germany, 1:2,000) were followed by biotinylated secondary antibodies, avidin coupled with alkaline phosphatase, and Vector Red AP Substrate Kit I, (Vector Labs, Burlingame, CA). Sections were counter-stained with hematoxylin.
The inner retinal vasculature in mice typically consists of four to six main arteries and four to six main veins (Figure 1A and Appendix 1). Arteries and veins originate from the optic nerve head and extend radially in an almost equiangular alternating fashion. The corresponding areas of arterial and venous capillaries typically do not overlap but are arranged side by side. Sometimes, a small vein has a small area of venous capillaries that does not reach the periphery. In this case, the remaining venous area is drained by a peripheral arc of a neighboring large vein (Figure 1A). The same is true when a larger artery branches so that the venous area between the two branches is drained from a peripheral vein. In this way, the typical murine retina does not show arteriovenous crossings.
Although the arrangement of retinal arteries and veins in rats is similar to that in mice, some arteriovenous crossings are present. The distribution of arteriovenous crossings was determined in 29 flat mounted retinas of rats. The mean number of crossings per retina was 2.8±1.4 with a range of 1–5. The mean distance from the optic nerve head was 2.79±0.53 mm with a range of 1.3–3.7 mm, while the distance from the optic nerve head to the border of the retina was around 4.5 mm. This means that most crossings are at a distance of two-thirds of the retinal width from the optic nerve head (Figure 1). Most arteries and veins run radially, alternating in a spoke wheel-like arrangement equivalent to the situation in mice. Therefore, the central part of the retina is sufficiently supplied with blood. However, as the retina of rats is larger than that of mice, not all peripheral venous areas that are located between two arterial branches or between two arteries separated by a short vein are drained by a peripheral arc of a large neighboring vein. Instead, veins are crossing arteries. Accordingly, more crossings were found in retinas with a small number of veins. The rather large distance of the crossings from the optic nerve head implies that the crossing vessels are rather small in diameter with a thin wall and thus unlikely to form a compressive RVO.
The spatial position of the artery in relation to the vein was determined by carefully focusing the microscope. The artery was above the vein (toward the vitreous) in 44% of the crossings in rats.
In porcine retinas, many arteriovenous crossings were found in a large variety of distances from the optic nerve head (Figure 2). Accordingly, the diameter of the vessels at the crossing sites varied widely. This is similar to the situation in humans. In total, 28.4±3.5 crossings per retina (mean ± standard deviation) were found in five pig eyes, and 23±11% of these were arterial overcrossings. Veins dive into the inner layers of the retina at small ramifications, mainly in the periphery. In these cases, it is sometimes difficult to see whether there is a crossing with the artery touching the vein or if it is simply an underpinning with a greater distance of both vessels. As a consequence, the percentage of true arterial overcrossings may be even smaller.
Serial paraffin sections were prepared to enable a closer look at the retinal arteriovenous crossing sites. Examples from the rat retina are shown in Figure 3 and Appendix 2 and Appendix 3. At the contact site, the artery and the vein seem to share a common vessel wall. No neuronal tissue was found between both vessels. Arterial overcrossings were observed in three out of nine crossing sites investigated in serial sections. The crossing vessels are rather small in diameter so that the crossings locate to the nerve fiber layer or ganglion cell layer and do not extend to deeper retinal layers, as is the case in larger animals, such as pigs or humans.
The arteriovenous crossing sites of larger vessels in the porcine retina show a typical composition known from human crossing sites. The tunica media layers of the artery and vein are intensely stained blue by trichrome staining (Figure 4, Appendix 4, Appendix 5, Appendix 6 and Appendix 7). or red by immunostaining for ACTA2 (Figure 5 and Appendix 8), and they are in close contact with no neuronal tissue in between, as shown by immunostaining for GFAP, an intermediate filament mainly expressed in astrocytes and also in Müller cells. GFAP staining was outside of this wall, and both formed a sharp border with no intermediate tissue (Figure 5). At the center of the arteriovenous crossing site, the media of the artery touched the media of the vein without fusion of both. In some cases, the neuronal tissue around the vessels appears loose so that the vessels may be surrounded by a common tunica adventitia. This is in accordance with a higher density of astrocytes immunostained by GFAP around the vessels (Figure 5). These features are similar to the human situation (Figure 6, Appendix 9 and Appendix 10).
Some differences between pigs and humans are as follows. While the ACTA2 staining covers the whole thickness of the porcine media, the staining is restricted to one or (in larger vessels) two rings in the human specimen. The cross-sectional areas and shapes usually did not change at porcine crossing sites. Only in cases where vessel diameters were highly different was some flattening or compression of the small vessel observed within the crossing area. This flattening was only visible in perpendicular cross sections of the small vessel. In human arterial overcrossings, the artery usually slightly impinges on the vein, resulting in a heart-shaped venous cross section (Figure 6). In addition, porcine vessels are positioned more superficially, within the nerve fiber layer and often extending into the vitreal space, whereas the human vessels are running within the ganglion cell layer. At the crossing site, the overlaying porcine vessel, usually the vein, deviates into the vitreal space, whereas the underlying human vessel, usually the vein, deviates toward the outer layers of the retina. Arterial overcrossing was observed in five of 27 (19%) porcine crossing sites investigated by serial sections. In the human specimen, six of seven (86%) crossing sites investigated by serial sections were arterial overcrossings. These differences should be considered when choosing an animal model.
RVO is a common disease in industrialized countries, and BRVO is more common than CRVO . BRVO was found to occur at arteriovenous crossing sites and is restricted almost exclusively to arterial overcrossings [4,18].
Arterial overcrossings are more common in humans (67% to 71% of crossings) and are almost exclusive at BRVO sites (97.6%) . In human eyes with BRVO, the arteries at the occlusion site are overlaying the vein toward the vitreous at 99% of arteriovenous crossings, whereas at other crossing sites, the artery is anterior to the vein in around 60% of the crossings . In another study, arteries were anterior to the vein, toward the vitreous cavity, at all BRVO sites in 26 eyes examined, while in a control group, the artery was anterior to the vein 65% of the time . The values of 44% of arterial overcrossings in flat mounts and 33% in retinal sections of rats, as well as 23% of arterial overcrossings in flat mounts and 19% in retinal sections of pigs were somewhat smaller. Similar ratios were reported earlier in studies of retinal vascular corrosion casts for rats  and for pigs . The small value for pigs is a feature of the porcine species and must be considered when selecting a model species.
RVOs were reported to occur most commonly in the superotemporal quadrant and second-most commonly in the inferotemporal quadrant of the human retina within a distance of three disc diameters (6 mm) from the optic disc [18,21-23]. In the superotemporal quadrant, a greater proportion of crossings were vein-posterior than in the inferotemporal quadrant , which may explain the distribution of RVOs. In pigs, no RVOs were reported, so there is no distribution of occlusion sites. In our study, the distribution of arteriovenous crossings was investigated in retinal flat mounts of rats but not pigs because of high distortions from flattening spherical tissues, and it is unknown if this is relevant to BRVO.
An arteriovenous crossing implicates that both vessels converge. In pigs, the tunica media of the vein and that of the artery touch at the center of the crossing site but do not fuse. There is no space left for neuronal tissue, as indicated by GFAP immunostaining. This fits the situation in humans and is in agreement with earlier histological reports [1,8]. Some of these reports also describe that arteries and veins have a common adventitial sheath at the crossing site. A slightly denser mesh of GFAP-positive filaments was observed in our study in pigs and humans that may be interpreted as a tunica adventitia. Thickening of the tunica media or other layers of the vessel wall at the crossing site, as described in earlier reports , was not observed in our study.
At arterial overcrossing sites in humans, the artery is straight while the vein is dipping into the retina to pass under the artery [1,25]. Other studies did not report such retinal vein dipping , so it is unclear whether this feature is important to RVO formation. In this study, we observed this feature at arteriovenous crossing sites in humans but not in pigs. In the latter, the artery rather deviates into the vitreous. This is related to the finding that the large vessels near the optic nerve head are on top of rather than within the retina . This porcine feature must be considered when selecting a model species.
A good model species for the study of human RVOs should represent as many of the typical histological features at the arteriovenous crossing site as possible. Important features are the thickness and structure of the vessel walls, as well as the position and course of the vessels within the retina. In addition, it might be worth studying arteriovenous crossings in a primate species that has a macula. The streak-shaped macular area of pigs contains no major vessels, but unlike the central fovea in the human eye, it is not completely avascular .
The histological aspect of the arteriovenous crossings in pigs is quite similar to that reported in humans. In contrast, arteriovenous crossings in rats are rare and located more peripherally, resulting in crossings of only small vessels. This is not typical in the human situation. Arteriovenous crossings in mice are usually missing. In conclusion, though a primate model might be an even better choice, the retinal arteriovenous crossings in pigs seem to be attractive sites to observe spontaneously occurring early stages of RVO.
Appendix 1. Murine and rat retinal flat mounts.
Appendix 2. Rat retinal arteriovenous crossings.
Appendix 3. Rat retinal arteriovenous crossings.
Appendix 4. Porcine retinal arteriovenous crossings.
Appendix 5. Porcine retinal arteriovenous crossings.
Appendix 6. Porcine retinal arteriovenous crossings.
Appendix 7. Porcine retinal arteriovenous crossings.
Appendix 8. Porcine retinal arteriovenous crossings.
Appendix 9. Human retinal arteriovenous crossings.
Appendix 10. Human retinal arteriovenous crossings.
We thank Prof. Dr. K. Kierdorf for providing mouse eyes and Prof. Dr. S. Schumann and Dr. S. Spassov for providing rat eyes after killing the animals at the end of their respective animal procedures. We thank Marc Guder for excellent technical assistance.