Abstract
BACKGROUND AND PURPOSE: The choice of the experimental aneurysm model is essential for valid embolization-device evaluations. So far, the use of the rabbit venous pouch arterial bifurcation aneurysm model has been limited by demanding microsurgery, low aneurysm patency rates, and high mortality. This study aimed to facilitate microsurgery and to reduce mortality by optimized peri-/postoperative management.
MATERIALS AND METHODS: Aneurysms were created in 16 New Zealand white rabbits under general intravenous anesthesia. Using modified microsurgical techniques, we sutured a jugular vein pouch into a bifurcation created between both CCAs. Aggressive anticoagulation (intraoperative intravenous: 1000-IU heparin, 10-mg acetylsalicylic acid/kg; postoperative subcutaneous: 14 days, 250-IU/kg /day heparin) and prolonged postoperative anesthesia (fentanyl patches: 12.5 μg/h for 72 hours) were applied. Angiographic characteristics of created experimental aneurysms were assessed.
RESULTS: The reduced number of interrupted sutures and aggressive anticoagulation caused no intra-/postoperative bleeding, resulting in 0% mortality. Four weeks postoperation, angiography showed patency in 14 of 16 aneurysms (87.5%) and Ohshima type B bifurcation geometry. Mean values of parent-artery diameters (2.3 mm), aneurysm lengths (7.9 mm), and neck widths (4.1 mm) resulted in a mean 1.9 aspect ratio.
CONCLUSIONS: Compared with historical controls, the use of modified microsurgical techniques, aggressive anticoagulation, and anesthesia resulted in higher aneurysm patency rates and lower mortality rates in the venous pouch arterial bifurcation aneurysm model. Gross morphologic features of these aneurysms were similar to those of most human intracranial aneurysms.
Abbreviations
- CCA
- common carotid artery
- DSA
- digital subtraction angiography
Endovascular embolization of intracranial aneurysms has become an equivalent alternative to clipping for ruptured aneurysms, especially in regard to short-term results.1 However, disappointing long-term results with unacceptably high rates of aneurysm recanalization and late aneurysm re-rupture were shown recently in large clinical trials.2 Thus, experimental animal studies are crucial to test new and better endovascular devices, to improve long-term aneurysm occlusion.3–5
The choice of the model is essential for the comparability of experimental findings with human conditions.6 In a comparison of the currently used animal models in rats, rabbits, canines, and swine,7–9 the rabbit model showed advantageous comparability with the human coagulation system and the best cost-effectiveness.10–12
At the moment, the most frequently used aneurysm model is the rabbit elastase model,13–15 based on intraluminal perfusion of the stump of 1 CCA with pancreatic elastase. The main advantages of this model are the relatively easy microsurgical technique, high aneurysm patency, and low morbidity.12,16,17 However, the aneurysm wall of elastase aneurysms consists of a former elastic artery, the multiple elastic membranes of which were destructed by elastase, probably causing a long-lasting inflammatory repair process in the entire aneurysm wall.18 Additionally, approximately 65%–85% of ruptured human intracranial aneurysms arise directly at bifurcations.19 However, elastase aneurysms are sidewall aneurysms that continue into an altered wall of a branching artery, as can be seen on 3T MR angiographic images.20 In particular his lack of true bifurcational hemodynamics seems to be the major drawback of this model.21
In general, arterial sidewall aneurysm models cannot predict the ability of new coils to improve long-term angiographic results under more challenging hemodynamic conditions.6 For example, it was shown by computer-assisted morphometric comparison of various aneurysm models that bare platinum coils performed equally as well as HydroCoils (MicroVention Terumo, Aliso Viejo, California) only in a canine arterial sidewall aneurysm model, while in arterial bifurcation models, HydroCoils provided better long-term stable occlusion.18
In contrast, the venous pouch arterial bifurcation model is created by a venous pouch sutured into an artificial true bifurcation of both CCAs. The postulated main advantages of this model are true bifurcational hemodynamics21 and the possibility of varying the anatomy of the bifurcation and neck/fundus size of the aneurysm.6 The postulated histomorphologic drawback is a supposed pronounced foreign body reaction around the suture lines at the neck plane, impairing thrombus organization and fibrovascular healing.10 However, it has already been shown that the foreign body response to the monofilament sutures around the anastomosis is only benign and that this chronic inflammatory reaction to nonresorbable sutures is locally confined to the outer parts of the respective vessel walls.5,22 What is more, the aneurysm wall in the venous pouch arterial bifurcation model consists of an unaltered vein transplant with just a few elastic membranes. These features can also be seen in human intracranial aneurysm walls.23 The major shortcomings, resulting in less frequent use of this aneurysm model in recent years, are the high demands of the microsurgical technique, low aneurysm patency rates, and high morbidity rates ≤50%.6,24
The present study aimed to show that these shortcomings could be minimized by facilitating microsurgical procedures and improved peri-/postoperative management.
Materials and Methods
The aneurysms were created in 16 female New Zealand white rabbits (body weight, 3.1–4.7 kg). All surgical procedures were performed at the Department of Clinical Research at the University of Berne. The study was approved by the responsible veterinarian agency of the Canton of Berne, Switzerland.
Anesthesia
All rabbits were premedicated with subcutaneous injection of 65-mg/kg xylazine and 4-mg/kg ketamine and received, preoperatively, a single dose of antibiotics (50-mg penicillin) intravenously. For general anesthesia, a solution of 130-mg/kg xylazine and 8-mg/kg ketamine in 100-mL 0.9% saline was intravenously administered via a perfusor with a rate of 1 mL/s. Animals received oxygen (1 L/min) via ventilation mask.
Microsurgical Aneurysm Creation
The animals were fixed in a supine position on a body warming plate. All operative procedures were performed under sterile conditions. A midline incision was made from the manubrium sterni up to the jaw. The following microsurgical procedures were performed by using an operation microscope: First, a 1.5-cm-long segment of the left external jugular vein without venous branches was prepared, ligated proximally and distally with 4–0 silk (Ethilon 4–0; Ethicon, West Somerville, New Jersey), resected, and kept in heparinized saline (a mixture of 1000-IU heparin in 20-mL 0.9% saline and 1-mL papaverin HCl 4%). The left CCA was then prepared over a distance of approximately 5 cm, starting from the aortic arch to the carotid bifurcation. Tiny arterial branches running medially and supplying laryngeal and tracheal structures and neural structures were preserved. The right CCA was then also isolated and mobilized up to the carotid bifurcation and proximally down to the brachiocephalic branching. Then the animals received 1000-IU heparin intravenously. To obtain a long donor artery for a tensionless anastomosis, we temporarily clipped the right CCA distally just below the carotid bifurcation and then proximally ligated it above the brachiocephalic branching and cut it just above this ligature. This stump was extensively irrigated with heparinized saline as described above, and the adventitia at the cut free end was carefully resected.
The segment of the left CCA planned for the anastomosis was also meticulously freed of the adventitia and then temporarily clipped distally and proximally. Between the clips, an elliptic arteriotomy was performed to accommodate the circumferences of the right CCA and the venous pouch, and then this portion between the clips was also extensively irrigated with heparinized saline to remove intraluminal clots. The posterior circumference of the right CCA stump was now sutured into the arteriotomy in the left CCA, by using 4–5 nonresorbable monofilament sutures (Ethilon10–0; Ethicon). Then a longitudinal cut was made in the stump of the right CCA to accommodate half the circumference of the venous pouch. The back side of the venous pouch wall was now first anastomosed with the arteriotomy in the left CCA by again using 4–5 sutures, and then it was anastomosed with the cut in the right CCA with 3–4 sutures (Fig 1A). The same procedures were performed in the same order at the anterior side of the anastomosis (Fig 1B). Then the distal end of the venous pouch was clipped, and the distal clips on the right CCA were removed. After prompt filling of the aneurysm, trapped air and debris were washed out by opening the clip at the dome of the venous pouch, which was then tightly sealed with a 4–0 polyfilament suture (Vicryl, Ethicon). The suture lines around the anastomosis and the aneurysm neck were then covered with small pieces of adipose tissue for additional hemostasis (Fig 2A). During the operation, 4% papaverin HCl solution and antibiotic solution (neomycin sulfate, 5 mg/mL) was frequently applied topically on the anastomoses to prevent vasospasm and local infections.
For deep and superficial wound closure, 4–0 resorbable sutures (Monocryl, Ethicon) were used.
Postoperative Management
Immediately after we finished the operation, all animals received 10-mg/kg acetylsalicylic acid intravenously and 60-mL 5% glucose subcutaneously to compensate for dehydration during surgery. For prolonged anesthesia, transdermal fentanyl matrix patches releasing 12.5 μg/h were applied for 72 hours in the shaved neck region of the animals. All animals received daily 250-IU/kg low-molecular heparin subcutaneously for 2 weeks.
Angiographic Follow-Up
Four weeks postoperatively, all animals underwent DSA, performed with the animal under general anesthesia, by using standard techniques via a transfemoral approach.21 To assess the gross morphologic characteristics, we measured the aneurysm parameters, total length, neck width, and parent-vessel diameters (at the level of the aneurysm orifice) on DSA images and calibrated them by paravertebrally placed skin clamps. The aneurysm aspect ratio (length/neck width) was calculated.25 Additionally, the distance of the neck plane center from the contour of the parent artery was measured (Fig 2B) to determine the Ohshima-type bifurcation aneurysm.26
All animals showing a patent aneurysm at follow-up were not killed but were included in ongoing experiments at the Department of Clinical Research of the University of Berne.
Results
With the modified microsurgery, on average, 150 minutes were needed for the operations, decreasing from 225 to 115 minutes in the course of the experimental series. The duration of the clamping time of both CCAs was, on average, 65 minutes, decreasing from approximately 120 to 45 minutes. Altogether, on average, 22 interrupted sutures (range, 20–29) were needed to create the anastomoses and aneurysms.
Perioperative and postoperative mortality was 0%. Despite intra- and postoperative high-dose heparinization, no spontaneous bleeding occurred at the site of the anastomoses. No postoperative wound infections and no gastric stress ulcera were observed in the present series; however, 1 animal (the heaviest at 4.7 kg) was impaired by slight hemiparesis but survived until follow-up.
Angiographic Follow-Up
Four weeks postoperatively, DSA showed patency of both CCAs and the aneurysms in 14 of 16 animals (87.5%), while aneurysm occlusion was observed in the hemiparetic animal (4.7 kg) and another animal (4.5 kg). Both aneurysms were created, however, at the beginning of the series (aneurysms 1 and 8). As measured on the calibrated DSAs, parent-artery diameters ranged between 1.6 and 2.7 mm (mean, 2.3 mm), the mean aneurysm length was 7.9 mm (range, 7.4.–8.6 mm), and the mean aneurysm neck width was 4.1 mm (range, 3.7–4.8 mm). These measurements resulted in a mean aspect ratio of 1.9 (range, 1.67–2.08). The neck orifice positioning in relation to the parent-artery axis (Fig 2B) showed a mean distance of 1.7 mm (range, 1.3-2.1 mm), thus corresponding to Ohshima type B aneurysms (Table). In human aneurysms, this type B geometry is statistically significantly correlated with a high risk of aneurysm rupture.26
Discussion
The results of the present study favor the venous pouch arterial bifurcation aneurysm model in rabbits. Unfortunately, in the available literature on this model, only general descriptions of the operative technique can be found, without special emphasis on surgical details or the importance of peri- and postoperative management strategies.4,21,24,27 In the authors' opinion, the following factors play key roles in facilitating microsurgery and improving the outcome of this experimental aneurysm creation:
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1) Careful preparation of a long segment of the left CCA, but without destruction of the superior laryngeal nerves and small vessels.
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2) Careful removal of the highly thrombogenic adventitial connective and fatty tissue from both parent arteries at the planned junction before the creation of the anastomosis.
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3) Creation of a tensionless anastomosis between both CCAs. Apparently, it makes no difference that in the present series, the right CCA was anastomosed to the left CCA, in contrast to the originally described and later modified procedure.21
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4) Reduction of the number of sutures and adjustment of the sequence of suturing around the anastomosis. The number of necessary sutures could be reduced to an average of 22, compared with the ≥32 sutures reported in the literature.21,24 For the sequence of suturing, the proposed beginning at the posterior aspect of the anastomosis (Fig 1) gives better visual control of these most difficult sutures, in contrast to previously proposed procedures.21,24,27
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5) The intimal layer around the anastomosis may not be penetrated by sutures, to avoid intimal damage causing thrombosis in the parent arteries. A reduced number of sutures also causes less injury to the vessel walls, further minimizing the risk of aneurysm thrombosis or embolism.
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6) Sealing of the outside of the suture lines with a thin layer of fatty tissue proved important to avoid bleeding from the anastomoses, despite the reduced number of sutures and the aggressive anticoagulation regimen, as discussed below.
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7) A reduced number of sutures results in shorter clamping times of both CCAs and shorter operation times, reducing the risk of neurologic deficits and complications from anesthesia.
Improved Anticoagulation Management
With the prolonged and more aggressive anticoagulation regimen, a high 87.5% aneurysm and parent-vessel patency could be achieved, but without the incidence of spontaneous aneurysm hemorrhage. These findings go along with Grunwald et al,28 who showed that combined anticoagulation provides good long-term parent-vessel patency.
Improved Peri- and Postoperative Management
In our opinion, a main factor in reducing the reported high rates of ≤26.3% postoperative respiratory complications21 was to replace intubation ventilation with general intravenous anesthesia. With the applied intravenous medication, combined with oxygen mask ventilation, satisfactory general anesthesia over the long operation time could be achieved. Furthermore, preservation of the superior laryngeal nerves during careful microsurgical dissection is also crucial for good respiratory outcomes. With this management, we did not observe any respiratory complications in the present series.
Other frequently reported postoperative complications are gastrointestinal problems, mainly caused by stress ulcera, reaching an incidence of ≤20%.21 Consequently, in the present series, we tried to provide intensified long-term anesthesia for 72 hours, compared with the standard of 24 hours. Obviously, this high dose and extended anesthesia reduced procedural stress for the animals considerably, evidenced by lack of complications with the postoperative nutrition in this series.
The only animal with postoperative hemiparesis was the heaviest animal in this series (4.7 kg) with an extensive subcutaneous fat layer. The second animal showing aneurysm occlusion also had a high body weight of 4.5 kg. Thus, it can be suspected that comparable with human patients, operative risks are higher for overweight subjects. For future experimental series, we suggest using only rabbits with <3.5 kg body weight.
The applied modifications of microsurgery and management resulted in 0% peri-/postoperative mortality in the present study. Thus the major limitation of this aneurysm model6 was apparently overcome. Despite the small number of animals who underwent surgery, this favorable mortality rate is comparable with the 8.4% mortality reported by Lewis et al29 during elastase aneurysm creation in an extremely large series of 700 rabbits undergoing surgery. The aneurysm patency rate of 87.5% in the present study is comparable with the 90%–95% patency rates reported for the elastase model.17,30,31 Because both occluded aneurysms were created in the beginning of the series, this result can be attributed to the surgical learning curve. Thus, it is likely that increasing patency rates can be obtained in larger series of the venous pouch model, achieving the level documented for the elastase model.29
Conclusions
The improved venous pouch arterial bifurcation aneurysm model using modified microsurgical techniques, aggressive anticoagulation, and anesthesia resulted in aneurysm patency rates and mortality rates comparable with those of the rabbit elastase model. Gross morphologic features of the created aneurysms are similar to those of most human intracranial aneurysms.
Acknowledgments
We thank the team of the Experimental Surgical Institute, University of Berne, for their excellent cooperation and extraordinary support. The authors are indebted to Professor Hanns Plenk, Jr, Department of Bone and Biomaterials Research at the Institute for Histology and Embryology, Medical University of Vienna, Austria, for his advice and review of the article. The authors thank Professor Heber Ferraz-Leite, Director of the European Workshop on Microsurgery and Cerebral Revascularization at the Medical University of Vienna, Austria, for his valuable microsurgical teaching.
Footnotes
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This work was supported by Boston Scientific Inc, who provided their technical support; S&T Microsurgical Instruments Inc, who provided us the microsurgical equipment; and Ethicon Inc, who provided the suture material.
References
- Received February 23, 2010.
- Accepted after revision June 6, 2010.
- Copyright © American Society of Neuroradiology