Abstract
Purpose
Endovascular techniques are frequently used for the treatment of intracranial aneurysms and flow diverter stents are relatively new and important devices in this field. The aim of our study is to report long-term follow-up results of flow diversion treatment.
Methods
We retrospectively examined angiographic images and clinical reports of 133 patients (female, 112 [84%]; mean age, 46.3 years [range, 12–70 years]) who were treated with flow diverters between 2008 and 2013 and were followed up radiologically at least 1 year. The aneurysms treated with flow diverters were assessed according to technical problems, stent patency, residual filling, re-growth, and occlusion status, and the patients were assessed according to morbidity and mortality.
Results
Except for ten patients, one aneurysm was treated per patient. Median duration of the follow-up was 927 days. Total occlusion rates in angiographic follow-up were found 76.2% for the sixth-month, 86.7% for the first-year, 93.6% for the third-year, 94.2% for the fifth-year, and 90.2% for entire follow-up period. Nine stent morphology changes were observed in the angiographic controls. Overall mortality and morbidity rates were 3.7% and 4.3%, respectively.
Conclusion
Despite technical difficulties and delayed hemorrhages, flow diverter stents are effective tools for the treatment of challenging aneurysms in the long run. Nonetheless, long-term results of flow diversion treatment must be evaluated hemodynamically and clinically in multicenter studies.
Similar content being viewed by others
Explore related subjects
Discover the latest articles, news and stories from top researchers in related subjects.Avoid common mistakes on your manuscript.
Introduction
The use of endovascular methods has been remarkably increased in recent years and is considered the first choice in the treatment of intracranial aneurysms [6, 18, 20]. Although endovascular treatment with coil embolization can be performed successfully in small and non-complex aneurysms, complete occlusion of large (> 10 mm) and giant (> 25 mm) intracranial aneurysms can be achieved at low rates, 40% and 26%, respectively [19]. As the recurrence and re-bleeding are associated with the residual filling in the treated aneurysms, ensuring the total occlusion is very important [10]. Therefore, flow-diverting devices have been developed to provide vascular remodeling. Without aiming to fill the aneurysmal sac, these devices are designed to direct the vascular flow to the parent artery and constitute the skeleton of endothelial reconstruction resulting in secondary thrombosis that leads to subsequent shrinkage of aneurysmal sac [8, 26, 27]. Theoretically, preventing recanalization of the aneurysm can ensure the long-term stable hemodynamic environment.
There are several studies in the literature regarding the early and mid-term results of flow diversion, in which promising results have been reported as well as technical difficulties and procedural complications such as delayed hemorrhage, thromboembolic events, in-stent stenosis, and parent artery occlusion [5, 16, 22,23,24,25,26]. Long-term clinical and radiological outcomes are required to improve treatment success, to avoid technical difficulties and complications.
In this study, we aimed to evaluate the long-term outcomes of flow diversion treatment.
Materials and methods
Ethics
The retrospective study was approved by our institutional ethics committee and carried out according to the requirements of the Declaration of Helsinki. All patients gave written informed consent to angiographic procedures and use of imaging data.
Patient population
A total of 161 patients underwent flow diverter stent treatment in the interventional neuroradiology department of Cerrahpasa Medical Faculty between May 2008 and November 2013. Only the patients with at least 1-year clinical and radiological follow-up were included in this study, which resulted in a total of 133 patients with 143 aneurysms. In addition, third-year and fifth-year follow-up data were available in 105 and 83 patients with 110 and 87 aneurysms, respectively. Figure 1 summarizes the number of patients and aneurysms in different time points.
Overall, 99 SILK stents, 11 Pipeline embolization device (PED), and 39 Flow Re-direction Endoluminal Devices (FRED) were used. Some of the patients’ early, short-term, and mid-term results (SILK stent, 55 patients with 63 aneurysms; FRED 33 patients with 37 aneurysms) were previously reported in authors’ other papers [12, 25]. But the focus of this study is the long-term results.
Indications of flow diversion treatment
Giant intracranial aneurysms, especially those with a wide neck (> 4 mm) or fusiform shape, are among the most demanding vascular lesions to treat and are common indications for flow diversion treatment. Other indications include aneurysms on dysplastic parent artery, ones with mass effect, small aneurysms (< 2 mm) that are seldom treatable with surgery or conventional endovascular techniques, and dissecting aneurysms.
Pre-treatment and post-treatment medication
Seventy-five milligrams of clopidogrel and 100 mg of aspirin were administered orally for at least 5 days before the procedure. If not received before, the treatment was given orally in the form of a loading dose of 300 mg of clopidogrel and 300 mg of aspirin on the day of the procedure. Of note, patients presented with subarachnoid hemorrhage prior to flow diverter treatment were loaded with 300 mg clopidogrel and 300 mg aspirin immediately before the treatment. Platelet function inhibition in the patients was confirmed by collagen ADP resistivity test; patients with platelet inhibition rate between 40 and 70% were treated with a flow diverter stent. However, for patients whose platelet inhibition rate could not reach 40%, aspirin dose was increased to 300 mg/day. In patients who still failed to maintain the appropriate platelet inhibition rate, in addition to 300 mg/day aspirin, the clopidogrel dose was doubled (150 mg/day) or clopidogrel exchanged for ticlopidine (250 mg 2×/day).
In all patients, endovascular treatment was performed after inducing general anesthesia and applying systemic heparinization. Following the placement of the femoral sheath, 5000 IU heparin was administered as intravenous bolus and then as continuous intravenous perfusion to maintain 2–2.5-fold baseline APTT (active partial thromboplastin time) during the procedure.
After the procedure, heparinization was extended to 24 h in all patients, and LMWH (low molecular weight heparin) was administered for the following days. Also, after discharge, it was recommended to take 75 mg clopidogrel/day for at least 6 months and 300 mg/day aspirin permanently.
In cases in which total aneurysm occlusion cannot be achieved, clopidogrel was discontinued after sixth month and aspirin was reduced to 100 mg at 1 year.
Flow diverter stent technique
All flow diverter stent implantations were performed by at least two senior neuroradiologists (CI., NK., and OK.) on Philips Integris Allura and Allura Xper FD 20/20 Biplane Angiography (Philips Medical Systems, Netherland).
Unilateral femoral access was used in all patients. After obtaining the appropriate study projection for the aneurysm, that is to be treated, a guide catheter was placed for intracranial access to the relevant vessel segment. Following this, the related microcatheter-microguide system included in the flow diverter stent system was opened after passing the aneurysm segment to cover the aneurysm neck. Since 2010, in all cases, stent apposition to the vessel wall was scanned with flat-panel detector C-arm CT angiography (Philips Healthcare) in neuroangiography suite in addition to regular angiographic images. When necessary, a second stent was implanted, or balloon angioplasty was performed to ensure a satisfactory stent apposition to the vessel wall. All patients underwent control angiography, and the procedure was terminated.
Post-treatment follow-up
After treatment, angiograms were obtained immediately in anteroposterior, lateral, and working positions. The patients were then transferred to the neurological intensive care unit and closely monitored for fluid balance, blood pressure, and neurological status.
On post-procedural day 1, control angiogram was performed. In suitable patients, closure devices were used for groin punctures.
At our institution, a standard follow-up protocol was used: (i), at first month, neurological examination and MRI scan; (ii), at third and sixth months, flat-panel detector C-arm CT angiography; (iii), at 12th month, digital subtraction angiography (DSA) and flat-panel detector C-arm CT angiography were performed, and the results were evaluated by at least two senior neuroradiologists.
The cases, in which total aneurysm occlusion was detected 1 year after treatment, were followed up by annual clinical examination and depending on the findings, appropriate radiological examinations (DSA, MRI, MR-angiography, CT, or flat-panel detector C-arm CT angiography) were performed when necessary. If the aneurysm is still not completely occluded after 1 year, annual MR angiographic imaging was performed. Control DSA or flat-panel detector C-arm CT angiography was planned in all patients at fifth year after flow diversion treatment.
The aneurysms treated with flow diverter stent were assessed according to technical problems, residual filling, stent patency, re-growth, and occlusion status during follow-up period, and the patients were assessed according to morbidity and mortality.
Angiographic outcome evaluation
Follow-up intervals about flow diversion treatment differ in the literature according to the time after procedure and usually defined as follows: early and short-term (0–180 days), mid-term (180–365 days), and long-term (> 1 year) [11].
Aneurysm occlusion status was assessed according to 3-point Raymond-Roy scale.
In-stent stenosis was evaluated based on the minimal luminal diameter and graded as follows: mild (< 50%), moderate (50–75%), or severe (> 75%).
Clinical outcome evaluation
Clinical outcome was evaluated postoperatively, at discharge, at first month, at first year, and annually thereafter using the modified Rankin scale. The primary outcomes assessed were neurological morbidity and mortality.
Results
Patients’ demographic data, clinical presentation, and aneurysm characteristics are given in Table 1 and Table 2.
Median follow-up periods after flow diversion treatment were 39 months (12–72 months) for SILK stent (Fig. 2), 36 months (24–48 months) for PED (Fig. 3), and 14 months (12–24 months) for FRED (Fig. 4). The length of follow-up ranged from 382 to 2288 days for all flow diverter stents (median, 31 months [927 days]).
After treatment, complete occlusion rates at sixth-month, first-year, third-year, and fifth-year follow-up period were 76.2% (109/143), 86.7% (124/143), 93.6% (103/110), and 94.2% (82/87), respectively (Fig. 5). Complete occlusion rate at entire follow-up period was found to be 90.2% (129/143).
Successful stent deployment was achieved technically in all procedures. Four of eight patients with bilateral aneurysms were treated with flow diverter stents in the same operation, and the remaining four were stented separately in different sessions. Except for six patients (4.5%), only one flow diverter was placed per aneurysm. In five patients, a second flow diverter stent was implanted telescopically to provide better coverage for entire aneurysm and dysplastic artery. In 20 patients, Leo stents (Balt, Montmorency, France) were implanted in addition to flow diverter stent and in three patients additional coiling was performed to reduce the volume of aneurismal thrombus.
During a total of 149 flow diverter stent implantations, technical complications were observed in 23 (15%) procedures. In 19 (13%) of these, poor apposition of SILK stents to the vessel wall was detected. In all these cases, microballoons were used to obtain optimum stent opening. In three cases, Leo stents were also implanted into the SILK stent to resolve the apposition problem. Other technical problems include detachment of stent in hub of microcatheter (n = 2), intra-aneurysmal air bubble (n = 1), and partial collapse in inner stent of FRED (n = 1). Non-technical procedural complications were observed in 3 (2%) procedures during flow diversion treatment. Bilateral flow diverter stent occlusion was detected in a patient who was treated with placement of an additional stent in the same session. And also, dissection of ICA petrous segment occurred in a patient during the procedure.
Six subarachnoid hemorrhages due to aneurysm rupture were observed postoperatively, and five of these six aneurysm ruptures resulted in mortality. These ruptured aneurysms had no previous history of rupture. All ruptures developed within the first postoperative month. In 5 patients with subarachnoid hemorrhage after flow diverter stent therapy, Glasgow coma scale was found to be 3 and we could not perform any additional intervention. These patients were followed up in the intensive care unit for medical treatment of subarachnoid hemorrhage after external ventricular drainage. The other patient had a mild subarachnoid hemorrhage with Glasgow coma score of 14 on the fifth day following flow diversion. We implanted a second SILK stent telescopically on the right side. The patient was discharged with slight (4/5) left upper extremity paresis.
Four cases of transient clinical worsening due to mass effect after stent implantation were observed. Aneurysm thrombosis was considered as the cause of this temporary clinical deterioration, and these four patients were administered oral steroids (8 mg dexamethasone/day) after having symptoms. At the end of the 1-month follow-up period, clinical findings were completely resolved in all these patients, and neurological examination was found normal.
Seven thromboembolic events occurred in the clinical follow-up period. Six patients experienced persistent morbidity due to stroke, and one patient had a transient ischemic attack.
In the angiographic controls, five in-stent stenoses with SILK stent and four fish mouthing phenomena with FRED were observed. The overall in-stent stenosis rate in control angiographies was 3.7% (5/133), and only one of these five patients was symptomatic. The stenosis in the symptomatic patient was severe (> 75%), but it was reduced below 50% on control angiography with dual antiplatelet therapy (150 mg clopidogrel plus 300 mg aspirin). Of the 133 patients, 4 (3%) showed mild (< 50%) in-stent stenosis with parental artery patency and no flow limitation. These cases were followed up without performing balloon angioplasty, and all these stenoses regressed to < 10% in 1-year control angiographies. Among four fish mouth cases, two of them showed regression, and one remained the same in angiographic controls. In the other case, fish mouth phenomenon was accompanied with intimal hyperplasia in angiographic examinations.
Additional interventional procedures were required in three patients included in our study. The increase in the size of the aneurysm sac and the persistent progression of the patient’s symptoms were determined as the most important criteria for additional treatment decision.
Regarding the six patients presented with subarachnoid hemorrhage preoperatively, one of those patients was treated with flow diverter 30 days after the hemorrhage. The remaining five patients were treated within the first week after the hemorrhage.
The overall stented parent artery occlusion rate was 3% (4/133), and two of these four patients were symptomatic. In our series, permanent morbidity occurred in 4.3% (n = 7) of procedures and overall mortality rate was 3.7% (n = 6). The combined major neurologic morbidity and mortality was 8%. One hundred and twenty-five (90.2%) of 133 patients with at least 1-year clinical follow-up had modified Rankin Scale scores ≤ 2.
Table 3 briefly shows the complications and related morbidity-mortality rates.
Discussion
Flow diversion with stents has been designed as a treatment modality for providing progressive occlusion of the aneurysm and long-term hemodynamic healing by reconstructing the parent artery instead of the treatment process by filling in the aneurysm applied in the past for the intracranial aneurysm treatment [16, 22, 26].
In our series, total aneurysm occlusion was achieved in 76.2% at 6 months, 86.7% at 12 months, 93.6% at 3 years, 94.2% at 5 years, and 90.2% during the entire follow-up period (median 927 days) after flow diversion treatment. In the literature, aneurysmal complete occlusion rate was at least 70% at 6 months and progressively increased over time up to 95.2% at fifth year angiographic follow-up [1,2,3,4, 11, 14, 16, 17, 21, 22]. Complete occlusion rates detected in the present series is in line with the studies published in the literature and demonstrates the efficacy of flow diverter stents especially in the treatment of complex aneurysms.
Reconstruction of the vascular wall and progressive thrombosis of the aneurysm are the expected outcomes in flow diversion treatment; but this process mainly depends on flow changes, main artery geometry, aneurysm size-shape, and blood coagulation parameters [15]. In the present study, as with all flow diverter stent studies in the literature, the possibility of total occlusion of an aneurysm increases with the time elapsed after treatment, but it is difficult to predict when the total occlusion will occur [5, 9, 11, 14, 16]. Dual antithrombotic treatment also contributes to this unpredictability in estimating the exact time of complete aneurysm occlusion.
Multifactorial reasons are thought to play a role in the absence of complete occlusion after flow diverter stent therapy. Among these, effects of dual antiplatelet therapy, variable response to antiplatelet therapy, poor apposition of the stent to the vessel wall, and new hemodynamic environment after flow diverter stent implantation are the most important factors that are responsible for the lack of complete occlusion. According to the occlusion status of the aneurysm and patient’s response to antiplatelet therapy, medical treatment can be modified after the evaluation of clinical and laboratory findings. Stent apposition to the vessel wall can also be scanned with flat-panel detector C-arm CT angiography in neuroangiography suite. However, with a retrospective study and in turn limited data, it is more difficult to evaluate the new hemodynamic environment following stent implantation, which may require prospectively designed biophysical studies.
Four cases of transient clinical worsening due to mass effect and six subarachnoid hemorrhages due to aneurysm rupture after stent implantation were observed in our series. Deterioration of mass effect and aneurysm rupture after flow diverter implantation also suggest that some aspects of the thrombus formation process are uncontrollable and unpredictable. Temporary clinical deterioration due to mass effect was completely resolved in all of these four patients after steroid therapy.
Despite successful implantation of flow diverter stent, delayed hemorrhage may be seen. In these cases, the etiology of the rupture is not clearly understood, but the lytic enzymes and inflammatory mediators secreted during thrombosis process may be responsible of aneurysm wall degeneration. In our series, six subarachnoid hemorrhages due to aneurysm rupture were observed and five of these resulted in mortality. All these patients were symptomatic at presentation and the sizes of the aneurysms were large or giant (18–50 mm). Defined aneurysms were ICA anterior loop aneurysms and ruptured within the first month after treatment.
Kulcsar et al. conducted a study aiming to reveal the characteristics of ruptured aneurysms after flow diversion and showed that symptomatic aneurysms, large or giant aneurysms, and saccular aneurysms with an aspect ratio > 1.6 are more susceptible to rupture [15]. This knowledge has contributed to the current approach of our clinic and since 2014, we have begun to implant flow diverter stent following coiling of the aneurysm sac in symptomatic patients with an aneurysm > 15 mm. Delayed aneurysm rupture following flow diversion is probably a multifactorial problem and pre-clinical studies will be necessary to assess the hemodynamic effects of concomitant coiling and flow diversion treatment.
While recurrence is one of the main concerns in conventional endovascular treatment of intracranial aneurysms, we have not experienced any recurrence after total occlusion or decline in occlusion level. Studies in the literature showed no regression in the grade of occlusion except for a study by Bryne et al. [5].
Changes in-stent morphology such as fish mouthing, which may lead to hemodynamic disturbances in the parent artery flow following flow diversion treatment, may also occur. In our angiographic follow-ups, four fish mouthing phenomena with FRED were detected. The location and temporary nature of this phenomenon suggest that it may be associated with delayed type hypersensitivity to metal constituents of flow diverter stent, and Kocer et al. showed a statistically significant association between fish mouthing and history of contact allergy to imitation jewelry, and a small aneurysm size [13]. Frequent control imaging was recommended in patients with history of contact allergy to detect fish mouthing and its subsequent hemodynamic effects on the flow of parent artery.
In-stent stenosis and parent artery occlusion are also other major concerns about flow diversion treatment. Although heterogeneity exists regarding antiplatelet regimens reported in the literature between different medical centers [7], under dual antithrombotic therapy, these types of complications are seen relatively low and become rarely symptomatic. The overall in-stent stenosis rate and overall stented parent artery occlusion rate in our control angiographies were 3.7% (5/133) and 3% (4/133), respectively. Among these patients only one (1/5) patient with in-stent stenosis and two (2/4) patients with parent artery occlusion were symptomatic. Cases with in-stent stenosis were followed up under dual antiplatelet therapy without performing balloon angioplasty and all stenoses regressed below 10% within 1-year period.
In our series; permanent morbidity rate, overall mortality rate, and combined major neurologic morbidity-mortality rate were found to be 3.7%, 4.3%, and 8%, respectively. A meta-analysis aiming to reveal the outcomes of flow diverters conducted by Brinjikji et al. showed a procedure-related neurologic morbidity rate of 5% and a procedure-related mortality rate of 4% [4].
Limitations
While the flow diverter stents function with the same principle, they show some technical differences in terms of metal content, design, and deployment. These differences may influence rates of occlusion and complication. In our study, 99 SILK stents, 11 PED, and 39 FRED were implanted, and the number of cases was not found sufficient to make statistical discrimination in terms of occlusion rates and complications between different types of flow diverter stents. In short, however, all types of deployed stents have high rates of occlusion and reasonable rates of complications.
We did not present the occlusion rates for the intervals after fifth-year follow-up because our department had no routine angiographic follow-up after 5 years except tenth year unless the aneurysm occlusion status is incomplete; the number of patients decreased in the subsequent follow-up periods (for instance, only 21 patients after sixth year). Another reason for this decrease was the patients’ incompliance and reluctance to long-term follow-up. Since the imbalanced distribution due to limited number of patients following sixth-year follow-up could provide misleading results, these data were not statistically analyzed. Nonetheless, for the future, our clinic also plans to update our long-term follow-up study by reporting the occlusion rates after tenth-year angiographic control, to reflect aneurysm occlusion process in a broader period with more detail.
Conclusion
Flow diverters are relatively new and effective tools in the management of complex aneurysms with reasonable rates of morbidity and mortality. Radiological follow-up results of these stents showed high aneurysm occlusion rate and durable treatment with high parent artery patency.
References
Becske T, Brinjikji W, Potts MB et al (2017) Long-term clinical and angiographic outcomes following pipeline embolization device treatment of complex internal carotid artery aneurysms: five-year results of the pipeline for uncoilable or failed aneurysms trial. Neurosurgery 80(1):40–48
Becske T, Potts MB, Shapiro M et al (2017) Pipeline for uncoilable or failed aneurysms: 3-year follow-up results. J Neurosurg 127(1):81–88
Briganti F, Napoli M, Leone G, Marseglia M, Mariniello G, Caranci F, Tortora F, Maiuri F (2014) Treatment of intracranial aneurysms by flow diverter devices: long-term results from a single center. Eur J Radiol 83(9):1683–1690
Brinjikji W, Murad MH, Lanzino G, Cloft HJ, Kallmes DF (2013) Endovascular treatment of intracranial aneurysms with flow diverters. Stroke 44(2):442–447
Byrne JV, Beltechi R, Yarnold JA, Birks J, Kamran M (2010) Early experience in the treatment of intra-cranial aneurysms by endovascular flow diversion: a multicentre prospective study. PLoS One 5(9):e12492
Cognard C, Pierot L, Anxionnat R, Ricolfi F, Clarity Study Group (2011) Results of embolization used as the first treatment choice in a consecutive nonselected population of ruptured aneurysms: clinical results of the Clarity GDC study. Neurosurgery 69(4):837–841 discussion 842
Faught RWF, Satti SR, Hurst RW, Pukenas BA, Smith MJ (2014) Heterogeneous practice patterns regarding antiplatelet medications for neuroendovascular stenting in the USA: a multicenter survey. J Neurointerv Surg 6(10):774–779
Fiorella D, Kelly ME, Albuquerque FC, Nelson PK (2009) Curative reconstruction of a giant midbasilar trunk aneurysm with the pipeline embolization device. Neurosurgery 64(2):212–217 discussion 217
Gross BA, Frerichs KU (2013) Stent usage in the treatment of intracranial aneurysms: past, present and future. J Neurol Neurosurg Psychiatry 84(3):244–253
Johnston SC, Dowd CF, Higashida RT, Lawton MT, Duckwiler GR, Gress DR, Investigators CARAT (2008) Predictors of rehemorrhage after treatment of ruptured intracranial aneurysms: the Cerebral Aneurysm Rerupture After Treatment (CARAT) study. Stroke 39(1):120–125
Killer-Oberpfalzer M, Kocer N, Griessenauer CJ et al (2018) European multicenter study for the evaluation of a dual-layer flow-diverting stent for treatment of wide-neck intracranial aneurysms: the European flow-redirection intraluminal device study. AJNR Am J Neuroradiol 39(5):841–847
Kocer N, Islak C, Kizilkilic O, Kocak B, Saglam M, Tureci E (2014) Flow re-direction endoluminal device in treatment of cerebral aneurysms: initial experience with short-term follow-up results: clinical article. J Neurosurg. https://doi.org/10.3171/2014.1.JNS131442
Kocer N, Mondel PK, Yamac E, Kavak A, Kizilkilic O, Islak C (2017) Is there an association between flow diverter fish mouthing and delayed-type hypersensitivity to metals?-a case-control study. Neuroradiology 59(11):1171–1178
Kulcsár Z, Ernemann U, Wetzel SG, Bock A, Goericke S, Panagiotopoulos V, Forsting M, Ruefenacht DA, Wanke I (2010) High-profile flow diverter (silk) implantation in the basilar artery: efficacy in the treatment of aneurysms and the role of the perforators. Stroke 41(8):1690–1696
Kulcsár Z, Houdart E, Bonafé A et al (2011) Intra-aneurysmal thrombosis as a possible cause of delayed aneurysm rupture after flow-diversion treatment. AJNR Am J Neuroradiol 32(1):20–25
Lubicz B, Collignon L, Raphaeli G, Pruvo J-P, Bruneau M, De Witte O, Leclerc X (2010) Flow-diverter stent for the endovascular treatment of intracranial aneurysms. Stroke 41(10):2247–2253
Lylyk P, Miranda C, Ceratto R, Ferrario A, Scrivano E, Luna HR, Berez AL, Tran Q, Nelson PK, Fiorella D (2009) Curative endovascular reconstruction of cerebral aneurysms with the pipeline embolization device: the Buenos Aires experience. Neurosurgery 64(4):632–642 discussion 642–3; quiz N6
Molyneux A, Kerr R, Stratton I, Sandercock P, Clarke M, Shrimpton J, Holman R, International Subarachnoid Aneurysm Trial (ISAT) Collaborative Group (2002) International Subarachnoid Aneurysm Trial (ISAT) of neurosurgical clipping versus endovascular coiling in 2143 patients with ruptured intracranial aneurysms: a randomised trial. Lancet 360(9342):1267–1274
Murayama Y, Nien YL, Duckwiler G, Gobin YP, Jahan R, Frazee J, Martin N, Viñuela F (2003) Guglielmi detachable coil embolization of cerebral aneurysms: 11 years’ experience. J Neurosurg 98(5):959–966
Pierot L, Spelle L, Vitry F, Investigators ATENA (2008) Immediate clinical outcome of patients harboring unruptured intracranial aneurysms treated by endovascular approach: results of the ATENA study. Stroke 39(9):2497–2504
Pumar JM, Banguero A, Cuellar H, Guimaraens L, Masso J, Miralbes S, Blanco-Ulla M, Vazquez-Herrero F, Souto M, Gelabert-Gonzalez M (2017) Treatment of intracranial aneurysms with the SILK embolization device in a multicenter study. A retrospective data analysis. Neurosurgery 81(4):595–601
Szikora I, Berentei Z, Kulcsar Z, Marosfoi M, Vajda ZS, Lee W, Berez A, Nelson PK (2010) Treatment of intracranial aneurysms by functional reconstruction of the parent artery: the Budapest experience with the pipeline embolization device. AJNR Am J Neuroradiol 31(6):1139–1147
Tähtinen OI, Manninen HI, Vanninen RL, Seppänen J, Niskakangas T, Rinne J, Keski-Nisula L (2012) The silk flow-diverting stent in the endovascular treatment of complex intracranial aneurysms. Neurosurgery 70(3):617–624
Turowski B, Macht S, Kulcsár Z, Hänggi D, Stummer W (2011) Early fatal hemorrhage after endovascular cerebral aneurysm treatment with a flow diverter (SILK-Stent): do we need to rethink our concepts? Neuroradiology 53(1):37–41
Velioglu M, Kizilkilic O, Selcuk H, Kocak B, Tureci E, Islak C, Kocer N (2012) Early and midterm results of complex cerebral aneurysms treated with silk stent. Neuroradiology. https://doi.org/10.1007/s00234-012-1051-7
Wagner A, Cortsen M, Hauerberg J, Romner B, Wagner MP (2012) Treatment of intracranial aneurysms. Reconstruction of the parent artery with flow-diverting (silk) stent. Neuroradiology 54(7):709–718
Walcott BP, Pisapia JM, Nahed BV, Kahle KT, Ogilvy CS (2011) Early experience with flow diverting endoluminal stents for the treatment of intracranial aneurysms. J Clin Neurosci 18(7):891–894
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
All procedures performed in the studies involving human participants were in accordance with the ethical standards of the institutional and/or national research committee and with the 1964 Helsinki Declaration and its later amendments or comparable ethical standards. Informed consent was obtained from all individual participants included in the study.
Conflict of interest
NK and CI have consultancy and proctoring agreement with Microvention, Inc.
Study-cohort overlap
Some of the patients’ short- and mid-term results were reported in authors’ other previous studies. But the focus of this study is the long-term results.
Additional information
Publisher’s note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
This article is part of the Topical Collection on Vascular Neurosurgery - Aneurysm
Rights and permissions
About this article
Cite this article
Korkmazer, B., Kocak, B., Islak, C. et al. Long-term results of flow diversion in the treatment of intracranial aneurysms: a retrospective data analysis of a single center. Acta Neurochir 161, 1165–1173 (2019). https://doi.org/10.1007/s00701-019-03912-6
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00701-019-03912-6