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Endovascular aneurysm repair

Endovascular aneurysm repair (EVAR) is a designed to treat , which are localized dilations of the exceeding 3 cm in diameter or 1.5 to 2.0 times the normal adjacent aortic diameter, by deploying a stent-graft via to exclude the from blood circulation and prevent potentially fatal rupture. Introduced in by Parodi and colleagues as an alternative to traditional open surgery, EVAR accesses the through small incisions in the arteries, guiding the collapsed stent-graft—typically a tube of metal mesh covered with polyester fabric—under fluoroscopic imaging to the site, where it is expanded to line the vessel wall and redirect blood flow. Indications for EVAR include AAAs ≥5.5 cm in men or ≥5.0 cm in women, symptomatic unruptured aneurysms, rapidly expanding sacs (growth >1 cm per year), or ruptured cases in suitable patients, with shared recommended for smaller aneurysms (4.0–5.4 cm) based on individual risk factors. Compared to open surgical repair, EVAR offers significant benefits, including lower 30-day mortality rates (0.5–1.6% versus 3.0–4.6%), reduced blood loss, shorter operative times, decreased stays, and faster recovery, making it particularly advantageous for high-risk patients such as the elderly or those with comorbidities. Despite these advantages, EVAR is not without risks and requires lifelong surveillance due to potential long-term complications, such as endoleaks (blood leakage into the aneurysm sac, occurring in 14–25.3% of cases, primarily type II), stent-graft migration, limb occlusion (0.4–11.9%), access vessel injury, (0.3–3.6%), and post-implantation . Overall complication rates can reach up to 30%, with some necessitating reintervention or conversion to open repair, underscoring the importance of patient selection based on aneurysm anatomy (e.g., adequate proximal and distal landing zones) and regular imaging follow-up using angiography or . Since its adoption, randomized trials like the EVAR-1 and DREAM studies have confirmed EVAR's superiority in short-term outcomes, though long-term survival benefits remain comparable to open repair, influencing its role as the preferred method for most elective cases today.

Overview

Definition and principles

Endovascular aneurysm repair (EVAR) is a minimally invasive and technique used to treat abdominal aortic aneurysms by deploying a stent-graft through a catheter-based approach, thereby excluding blood flow from the aneurysmal sac while maintaining patency of essential branch vessels such as the renal arteries. This method contrasts with traditional open surgical repair by accessing the vascular system via small incisions in the groin, typically under fluoroscopic guidance, to deliver and position the device endovascularly. The core principles of EVAR revolve around achieving complete endovascular exclusion of the through strategic sealing and fixation. The stent-graft exerts radial force against the healthy arterial walls in proximal and distal sealing zones—typically 10-20 mm in length—to prevent blood leakage (endoleak) into the sac and ensure hemodynamic , which promotes sac and remodeling over time. Unlike open repair, which requires direct suturing of a graft to the via a large abdominal incision, EVAR minimizes , resulting in reduced intraoperative blood loss (often <500 mL compared to >1,000 mL in open procedures) and lower morbidity. Endografts used in EVAR are modular devices comprising a tubular fabric graft, commonly made of woven (Dacron) or expanded (ePTFE), supported by a self-expanding metallic skeleton such as nitinol—a nickel-titanium valued for its shape memory and fatigue resistance—or . These components are compressed within a low-profile delivery system, including a hydrophilic-coated and , for introduction and controlled deployment via balloon expansion or self-expansion mechanisms. The term "EVAR" originated in the early 1990s with the pioneering human implantation for abdominal aortic aneurysms by Juan Parodi and colleagues in 1991, marking a shift toward endovascular therapies that has since expanded to include thoracic aortic applications.

Anatomy and pathophysiology

The aorta, the body's largest artery, originates from the left ventricle and extends through the thorax and abdomen, serving as the primary conduit for oxygenated blood. In the abdomen, it descends from the diaphragm at T12 to bifurcate into the common iliac arteries at L4, with the infrarenal segment—extending below the renal arteries at L1-L2—being the most common site for aneurysmal dilation due to its relative lack of major branching and exposure to hemodynamic stress. The suprarenal abdominal aorta lies above the renal arteries and includes critical visceral branches such as the celiac artery (at T12-L1) and superior mesenteric artery (just inferior to the celiac). The common iliac arteries, measuring 3-4 cm in length, divide at L4 into the internal iliac arteries (1-6 cm long, perfusing pelvic organs via anterior and posterior divisions) and external iliac arteries (continuing to the lower extremities). The inferior mesenteric artery arises from the infrarenal aorta at L3. Aortic aneurysms are classified by and , with aneurysms presenting as symmetrical, spindle-shaped dilations involving the entire circumference of the vessel wall, while saccular aneurysms form asymmetric, pouch-like outpouchings on one side. Abdominal aortic aneurysms (AAAs) primarily affect the infrarenal segment. Aortic dissections, though distinct, can complicate aneurysms by creating a tear in the intimal layer, allowing blood to flow between aortic wall layers and potentially leading to expansion or rupture. The of aortic aneurysms involves multifactorial degradation of the aortic wall's structural integrity, primarily through degenerative processes where leads to and weakening of the media layer. Proteolytic enzymes, such as matrix metalloproteinases, are upregulated in the aneurysmal wall, accelerating the breakdown of and , which normally provide tensile strength. Genetic predispositions, including disorders like , impair fibrillin-1 function and contribute to cystic medial degeneration, increasing susceptibility. Inflammatory causes, such as autoimmune responses or infections, can also drive cytokine-mediated wall remodeling and thinning. The prevalence of AAAs is approximately 2-4% in men over 65 years, with rupture carrying a of about 80%, and risk escalating significantly for diameters exceeding 5.5 cm due to progressive wall stress. Hemodynamic factors play a central role in aneurysm progression, with wall stress governed by , which posits that tensile stress in the vessel wall increases with and radius while inversely relating to wall thickness: \sigma = \frac{P \times r}{2 \times h} where \sigma is wall , P is transmural pressure, r is , and h is wall thickness. As aneurysms enlarge, the increased radius amplifies , promoting further and thinning, while turbulent blood flow within the sac induces shear forces that exacerbate endothelial damage and inflammatory infiltration, contributing to expansion.

Indications and patient selection

Medical indications

Endovascular aneurysm repair (EVAR) is primarily indicated for the treatment of abdominal aortic aneurysms (AAA) that exceed specific size thresholds to prevent rupture, particularly in cases measuring greater than 5.5 cm in diameter for men and greater than 5.0 cm for women.00754-0/fulltext) Symptomatic AAAs, which may present with abdominal or attributable to expansion or impending rupture, also warrant repair regardless of size, as do ruptured AAAs requiring emergent intervention. Evidence from landmark randomized controlled trials supports these indications, demonstrating EVAR's perioperative advantages over open repair. The EVAR-1 trial, part of the EndoVascular Aneurysm Repair (EVAR) program, reported a 30-day operative mortality of 1.8% for EVAR compared to 4.3% for open repair in patients suitable for both procedures, highlighting reduced early mortality for elective treatment. The EVAR-2 trial extended this to high-risk patients unfit for open surgery, showing no long-term survival benefit over medical management alone but confirming EVAR's feasibility in this cohort with a 30-day mortality of 9%.60923-3/fulltext) Long-term follow-up from these trials indicated equivalent overall survival beyond the perioperative period, with aneurysm-related mortality similar between EVAR and open repair after 8 years, underscoring EVAR's role in short-term risk reduction while necessitating lifelong surveillance. Specific applications of EVAR include elective repair in high-surgical-risk patients with suitable , where it offers a less invasive alternative to open for asymptomatic . In emergencies, such as ruptured , EVAR reduces to approximately 35-40% compared to higher rates with open repair, though overall rupture mortality remains substantial due to prehospital deaths. approaches combining EVAR with open visceral debranching are utilized for complex thoracoabdominal aneurysms unsuitable for standard endovascular coverage. The (SVS) guidelines recommend surveillance with imaging for AAAs measuring 4.0 to 5.4 cm in men and 3.5 to 4.9 cm in women, with repair thresholds as noted to balance rupture risk against procedural morbidity.00754-0/fulltext) Benefits of EVAR over open repair include shorter hospital stays, typically 2-4 days versus 7-10 days, and accelerated recovery, enabling faster return to baseline function, particularly advantageous for elderly or comorbid patients.

Contraindications and risk factors

Endovascular aneurysm repair (EVAR) has specific absolute contraindications that render the procedure infeasible or excessively hazardous. These include uncorrectable , which poses significant risks during large-bore vascular access and graft deployment. Severe contrast allergy or renal failure without capability is also absolute, as is essential for intraoperative imaging and guidance, with alternatives like CO2 limited in efficacy. Anatomically, inadequate proximal length (<10 mm) or severe angulation (>60°) prevents secure endograft sealing and fixation, leading to high rates of migration or endoleak. Relative contraindications encompass anatomical and clinical factors that increase procedural complexity but may allow EVAR with advanced techniques or careful selection. Hostile neck anatomy, such as conical , reverse taper, or >50% circumferential , compromises seal integrity and elevates type Ia endoleak risk. Severe iliac tortuosity or diameter <6 mm hinders device delivery, often requiring adjunctive interventions like conduit placement. Active infection, including mycotic aneurysms, is relatively contraindicated due to graft infection risks, though EVAR may serve as a bridge in unstable cases. A life expectancy <1 year, often from advanced malignancy or frailty, weighs against intervention given the need for lifelong surveillance. Patient-specific risk factors further stratify suitability for EVAR, emphasizing modifiable and non-modifiable elements that amplify perioperative morbidity. Advanced age (>80 years) correlates with higher 30-day mortality and reduced long-term survival due to frailty and . Comorbidities such as (COPD), decompensated , and moderate renal impairment (eGFR 30-60 mL/min/1.73 m²) elevate risks of respiratory failure, cardiac events, and contrast-induced nephropathy, respectively. Anatomical challenges like extensive burden (>50% neck coverage) or ectatic iliac arteries (>20 mm) heighten technical failure rates. Preoperative risk stratification employs validated scoring systems to guide decision-making. The for Vascular Surgery/American Association for Vascular Surgery (SVS/AAVS) Severity Score grades major (cardiac, pulmonary, renal) and minor (, ) factors on a 0-3 scale per category, predicting operative mortality and aiding in EVAR versus open repair selection. The SVS Vascular Quality Initiative (VQI) mortality risk score integrates aneurysm characteristics and comorbidities for personalized prognostication. For patients with contraindications, alternatives include open surgical repair, which is preferred for favorable in younger patients with longer despite higher upfront morbidity. In high-risk or anatomically unsuitable cases, medical management with surveillance and risk factor optimization (e.g., , control) may be appropriate to mitigate rupture risk without intervention.

Preoperative preparation

Imaging and planning

() serves as the primary imaging modality for preoperative planning in endovascular aneurysm repair (EVAR), providing high-resolution, three-dimensional (3D) reconstructions essential for assessing aortic anatomy and device suitability. Thin-slice protocols (≤1 mm) with dual- or triple-phase contrast enhancement enable precise evaluation of the aneurysm neck diameter (typically 16–32 mm), length (optimal ≥15 mm), angulation (≤60°), and iliac artery features such as , , and branch origins, which are critical for ensuring adequate proximal and distal landing zones to prevent endoleaks and migration. Duplex ultrasound () acts as an adjunctive tool for initial AAA screening and diameter surveillance, offering non-invasive assessment with high (approximately 100%) but limited utility for detailed procedural planning due to challenges from bowel gas or . Magnetic resonance angiography () or MRI provides an alternative for patients with contrast allergies or renal impairment, yielding measurements comparable in accuracy to for neck dimensions and iliac access while avoiding . Preoperative planning begins with centerline analysis of CTA images to standardize measurements perpendicular to the vessel axis, facilitating oversizing calculations (10–20% of neck diameter) for optimal endograft sealing and fixation. Device selection—such as bifurcated versus unilateral grafts—relies on these assessments alongside manufacturer instructions for use (IFU), prioritizing aorto-iliac morphology to minimize access complications. Dedicated software tools enable and of endograft deployment, particularly for fenestrated or ed devices, by integrating centerline to predict conformability and . These platforms enhance precision in complex anatomies, reducing reliance on manual measurements and supporting customized planning. Recent advances as of 2025 include AI-assisted tools for automated segmentation of scans, extracting aneurysm features like neck morphology and to streamline planning and improve . These systems, leveraging for semantic segmentation, aid in risk stratification and device sizing, though validation across diverse datasets remains ongoing.

Patient evaluation and optimization

Patient evaluation for endovascular aneurysm repair (EVAR) begins with a multidisciplinary approach involving vascular surgeons, anesthesiologists, cardiologists, and other specialists as needed to assess overall fitness for the procedure. A thorough medical history is obtained, focusing on cardiovascular risk factors such as , history, and family predisposition to aneurysms, alongside a that includes of peripheral pulses and evaluation of access vessels. Laboratory assessments are essential, including , renal function tests (e.g., serum and estimated ), coagulation profile, and a preoperative electrocardiogram to identify baseline cardiac status. Optimization of comorbidities is critical to minimize risks and improve outcomes. is strongly recommended at least two weeks prior to EVAR, with counseling and (e.g., replacement or bupropion) to reduce complications such as issues and progression. control targeting less than 140/90 mmHg is advised through antihypertensive medications, with beta-blockers or inhibitors adjusted as part of the regimen, while holding the latter on the morning of if renal concerns exist. therapy is initiated or continued preoperatively—at least four weeks in advance—for plaque stabilization and cardiovascular risk reduction, with high-dose regimens considered around contrast exposure to mitigate contrast-induced nephropathy. Risk stratification employs tools such as the (ASA) physical status classification to categorize patients and guide further testing. For high-risk individuals—particularly those with poor functional capacity (metabolic equivalents <4), recent myocardial infarction, or multiple comorbidities—noninvasive cardiac stress testing or echocardiography is recommended to evaluate ischemic potential. The Society for Vascular Surgery Vascular Quality Initiative (VQI) mortality risk score may also be utilized to inform decision-making and patient counseling. Informed consent is obtained through shared decision-making, where the multidisciplinary team discusses the benefits and risks of EVAR compared to open surgical repair, incorporating data from randomized trials such as the EVAR-1 and OVER studies, along with personalized risk estimates. Decision aids are encouraged to facilitate understanding of procedural outcomes and long-term surveillance needs. Special preoperative preparations include tailored management of antiplatelet therapy: single-agent therapy (e.g., aspirin) is typically continued, while dual antiplatelet agents are discontinued five to seven days prior unless required for recent coronary stents, in which case they may be maintained perioperatively. Routine bowel preparation is not recommended unless specific indications arise, such as concurrent colonic pathology. Hydration protocols, such as intravenous normal saline, are implemented for patients with renal impairment to prevent contrast-related injury.

Procedure techniques

Standard EVAR

Standard endovascular aneurysm repair (EVAR) is the conventional minimally invasive technique used to treat infrarenal abdominal aortic aneurysms (AAAs) in patients with suitable anatomy, involving the deployment of a bifurcated stent-graft via femoral access to exclude the aneurysm sac from systemic circulation. This approach relies on preoperative imaging measurements to select an appropriately sized endograft that ensures adequate proximal and distal fixation while preserving flow to the iliac arteries. The procedure is typically performed in a hybrid operating room equipped with fluoroscopic capabilities, under sterile conditions, and lasts approximately 1.5 to 2.5 hours. Access to the vascular system begins with bilateral exposure of the common femoral arteries, achieved through either open surgical cutdown or percutaneous puncture using ultrasound guidance. For open access, a longitudinal incision is made over each groin, followed by arteriotomy to allow insertion of guidewires and sheaths; percutaneous access employs with smaller initial needles advanced to larger sheaths (typically 12- to 24-French) over stiff guidewires under fluoroscopic monitoring to reach the aorta. The ipsilateral side accommodates the larger main body introducer sheath, while the contralateral side uses a smaller diagnostic sheath for initial angiography. Anesthesia for standard EVAR prefers local infiltration with sedation or regional techniques (such as spinal or epidural) to facilitate patient cooperation during deployment and minimize cardiopulmonary stress, though general anesthesia may be selected for more complex anatomies or patient intolerance. Intraoperative monitoring includes continuous arterial pressure, electrocardiography, and pulse oximetry, with heparin administered for anticoagulation. The deployment sequence commences with advancement of a guidewire from the ipsilateral femoral access into the proximal aorta, confirmed by fluoroscopy, followed by insertion of the main body endograft in a collapsed state within its delivery sheath. The main body is positioned just below the renal arteries, partially deployed to expose an ipsilateral gate, and a wire is passed through the contralateral femoral access to cannulate this gate for limb extension. The contralateral limb is deployed first to secure the bifurcation, followed by full deployment of the main body and ipsilateral limb, with balloon angioplasty performed at the proximal neck, iliac attachments, and bifurcation to ensure apposition and fixation without kinking. Intraoperative imaging relies on fluoroscopy for real-time guidewire and device navigation, with intravascular ultrasound (IVUS) occasionally used to assess aortic diameter, branch patency, and graft conformation. A completion angiogram is routinely performed via the contralateral sheath to verify endograft position, exclude endoleaks, and confirm iliac limb patency and renal artery perfusion. Closure of the femoral access sites involves direct vascular repair with polypropylene sutures for open arteriotomies or deployment of percutaneous closure devices such as the Perclose ProGlide system, which uses suture-mediated cinching to achieve hemostasis and reduce recovery time.

Advanced variations

Advanced variations of (EVAR) extend the applicability of the procedure to complex aortic anatomies, such as juxtarenal, thoracoabdominal, and thoracic aneurysms, where standard infrarenal grafting is inadequate. These techniques incorporate modifications like specialized graft designs, hybrid open-endovascular strategies, and adjunctive interventions to preserve critical branch vessels and optimize outcomes in high-risk patients. Percutaneous EVAR employs ultrasound-guided femoral artery access to achieve full percutaneous closure, avoiding open groin incisions and thereby reducing wound complications, infection rates, and recovery time compared to surgical cutdown. Technical success rates for this approach exceed 95% in experienced centers, with failures primarily due to hemorrhage or vessel occlusion requiring conversion to open repair. Fenestrated EVAR (FEVAR) uses custom-fabricated endografts featuring scallop or fenestration windows aligned with the origins of visceral and renal arteries, enabling treatment of juxtarenal abdominal aortic aneurysms (AAAs) that involve short infrarenal necks. Initially reported in 1999 as a minimally invasive option for complex AAAs, FEVAR demonstrates high technical success and low perioperative mortality, with mid-term aneurysm exclusion rates comparable to open surgery. Branched EVAR (BEVAR) deploys multibranched endografts with directional branches for celiac, mesenteric, and renal arteries, targeting thoracoabdominal aortic aneurysms (TAAAs) that extend beyond the visceral segment. Custom-made devices allow tailored branch orientation for patient-specific anatomy, while off-the-shelf options provide immediate availability for urgent or ruptured cases; midterm outcomes, including survival and branch patency, are similar between these configurations in selected cohorts. Hybrid procedures integrate EVAR with open surgical debranching, where visceral and renal arteries are extra-anatomically bypassed prior to endograft deployment, facilitating aneurysm exclusion in extensive TAAAs unsuitable for fully endovascular repair. This approach reduces spinal cord ischemia risk through staged revascularization and is associated with acceptable perioperative morbidity in high-risk patients. Thoracic EVAR (TEVAR) addresses thoracic aortic aneurysms (TAAs) and dissections using stent-grafts deployed in the descending thoracic aorta, with proximal landing zones classified as 0 (proximal to the innominate artery), 1 (between the innominate and left common carotid arteries), 2 (between the left common carotid and left subclavian arteries), or 3 (distal to the left subclavian artery). Chimney grafts, parallel stents placed in arch branches during zone 0 TEVAR, preserve supra-aortic vessel flow and enable arch involvement with technical success rates over 90% and low stroke incidence in experienced settings. Adjunctive embolization of the internal iliac artery (IIA) is performed pre- or intraoperatively to resolve unfavorable iliac tortuosity or aneurysms, allowing safe distal seal zone extension during EVAR and increasing procedural feasibility without excessive ischemic complications when unilateral. Prophylactic spinal drainage, involving lumbar cerebrospinal fluid diversion, is routinely prepared for extensive TEVAR cases to lower spinal cord ischemia risk by maintaining intrathecal pressure below 10-15 mm Hg during and after deployment.

Risks and complications

Procedure-related risks

Endovascular aneurysm repair (EVAR) involves percutaneous access, catheter navigation, and device deployment under fluoroscopic guidance, exposing patients to several immediate procedural risks distinct from long-term device issues. These risks arise primarily from vascular access, contrast administration, radiation, and potential intraoperative mishaps, with overall complication rates during the procedure ranging from 16% to 30%. Recent analyses as of 2024 indicate declining intraoperative complication rates (decreasing by 0.5% per year) and overall morbidity for EVAR. Management focuses on prevention through careful technique and prompt intervention to minimize morbidity. Access complications are among the most common procedural hazards in EVAR, occurring due to femoral artery puncture and large sheath insertion. Groin hematomas, resulting from bleeding at the puncture site, affect 5% to 10% of patients, often resolving conservatively but occasionally requiring transfusion or evacuation. Pseudoaneurysms, formed by arterial wall disruption and contained hematoma, occur in approximately 2% to 3% of cases and may necessitate ultrasound-guided compression, thrombin injection, or surgical repair. Arterial injury, such as dissection or perforation, is less frequent but can lead to conversion to open surgery in 1% to 2% of procedures, particularly in patients with calcified or tortuous vessels. Embolization during EVAR can cause distal ischemia if thrombi or atherosclerotic debris dislodge during catheter manipulation or device deployment. This affects about 1% of patients, manifesting as limb-threatening hypoperfusion that requires immediate recognition via angiography. Management typically involves aspiration thrombectomy or surgical embolectomy to restore flow and prevent tissue loss. Contrast-induced nephropathy poses a significant risk, especially in patients with chronic kidney disease (CKD), where acute kidney injury develops in up to 20% following iodinated contrast exposure. This is mitigated by preoperative hydration protocols and the use of low-osmolar or iso-osmolar contrast agents, which reduce renal vasoconstriction and osmotic stress. Radiation exposure from prolonged fluoroscopy is inherent to EVAR, with dose-area product typically ranging from 50 to 100 Gy·cm², depending on procedural complexity and patient anatomy. While skin erythema is rare below 2 Gy skin dose, cumulative exposure elevates long-term cancer risk, with studies showing a 20% increased risk (hazard ratio 1.20) of abdominal malignancies compared to open repair. Intraoperative conversion to open repair occurs in approximately 1% of EVAR cases, most often due to access failure, unfavorable anatomy, or device maldeployment that precludes endovascular completion. This carries higher perioperative mortality (up to 22%) and underscores the need for hybrid operating suites and multidisciplinary planning. Advanced variations, such as fenestrated EVAR, may introduce additional access challenges but are addressed through tailored techniques.

Device-related complications

Device-related complications in endovascular aneurysm repair (EVAR) primarily arise from the endograft's interaction with the vascular anatomy, potentially leading to aneurysm sac pressurization, ischemia, or device failure. These issues, occurring in 16-30% of patients, necessitate vigilant surveillance to mitigate risks of rupture or reintervention. Endoleaks represent the most prevalent device-related complication, with an overall incidence of 15-30% following EVAR. Classified into five types based on etiology, they involve persistent blood flow into the aneurysm sac outside the endograft. Type I endoleaks, resulting from inadequate sealing at the proximal or distal attachment sites, occur in 5-10% of cases and pose a high rupture risk due to direct pressurization. Type II endoleaks, caused by retrograde flow from collateral branches such as lumbar or inferior mesenteric arteries, are the most common, affecting 10-25% of patients; while often benign without sac expansion, they may require intervention if persistent. Type III endoleaks stem from structural defects in the graft, including fabric tears or modular disconnection, with a reported incidence of 2-5%. Type IV endoleaks, due to porosity of the graft material, are rare (<1%) and typically self-resolve, particularly with modern devices. Type V endoleaks, or endotension, involve sac enlargement without detectable leakage, attributed to pressure transmission through the thrombus or graft wall, though their exact incidence remains undefined. Endograft migration, defined as caudal or proximal displacement exceeding 10 mm, occurs in 1-10% of cases within the first year post-EVAR, often due to undersizing of the device relative to the aneurysm neck or progressive neck dilation from hemodynamic forces. This complication can precipitate type I endoleaks or limb occlusion, underscoring the importance of precise anatomical matching during planning. Graft thrombosis, manifesting as limb occlusion, affects 2-5% of patients and is frequently linked to endograft kinking or stenosis in tortuous iliac vessels, compromising distal perfusion and potentially requiring thrombolysis or relining. Unsupported grafts exhibit higher rates, up to 40%, compared to 0-5% in those with radial force support. Endograft infection is uncommon, with rates of 0.4-3%, but carries severe consequences including sepsis or secondary endoleaks; clinical presentation often includes fever, back pain, or perigraft fluid collections, frequently necessitating complete device explantation. Stent fracture or structural failure, such as discontinuity in the nitinol frame or sutures, is rare in contemporary devices, occurring in approximately 5.5% of monitored cases, and is typically identified through serial imaging during surveillance to prevent associated endoleaks or migration.

Postoperative care and outcomes

Recovery process

Following the endovascular aneurysm repair (EVAR) procedure, patients are transferred to the post-anesthesia care unit (PACU) for initial monitoring, where vital signs such as blood pressure, heart rate, and oxygen saturation are closely observed, along with urine output to ensure adequate renal perfusion (targeting 0.5–2.0 mL/kg/hour). This phase typically lasts until the patient is hemodynamically stable, after which they move to a general ward for continued observation. The hospital stay for elective EVAR is generally short, averaging 2–3 days, allowing for recovery in a controlled setting with serial assessments of graft position via imaging if needed. Pain management employs a multimodal approach, prioritizing non-opioid agents like acetaminophen and local measures for groin access sites, with opioids used sparingly to minimize side effects; access sites require careful monitoring and dressing changes to prevent infection or hematoma formation. Early mobilization is encouraged, with patients ambulating within 24 hours to promote circulation and reduce complications, supported by deep vein thrombosis (DVT) prophylaxis including intermittent pneumatic compression devices and low-molecular-weight heparin. Discharge occurs once criteria are met, including stable vital signs, tolerance of oral diet, independent ambulation, and absence of expanding hematoma or other acute issues at the access sites. Early outcomes for elective EVAR are favorable, with a 30-day mortality rate of approximately 1.3% and a readmission rate of around 10–12%, often for observation of minor access-site issues.

Surveillance and long-term management

Surveillance after endovascular aneurysm repair (EVAR) is essential to monitor for complications such as endoleaks, device migration, and aneurysm sac expansion, ensuring the durability of the repair. The European Society for Vascular Surgery (ESVS) 2024 guidelines recommend computed tomography angiography (CTA) as the primary imaging modality, with protocols typically involving CTA at 1 month, 6 months, and 12 months post-procedure, followed by annual imaging if the aneurysm sac is stable and no endoleaks are present. Duplex ultrasound (DUS) serves as a non-invasive alternative after the first year in low-risk patients, offering sensitivity of 0.77 and specificity of 0.97 for detecting endoleaks, while contrast-enhanced ultrasound (CEUS) provides even higher accuracy with sensitivity of 0.94 and specificity of 0.93. These guidelines emphasize lifelong surveillance for all patients, with intensified imaging (e.g., annual CTA) for high-risk cases involving short neck anatomy, type II endoleaks, or specific devices like the Nellix endograft. Aneurysm sac dynamics are a key indicator of procedural success during follow-up. Sac regression of more than 5 mm from baseline is considered a marker of effective aneurysm exclusion, while a stable sac (change ≤5 mm) is also viewed as successful in many protocols. Studies report that approximately 70-75% of patients achieve either sac regression or stability at 1-year follow-up, correlating with lower rates of late complications. Conversely, sac expansion greater than 5 mm warrants immediate evaluation for endoleaks or migration, as it is associated with increased aneurysm-related mortality. Reintervention rates after EVAR range from 10-20% at 5 years, primarily driven by endoleaks (especially type I or II) and device migration, with higher rates in complex anatomies or fenestrated/branched procedures (up to 15.7%). The EVAR-1 trial's 15-year follow-up demonstrated significantly higher reintervention needs for EVAR compared to open repair (adjusted hazard ratio [HR] 2.42, 95% CI 1.82-3.21), at a rate of 4.1 versus 1.7 per 100 person-years, though overall survival was equivalent (median 8.7 vs. 8.3 years; adjusted HR 1.11, 95% CI 0.97-1.27). Aneurysm-related mortality was similar between groups (1.1 vs. 0.9 deaths per 100 person-years), but EVAR showed higher late risks after 8 years. Recent advancements in 2024-2025 include the integration of artificial intelligence (AI) for enhanced endoleak detection during surveillance. AI-based deep learning models have demonstrated high accuracy in automating endoleak identification on digital subtraction angiography (DSA) post-EVAR, with potential to reduce imaging burden and improve precision in risk-stratified protocols. The ESVS guidelines support such innovations for risk prediction and imaging analysis, aligning with the shift toward personalized, lifelong management to mitigate long-term failure rates of 5-10% over 5-10 years.

History and advancements

Early development

The concept of endovascular aneurysm repair (EVAR) originated with the pioneering work of , who performed the first successful human case on September 7, 1990, in , . Parodi, collaborating with , deployed a handmade device consisting of a and a crimped tube graft inserted via a femoral approach to exclude an () in a 68-year-old patient, marking a shift from traditional open surgery. Early EVAR devices evolved from Parodi's initial aorto-uni-iliac prototype, which required surgical crossover femorofemoral bypass for iliac occlusion. By the mid-1990s, bifurcated configurations emerged to address bilateral iliac involvement more effectively, with the AneuRx stent graft—a modular, fully supported nitinol device—receiving initial European approval in 1996 and U.S. Food and Drug Administration (FDA) approval in 1999 as the first commercially available bifurcated system. Pivotal clinical trials in the late 1990s and early 2000s established EVAR's role compared to open repair. The EVAR-1 trial, conducted in the United Kingdom from 1999 to 2004, randomized 1,252 patients with AAAs ≥5.5 cm to EVAR versus open surgery, demonstrating lower 30-day mortality with EVAR (1.7% vs. 4.7%) but similar long-term survival. The United Kingdom Small Aneurysm Trial (UKSAT), initiated in 1991 for aneurysms 4.0-5.5 cm, informed EVAR applications by showing no survival benefit from early open repair over surveillance, prompting evaluations of EVAR's lower-risk profile for smaller AAAs.04144-0/fulltext) Initial adoption faced significant challenges, including high rates of endoleaks—persistent blood flow into the aneurysm sac—which occurred in up to 40-47% of early cases across initial trials, often necessitating reinterventions or conversions to open repair due to device migration and incomplete sealing.00283-6/fulltext) These issues drove refinements in graft design and deployment techniques throughout the 1990s. Key milestones included the extension to thoracic applications, with the first thoracic endovascular aortic repair (TEVAR) cases performed experimentally in the early 1990s, though widespread use awaited FDA approval of the Gore TAG device in 2005 following its pivotal trial, which reported 90-day freedom from aneurysm-related death at 96%.

Recent innovations

Since the 2010s, advancements in EVAR graft materials have focused on enhancing durability and minimizing endoleak risks, particularly through polymer-sealed fabrics. The Ovation Prime and Alto abdominal stent grafts, for instance, incorporate polyethylene glycol (PEG)-based polymer-filled sealing rings that conform to the aortic neck, achieving a low-profile delivery while effectively sealing the aneurysm sac and reducing the incidence of Type I and II endoleaks; five-year data indicate freedom from Type I/II endoleak rates exceeding 95% in suitable anatomies.02205-4/fulltext) These polymer technologies address limitations in traditional porous fabrics prone to Type IV endoleaks, which result from graft material permeability, by promoting more uniform sac exclusion and potentially lowering delayed porosity-related complications. Parallel innovations include bioactive coatings on stent grafts to accelerate endothelialization and improve long-term patency. Nitrogen-rich plasma polymer coatings applied to polyester and polytetrafluoroethylene (PTFE) fabrics have demonstrated enhanced endothelial cell adhesion and proliferation in vitro, reducing thrombus formation and promoting neointimal healing post-EVAR without eliciting significant inflammation. Such coatings mimic extracellular matrix cues, fostering rapid coverage of the graft surface and mitigating risks associated with delayed endothelial regrowth in high-flow aortic environments. Off-the-shelf branched devices have revolutionized treatment for complex thoracoabdominal aortic aneurysms (TAAAs), eliminating the delays of custom fabrication. The Zenith t-Branch endograft, with its four downward-oriented inner branches, enables immediate deployment for urgent cases, achieving target vessel patency rates of 94-98% at one year and reducing procedural wait times from weeks to hours compared to physician-modified or custom devices. Clinical outcomes from multicenter registries show technical success in over 90% of TAAA repairs, with early mortality under 10% in elective settings, broadening applicability to patients with challenging anatomy. Robotic assistance has emerged to enhance precision in EVAR deployment, particularly for fenestrated and branched procedures. The Magellan robotic system, featuring flexible catheters with haptic feedback, has undergone preclinical and first-in-human trials demonstrating improved navigation through tortuous iliacs and reduced radiation exposure for operators; animal studies confirm safe vessel traversal with 100% success in randomized cohorts.00488-3/fulltext) More recent platforms, like the CorPath GRX adapted for endovascular use, enable remote manipulation, minimizing hand fatigue and enhancing alignment accuracy in complex cases. Perioperative innovations continue to optimize access and imaging. Low-profile sheaths under 14F, such as those in the and systems (12-14F outer diameter), facilitate EVAR in patients with small or calcified iliac arteries, expanding eligibility to anatomies previously limited to open repair; comparative studies report equivalent aneurysm exclusion rates with reduced access complications. Integration of (IVUS) during procedures provides real-time cross-sectional imaging, decreasing contrast use by up to 50% and improving endograft apposition assessment; national database analyses from 2016-2023 link IVUS adoption to lower 30-day mortality (1.5% vs. 2.3%) and reintervention rates in both EVAR and TEVAR. As of 2025, key updates include the European Society for Vascular Surgery (ESVS) consensus on ascending thoracic endovascular aortic repair (aTEVAR), endorsing its use in high-risk patients with penetrating aortic ulcers, pseudoaneurysms, and type A dissections via investigational grafts like the Gore Ascending Stent Graft, with recommendations for ≥2 cm landing zones and 10-30% oversizing to ensure seal in dynamic ascending aorta segments. Artificial intelligence (AI) tools for preoperative planning and outcome prediction have gained traction, with machine learning models analyzing CT angiography to forecast post-EVAR sac regression and complications, achieving AUC scores >0.85 for 1-year aneurysm shrinkage; prospective trials from 2024-2025 validate AI simulations in reducing operative time by 20-30%. Additionally, EVAR utilization for ruptured abdominal aortic aneurysms (rAAAs) has increased, with 30-day mortality rates below 30% in centralized centers, driven by refined protocols and lower-profile devices that enable faster deployment in hemodynamically unstable patients.

Special applications

Human special populations

Women undergoing endovascular aneurysm repair (EVAR) for abdominal aortic aneurysms (AAAs) face unique challenges due to smaller vascular , including narrower aortic necks and iliac arteries, which reduce eligibility for standard devices and increase the risk of technical difficulties during deployment. This anatomical difference contributes to higher rates of intraoperative complications, such as access vessel injury, with studies reporting odds ratios for technical failure approximately twice that of men (OR 2.0). Consequently, procedural planning for women often requires customized protocols, smaller sizes, and alternative strategies like brachial or direct aortic approaches to mitigate these risks. Additionally, women exhibit a higher at smaller diameters compared to men, prompting guidelines to recommend at a lower of 5.0 cm for AAAs in females to prevent rupture. Subgroup analyses from major trials, such as EVAR-1, indicate that women experience approximately 1.5 times the reintervention rate post-EVAR compared to men, often due to endoleaks or device migration influenced by their vascular morphology. In patients with renal or heart transplants, EVAR is generally preferred over open repair to minimize disruption to immunosuppressive regimens and preserve graft function, as the endovascular approach avoids aortic cross-clamping and prolonged hemodynamic instability. For renal transplant recipients, where the graft is typically anastomosed to the , meticulous is essential to select contralateral iliac that bypasses the transplant site, thereby preventing ischemia or injury to the allograft during device deployment. Similarly, in heart transplant patients, EVAR has demonstrated feasibility and low morbidity, with case series reporting successful outcomes without significant impact on cardiac allograft function or needs. Elderly patients over 80 years old often present with elevated comorbidities, including cardiovascular and pulmonary disease, which heighten overall procedural risks; however, EVAR offers lower compared to open repair in this group, with 30-day rates as low as 1-2% in select cohorts. Frailty assessment tools, such as the modified , are recommended to stratify risk, as frail octogenarians face nearly double the hazard of all-cause mortality post-EVAR ( 1.95), guiding decisions on candidacy and postoperative care. Patients with genetic syndromes like vascular Ehlers-Danlos syndrome (vEDS) pose additional complexities due to fragile vessel walls prone to or rupture, necessitating highly individualized EVAR strategies, including custom-made fenestrated or branched grafts to accommodate aneurysmal morphology while minimizing manipulation of diseased tissue. Outcomes in these cases are favorable with endovascular techniques when anatomy permits, showing low rates of access-site complications and sustained exclusion, though long-term is intensified to detect rare device-related failures.

Veterinary use

Endovascular aneurysm repair (EVAR) has seen limited clinical application in , with reported cases primarily involving dogs suffering from aortic aneurysms or related complications such as rupture or . Unlike in , where EVAR is a standard procedure for abdominal aortic aneurysms () or thoracic aortic aneurysms (TAA), veterinary use remains rare due to the infrequent occurrence of such conditions in companion animals and the challenges of adapting human-sized devices to veterinary patients. The technique draws from human principles but requires significant modifications for animal anatomy, such as using smaller, custom balloon-expandable stent-grafts deployed under fluoroscopic guidance via femoral access. A notable case involved a 4-year-old, 25-kg mixed-breed dog presenting with acute weakness, respiratory distress, and confirmed with rupture via computed tomography, revealing and peri-aortic . Treatment consisted of deploying a 12-mm × 50-mm balloon-expandable aortic -graft through a right approach under general , supported by intravenous fluids, , and to manage . The procedure successfully excluded the , preventing further bleeding, with the dog recovering uneventfully and being discharged after 2 days; at 90-day follow-up, the animal was clinically normal with stable stent position confirmed radiographically. This case demonstrated EVAR's potential to reduce rupture risk in canine aortic , though prior reports, such as those on without endovascular intervention, highlight the condition's diagnostic challenges and poor without treatment. Adaptations for veterinary patients include oversized or custom grafts to accommodate varying vessel diameters in (typically 8-15 mm for the ), with or preferred over for guidance due to cost and availability in clinical settings. No clinical EVAR cases have been widely reported in , despite the breed predisposition to aortic ruptures in Friesians, where aneurysms often present as pseudoaneurysms; treatment in equines remains predominantly surgical or conservative. Challenges in veterinary EVAR include high procedural costs (often exceeding $10,000 due to specialized equipment and ), risks associated with general in compromised animals, and a paucity of long-term , with short-term rates in reported cases approaching 100% but lacking multi-year follow-up. Limited to facilities further restricts adoption. Ongoing research utilizes porcine models to test EVAR devices for human applications, with 2024 studies developing thoracic models via remote drug infusion systems to simulate endograft deployment while preserving distal and minimizing surgical . These models achieved successful aneurysm creation in 100% of cases in small cohorts (n=5) short-term, informing device refinements but not yet translating to broader veterinary clinical use.