Advances in surgical thresholds for ascending aortic aneurysms: an expert perspective
0 Abstract
The ascending aortic aneurysm represents a critical clinical concern due to its potential for catastrophic complications. With global demographic shifts toward aging populations, the incidence of ascending aortic aneurysms is projected to rise significantly. This brief perspective examines the evolution of our understanding regarding the natural history of ascending aortic aneurysms and the refinement of surgical intervention criteria over time. We discuss the transition from simplistic diameter-based metrics to multidimensional assessment approaches that consider patient-specific factors, including anatomical variations, biomechanical properties, and genetic predispositions. Recent paradigm shifts, such as the recalibration of diameter thresholds from 5.5 cm to
Keywords
INTRODUCTION
The ascending aortic aneurysm represents a critical focus in cardiovascular medicine due to the potentially catastrophic consequences of aneurysmal complications. As global populations continue to age, the prevalence of ascending aortic aneurysms is anticipated to increase, presenting heightened clinical challenges. Recent compelling evidence has demonstrated that chronological age alone constitutes an inadequate metric for surgical risk assessment. Carefully selected elderly patients with threatening aortic aneurysms can derive significant benefit from surgical intervention despite advanced age[1].
The fundamental question that continues to challenge clinicians remains: What constitutes the optimal timing for intervention? This perspective aims to provide an overview of the evolution in our understanding of the natural history of ascending aortic aneurysms and the progressive refinement of surgical intervention criteria, integrating historical perspectives with contemporary evidence-based approaches.
Historical development of surgical standards
Systematic investigation of surgical standards for aortic aneurysms began with the landmark study by
A significant advancement occurred in 1997 when Elefteriades initiated a comprehensive, ongoing research program on the natural history of thoracic aortic aneurysms. Their initial studies determined that the median diameter at which rupture or dissection occurred was 6.0 cm for ascending aortic aneurysms and 7.2 cm for descending aortic aneurysms[3]. This analysis yielded a crucial insight: if the median diameter at catastrophic complication were used as the intervention threshold, half of all patients would suffer severe consequences before surgical intervention. Consequently, they proposed 5.5 cm as an appropriate threshold for elective resection of ascending aortic aneurysms. This standard was subsequently adopted by the American Heart Association (AHA) guidelines in 2010 and the European Society of Cardiology (ESC) guidelines for aortic disease management in 2014.
Individualization of surgical criteria: consideration of patient body size
Recognizing the limitations of a "one-size-fits-all" approach based solely on absolute aortic diameter,
Importance of aortic length
Working with Dr. Elefteriades, Zafar Mohammad conducted a systematic review of Yale's aortic data, establishing an elegant and invaluable natural history database of the thoracic aorta, compiling information from over 3,000 patients. Between 2018 and 2019, the author had the privilege of participating in most subsequent research on the natural history of thoracic aortic disease[7]. Inspired by work from European colleagues[7], we investigated the clinical significance of ascending aortic length. Surprisingly, elongation of the ascending aorta proved to be an extraordinarily accurate predictor of adverse outcomes in ascending aortic aneurysms. Based on these findings, we proposed an ascending aortic length of 11 cm as an intervention criterion, complementing established diameter-based approaches[8]. The 2024 EACTS/STS Guidelines indicated that in patients with non-syndromic Tricuspid Aortic Valve (TAV) with "ascending phenotype", in a low-surgical-risk setting, surgery may be considered at a maximum diameter
Reassessment of diameter-based criteria: the aortic size paradox
The International Registry of Acute Aortic Dissection (IRAD), led by Pape et al., identified the so-called "aortic size paradox"[9]. This paradoxical finding revealed that a substantial proportion of aortic dissections occur in patients with aortic diameters below the conventional 5.5 cm intervention threshold[9]. This observation raised a critical question: should diameter-based aortic surgical standards be lowered?
The 2022 ACC/AHA Guideline recommended that “At centers with Multidisciplinary Aortic Teams and experienced surgeons, the threshold for surgical intervention for sporadic aortic root and ascending aortic aneurysms has been lowered from 5.5 cm to 5.0 cm in selected patients, and even lower in specific scenarios among patients with heritable thoracic aortic aneurysms[6]”. We conducted a study in 2023, encompassing three decades of experience at Yale University's Aortic Institute. It was demonstrated that 5.0 cm rather than 5.5 cm represents a more accurate intervention threshold[10]. This finding supports the concept of a "leftward shift" in surgical standards - earlier intervention based on a more profound understanding of the natural history of aortic disease.
The "phenomenon of five"
Extending the research to the descending thoracic aorta, we discovered that the probability of fatal complications (aortic rupture or death) increases sharply at two distinct inflection points: 6.0 cm and
Interestingly, we observed a pattern informally termed the "Phenomenon of Five": ascending aortic aneurysms exceeding 5.0 cm are prone to dissection, descending aortic aneurysms beyond 5.0 cm are susceptible to both dissection and rupture, while abdominal aortic aneurysms larger than 5.0 cm primarily tend toward rupture. This observation provides a useful clinical mnemonic while highlighting regional differences in the natural history of aortic pathology. This phenomenon likely reflects distinct embryological origins of different aortic segments. The ascending aorta derives from neural crest cells, while the descending thoracic and abdominal segments originate from mesodermal tissue. These developmental distinctions manifest in varying extracellular matrix compositions, mechanical properties, and pathophysiological responses to hemodynamic stress.
Beyond diameter: volume assessment
The integration of multiple dimensions of aortic geometry may provide greater predictive capability than single-dimensional measurements. While a 1 mm change in aortic diameter might not attract sufficient clinical attention, it may correspond to a volume change exceeding 100 uL - representing a more readily detectable alteration in aortic geometry. Applying hemodynamic principles, we demonstrated that ascending aortic volume serves as an excellent predictor of adverse outcomes[12]. Volumetric assessment represents a promising advancement, integrating multiple aspects of aortic geometry into a single comprehensive measurement. Three-dimensional modeling reveals that volume expansion correlates more strongly with wall stress distribution than diameter alone. Advanced imaging protocols now permit semi-automated volumetric quantification with high reproducibility, facilitating clinical implementation of this metric.
Genetic considerations in surgical decision-making
Aortic genetics and phenotype are intrinsically linked. Thanks to the pioneering research by
Bicuspid aortic valve: updated understanding
Bicuspid aortic valve (BAV) represents one of the most common cardiovascular congenital anomalies, frequently coexisting with ascending aortic dilatation. Traditional perspectives suggested aggressive management of the aorta in BAV patients with ascending aortic expansion. However, recent research challenges this assumption.
We found that the threshold for ascending aortic aneurysm surgical repair should not differ between BAV and TAV patients. Specifically, preventive surgery should be considered at 5.0 cm for both patient populations when treated at specialized centers[15]. Our recent research encompassing 698,795 individuals supports this updated understanding, demonstrating that while BAV patients exhibit higher rates of aortic enlargement (37.00%) and aneurysm formation (16.46%), the incidence of aortic dissection remains relatively low (0.74%)[16]. These findings suggest that the natural history of aortic pathology in BAV patients may be less aggressive than previously thought.
FUTURE DIRECTIONS
As our understanding of aortic disease continues to deepen, several promising avenues for further refinement of surgical standards are emerging.
Integration of multiple risk factors
Future approaches may integrate multiple risk factors - including diameter, length, volume, growth rate, family history, genetic markers, and biomechanical properties - into comprehensive risk assessment models. Machine learning algorithms may facilitate the development of personalized risk calculators that synthesize these diverse inputs to generate individualized recommendations.
Advanced imaging biomarkers
Emerging imaging technologies, including 4D flow magnetic resonance imaging (MRI) and computational fluid dynamics simulations, provide deeper insights into aortic hemodynamics and wall stress distribution. These advanced modalities may identify "vulnerable" regions of the aorta before significant abnormalities are detected by routine measurements.
Recent developments in elastography techniques permit direct assessment of aortic wall stiffness, revealing mechanical compromises that precede geometric changes[17]. Similarly, positron emission tomography using targeted radiotracers can detect inflammatory activity within the aortic wall, identifying active disease processes that may accelerate aneurysm progression[18]. The integration of these functional imaging biomarkers with traditional anatomic measurements represents a significant advancement in risk stratification.
Molecular and cellular biomarkers
Circulating biomarkers reflecting aortic wall degeneration or inflammation may complement imaging-based assessments, potentially allowing earlier identification of patients at high risk for aortic complications[19]. Research in this area, including extracellular matrix proteins, inflammatory mediators, and microRNAs, shows promising results. Proteomic analysis of plasma samples from patients with progressive versus stable aneurysms has identified distinct molecular signatures that precede clinical deterioration[20]. Longitudinal biorepositories linked to clinical outcomes databases are the key for those molecular candidates advancing toward clinical implementation.
CONCLUSION
The evolution of surgical standards for ascending aortic aneurysms reflects the progressive refinement of our understanding of aortic disease. As summarized in Table 1, the field has evolved from initial crude diameter-based thresholds to current multifaceted approaches incorporating patient-specific factors, representing significant advancements in optimizing the decision-making process.
Evolution of surgical thresholds for ascending thoracic aortic aneurysms
| Parameter | Threshold | Patient population | Evidence level | Key supporting study |
| Diameter-based Criteria | ||||
| Ascending aorta diameter | 5.5 cm | General population (TAV) | Historical standard | Coady et al., 1997[3] |
| Ascending aorta diameter | 5.0 cm | General population (updated) | Strong | Wu et al., 2023[10] |
| Ascending aorta diameter | 5.0 cm | BAV patients | Strong | Zafar et al., 2024[15]; Wu et al., 2023[16] |
| Ascending aorta diameter | 4.0-4.5 cm | High-risk genetic variants | Expert consensus | Ostberg et al., 2020[14] |
| Body size-indexed Criteria | ||||
| Aortic cross-sectional area/height ratio | 10 cm2/m | Patients with Marfan syndrome | Moderate | Svensson et al., 2002[21] |
| Aortic size index (ASI) | 3.00 cm/m2 | General population | Moderate | Zafar et al., 2018[4] |
| Aortic height index (AHI) | 3.21 cm/m | General population | Moderate | Zafar et al., 2018[4] |
| Length-based Criteria | ||||
| Ascending aortic length | 11 cm | General population | Moderate | Wu et al., 2019[8] |
| Volume-based Criteria | ||||
| Ascending aortic volume | 197 mL | General population | Emerging | Xiao et al., 2023[12] |
Looking ahead, the integration of anatomical, biomechanical, genetic, and molecular factors promises to further personalize surgical decision-making, ensuring that each patient receives appropriately timed intervention with optimized risk-benefit ratios. The ultimate goal remains unchanged: to intervene before catastrophic complications occur while avoiding unnecessary surgery in low-risk patients.
DECLARATIONS
Authors' contributions
The author contributed solely to the article.
Availability of data and materials
This is a perspective article based on published literature. All data referenced in this manuscript are available in the cited publications. No new datasets were generated or analyzed during the current study.
Financial support and sponsorship
This work was supported by the National Natural Science Foundation of China (82200518), Outstanding Young Talent Trainee Program of Guangdong Provincial People’s Hospital (KY012023331) and Noncommunicable Chronic Diseases-National Science and Technology Major Project (No. 2023ZD0504400).
Conflicts of interest
The author declares that there are no conflicts of interest.
Ethical approval and consent to participate
Not applicable.
Consent for publication
Not applicable.
Copyright
© The Author(s) 2025.
REFERENCES
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