Augmentation Index in Patients with Thoracic Aortic Aneurysm: A Matched Case-Control Study.
Patrick BaumgartnerProtazy RejmerMartin OsswaldStefan MalesevicNoriane Andrina SieviMaurice RoederJonas HerthSimon F StämpfliChristian F ClarenbachFelix C TannerThomas GaislMalcolm KohlerPublished in: Journal of cardiovascular development and disease (2022)
Thoracic aortic aneurysms (TAA) may be associated with complications such as rupture and dissection, which can lead to a fatal outcome. Increased central arterial stiffness has been proposed to be present in patients with TAA compared to unmatched controls. We aimed to assess whether wall properties in patients with TAA are also altered when compared to a matched control group. Applanation tonometry was performed in 74 adults with TAA and 74 sex, age, weight, height, and left ventricular ejection fraction matched controls. Subsequently analysis of the pulse wave was done using the SphygmoCor System. For comparing the two groups, AIx was adjusted to a heart rate of 75/min (AIx@75). 148 1-to-1 matched participants were included in the final model. There was no significant difference in the Alx@75 between the TAA group and the matched control group [mean (SD) of 24.7 (11.2) % and 22.8 (11.2) %, p = 0.240]. Adjusted for known cardiovascular risk factors, there was no association between TAA and AIx@75. Patients with TAA showed comparable arterial wall properties to cardiovascular risk factor matched controls. Since higher arterial stiffness is associated with TAA progression, it remains to be investigated if increased central arterial stiffness is a relevant factor of TAA emergence.
Keyphrases
- coronary artery
- blood pressure
- heart rate
- ejection fraction
- left ventricular
- cardiovascular risk factors
- risk factors
- body mass index
- heart rate variability
- aortic stenosis
- type diabetes
- metabolic syndrome
- aortic aneurysm
- weight loss
- high resolution
- atomic force microscopy
- spinal cord injury
- mitral valve
- atrial fibrillation
- pulmonary arterial hypertension
- single molecule
- high speed
- body weight