CORRELATION BETWEEN AORTIC ROOT STIFFNESS AND AORTIC ROOT 2D SPECKLE STRAIN IN PATIENTS HAVING CORONARY ARTERY DISEASE

Document Type : Original Article

Authors

Cardiology Department, Faculty of Medicine, Al-Azhar University, Cairo, Egypt

Abstract

Background: Aortic stiffness is a hallmark of aging, and classic cardiovascular risk factors play a role in accelerating this process. Current changes in medicine, which focus on preventive care, have led to an interest in noninvasive evaluation of aortic stiffness. Aortic stiffness has emerged as a good tool for further risk stratification because it has been linked to increased risk of atherosclerotic heart disease, myocardial infarction and heart failure.
Objective: To assess feasibility of aortic root 2D-ST echocardiography for the early prediction of ischemic heart patients and its correlation with aortic stiffness parameters.
Patients and Methods: Seventy patients were included in this study which further subdivided into 45 ischemic patients (ischemic group) and 25 non ischemic patients (normal group). Informed consent, detailed history, physical examination, resting 12 leads ECG, full laboratory investigations, conventional 2D echocardiography, aortic root 2D-ST echocardiography and coronary angiography were done. The study was performed at Bab Al-Sharia University Hospital during the period from April 2020 to October 2020.
Results: Global circumferential ascending aortic root strain (CAAS) and longitudinal ascending aortic root strain (LAAS) significantly decreased with the presence of significant coronary stenosis, both of them decreased incrementally with increasing severity of CAD, and there was significant correlation between aortic root 2D strain parameters and aortic stiffness parameters.
Conclusion: Global circumferential ascending aortic root strain and longitudinal ascending aortic root strain assessed by aortic root 2D-ST echocardiography at rest were an independent predictor of significant CAD. Furthermore, global CAAS and LAAS were related to the severity of CAD and capable of identifying multivessel disease.

Keywords

Main Subjects


CORRELATION BETWEEN AORTIC ROOT STIFFNESS AND AORTIC ROOT 2D SPECKLE STRAIN IN PATIENTS HAVING CORONARY ARTERY DISEASE

By

Ahmed Hamdy Abd El-Aziz**, Abou-Bakr El-Seddik Tammam Hussein* and Al-Hussein Mustafa Zahran

*Cardiology Department, Faculty of Medicine, Al-Azhar University, Cairo, Egypt

**Corresponding author: Ahmed Hamdy Abd El-Aziz,

Mobile: 01015218546, E-mail: ahm.ham.bay@gmail.com

ABSTRACT

Background: Aortic stiffness is a hallmark of aging, and classic cardiovascular risk factors play a role in accelerating this process. Current changes in medicine, which focus on preventive care, have led to an interest in noninvasive evaluation of aortic stiffness. Aortic stiffness has emerged as a good tool for further risk stratification because it has been linked to increased risk of atherosclerotic heart disease, myocardial infarction and heart failure.

Objective: To assess feasibility of aortic root 2D-ST echocardiography for the early prediction of ischemic heart patients and its correlation with aortic stiffness parameters.

Patients and Methods: Seventy patients were included in this study which further subdivided into 45 ischemic patients (ischemic group) and 25 non ischemic patients (normal group). Informed consent, detailed history, physical examination, resting 12 leads ECG, full laboratory investigations, conventional 2D echocardiography, aortic root 2D-ST echocardiography and coronary angiography were done. The study was performed at Bab Al-Sharia University Hospital during the period from April 2020 to October 2020.

Results: Global circumferential ascending aortic root strain (CAAS) and longitudinal ascending aortic root strain (LAAS) significantly decreased with the presence of significant coronary stenosis, both of them decreased incrementally with increasing severity of CAD, and there was significant correlation between aortic root 2D strain parameters and aortic stiffness parameters.

Conclusion: Global circumferential ascending aortic root strain and longitudinal ascending aortic root strain assessed by aortic root 2D-ST echocardiography at rest were an independent predictor of significant CAD. Furthermore, global CAAS and LAAS were related to the severity of CAD and capable of identifying multivessel disease.

Keywords: Global circumferential ascending aortic root strain, longitudinal ascending aortic root strain, aortic stiffness index, aortic distensibility, aortic root 2D speckle tacking echocardiography.

 

 

INTRODUCTION

     Arterial stiffening is one of the earliest detectable manifestations of adverse structural and functional changes within the vessel wall. Degenerative stiffening of the arterial beds i.e., arteriosclerosis tends to coexist, causing progressive, diffuse, and age-related deterioration in all vascular beds (Cavalcante et al., 2011).

     Increased aortic stiffness is a risk factor for cardiovascular diseases and a predictor of cardiovascular morbidity and mortality. Consequently, assessment of arterial stiffness is increasingly used in clinical practice. However, validity and reproducibility of the conventional methods used for local assessment of arterial stiffness, such as elastic modulus, distensibility, and stiffness index, are limited by their dependence on the patient’s blood pressure (Kim et al., 2012).

     Two-dimensional speckle tracking echocardiography is a promising new imaging modality. It permits offline assessment of tissue velocities and deformation parameters such as strain and strain rate. It is well accepted that these parameters provide important insights into systolic and diastolic function, myocardial mechanics and many other pathophysiological processes of the heart (Yuda et al., 2011).

     Two-dimensional (2D) strain echocardiography was developed to allow a rapid, accurate, angle-independent determination of regional myocardial deformation (Bu et al., 2018).

     Circumferential deformation of the descending thoracic aorta, abdominal aorta, or carotid arteries can be measured using 2D speckle tracking (2D-ST), allowing a simple and accurate determination of aortic stiffness (Teixeira et al., 2015).

     The development and progression of atherosclerosis is important, especially in cardiovascular diseases. Atherosclerosis decreases the flexibility of large vessels and the vascular bed, and the decreased flexibility facilitates atherosclerotic development. Currently, it is possible to measure the flexibility change (aortic stiffness index and distensibility) by noninvasive echocardiography (Şatiroğlu et al., 2012).

     Aorta influences the circulation in a global fashion by serving as a conduit and playing important roles in modulating left ventricular (LV) performance, myocardial perfusion, central hemodynamics, and arterial function throughout the entire cardiovascular system (Boudoulas et al., 2012).

     The elastic properties of the aorta can be related to the degree of CAD. Hence, it would be appealing if the ascending aortic strain assessed by 2D-ST echocardiography could improve the diagnostics for coronary artery stenosis (Bu et al., 2018).

     The aim of this work was to assess feasibility of real-time two-dimensional speckle tracking echocardiography on the aortic root for the early prediction of ischemic heart patients and its correlation with aortic stiffness parameters.

PATIENTS AND METHODS

     This pilot study involved patients with acute myocardial infarction (STEMI, non-STEMI and unstable angina) and patients with stable anginal pain, the patients were screened for the study enrolment prospectively. The study was performed at Bab Al-Sharia Hospital, Al-Azhar University, during the period from April 2020 to October 2020. The protocol and all corresponding documents were approved by Ethical and Research committee, Faculty of Medicine, Al-Azhar University and patients provided informed consents.

The patients were classified into two groups matched in age:

Group (1): Patients group: 45 patients (50-75 years old) with acute coronary syndrome or patients with stable anginal pain.

Group (2): Control group 25 patients (same age group) with similar demographic characteristics but with normal coronary angiography.

Inclusion criteria: All patients with acute coronary syndrome (STEMI, non-STEMI and unstable angina) and stable anginal pain.

Exclusion criteria: Patients with impaired LV systolic function (EF< 50%), patients with significant valvular heart disease, myocardial and pericardial disease, congenital heart disease, left ventricular hypertrophy, chronic systemic or inflammatory diseases, any form of malignancy, aortic aneurysms, systematic diseases affecting the aorta, arrhythmias and intraventricular conduction disturbances.

     All subjects were exposed to full history taking, general and local cardiac examination, resting 12-lead ECG, resting conventional echocardiography, aortic root 2D-ST echocardiograph and coronary angiography.

     Gensini score was used to assess the severity of epicardial coronary artery disease (Kobayashi, et al., 2017).

 

Figure (1): (A) Representative CAAS curves in a patient without significant coronary stenosis. Peak values of CAAS in each color-coded curve were measured, and then the global CAAS was calculated as the mean of 6 peak values. This patient had a global CAAS of 9.3%. (B) Representative LAAS curves in a patient with significant coronary stenosis. This patient had a global LAAS of 12%

 

 

 

Statistical analysis:

     Data were tabulated and analyzed using the computer programme SPSS (Statistical package for the social sciences) version 20.0 (SPSS Inc., Chicago, Illinois, USA). Quantitative data were expressed as mean ± standard deviation (SD) and range. Qualitative data were expressed as frequency and percentage.

The following tests were done:

•   Independent-samples t-test of significance was used when comparing between two means.

•   A one-way analysis of variance (ANOVA) when comparing between more than two means.

•   Post Hoc test: Least Significant Difference (LSD) was used for multiple comparisons between different variables.

•   Mann Whitney U test  for two-group comparisons in non-parametric data.

•   Chi-square (x2) test of significance was used in order to compare proportions between qualitative parameters.

•   Pearson's correlation coefficient (r) test was used to assess the degree of association between two sets of variables.

•   Scatter plot: A graph in which the values of two variables are plotted along two axes, the pattern of the resulting points revealing correlation present.

•   Receiver operating characteristic (ROC curve) analysis was used to find out the overall predictively of parameter and to find out the best cut-off value with detection of sensitivity and specificity at this cut-off value.


 

RESULTS

 

 

     The study included 49 males and 21 females. The mean age was 60.69 ± 5.8 years. Age ranged from 50 years to 73 years. There was a statistically significant difference between both groups regarding diabetic history. Patients were 57.8 % diabetic, while control were 32% (p=0.039). On the other hand, there was no statistically significant difference between both groups as regarding other risk factors including hypertension, smoking and dyslipidemia. Patients were 55.6% hypertensive (p=0.544), 48.9% smokers (p=0.474), and 35.6% with dyslipidemia (p=0.318), while control were 48% hypertensive, 40% smokers and 24% with dyslipidemia.

     There was no statistically significant difference between both groups according to systolic (p=0.165) and diastolic (p=0.122) blood pressure (Table 1).

     There was a statistically significant difference between both groups according to LAD (p=0.039), LVESD (p=0.041) and LV EF% (p=0.006) but there was no statistically significant difference according to others (Table 2).


 

 

 

( Table  1): Comparison between patients and control according to blood pressure

Groups

Blood pressure

Patients (n=45)

Control (n=25)

p-value

Systolic (mmHg)

 

 

 

Mean ± SD

137.56±18.88

130.80±20.04

0.165

Range

100-170

110-180

Diastolic (mmHg)

 

 

 

Mean ± SD

89.11±13.41

83.80±13.94

0.122

Range

60-110

60-100

Using: Independent Sample t-test

 

 

(Table  2):  Comparison between patients and control according to echo parameters

Groups

Echo parameters

Patients (n=45)

Control (n=25)

p-value

LAD (cm)

 

 

 

Mean ± SD

3.84±0.55

3.61±0.38

0.068

Range

2.8-4.7

2.9-4.3

ADD (cm)

 

 

 

Mean ± SD

3.07±0.41

2.96±0.39

0.278

Range

1.9-4.1

2.2-3.6

ASD (cm)

 

 

 

Mean ± SD

3.25±0.43

3.28±0.39

0.774

Range

2-4.24

2.5-3.9

LVEDD (cm)

 

 

 

Mean ± SD

4.88±0.60

4.94±0.45

0.666

Range

3.42-6.1

3.97-5.45

LVESD (cm)

 

 

 

Mean ± SD

3.43±0.39

3.20±0.76

0.098

Range

2.5-4.4

0-3.9

LV EF (%)

 

 

 

Mean ± SD

58.38±5.77

62.30±4.12

0.004

Range

36-71

55-71

Using: Independent Sample t-test

 

 

     There was a statistically significant difference between both groups regarding longitudinal and circumferential aortic root strain (P> 0.001) (Table 3).

     There was a statistically significant difference between both groups according to aortic stiffness index (P> 0.001) (Table 4).

 

 

 

 

 

 

 

 

 

 

 

(Table  3):  Comparison between patients and control according to strain values

Groups

Speckle tracking

Patients
(n=45)

Control (n=25)

p-value

Longitudinal Aortic root strain

 

 

 

Mean±SD

9.10±2.05

13.63±2.25

<0.001

Range

5.9-13

8-17

Circumferential Aortic root strain

 

 

 

Mean±SD

6.22±1.97

11.82±1.95

<0.001

Range

3.2-9.55

8.5-15

Using: Independent Sample t-test

 

(Table  4):  Comparison between patients and control according to aortic stiffness index

Groups

Aortic stiffness index

Patients (n=45)

Control (n=25)

p-value

Mean ± SD

7.69±1.71

4.98±2.41

<0.001

Range

4.21-10.86

1.77-10.61

Using: Mann-Whitney test

 

 

     Global CAAS decreased incrementally with increasing severity of CAD as determined by an increasing number of coronary vessels with lumen area stenosis ≥70%. In patients having no CAD or 1, 2, and 3 vessel disease (P> 0.001) (Table 5).

 

 

Table (5):   Relation between number of vessels affected with longitudinal and circumferential aortic root strain in patients group

Groups

Speckle tracking

Number of vessels affected

ANOVA

1 vessel (11)

2 vessels (18)

3 vessels (16)

p-value

Longitudinal aortic root strain

 

 

 

 

Mean ± SD

11.70±0.69

9.49±0.99a

6.87±0.66ab

<0.001

Range

10.39-13

7.99-11.65

5.9-8.21

Circumferential aortic root strain

 

 

 

 

Mean ± SD

8.90±0.64

6.42±0.75a

4.16±0.77ab

<0.001

Range

7.8-9.55

5.3-8

3.2-5.8

Using: One Way Analysis of Variance: Post HOC test: a: significant difference with 1 vessel; b: significant difference with 2 vessels

 

 

     There was a positive correlation between longitudinal ascending aortic root strain with circumferential ascending aortic root strain (P> 0.001), and aortic distensibility (P> 0.001). There was a negative correlation between longitudinal aortic root strain with   aortic stiffness index (P> 0.001), hypertension (P=0.004), systolic (P> 0.001) and diastolic (P> 0.001) blood pressure, number of vessels affected (P> 0.001) and left atrial diameter (P=0.002) (Figure 2).

 

 

 


(Figure  2):     Scatter plot between circumferential and longitudinal aortic root strain

 

 

 
   


     Also, there was a positive correlation between circumferential aortic root strain with aortic distensibility (P> 0.001). While there was a negative correlation between circumferential aortic root strain with aortic stiffness index (P> 0.001), hypertension (P=0.004), systolic (P> 0.001) and diastolic (P> 0.001) blood pressure, number of vessels affected(P> 0.001) and left atrial diameter(p=0.002) (Figure  3).

 

 

(Figure  3):     Scatter plot between circumferential aortic root strain and aortic stiffness index

 

 

     There was a positive correlation between aortic stiffness index with diabetes (P> 0.005), hypertension (P> 0.001), waist circumference (p=0.037), dyslipidemia (p=0.0 97), systolic (P> 0.001) and diastolic blood pressure (P> 0.001), number of vessels affected (P> 0.001) and left atrial diameter (P> 0.001) while there was a negative correlation between aortic stiffness index with aortic distensibility (P > 0.001). Also, there was a negative correlation between aortic distensibility with diabetes (p=0.012), hypertension (P> 0.001), waist circumference (p=0.046), systolic(P> 0.001) and diastolic(P> 0.001) blood pressure, number of vessels affected (P> 0.001), and left atrial diameter (P> 0.001).

     Receiver operating characteristic curve found the cut-off value for prediction of ischemic heart disease (Figure 4 and Table 6).

 


(Figure  4):     Receiver-operating characteristic (ROC) curve for prediction of ischemic heart disease using longitudinal aortic root strain, circumferential aortic root strain, aortic stiffness index and aortic distensibility

 

Table (6):   Cut-off value for prediction of ischemic heart disease

Items

Cut-off

Sen.

Spec.

PPV

NPV

Accuracy

Longitudinal aortic root strain

≤11.5

84.4%

76%

86.4%

73.1%

85.9%

Circumferential aortic root strain

≤9.1

96.7%

92%

95.1%

79.3%

98.8%

Aortic stiffness index

≥6.5

77.8%

80%

87.5%

66.7%

81.3%

Aortic distensibility

≤3.03

73.3%

64%

78.6%

57.1%

77.5%

 

 

DISCUSSION

     Regarding 2D conventional echocardiographic parameters, there was a statistically significant difference between both groups according to LV EF% and this in agreement with Şatiroğlu et al. (2012), Güngör et al. (2014) and Bu et al. (2018).

     There was no statistically significant difference according to other parameters i.e., LAD, ASD, ADD, LVESD and LVEDD. This was consistent with Bu et al. (2018), but against Şatiroğlu et al. (2012) and Güngör et al. (2014) which can be explained by the same prevalence of hypertension and age in both groups which significantly affect aortic diameters.

     Regarding 2D-ST echo parameters, there were statistically significant differences between both groups regarding longitudinal and circumferential aortic root strain.

     The global CAAS assessed by 2D-ST echocardiography at rest was significantly lower in patients with significant CAD than in patients without CAD which was in agreement with Bu et al. (2018).

     The global LAAS assessed by 2D-ST echocardiography at rest was significantly lower in patients with significant CAD than in patients without CAD .

     Regarding aortic stiffness index and aortic distensibility. There was high statistically significant difference between both groups according to aortic stiffness index and aortic distensibility, which were consistent with Şatiroğlu et al. (2012), Güngör et al. (2014), Bu et al. (2018), Ahmed et al. (2019) and Lønnebakken et al. (2019) and El-Naggar et al. (2020).

     In this current study, the global CAAS obtained by 2D-ST echocardiography had a high feasibility and satisfactory reproducibility, global CAAS at rest predict significant CAD with high sensitivity (96%) in patients with CAD, and this was consistent with Bu et al. (2018) who concluded the same results, but with sensitivity of 86%.

     Based on the ROC curve of the global CAAS for diagnosing significant CAD, the area under the ROC curve was significantly large, and the optimal cut-off value of global CAAS was 9.1%. The ability of global CAAS to differentiate significant CAD was remarkable, with 92% of enrolled patients with global CAAS ≤9.1% having significant coronary stenosis confirmed by coronary angiography. According to the data from this study, global CAAS had a high accuracy to predict significant CAD, rendering it a potential marker for CAD, compared to LAAS with area under the ROC curve smaller than that of global CAAS with optimal cut-off value was 11.5 % with 76% of enrolled patients with global LAAS ≤11.5% having significant coronary stenosis confirmed by coronary angiography. Also, the optimal cut of value of aortic stiffness index was 6.5 with 80% of enrolled patients with aortic stiffness index ≥6.5 having significant coronary stenosis. Global CAAS was considered the most significant predictor of CAD, and this finding was consistent with Bu et al. (2018).

     This study demonstrated that both global CAAS and LAAS decreased incrementally with increasing severity of CAD, as determined by an increasing number of diseased vessels. Further analysis showed that global CAAS had a significant association with 3-Vessele Disease and was able to detect or exclude multivessel CAD with a satisfactory diagnostic performance (sensitivity 96.7%, specificity 92%), compared to the study of Bu et al. (2018) with sensitivity 86% and specificity 70%.

     Global CAAS decreased incrementally with increasing severity of CAD as determined by an increasing number of coronary arteries with lumen area stenosis ≥70%. Accordingly, global CAAS and LAAS can be used as a predictor of severity of coronary artery disease and this correlated with Bu et al. (2018).

CONCLUSION

     Global circumferential ascending aortic root strain and longitudinal ascending aortic root strain assessed by 2D-ST echocardiography at rest were an independent predictor of significant CAD. Also, global CAAS and LAAS were related to the severity of CAD and capable of identifying multivessel disease; aortic stiffness index and distensibility were an old method used for a local assessment of arterial stiffness. However, validity and reproducibility of these methods are limited because of their dependence on the patient’s blood pressure and now can be replaced by new strain methods.

REFERENCES

  1. Ahmed, M., Adam, K. and El-Shafey, W.  (2019): Assessment of Aortic Root Mechanics in Hypertensive Patients by Speckle Tracking Echocardiography. World Journal of Cardiovascular Diseases, 9:  212-222.
  2. Bieseviciene, M., Vaskelyte, J., Mizariene, V., Karaliute, R., Lesauskaite, V. and Verseckaite, R. (2017): Two-dimensional speckle-tracking echocardiography for evaluation of dilative ascending aorta biomechanics. Bio Medical Center, 17: 27-35.
  3. Boudoulas, K., Vlachopoulos, C., Raman, S., Sparks, E., Triposciadis, F., Stefanadis, C. and Boudoulas, H. (2012): Aortic function: from the research laboratory to the clinic. Cardiology, 121:  31-42.
  4. Bu, Z., Ma, J., Fan, Y., Qiao, Z., Kang, Y., Zheng, Y., Wang, W., Du, Y., Zheng, Z., Shen, X. and He, B. (2018): Ascending Aortic Strain Analysis Using 2-Dimensional Speckle Tracking Echocardiography Improves the Diagnostics for Coronary Artery Stenosis in Patients with Suspected Stable Angina Pectoris. Journal of the American Heart Association, 7: 8802-8850.
  5. Cavalcante, J., Lima, J., Redheuil, A. and Al-Mallah, M. (2011): Aortic stiffness: current understanding and future directions. Journal of the American College of Cardiology, 57: 1511-1522.
  6. El-Naggar, H., Anwar, H., Helmy, H. and Demitry, S. (2020): Aortic root distensibility and stiffness assessed by echocardiography as predictors of coronary artery lesion severity in patients undergoing coronary angiography. European Heart Journal-Cardiovascular Imaging, 21: 319-927.
  7. Güngör, B., Yılmaz, H., Ekmekçi, A., Özcan, K., Tijani, M., Osmonov, D., Karataş, B., Alper, A., Mutluer, F., Gürkan, U. and Bolca, O. (2014): Aortic stiffness is increased in patients with premature coronary artery disease: a tissue Doppler imaging study. Journal of Cardiology, 63: 223-229.
  8. Kim, S., Park, S., Kim, M., Kim, Y., Cho, D., Ahn, C., Hong, S., Lim, D. and Shim, W. (2012): The relationship between mechanical properties of carotid artery and coronary artery disease. European Heart Journal–Cardiovascular Imaging, 13: 568-573.
  9. Kobayashi, Y., Lee, J., Fearon, W., Lee, J., Nishi, T., Choi, D. and Nam, C. (2017): Three-vessel assessment of coronary microvascular dysfunction in patients with clinical suspicion of ischemia: prospective observational study with the index of microcirculatory resistance. Circulation: Cardiovascular Interventions, 10: 54-60.
  10. Lønnebakken, M., Eskerud, I., Larsen, T., Midtbø, H., Kokorina, M. and Gerdts, E. (2019): Impact of aortic stiffness on myocardial ischaemia in non-obstructive coronary artery disease. Open Heart, 6: 981-999.
  11. Şatiroğlu, Ö., Bostan, M., Bayar, N., Çiçek, Y., Cetin, M. and Bozkurt, E. (2012): Relation between aortic stiffness and extension of coronary artery disease. Turkish Journal of Medical Sciences, 42: 417-424.
  12. Teixeira, R., Monteiro, R., Baptista, R., Barbosa, A., Leite, L., Ribeiro, M., Martins, R., Cardim, N. and Gonçalves, L. (2015): Circumferential vascular strain rate to estimate vascular load in aortic stenosis: a speckle tracking echocardiography study. The International journal of Cardiovascular Imaging, 31: 681-689.
  13. Yuda, S., Kaneko, R., Muranaka, A., Hashimoto, A., Tsuchihashi, K., Miura, T., Watanabe, N. and Shimamoto, K. (2011): Quantitative measurement of circumferential carotid arterial strain by two-dimensional speckle tracking imaging in healthy subjects. Echocardiography, 28: 899-906.


العلاقة بين تيبس جذع الشريان الأورطى والتتبعى النقطى بالموجات فوق الصوتية ثنائية الأبعاد بمرضى قصور الشريان التاجى

أحمد حمدى عبدالعزيز بيومى، أبوبکر الصديق تمام حسين، الحسين مصطفى زهران

قسم القلب والاوعية الدموية، کلية الطب، جامعة الأزهر

E-mail: ahm.ham.bay@gmail.com

خلفية البحث: يعتبر زيادة تيبس الشريان الأورطى عامل ذا خطورة لأمراض القلب والأوعية الدموية والتنبوء بالإعتلال والوفيات بأمراض الشرايين التاجية. وبالتالي، فإن تقييم تيبس الشرايين يستخدم بشکل متزايد في الممارسة السريرية. ومع ذلک، فإن صلاحية واستعمال  الطرق التقليدية المستخدمة للتقييم المحلي لتييبس الشرايين مثل معامل المرونة ومؤشر الصلابة محدودة باعتمادها على ضغط دم المريض، ويعد تخطيط صدى القلب بالتتبع النقطى ثنائي الأبعاد على جذع الاورطى طريقة تصوير جديدة واعدة، والتى تسمح بالتقييم غير المتصل لسرعات الأنسجة.

الهدف من البحث: تقييم جدوى تخطيط صدى القلب بالتتبع النقطى ثنائى الأبعاد على جذع الشريان الأورطى للتنبؤ المبکر بمرضى قصور واعتلال الشرايين التاجية وارتباطه بعوامل تصلب ومرونة  الشريان الأورطى والتى کانت تستخدم قديما.

المرضي وطرق البحث: تضمن البحث خمسة واربعون مريضاً يعانون من قصور بالشرايين التاجية، وخمسة وعشرون شخصاً آخرين کمجموعة مقارنة لايعانون من اعتلال الشرايين التاجية، وقد تم إجراء هذا البحث فى مستشفى باب الشعرية الجامعى وتم عمل تخطيط القلب الکهربائى اثناء الراحه وموجات فوق صوتيه ثنائية الأبعاد وموجات فوق صوتية ثنائية الأبعاد بطريقة التتبع النقطى على جذع الشريان الأورطى ثم قسطرة تشخيصية للشرايين التاجية لجميع الحالات فى الفترة من ابريل 2020 الى أکتوبر 2020.

نتائج البحث: التتبع النقطى بواسطة الموجات فوق الصوتية ثنائية الأبعاد على جذع الشريان الاورطى قادرعلى التنبوء باکتشاف مرضى قصور الشرايين التاجية وعدد الشرايين التاجية المعتلة، کما أنه يوجد علاقة وطيدة بين معامل المرونة ومؤشر الصلابة وبين معدل الإجهاد والتوتر والذى يتم حسابه من خلال التتبع النقطى بالموجات فوق الصوتية ثنائية الابعاد.

الاستنتاج: معدل التوتر المحيطى والطولى لجذع الشريان الاورطى والتى تم تقيمها بواسطة تخطيط صدى القلب أثناء الراحة مؤشرمستقل للتنبوء بقصور الشرايين التاجية.

الکلمات الدالة: التوتر المحيطى لجذع الشريان الاورطى، التوتر الطولى لجذع الشريان الاورطى، معامل الصلابة، معامل المرونة، التتبع النقطى بالموجات فوق الصوتية ثنائية الابعاد.

  1. REFERENCES

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    2. Bieseviciene, M., Vaskelyte, J., Mizariene, V., Karaliute, R., Lesauskaite, V. and Verseckaite, R. (2017): Two-dimensional speckle-tracking echocardiography for evaluation of dilative ascending aorta biomechanics. Bio Medical Center, 17: 27-35.
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