Influence of right coronary artery shape on TIMI frame count and lesion distribution

Altintas, Mehmet S.; Ermis, Necip; Cuglan, Bilal; Alturk, Erdal; Ozdemir, Ramazan; Altintas, Mehmet S.; Ermis, Necip; Cuglan, Bilal; Alturk, Erdal; Ozdemir, Ramazan

doi:10.24875/acm.20000083

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Archivos de cardiología de México

versión On-line ISSN 1665-1731versión impresa ISSN 1405-9940

Arch. Cardiol. Méx. vol.90 no.4 Ciudad de México oct./dic. 2020 Epub 10-Feb-2021

https://doi.org/10.24875/acm.20000083

Artículo de investigación

Influence of right coronary artery shape on TIMI frame count and lesion distribution

Influencia de la forma de la arteria coronaria derecha en el recuento de cuadros TIMI y la distribución de la lesión

Mehmet S. Altintas¹^*

Necip Ermis¹

Bilal Cuglan¹

Erdal Alturk¹

Ramazan Ozdemir¹

¹Department of Cardiology, Inonu University, Faculty of Medicine. Malatya, Turkey

Abstract

Background:

The shape of the right coronary artery (RCA) may vary between individuals.

Objective:

The aim of this study was to investigate whether the shape of RCA has any effect on TIMI frame count (TFC), TIMI flow score, and lesion distribution length in patients with ST-elevation myocardial infarction (STEMI) caused by RCA.

Materials and methods:

The angiograms of 163 patients who applied to our hospital with STEMI caused by the RCA were included in the study. TFCs were calculated.

Results:

The patients were divided into two groups according to the geometric shape of the RCA as C (124 pts, 101 males, mean age 66.1 ± 12.3 years) or S (39 pts, 30 males, mean age 60.0 ± 10.8 years) based on the angiographic view from the left oblique position. Lesion location was significantly higher in the proximal and mid regions compared to the distal region in patients with C-RCA (p < 0.001). TFC was significantly higher in the S-RCA group (p = 0.0014). There was a statistically significant difference between the groups in terms of mean age of p = 0.003.

Conclusion:

Lesion frequency was significantly higher in the proximal and mid regions in patients with C-RCA. TFCs were significantly higher in the S-RCA group. Longer S-RCA length compared to C-RCA and local shear stress characteristics may also explain these findings.

Key words Right coronary artery; TIMI frame count; Coronary artery shape

Resumen

Antecedentes:

La forma de la arteria coronaria derecha puede variar entre los individuos.

Objetivo:

El objetivo de este estudio fue investigar si la forma de la arteria coronaria derecha (RCA) tiene algún efecto sobre el conteo de cuadros TIMI (TFC), el puntaje de flujo TIMI y la longitud de distribución de la lesión en pacientes con infarto de miocardio con elevación del ST (STEMI) causado por RCA.

Material y métodos:

Se incluyeron en el estudio los angiogramas de 163 pacientes que se aplicaron a nuestro hospital con STEMI causado por la arteria coronaria derecha. Se calcularon los TFC.

Resultados:

Los pacientes se dividieron en dos grupos según la forma geométrica de la arteria coronaria derecha como C (124 puntos, 101 masculino, edad media 66.1 ± 12.3 años) o S (39 puntos, 30 masculino, edad media 60.0 ± 10.8 años) según vista angiográfica desde la posición oblicua izquierda. La ubicación de la lesión fue significativamente mayor en las regiones proximales y medias en comparación con la región distal en pacientes con C-RCA (p < 0.001). TFC fue significativamente mayor en el grupo S-RCA (p = 0.0014). Hubo una diferencia estadísticamente significativa entre los grupos en términos de edad media de (p = 0.003).

Conclusión:

La frecuencia de las lesiones fue significativamente mayor en las regiones proximales y medias en pacientes con C-RCA. Los TFC fueron significativamente más altos en el grupo S-RCA. Una mayor longitud de S-RCA en comparación con C-RCA y las características locales de tensión de corte también pueden explicar estos hallazgos.

Palabras clave Arteria coronaria derecha; Conteo de cuadros TIMI; Forma de arteria coronaria

Introduction

Besides known risk factors, atherogenesis is associated with hemodynamic factors such as increased and decreased flow velocity and disturbances in vascular system. These factors have been shown to be related with the geometric shape of the vessel¹. Branching regions, bifurcation, and proximal portions of coronary arteries are more frequently affected than other regions². McDaniel et al. showed that target lesions of ST elevation myocardial infarction (STEMI) were generally the proximal region of RCA, the proximal part of large curve, and just distal to the bifurcation, which create a turbulence of blood flow in the angiograms of patients undergoing cardiac catheterization due to STEMI³. The length, curve, and flow pattern of the right coronary artery (RCA) have been shown to be associated with development atherosclerosis in RCA⁴-⁷. The previous studies showed that the probability of having STEMI due to RCA was more frequent in patients with C shaped RCA³,⁸. However, the effect of the RCA shape on TIMI frame count (TFC), TIMI flow score, and lesion distribution length has not been evaluated in this patient group.

Materials and methods

This study was conducted between February 2010 and June 2012. We evaluated the angiograms of 163 patients who applied to the hospital with STEMI caused by the RCA. The patients were divided into two groups according to the geometric shape of the RCA as C or S based on the angiographic view from the left oblique position. In our study group, 124 patients had C-RCA and 39 had S-RCA. The study protocol was approved by the Ethics Committee of the Faculty of Medicine in İnonu University. The files of all patients were evaluated to obtain data such as age, gender, co-morbidities, risk factors, and laboratory results. The exclusion criteria included heart failure, cardiomyopathy, coronary artery bypass history, any previous intervention to RCA, artery diameter < 2 mm, failing to pass the distal part of lesion, and the absence of an angiographic image to assess TFCs according to the Gibson method.

Coronary angiographic evaluation

The angiographic images of patients with femoral or radial access were examined, and the coronary angiography procedure was done using the Philips Integris 5000, Netherland device. The evaluation was done by two-independent observers. The shape of RCA was determined by angiography from the left oblique position. Proximal region is defined as from the RCA ostium to the right ventricle branch; mid region is defined as from the right ventricular branch to the acute margin branch; and distal region is defined as after the acute margin branch. Arterial diameter measurements were done, and lesion region and length were determined from angiographic images. The TFC method of Gibson et al. was used to determine TFC after percutaneous intervention. The first frame includes the first opaque material seen in coronary artery ostium, and the last frame is the opaque material seen in the distal point of coronary artery. Distal point is described as the first branch of posterolateral artery for RCA. The difference between the first and the last frames was considered as the number of frames. We did not correct the frames by the length of the arteries. Interobserver variability was acceptable ranges (6.1% for TFC).

Statistical analysis

Statistical analyses were performed using the SPSS software, version 17.0 (SPSS, Inc. Chicago, IL, USA). Continuous variables are presented as mean ± standard deviation, and defined categorical variables are given as number and percentage. The ShapiroWilk normality test was used to test the normality of distribution of quantitative data. Differences between the variables of two groups were tested with the students t-test or MannWhitney U-test when appropriate. The Chi-squared test was used to compare categorical variables. P values below 0.05 were accepted as statistical significance.

Results

The study group consisted of a total of 163 patients undergoing primary percutaneous intervention who applied to the hospital with acute myocardial infarction resulting from RCA. 124 of the patients had C-RCA, while 39 had S-RCA. The baseline clinical characteristics of the patients in each group are summarized in table 1.

Table 1 Demographic characteristics of patients

	C shape (n = 124)	S shape (n = 39)	p value
Age (year)	66.1 ± 12.3	60.0 ± 10.8	0.003
DM	31 (25%)	12 (30.8%)	0.476
Hyperlipidemia	29 (23.4%)	8 (20.5%)	0.709
Smoking	34 (27.4%)	12 (30.8%)	0.685
Gender	Men 101 (81.5%)	Men 30 (76.9%)	0.535
Gender	Women 23 (%18.5)	Women 9 (%23.1)	0.535

The mean age was 66.1 ± 12.3 years in the C-shaped group and 60.0 ± 10.8 in the S-shaped group. There was a statistically significant difference between the groups in terms of mean age (p = 0.003). There was no statistically significant difference between the groups in terms of gender, diabetes mellitus, hypertension, smoking, and hyperlipidemia. In addition, there was no statistically significant difference in terms of fasting blood glucose, BUN, creatinine, hemoglobin, hematocrit, white blood cell count, platelet count, and mean platelet volume (Table 2).

Table 2 TIMI frame count and laboratory findings of patients group

	C shape (n = 124)	S shape (n = 39)	p value
TIMI frame count (frame)	12.4 ± 5.3	14.5 ± 5.4	0.014
White blood cell	12.5 ± 4.3	11.6 ± 3.7	0,233
Hemoglobin (gr/dL)	14.2 ± 1.8	13.6 ± 1.7	0.063
Hematocrit	42.5 ± 5.4	41.0 ± 5.2	0.137
Mean platelet volume (fL)	8.35 ± 1.00	8.13 ± 0.74	0.475
Mean corpuscular volume (fL)	89.8 ± 5.22	91.75 ± 5.26	0.018

Lesion location was significantly higher in the proximal and mid regions compared to the distal region in patients with C-RCA (p < 0.001). There was no statistically significant difference in the S-shaped group in terms of lesion location (p > 0.05). TFC was significantly higher in the S-RCA group compared to the C-RCA group (p = 0.0014) (Fig. 1). Considering lesion localizations, there was no difference between the groups in terms of proximal, mid, and distal segments (p = 0.116).

Figure 1 Comparison of TIMI frame count of patients group

There was no statistically significant difference between TFCs in terms of having diabetes mellitus, smoking, hypertension, and hyperlipidemia ([p = 0.799]; [p = 0.975]; [p = 0.446]; and [p = 0.214], respectively). Both groups were compared for the presence of other coronary artery lesions accompanying the RCA lesion. There was no statistically significant difference between the groups in terms of the presence of a left anterior descending (LAD), lesion or circumflex artery (Cx) lesion, and three vessel disease ([p = 0.622]; [p = 0.413]; and [p = 0.682], respectively).

When the groups were compared in terms of lesion length, no statistically significant difference was found (p = 0.051; 19.36 ± 8.23 vs. 17.34 ± 8.75). In addition, no statistically significant difference was found in terms of mean arterial diameter (p > 0.05).

Discussion

Although atherosclerosis is usually localized, it is associated with systemic risk factors such as hypertension, smoking, and hyperlipidemia⁴,⁹-¹². Some regions of coronary arteries such as coronary artery bifurcation, proximal portions, and branching regions are more affected than other locations². Some researchers have suggested that these regions are prone to atherogenesis due to the impact of hemodynamic stress associated with anatomic variations in the arterial wall and local geometry in these regions¹³-²². Studies have shown the shape, flow pattern, and length of the RCA to be associated with the development of atherosclerosis⁴-⁷. In the current study, the frequency of lesions in the proximal and mid regions was significantly higher compared to the distal region. It has been shown that lesions in the proximal region of C-shaped right coronary arteries are more prone to acute myocardial infarction due to their thin structure. McDaniel et al. suggested that turbulent flow may play an important role in the pathogenesis of acute coronary syndrome and the settlement of the culprit lesions in the proximal regions of the coronary artery³. Sabbah et al. showed that the inner wall of the RCA had lower shear stress rate, while several autopsy studies have found these regions to have plaques with great intensity and severity²³-²⁵. In their study, Nwasokwa et al. investigated the relationship between thin coronary arteries and atherogenesis, and similar to our study, they suggested that having a thin coronary artery can be a risk factor for coronary atherosclerosis²⁶. It is unclear how the diameter of coronary artery, which normally affects hemodynamics, influences the presence of atherosclerosis. Hemodynamic patterns such as increased blood flow, blood flow rate, and shear stress can accelerate the development of or suppress atherogenesis²⁷. Endothelium is extremely sensitive to the shear stress, producing anti-atherogenic substances (e.g., nitric oxide). Low shear stress conditions are pro-atherogenic and lead to atherosclerotic plaque formation. Shear stress also influences the activation of endothelial cells through multiple mechanisms that target mitogen-activated protein kinases, nuclear factor-kappa-B, and endothelial nitric oxide synthase. Low shear stress can trigger intracellular cascades and shift phenotypic endothelial cell expression to an atherosclerotic prone state²⁸. In their experimental study, Qiu et al.²⁹ showed higher numbers of intraplaque microvessels in the high shear stress region and abnormal ECs in the microvessels in the plaque with membrane blebs, intracytoplasmic vacuoles, and leukocyte infiltration. In addition, in the present study, the rate of MI in the mid region was statistically higher compared to the distal region of RCA. However, there was no statistically significant difference between S-shaped RCA regions in terms of lesion frequency. A few studies have examined the relationship between RCA and other coronary arteries in terms of frequency and severity of lesions⁸,³⁰. Demirbağ et al. evaluated the coronary artery severity of patients according to the gensini score and found that C-RCA patients had significantly higher scores compared to S-RCA patients with no difference in terms of risk factors. In multivariate analyses, two or three vessel diseases were more common in patients with C-RCA, while the possibility of normal coronary artery angiogram was higher in patients with S-RCA⁸. In this study, there was no statistically significant difference in terms of accompanying LAD or Cx coronary artery lesions (p = 0.62 and p = 0.41, respectively). Similarly, there was no significant difference in terms of LAD and Cx lesions existing together (p = 0.68). This difference was thought to be due to all the enrolled patients having STEMI. Previously, the relationship between the presence of coronary artery disease and the shape of coronary artery was partially explained by some theories based on factors such as hemodynamics, arterial geometry, blood velocity, and shear stress⁵,²⁸,³¹-³⁴. It has been reported that there was a substantial relationship between the short elongation of RCA and atherosclerosis⁴. Another study has shown that longer arterial segments had larger diameters³⁵. As C-RCA has a smaller diameter, it has an increased risk of atherogenesis due to effect of a smaller diameter on inner hemodynamics. In this study, TFCs were significantly higher in the S-RCA group. This may be associated with longer durations of S-RCA compared to C-RCA, as mentioned by previous studies. However, our study had several limitations. Factors that may affect TFCs and cause acute coronary events, such as plaque morphology, length of the arteries, and unknown plaque contents, were undetermined during the study. Corrected TFC did not calculate. Finally, intracoronary thrombus burden was not measured.

Conclusion

In patients with acute myocardial infarction, lesion frequency was significantly higher in the proximal and mid regions in patients with C-RCA, which may be explained by local shear stress characteristics. There was no statistically significant difference in the S-RCA group in terms of lesion localization. TFCs were significantly higher in the S-RCA group compared to the C-RCA group, which is thought to be due to the longer duration of S-RCA.

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FundingThis research has not received any private donations from public, commercial, or nonprofit organizations.

Ethical disclosures

Protection of human animal and subjects: The authors declare that no experiments were performed on humans and animals for this study.

Confidentiality of data: The authors declare that they have followed the protocols of their work center on the publication of patient data.

Right to privacy and informed consent: The authors declare that no patient data appear in this article.

Received: February 23, 2020; Accepted: June 12, 2020

^* Correspondence: Mehmet S. Altintas E-mail: pirpirima21@gmail.com

^{Conflict of interests}

The authors report no competing interests.

Instituto Nacional de Cardiología Ignacio Chávez. Published by Permanyer. This is an open ccess article under the CC BY-NC-ND license