ABSTRACT
Aim:
The aim of the present study was to determine the normal distances between the origins of the major branches of the abdominal aorta, and their distances to the aorta at the diaphragmatic region and iliac bifurcation on multidetector computed tomography (MDCT) angiography in pediatric patients.
Materials and Methods:
The MDCT angiography scans obtained from 245 children aged between 0 and 18 years (mean age±standard deviation, 8.48±5.14 years) were retrospectively re-evaluated. The distances between the origins of the celiac trunk (CTR), superior mesenteric artery (SMA), right renal artery (RRA), left renal artery (LRA), and inferior mesenteric artery (IMA) were measured. The distance measurements between the aorta at the diaphragmatic region, iliac bifurcation, and the origins of the major branches (CTR, SMA, RRA, LRA, IMA) were performed as well.
Results:
The distances between the abdominal aorta and its branches were reported to vary in the age groups. All the distance measurements increased significantly with increasing age (p<0.0001). The distances between the aorta at the diaphragmatic region and the origins of the major branches were significantly higher in girls (p<0.05). The origin of the RRA was higher than the LRA in 51.8% of the study population.
Conclusion:
This study is the first to provide data on the distances between the abdominal aorta and its branches in children. The present results may contribute to enhance the efficacy and safety of the endovascular and surgical procedures in the abdominal region.
INTRODUCTION
The widespread availability of low dose, contrast-enhanced multidetector computed tomography (MDCT) has significantly reduced the need for invasive conventional angiography providing useful information on the vascular anatomy of the human body1.
Several cadaveric and radiological series in adults have reported that the distances between the major branches of the abdominal aorta are highly variable in relation to age, gender, and ethnicity. Knowing the distances between the anatomical landmarks is important especially for the vascular surgeons and interventional radiologists to avoid complications during the surgical and endovascular procedures in the abdominal region2,3. However, to the author’s knowledge, no previous study has examined the distances between the abdominal aorta and its branches in children of various age groups.
The objective of the present study was to determine the normal distances between the origins of the major branches of the abdominal aorta, and their distances to the aorta at the diaphragmatic region and iliac bifurcation on MDCT angiography in pediatric patients.
GİRİŞ
Düşük dozlu, kontrastlı çok dedektörlü bilgisayarlı tomografinin (ÇDBT) yaygın olarak kullanılması, insan vücudunun vasküler anatomisi hakkında faydalı bilgiler sağlayan invaziv konvansiyonel anjiyografi ihtiyacını önemli ölçüde azaltmıştır1.
Erişkinlerde yapılan bazı kadavra ve radyolojik seri çalışmalarında, abdominal aortun ana dalları arasındaki mesafelerin yaş, cinsiyet ve etnik kökene göre oldukça değişken olduğu bildirilmiştir. Anatomik işaretler arasındaki mesafelerin bilinmesi özellikle damar cerrahları ve girişimsel radyologlar için karın bölgesindeki cerrahi ve endovasküler işlemler sırasında komplikasyonlardan kaçınmak için önemlidir2,3. Ancak, yazarın bilgisine göre, daha önce çeşitli yaş gruplarındaki çocuklarda abdominal aort ve dalları arasındaki mesafeleri inceleyen hiçbir çalışma yapılmamıştır.
Bu çalışmanın amacı, pediatrik hastalarda ÇDBT anjiyografide, abdominal aortun ana dallarının orijinleri ile diyafragmatik bölgede aorta ve iliak bifurkasyona olan normal mesafeleri belirlemektir.
MATERIALS AND METHODS
Patients
A descriptive cross-sectional and retrospective study design was adopted. From March 2014 to February 2019, a total of 827 children who underwent abdominal CT examinations for various reasons were retrospectively evaluated. The exclusion criteria were listed as follows: Subjects over 18 years of age; CT examinations performed without intravenous contrast agents (n=300); vascular distortion caused by the presence of abdominal tumor mass or lymphadenopathy (n=87); massive ascites (n=31); active bleeding caused by polytrauma (n=7); supernumerary renal arteries (n=127); severe vertebral scoliosis or kyphosis (n=16); and CT images of insufficient quality for analysis (n=14).
The MDCT angiography images of 245 children with normal body weight for chronological age were finally enrolled in the current study. The study flowchart is shown in Figure 1.
CT Protocol and Analysis of The CT Findings
The abdominopelvic contrast-enhanced CT examinations were performed with a 32 multi-slice CT scanner (SOMATOM go. Now, Siemens, Erlangen, Germany). The non-ionic iodinated contrast agent (Iobitridol, 300 mg I/mL) was injected intravenously by using a power injector (dose: 1-2 mL/kg, injection rate: 2 mL/s). To adhere to as low as reasonably achievable (ALARA) principle, the CT scans were made at a tube voltage of 80-120 kV and tube current of 20-350 mAs depending on the patient’s weight. The CT parameters were as follows: Tube rotation time, 0.3-0.5 s; pitch, 1; and reconstruction interval, first multiplanar data reconstruction with a slice thickness less than or equal to 3 mm was performed to identify the abdominal aorta and its branches.
A single board-certified radiologist (European Board of Radiology) performed all the measurements for this study. The maximum distance measurements between the abdominal aorta and its branches were obtained in the arterial phase from sagittal-oblique sagittal and coronal-oblique coronal CT images. The curve of the abdominal aorta was taken into consideration. To measure the distance between the origins of the major branches, a line parallel to the abdominal aorta was drawn between the inferior margin of the cranially situated vessel and the inferior margin of the caudally positioned vessel (Figure 2A). The distance between the aortic hiatus and the origins of the major branches was measured between the inferior margin of the vessel and the horizontal line, which represents the diaphragmatic level (Figure 2B). The length between the iliac bifurcation and the origins of the major branches was measured between the inferior border of the vessel and the horizontal line, which passes through the bifurcation level (Figure 2C).
The distances between the origin of the celiac trunk (CTR) and superior mesenteric artery (SMA); CTR and right renal artery (RRA); CTR and left renal artery (LRA); and CTR and inferior mesenteric artery (IMA) were measured. The distance measurements between the SMA-RRA, SMA-LRA, SMA-IMA, IMA-RRA, and IMA-LRA were performed as well. Moreover, the distances between the aorta at the diaphragmatic region, aortic bifurcation, and the origins of the major branches (CTR, SMA, RRA, LRA, IMA) were reported.
Ethical Statement
The study protocol was approved by University of Health Sciences Turkey, Dr. Behçet Uz Pediatric Diseases and Surgery Training and Research Hospital, Ethics Committee (protocol number: 2019/285, date: 11.04.2019). The declaration of Helsinki was preserved. The need for informed consent was waived by the ethics committee.
Statistical Analysis
The normality of continuous data was assessed visually using histograms and Q-Q plots for each measurement. The variables had a normal distribution and were expressed as mean±standard deviation (SD), and the categorical variables were presented as frequencies and percentages. The chi-square and one-way ANOVA tests were used to compare categorical and continuous data, respectively. Significant correlations were determined by the Pearson correlation test. Statistical Package for the Social Sciences (SPSS) software (version 20.0, SPSS Inc., Chicago, IL, USA) was used for statistical analyses. The level of significance was set at a p value of less than 0.05.
RESULTS
Demographic Data
The study population consisted of 134 (54.7%) boys and 111 (45.3%) girls aged between 0 and 18 years (mean age±SD, 8.48±5.14 years; 95% confidence interval7.83-9.13 years). The subjects were classified into six groups according to their age (Table 1).
Distances Between the Origins of the Major Branches
The mean distances between the origins of the CTR-SMA, CTR-RRA, CTR-LRA, and CTR-IMA were 12.8±4.2 (range; 4.7-27.2), 22.1±6.6 (range; 6.4-45.1), 23.0±6.6 (range; 6.2-48.3), and 67.0±17.8 (range; 16.6-116.1) mm, respectively. The mean distances between the origins of the SMA-RRA, SMA-LRA, and SMA-IMA were 9.3±5.4 (range; 0.9-32.1), 10.3±5.3 (range; 1.0-29.6), and 54.2±15.2 (range; 11.9-99.8) mm, respectively. The mean distances between the origins of the IMA-RRA and IMA-LRA were 45.8±14.4 (range; 9.6-87.5) and 44.6±13.9 (range; 9.5-84.5) mm, respectively.
The origin of the RRA was higher than LRA in 127 (51.8%) patients. The origins of the renal arteries were at the same level in only 50 (20.4%) cases. The origins of the renal arteries according to age groups were as follows: Group 1 [RRA higher than LRA (n=8); LRA higher than RRA (n=4); RA at same level (n=6)]; group 2 [RRA higher than LRA (n=14); LRA higher than RRA (n=8); RA at same level (n=12)]; group 3 [RRA higher than LRA (n=25); LRA higher than RRA (n=14); RA at same level (n=8)]; group 4 [RRA higher than LRA (n=31); LRA higher than RRA (n=16); RA at same level (n=13)]; group 5 [RRA higher than LRA (n=25); LRA higher than RRA (n=10); RA at same level (n=7)]; and group 6 [RRA higher than LRA (n=24); LRA higher than RRA (n=16); RA at same level (n=4)].
The distances between the origins of the major branches increased significantly with increasing age (p<0.0001 for all). Gender was not associated with any of these measurements (p>0.05 for all). Data for the distances between the origins of the major branches according to age and gender are summarized in Table 2.
Distances Between the Aorta at the Diaphragmatic Region and the Origins of the Major Branches
The mean distances between the aortic hiatus and the origins of the CTR, SMA, RRA, LRA, and IMA were 38.8±13.7 (range; 6.4-101.0), 51.5±15.8 (range; 11.1-116.5), 58.4±17.0 (range; 16.6-115.5), 60.2±17.3 (range; 16.3-117.7), and 104.0±27.7 (range; 26.2-180.9) mm, respectively. The distances between the aorta at the diaphragmatic region and the origins of the major branches showed a significant positive correlation with age (p<0.0001 for all). These measurements were higher in girls than boys and this gender difference reached the statistically significant level (p<0.05 for all).
The distances between the aortic hiatus and the origins of the major branches according to age and gender are reported in Table 3. The age-dependent distributions of these distances are presented in Figure 3.
Distances Between the Iliac Bifurcation and the Origins of the Major Branches
The mean distances between the iliac bifurcation and the origins of the CTR, SMA, RRA, LRA, and IMA were 89.7±24.5 (range; 31.6-142.1), 77.0±21.6 (range; 25.4-122.5), 70.2±21.0 (range; 21.4-118.2), 68.5±19.8 (range; 21.7-111.4), and 24.7±9.7 (range; 4.7-51.5) mm, respectively. The mean distance between the aorta at diaphragmatic region and iliac bifurcation was 128.7±33.3 (range; 38.0-207.5) mm.
Children’s age was significantly associated with the distances between the aortic bifurcation and the origins of the main branches (p<0.0001 for all). Gender did not have a significant impact on these distance values (p>0.05 for all). The mean distances between the aortic bifurcation and the origins of the major branches according to age and gender are presented in Table 4. The age-dependent distributions of these distances are demonstrated in Figure 4.
DISCUSSION
The present study is the first to calculate the distances between the origins of the major branches of the abdominal aorta and their distances to the aorta at the diaphragmatic region and iliac bifurcation in children aged 0 to 18 years. Here, we emphasize that knowing the distances between the major branches of the abdominal aorta may contribute to enhancing the safety and quality of the endovascular procedures in the abdominal region. The contrast-enhanced MDCT allows comprehensive and fast imaging of the abdominal aorta and its branches, thus minimizing the need for sedation in children2. Moreover, low dose CT provides images with a radiation dose that is much lower than conventional CT4. The three-dimensional multiplanar reformations present unique viewing and measuring advantages as well5. As a result, MDCT has become a valuable tool in the evaluation of vascular anatomy and pathologies in children3,6. The distance measurements between the abdominal aorta and its branches have been reported in various radiological and cadaveric studies focusing only on adults or both adults and children. Thus, a comparison of the present results with those from previous studies was undertaken with caution due to the differences in the age of patients, methodological approach, and geographical location.
A cadaveric study, carried out by Ozan et al.7, reported the mean distance between CTR and SMA, RRA, and LRA as 18.0, 30.0, and 33.2 mm, respectively. According to Lawton et al.8, the average CTR-SMA, CTR-RRA, and CTR-LRA distances on MDCT were 16.7±5.0, 30.7±7.9, and 30.5±7.7 mm, respectively. Arslan and Karacan9 reported the mean distances for CTR- SMA, CTR-RRA, CTR-LRA, and CTR-IMA as 15.08±4.36, 30.35±9.17, 33.49±7.80, and 89.00±1.42 mm, respectively. Most of the studies measured the mean CTR-SMA distance between 14 and 18 mm10-12. The origins of the RRA and LRA were located between 28.5-32 mm, and 27-36 mm below the CTR, respectively10,12. A recent MDCT angiography study by Ekingen et al.13 reported the mean CTR-SMA and CTR-IMA distances as 13.5±0.37 and 89.40±0.99 mm for males and 12.20±0.33 and 84.80±0.92 mm for females, respectively.
These studies were performed on adults and cannot be considered relevant for pediatric patients. The current study is the initial and unique imaging study to evaluate the vascular distances in children according to their age and gender. The mean distances between the origins of the CTR-SMA, CTR-RRA, CTR-LRA, and CTR-IMA were between 20% and 30% lower than those reported in adults7-9,13. Moreover, these distances increased significantly with age possibly related to aortic elongation with the age and body height of the children. Although not statistically significant, these distances were slightly longer among females probably due to the fact that girls in the pubertal and prepubertal periods tend to be taller than the boys. These findings were consistent with previously published results8,14.
Sośnik and Sośnik15 measured the SMA-RRA and SMA-LRA distances in 324 cadavers aged between 0 and 90 years. The average distance between SMA and renal arteries in children aged 0 to 20 years was 3.3±2.5 mm for the RRA and 4.1±3.7 mm for the LRA. The values reported by Sośnik and Sośnik15 were nearly 60% lower than ours. The reasons for this discrepancy might be explained by the differences in the diagnostic tools, age of the study population, and geographical factors. Previous studies conducted on adult patients found that the origins of the RRA, LRA, and IMA were located between 2-84 mm, 3-50 mm, and 24-100 mm below the SMA, respectively7,9,14,15, and were nearly 50% higher than the ranges reported in our study.
We found no data in the literature on the distances between IMA and renal arteries in the pediatric population. The mean distance between IMA and renal arteries in adults was 58.55±11.98 mm for the RRA and 55.10±11.38 mm for the LRA9. Our distance measurements were more than 20% lower than those reported in adults9,14. In the current study, the origin of the RRA was higher than LRA, which is in agreement with previous reports on adults8,16.
Anamaria et al.14 postulated that the origins of the CTR, SMA, RRA, LRA, and IMA in adults were located between 5.1-42.0 mm, 31.6-64.1 mm, 28.4-76.7 mm, 30.4-76.8 mm, and 107.4-153 mm below the level of the diaphragmatic aortic hiatus, respectively14. In the present study, the distances between the aorta at the diaphragmatic region and the origins of the major branches in children were between 40% and 65% lower than those reported by Anamaria et al.14 Moreover, these distances were significantly longer among females, which is in disagreement with the previous study14. This evidence could be important in order to plan different diagnostic and treatment procedures in boys and girls; however, the clinical impact of this finding is still to be determined.
Yahel and Arensburg10 measured the distances between aortic bifurcation and the origins of the unpaired splanchnic arteries in thirty-four adults and eight cadavers aged between 4 and 11 years. The average distances from the CTR, SMA, and IMA to the aortic bifurcation were 125.0±16.8 mm, 109.8±15.5 mm, and 41.8±6.9 mm, respectively10. Our distance measurements were approximately 35% lower than those reported by Yahel and Arensburg10. This discrepancy may have resulted from the selection bias, a small number of cadavers, and the differences in the diagnostic approach. These distances were not associated with gender, which is consistent with the findings reported by Yahel and Arensburg10.
A previous MDCT study on adults showed that the origins of the RRA and LRA were located between 59.3-113 mm and 59.2-109 mm above the aortic bifurcation, respectively14. The distance from the aorta at the diaphragmatic region to the aortic bifurcation was between 135.3 and 183.0 mm14. These results were approximately 60% higher than those reported in the current pediatric study.
The normative data for the distances between the origins of the major branches of the abdominal aorta, and their distances to the aorta at the diaphragmatic region and iliac bifurcation in pediatric patients may show wide variations due to the differences in the geographical, racial, ethnic, and genetic factors. Thus, we recommend that reference data for the vascular distances should be determined on a national level.
Study Limitations
Our study had several limitations that should be acknowledged. The presented findings were compared with the results of similar studies on adults due to the lack of currently available standardized measures for children. There was also no “gold standard” measurement tool for confirming the CT results. We did not evaluate the diameters and the topographic location of the main branches of the abdominal aorta in relation to the vertebral bodies, which should be addressed in future studies. This was a single-center study including a limited number of patients in each age group, so that future multicenter studies of a larger pediatric population are recommended to verify our findings.
TARTIŞMA
Bu çalışma, 0-18 yaş arası çocuklarda abdominal aortun ana dallarının orijinleri ile diyafragmatik bölgede aorta ve iliak bifurkasyon arasındaki mesafeleri hesaplayan ilk çalışmadır. Bu çalışmada, abdominal aortun ana dalları arasındaki mesafelerin bilinmesinin abdominal bölgedeki endovasküler prosedürlerin güvenliğini ve kalitesini artırmaya katkıda bulunabileceğini vurguluyoruz. Kontrastlı ÇDBT, abdominal aort ve dallarının kapsamlı ve hızlı görüntülenmesine olanak sağlayarak çocuklarda sedasyon ihtiyacını en aza indirir2. Ayrıca düşük doz BT, geleneksel BT’den çok daha düşük radyasyon dozuyla görüntüler sağlar4. Üç boyutlu multiplanar reformasyonlar, benzersiz görüntüleme ve ölçüm avantajları da sunarlar5. Sonuç olarak ÇDBT çocuklarda vasküler anatomi ve patolojilerin değerlendirilmesinde değerli bir araç haline gelmiştir3,6. Abdominal aort ve dalları arasındaki mesafe ölçümleri, sadece yetişkinlere veya hem yetişkinlere hem de çocuklara odaklanan çeşitli radyolojik ve kadavra çalışmalarında rapor edilmiştir. Bu nedenle, hastaların yaşı, metodolojik yaklaşım ve coğrafi konumdaki farklılıklar nedeniyle, mevcut sonuçlar önceki çalışmalardan elde edilenlerle dikkatli bir şekilde karşılaştırıldı.
Ozan ve ark.7 tarafından yapılan bir kadavra çalışmasında, ÇT ve SMA, RRA ile LRA arasındaki ortalama mesafe sırasıyla; 18,0, 30,0 ve 33,2 olarak rapor edilmiştir. Lawton ve ark.’na8 göre, ÇDBT’de ortalama ÇT-SMA, ÇT-RRA, ve ÇT-LRA mesafeleri sırasıyla; 16,7±5,0, 30,7±7,9 ve 30,5±7,7 mm idi. Arslan ve Karacan9 ÇT-SMA, ÇT-RRA, ÇT-LRA ve ÇT-İMA için ortalama mesafeleri sırasıyla; 15,08±4,36, 30,35±9,17, 33,49±7,80 ve 89,00±1,42 mm olarak bildirmişlerdir. Çalışmaların çoğu, ortalama ÇT-SMA mesafesini 14 ile 18 mm arasında ölçmüştür10-12. RRA ve LRA’nın orijinleri sırasıyla ÇT’nin 28,5-32 mm ve 27-36 mm altındaydı10,12. Ekingen ve ark.13 tarafından son zamanlarda yapılan bir ÇDBT anjiyografi çalışmasında ortalama ÇT-SMA ve ÇT-İMA mesafeleri sırasıyla erkeklerde 13,5±0,37 ve 89,40±0,99 mm ve kadınlarda 12,20±0,33 ve 84,80±0,92 mm olarak bildirilmiştir.
Bu çalışmalar yetişkinler üzerinde gerçekleştirilmiştir ve pediatrik hastalar için uygun kabul edilemez. Mevcut çalışma, çocuklarda vasküler mesafeleri yaşlarına ve cinsiyetlerine göre değerlendiren ilk ve tek bir görüntüleme çalışmasıdır. ÇT-SMA, ÇT-RRA, ÇT-LRA ve ÇT-İMA’nın orijinleri arasındaki ortalama mesafeler, yetişkinlerde bildirilenlerden %20-%30 arasında daha düşüktü7-9,13. Ayrıca, bu mesafeler, muhtemelen çocukların yaşı ve boy ile aort elongasyonuna bağlı olarak yaşla birlikte önemli ölçüde artmıştır. İstatistiksel olarak anlamlı olmasa da, bu mesafeler muhtemelen pubertal ve prepubertal dönemlerdeki kızların erkeklerden daha uzun olma eğiliminden dolayı kadınlarda biraz daha uzundu. Bu bulgular daha önce yayınlanmış sonuçlarla uyumluydu8,14.
Sośnik ve Sośnik15 0-90 yaş arası 324 kadavrada SMA-RRA ve SMA-LRA mesafelerini ölçmüşlerdir. 0-20 yaş arası çocuklarda SMA ile renal arterler arasındaki ortalama mesafe RRA için 3,3±2,5 mm ve LRA için 4,1±3,7 mm idi15. Sośnik ve Sośnik15 tarafından rapor edilen değerler bizimkinden yaklaşık %60 daha düşüktü. Bu farklılığın nedenleri, tanı araçları, çalışma popülasyonunun yaşı ve coğrafi faktörlerdeki farklılıklar ile açıklanabilir. Erişkin hastalar üzerinde yapılan önceki çalışmalar, RRA, LRA ve İMA’nın orijinlerinin SMA’nın sırasıyla; 2-84 mm, 3-50 mm ve 24-100 mm altında olduğunu göstermişlerdir7,9,14,15 ve bu değerler çalışmamızda bildirilen aralıklardan yaklaşık %50 daha yüksektir.
Pediatrik popülasyonda İMA ve renal arterler arasındaki mesafeler hakkında literatürde veri bulamadık. Erişkinlerde İMA ile renal arterler arasındaki ortalama mesafe RRA için 58,55±11,98 mm ve LRA için 55,10±11,38 mm idi9. Mesafe ölçümlerimiz yetişkinlerde bildirilenlerden %20 daha düşüktü9,14. Mevcut çalışmada, yetişkinlerle ilgili önceki raporlarla uyumlu olarak, RRA’nın orijini LRA’dan daha yüksekti8,16.
Anamaria ve ark.14 yetişkinlerde ÇT, SMA, RRA, LRA ve İMA’nın orijinlerinin diyafragmatik aortik hiatus seviyesinin altında sırasıyla 5,1-42,0 mm, 31,6-64,1 mm, 28,4-76,7 mm, 30,4-76,8 mm ve 107,4-153 mm arasında olduğunu varsaymışlardır. Mevcut çalışmada, çocuklarda diyafragmatik bölgedeki aort ile ana dalların orijinleri arasındaki mesafeler, Anamaria ve ark.14 tarafından bildirilen değerlerden %40-%65 arasında daha düşük bulunmuştur. Ayrıca, bu mesafeler, bir önceki çalışma ile çelişkili olarak, kadınlarda önemli ölçüde daha uzundu14. Bu kanıt, erkek ve kız çocuklarında farklı tanı ve tedavi prosedürlerinin planlanması için önemli olabilir; fakat, bu bulgunun klinik etkisi henüz belirlenmemiştir.
Yahel ve Arensburg10 34 yetişkin ve yaşları 4 ile 11 arasında değişen sekiz kadavrada aort bifurkasyonu ile eşleştirilmemiş splanknik arterlerin orijinleri arasındaki mesafeleri ölçtüler. ÇT, SMA ve İMA’dan aortik bifurkasyona olan ortalama mesafeleri sırasıyla; 125,0±16,8 mm, 109,8±15,5 mm ve 41,8±6,9 mm olarak gösterdiler10. Mesafe ölçümlerimiz, Yahel ve Arensburg10 tarafından bildirilenlerden yaklaşık %35 daha düşüktü. Bu farklılık, seçim yanlılığı, az sayıda kadavra ve tanısal yaklaşımdaki farklılıklardan kaynaklanmış olabilir. Bu mesafeler, Yahel ve Arensburg10 tarafından bildirilen bulgularla tutarlı olarak cinsiyet ile ilişkili değildi.
Yetişkinler üzerinde daha önce yapılan bir ÇDBT çalışması, RRA ve LRA’nın orijinlerinin aort bifurkasyonunun üzerinde sırasıyla; 59,3-113 mm ve 59,2-109 mm olduğunu göstermiştir14. Diyafragmatik bölgede aorttan aort bifurkasyonuna kadar olan mesafe 135,3 ile 183,0 mm arasındaydı14. Bu sonuçlar, mevcut pediatrik çalışmada bildirilenlerden yaklaşık %60 daha yüksekti.
Pediatrik hastalarda abdominal aortun ana dallarının orijinleri arasındaki mesafeler ile diyafragmatik bölgede aorta ve iliak bifurkasyona mesafelerine ilişkin normatif veriler coğrafi, ırksal, etnik, ve genetik faktörlere bağlı olarak geniş bir varyasyon sergileyebilir. Bu nedenle vasküler mesafeler için referans verilerin ulusal düzeyde belirlenmesini öneriyoruz.
Çalışmanın Kısıtlılıkları
Çalışmamızın kabul edilmesi gereken birkaç kısıtlılığı vardı. Sunulan bulgular, çocuklar için halihazırda mevcut standartlaştırılmış önlemlerin olmaması nedeniyle yetişkinler üzerinde yapılan benzer çalışmaların sonuçlarıyla karşılaştırıldı. Ayrıca, BT sonuçlarını doğrulamak için “altın standart” bir ölçüm aracı da yoktu. Gelecekteki çalışmalarda ele alınması gereken, abdominal aortun ana dallarının çaplarını ve topografik lokasyonlarını vertebral cisimlerle ilişkili olarak değerlendirmedik. Bu çalışma, her yaş grubundan sınırlı sayıda hasta içeren tek merkezli bir çalışmaydı. Bu nedenle bulgularımızı doğrulamak için daha büyük bir pediatrik popülasyonla çok merkezli çalışmaların yapılması önerilmektedir.
CONCLUSION
In conclusion, to the best of our knowledge, this is the first study to report the distances between the abdominal aorta and its branches in children up to 18 years of age. Our results might be used as a reference tool for determining the position of the major branches of the abdominal aorta which in turn may help to reduce the endovascular and surgical procedure-related complications in pediatric patients.
