Changes in topographical relation between the ductus arteriosus and left subclavian artery in human embryos: a study using serial sagittal sections
Abstract
Background: At birth, the ductus arteriosus (DA) merges with the aortic arch in the slightly caudal side of the origin of the left subclavian artery (SCA). Since the SCAs (7th segmental arteries) were fixed on the level of the 7th cervical-first thoracic vertebral bodies, the confluence of DA should migrate caudally. We aimed to describe timing and sequence of the topographical change using serial sagittal sections of 36 human embryos and foetuses (CRL 8–64 mm; 5–10 weeks), Those made easy evaluation of the vertebral levels possible in a few section. Materials and methods: The DA or 6th pharyngeal arch artery seemed to slide down in front of the sympathetic nerve trunk along 1.0–1.2 mm from the second cervical vertebral level at 5–6 weeks and, at 6 weeks (CRL 14–17 mm), the DA confluence with aorta reached the 7th cervical level. Because of the highly elongated common carotid artery, the sliding of DA confluence seemed to be much shorter than the cervical vertebrae growing from 1 mm to 2.4 mm. Results: At the final topographical change at 6–7 weeks, the DA confluence further descended to a site 1-vertebral length below the left SCA origin. From 6 to 9 weeks, a distance from the top of the aortic arch to the left SCA origin was almost stable: 0.3–0.5 mm at 6 weeks and 0.4–0.6 mm at 9 weeks. Conclusions: The heart descent and the caudal extension of the trachea and bronchi, those occurred before the DA sliding, were likely to be a major driving force for the sliding.
Keywords: heart descentductus arteriosussubclavian arterytopographical anatomypharyngeal archhuman embryo
References
- Abe H, Yamamoto M, Suzuki R, et al. Changes in topographical relation between the ductus arteriosus and left subclavian artery in human embryos: a study using serial sections. Okajimas Folia Anat Jpn. 2017; 94(1): 27–35.
- Anderson RH, Chaudhry B, Mohun TJ, et al. Normal and abnormal development of the intrapericardial arterial trunks in humans and mice. Cardiovasc Res. 2012; 95(1): 108–115.
- Barry A. The aortic arch derivatives in human adult. Anat Rec. 1951; 111(2): 221–238.
- Fukuoka K, Wilting J, Rodríguez-Vázquez JF, et al. The Embryonic Ascent of the Kidney Revisited. Anat Rec (Hoboken). 2019; 302(2): 278–287.
- Hamilton WJ, Mossman HW. Human embryology. 4th ed. Williams & Wilkins, London 1978: 230–271.
- Honkura Y, Yamamoto M, Yoshimoto T, et al. Is the ultimobranchial body a reality or myth: a study using serial sections of human embryos. Okajimas Folia Anat Jpn. 2016; 93(2): 29–40.
- Jin ZW, Yamada T, Kim JiH, et al. Pathogenesis of solitary right aortic arch: a mass effect hypothesis based on observations of serial human embryonic sections. Cardiol Young. 2017; 27(2): 359–368.
- Orts-Llorca F, Puerta Fonolla J, Sobrado J. The formation, septation and fate of the truncus arteriosus in man. J Anat. 1982; 134(Pt 1): 41–56.
- Radlanski RJ, Renz H. An atlas of prenatal development of the human orofacial region. Eur J Oral Sci. 2010; 118(4): 321–324.
- Rana MS, Sizarov A, Christoffels VM, et al. Development of the human aortic arch system captured in an interactive three-dimensional reference model. Am J Med Genet A. 2014; 164A(6): 1372–1383.
- Sizarov A, Lamers WH, Mohun TJ, et al. Three-dimensional and molecular analysis of the arterial pole of the developing human heart. J Anat. 2012; 220(4): 336–349.
- Skandalakis JE, Gray SW. Embryology for surgeons. 2nd ed. Williams & Wilkins, Baltimore 1994: 976–1030.
- Takanashi Y, Honkura Y, Rodriguez-Vazquez JF, et al. Pyramidal lobe of the thyroid gland and the thyroglossal duct remnant: a study using human fetal sections. Ann Anat. 2015; 197: 29–37.
- Thompson RP, Sumida H, Abercrombie V, et al. Morphogenesis of human cardiac outflow. Anat Rec. 1985; 213(4): 578–86, 538.
- Van Mierop LH, Alley RD, Kausel HW, et al. Pathogenesis of transposition complexes. I. Embryology of the ventricles and great arteries. Am J Cardiol. 1963; 12: 216–225.
