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Surgical and Radiologic Anatomy
Published in: Surgical and Radiologic Anatomy 1/2013

01-01-2013 | Original Article

Morphology of the ligament of Treitz likely depends on its fetal topographical relationship with the left adrenal gland and liver caudate lobe as well as the developing lymphatic tissues: a histological study using human fetuses

Authors: Jae Do Yang, Kazuo Ishikawa, Hong Pil Hwang, Hee Chul Yu, Jose Francisco Rodríguez-Vázquez, Gen Murakami, Baik Hwan Cho

Published in: Surgical and Radiologic Anatomy | Issue 1/2013

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Abstract

To investigate the factors affecting the development of the ligament of Treitz, we examined sagittal and frontal histological sections of 35 human fetuses with a crown-rump length of 100–300 mm (approximately 16–38 weeks of gestation). The retropancreatic fascia consistently extended in a layer behind the pancreatic body and the splenic artery and vein, and also in front of the left renal vein and left adrenal. In 18 specimens, a connective tissue band was seen originating from the diaphragmatic crus around the esophageal opening and ending at the retropancreatic fascia to the left of the origin of the celiac artery. In 10 of these 18 specimens, these putative upper parts of the ligament contained striated muscles, or so-called Hilfsmuskel. Although most of other 17 specimens were larger fetuses, the left adrenal, the liver caudate lobe and the celiac ganglion made space for the ligament very limited. In 22 specimens including the above 18, the retropancreatic fascia extended inferiorly to approach the fourth portion of the duodenum (D4) or the duodenojejunal junction (DJJ). However, in 11 of the 22 examples of the putative lower part of the ligament, the connection between the duodenal muscle coat and the fascia was interrupted by developing lymphatic tissues. Consequently, the ligament of Treitz seemed to develop from both pleuroperitoneal membrane-derived cells and the retropancreatic fusion fascia, although the morphology was markedly modified by adjacent structures such as the adrenal gland. The ligament may “recover” after the adrenal becomes reduced in size after birth.
Literature
1.
Androulakis J, Colbom GL, Skandalakis PM, Skandalakis LJ, Skanadalakis JE (2000) Embryologic and anatomic basis of duodenal surgery. Surg Clin N Am 80:171–199PubMedCrossRef
2.
Borghi F, Gattolin A, Bogliatto F, Garavoglia M, Levi AC (2002) Relationships between gastric development and anatomic bases of radical surgery for cancer. World J Surg 26:1139–1144PubMedCrossRef
3.
Cho BH, Kimura W, Song CH, Fujimiya M, Murakami G (2009) An investigation of the embryologic development of the fascia used as the basis for pancreaticoduodenal mobilization. J Hepatobiliary Pancreat Surg 16:824–831PubMedCrossRef
4.
Costacurta L (1972) Anatomical and functional aspects of the human suspensory muscle of the duodenum. Acta Anat 32:34–46CrossRef
5.
Deki H, Sato T (1988) An anatomic study of the pancreatic lymphatics. Surg Radiol Anat 10:121–135PubMedCrossRef
6.
Haley JC, Perry JH (1943) The suspensory muscle of the duodenum. Am J Surg 59:546–550CrossRef
7.
Haley JC, Perry JH (1949) Further study of the suspensory muscle of the duodenum. Am J Surg 77:590–595PubMedCrossRef
8.
Hamilton WJ, Mossman HW (1978) Human embryology, 4th edn. MacMillan Press, London, p 339 (351–352)
9.
Hayashi S, Rodríguez-Vázquez JF, Cho BH, Verdugo-López S, Murakami G, Nakano T (2011) Pleuroperitoneal canal closure and fetal adrenal gland. Anat Rec 294:633–644CrossRef
10.
Hwang SE, Cho BH, Hirai I, Kim HT, Kim JH, Fujimiya M, Murakami G, Kimura W (2010) Topographical anatomy of Spiegel’s lobe and its adjacent organs in mid-term fetuses: its implication on the development of the lesser sac and adult morphology of the upper abdomen. Clin Anat 23:712–719PubMedCrossRef
11.
Inoue Y (1936) Über das Lymphgefässyetem des Magens, Duodenums, Pankreas und des Zwerchfells. Acta Anat Nippon 9:35–117 (In Japanese with German abstract)
12.
Jin ZW, Nakamura T, Yu HC, Kimura W, Murakami G, Cho BH (2010) Fetal anatomy of peripheral lymphatic vessels: a D2–40 immunohistochemical study using an 18-week human fetus (CRL 155 mm). J Anat 216:671–682PubMedCrossRef
13.
Jin ZW, Cho BH, Murakami G, Fujimiya M, Kimura W, Yu HC (2010) Fetal development of the retrohepatic inferior vena cava: re-evaluation of the Alexander Barry’s hypothesis. Clin Anat 23:297–303PubMed
14.
Jit I (1952) The development and the structure of the suspensory muscle of the duodenum. Anat Rec 113:395–407PubMedCrossRef
15.
Jit I, Grewal SS (1977) The suspensory muscle of the duodenum and its nerve supply. J Anat 123:397–405PubMed
16.
Kim SK, Cho CD, Wojtowycz AR (2008) The ligament of Treitz (the suspensory ligament of the Duodenum): anatomic and radiographic correlation. Abdom Imaging 33:395–397PubMedCrossRef
17.
Kim JH, Han EH, Jin ZW, Lee HK, Fujimiya M, Murakami G, Cho BH (2012) Fetal topographical anatomy of the upper abdominal lymphatics: its specific features in comparison with other abdominopelvic regions. Anat Rec 295:91–104CrossRef
18.
Low A (1907) A note on the crura of the diaphragm and the muscle of Treitz. J Anat Physiol 42:93–96PubMed
19.
Matsubara A, Murakami G, Niikura H, Kinugasa Y, Fujimiya M, Usui T (2009) Development of the human retroperitoneal fasciae. Cells Tissues Organs 190:286–296PubMedCrossRef
20.
21.
Nebot-Cegarra J, Maraculla-Sanz E, Reina-De La Torre F (1999) Factors involved in the “rotation” of the human embryonic stomach around its longitudinal axis: computer-assisted morphometric analysis. J Anat 194:61–69PubMedCrossRef
22.
Treitz W (1853) Uber einem neuren Muskel am Duodenum des Menshen, űber elastische Sehen, und andere anatomische Verhältnisse. Vierteljahsrsschrift fuer die praktische Heilkunde 37:113–144
23.
Van der Zypen E, Révész E (1984) Investigation of development, structure and function of the phrenocolic and duodenal suspensory ligaments. Acta Anat 119:142–148PubMedCrossRef
Metadata
Title
Morphology of the ligament of Treitz likely depends on its fetal topographical relationship with the left adrenal gland and liver caudate lobe as well as the developing lymphatic tissues: a histological study using human fetuses
Authors
Jae Do Yang
Kazuo Ishikawa
Hong Pil Hwang
Hee Chul Yu
Jose Francisco Rodríguez-Vázquez
Gen Murakami
Baik Hwan Cho
Publication date
01-01-2013
Publisher
Springer-Verlag
Published in
Surgical and Radiologic Anatomy / Issue 1/2013
Print ISSN: 0930-1038
Electronic ISSN: 1279-8517
DOI
https://doi.org/10.1007/s00276-012-0996-x

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