Clinical anatomy of the inferior phrenic artery

The majority of anatomical textbooks of gross anatomy offer very little information concerning the anatomy and distribution of the inferior phrenic artery (IPA). In the last decade, however, increased numbers of reports have appeared with reference to the arterial supply of hepatocellular carcinoma (HCC). The IPA is a major source of collateral or parasitized arterial supply to this type of carcinoma, second only to the hepatic artery. The aim of this study was to identify the origin and distribution of the IPA (right and left), in normal and pathological cases, and to apply such findings to the clinical scenario of treating hepatic cancer. We have examined 300 formalin-fixed adult cadavers lacking abdominal pathology, and 30 cadavers derived from patients with HCC. Dissections in normal cadavers showed that the right IPA originated from the: a) celiac trunk in 40% of the specimens; b) aorta in 38%; c) renal in 17%; d) left gastric in 3%; and e) hepatic artery proper in 2% of the specimens. The left IPA originated from the: a) celiac trunk in 47%; b) aorta in 45%; c) renal in 5%; d) left gastric in 2%; and e) hepatic artery proper in 1% of the specimens. The IPA gave rise to eight notable branches: ascending, descending, inferior vena cava, superior suprarenal, middle suprarenal, esophageal, diaphragmatic hiatal, and accessory splenic. The right IPA was always associated with HCC and served as the major collateral artery adjunct to the hepatic artery. These findings could have major implications in the transcatheter embolization of HCC patients.     

Multiple variations in the paired arteries of the abdominal aorta

Variations in the origin of arteries in the abdomen are very common. The arteries that show frequent variations include the celiac trunk, renal arteries, and gonadal arteries. We observed multiple variations in a 45-year-old male cadaver. The variations found on the left side were: one accessory renal artery, two testicular arteries, and middle suprarenal and inferior phrenic arteries that branched from the celiac trunk. On the right side, the inferior phrenic and middle suprarenal arteries arose from the right renal artery.     

Rare case of right accessory renal artery originating as a common trunk with the inferior mesenteric artery: a case report

Dissection of a male cadaver revealed several vascular abnormalities in the abdominal cavity, notably of the renal circulation. In particular, three renal arteries were observed on the right side and two on the left. On the right side, one accessory renal artery originated as a common trunk with the inferior mesenteric artery. Additional variations included a left inferior phrenic artery originating from the celiac trunk, bilateral testicular veins emptying into renal veins, and the left testicular artery arising from the left renal artery. The possible embryonic development of these branching patterns and their clinical significance are discussed briefly.     

Coexistence of multiple anomalies in the celiac-mesenteric arterial system

The origins and distribution of arteries of the celiac-mesenteric system were examined by dissection of 52 formalin-fixed human cadavers. Seventy-five percent of the cadavers exhibited the classic Michels' Type I hepatolienogastric pattern; 25% had different branching patterns. Multiple anomalies of the celiac-mesenteric arterial system were observed in one Caucasian female cadaver: a short lienogastric trunk; a common hepatic artery arising directly from the abdominal aorta; an anomalous course of the hepatic arteries; an accessory left hepatic artery arising from the left and right gastric arterial anastomosis along the lesser curvature of the stomach; a double cystic artery; a common inferior phrenic trunk arising from the celiac trunk; and an aberrant arterial channel connecting the proximal segments of the splenic and gastroduodenal arteries. A patent ductus venosus and an anomalous formation of the portal vein by the confluence of the splenic and superior and inferior mesenteric veins was also observed. Although single anomalies of the celiac-mesenteric arterial system are common, complex combinations, such as were observed in the present case, represent a significant deviation from the normal developmental pattern. There seems to be no report in the literature of such a combination of anomalies coexisting in one individual. The developmental and clinical significance of these anomalous vessels is discussed.     

正常成人膈下动脉的超声观测

目的：观察膈下动脉的超声解剖及血流参数。方法：应用二维及多普勒超声观测100例正常成人的膈下动脉的起源、直径、血流参数（包括收缩期峰值速度、阻力指数、搏动指数）,并提出正常值范围。结果：超声能够显示起始于腹腔动脉干和腹主动脉的膈下动脉,右侧膈下动脉显示率（83％）较左侧（62％）高。正常成人膈下动脉直径左侧为（2．03±0．28）mm,右侧（2．07±0．30）mm,95％可信度上限值左侧2．58mm,右侧2．66mm;最大流速左侧为（45．95±12．65）cm／s,右侧（42．85±10．31）cm／s,95％可信区间左侧21．16～70．74cm／s,右侧22．64～63．16cm/s;阻力指数左侧为（0．78±0．04）cm/s,右侧（0．77±0．04）,95％可信区间：左侧0．70～0．86,右侧0．69～0．85。结论：超声能在一定程度上显示膈下动脉,评价膈下动脉起源及其血流参数.     

Aortic origin of right hepatic artery and superior mesenteric origin of splenic artery two rare variations demonstrated angiographically

Abstract Anatomical variations of the celiac trunk and superior mesenteric artery are not infrequent. Knowledge of the existing aberrations is important in planning and conducting surgical or radiological procedures. A case of right hepatic artery arising independently from the aorta supplying an hepatocellular carcinoma was identified, through which transarterial chemoembolization was successfully performed. A second case is presented with a common splenomesenteric trunk branching into the splenic and superior mesenteric arteries. These two cases represent exceptional arterial variations in the upper abdomen.     

The Contribution of the Left Phrenic Nerve to Innervation of the Esophagogastric Junction

The contribution of the left phrenic nerve to innervation of the esophagogastric junction. The esophagogastric junction is part of the barrier preventing gastroesophageal reflux. We have investigated the contribution of the phrenic nerves to innervation of the esophagogastric junction in humans and piglets by dissecting 30 embalmed human specimens and 14 piglets. Samples were microdissected and nerves were stained and examined by light and electron microscopy. In 76.6% of the human specimens, the left phrenic nerve participated in the innervation of the esophagogastric junction by forming a neural network together with the celiac plexus (46.6%) or by sending off a distinct phrenic branch, which joined the anterior vagal trunk (20%). Distinct left phrenic branches were always accompanied by small branches of the left inferior phrenic artery. In 10% there were indirect connections with a distinct phrenic nerve branch joining the celiac ganglion, from which celiac plexus branches to the esophagogastric junction emerged. Morphological examination of phrenic branches revealed strong similarities to autonomic celiac plexus branches. There was no contribution of the left phrenic nerve or accompanying arteries from the caudal phrenic artery in any of the piglets. The right phrenic nerve made no contribution in any of the human or piglet samples. We conclude that the left phrenic nerve in humans contributes to the innervation of the esophagogastric junction by providing ancillary autonomic nerve fibers. Experimental studies of the innervation in pigs should consider that neither of the phrenic nerves was found to contribute. Clin. Anat. 33:265–274, 2020. © 2019 Wiley Periodicals, Inc.     

An anomalous case of the hepatic artery arising from the superior mesenteric artery

In a stdudenet course of gross anatomy dissection at Kanagawa Dental College in 2006, we found an extremely rare case of the hepatic artery arising from the superior mesenteric artery of a 78-year-old Japanese male cadaver. This case belonged to type V in Adachi's classification of the celiac trunk and the superior mesenteric artery (1928). The gastro-splenic trunk and hepato-mesenteric trunk both arose from the abdominal aorta and the left gastric artery arose from the gastro-splenic trunk. The hepatic artery arose from the hepato-mesenteric trunk and crossed the portal vein anteriorly.     

Three cases of the gastrosplenic and the hepatomesenteric trunks

Three common branches of the celiac trunk are the left gastric artery, the splenic artery and the common hepatic artery. The variation of the three branches of the celiac trunk has an importance for the arterial supply to the digestive organs of the upper abdomen. In this study, we present three cases of the gastrosplenic and the hepatomesenteric trunks in Japanese cadavers. Especially, in Case 1, the left inferior phrenic artery arose from the gastrosplenic trunk and the left hepatic artery arose from the left gastric artery. In Cases 2 and 3, the common hepatic artery penetrated the pancreatic parenchyma before reaching liver. In Case 3, the right hepatic artery arose from the hepatomesenteric trunk.     

Rare case of the trunk of the inferior phrenic arteries originating from a common stem with a superior additional left renal artery from the abdominal aorta

We describe in this article a rare case of a 39‐year‐old male with an inferior phrenic arteries trunk (IPAaT) originating from a common stem with a superior additional left renal artery (SAdLRA) from the abdominal aorta as revealed by routine multidetector computed tomography angiography. The IPAaT with an endoluminal diameter at the origin of 2.8 mm had an upward path with a total length of 18.4 mm, forking to the right inferior phrenic artery and left inferior phrenic artery. These two arteries had an endoluminal diameter at the origin of 1.7 mm and 2.0 mm, respectively. The presence of the common stem of the IPAaT with a SAdLRA and the length of the IPAaT complicate selective chemoembolization of the liver parenchyma. Clin. Anat. 25:979–982, 2012. © 2012 Wiley Periodicals, Inc.     

肠系膜下动脉根部自主神经保护的解剖学基础

目的　观察肠系膜下动脉（IMA）根部与其周围自主神经的解剖学关系,为肠系膜下动脉根部自主神经保护提供解剖学证据。 方法　7例10%福尔马林固定标本进行大体解剖及显微解剖;2例新鲜标本模拟腹腔镜下直肠癌D3根治术中肠系膜下动脉根部自主神经的显露和保护。 结果　上腹下丛(SHP)的左、右侧束及束间交通支与肠系膜下动脉根部关系密切。右侧束距离肠系膜下动脉根部较远,位于肾前筋膜下。以左侧束降支为界,其近端,上腹下丛左侧束、肠系膜下丛、腹主动脉丛紧贴肠系膜下动脉根部左侧壁并相互延续,其远端左侧束走行于肾前筋膜下。左侧束降支距离IMA起点的距离不恒定。 结论　在肾前筋膜前平面分离可有效保护上腹下丛右侧束及侧束间交通支;以SHP左侧束降支作为肠系膜下动脉根部离断的解剖学标志可以有效保护左侧束。     

A rare case of inferior mesenteric artery arising from the superior mesenteric artery,with a review of the review of the literature

Anatomical variations of the inferior mesenteric artery (IMA) are uncommon. Generally, the IMA is very stable, arises directly from the abdominal aorta at the level of the third lumbar vertebra. We describe here an extremely rare case in which the IMA arose from the superior mesenteric artery. The findings were made during routine dissection of the cadaver of a 79-year-old Japanese man. This present case is the ninth report of this variation and was associated with gastrophrenic trunk, hepatosplenic trunk, hypoplastic spleen and accessory spleen. Clinically, cases like this highlight the importance of knowing the IMA anatomy and the possibility of its numerous variations in surgical procedures such as right hemicolectomy, resection of the transverse colon, left hemicolectomy, sigmoidectomy, and en bloc resection of the head of the pancreas and the superior mesenteric vessels. The developmental significance of this variation is also discussed with a detailed review of the literature.     

Common stem origin of left gastric,right and left inferior phrenic arteries,in association with a hepatosplenomesenteric trunk,independently arising from the abdominal aorta: Case report using MDCT angiography

We describe in this paper a rare case of a 45‐year‐old male with a common stem origin of the left gastric artery (LGA), right inferior phrenic artery (RIPA), and left inferior phrenic artery (LIPA), in association with the presence of a hepatosplenomesenteric trunk (HSMT) arising from the abdominal aorta (AA), as revealed by routine multidetector computed tomography (MDCT) angiography. The common stem origin of the LGA, RIPA, and LIPA had an endoluminal diameter of 3.3 mm, the LGA of 2.8 mm. The endoluminal diameter of the RIPA and LIPA was at the origin of approximately 1 mm, complicating selective chemoembolization of the liver parenchyma. Clin. Anat. 26:980–983, 2013. © 2012 Wiley Periodicals, Inc.     

Duplication of the inferior vena cava associated with other variations

Multiple vascular variations, including duplication of the inferior vena cava, double renal arteries and anomalies of the testicular blood vessels, were observed during dissection of the retroperitoneal region of a cadaver of an 87-year-old Japanese man. The right inferior vena cava arose from the union of right common iliac veins and a thinner interiliac vein. This interiliac vein ascended obliquely from right to left and joined the left common iliac veins to form the left inferior vena cava. The right and left inferior venae cavae were of approximately equal width. The right testicular vein consisted of medial and lateral venous trunks. The two venous trunks coalesced to form a single vein, which drained into the confluence of the right inferior vena cava and right renal vein. The left testicular vein was composed of the medial and lateral testicular veins, which drained into the left renal vein. Double renal arteries were seen bilaterally, which originated from the lateral aspects of the abdominal aorta. The right testicular artery arose from the right inferior renal artery and accompanied the lateral trunk of the right testicular vein running downwards. The left testicular artery arose from the ipsilateral inferior renal artery and ran downwards accompanied by the left lateral testicular vein. In addition, the bilateral kidneys showed multicystic changes.     

A morphometric study of the celiac trunk and review of the literature

The anatomy of the celiac trunk and its branches was examined in 77 adult human cadavers of Caucasian (Hellenic) origin. The celiac trunk followed the normal pattern, namely trifurcation to the common hepatic, splenic, and left gastric arteries, in 90.9% of the dissections (70/77). Two different types of trifurcation were observed: (a) a true tripod when the celiac trunk ended in a complete trifurcation (74.0%, 57/77) and (b) a false tripod when the three arteries did not have a common origin (16.9%, 13/77). Such a clear predominance of the true tripod is not reported elsewhere. Anatomic variations were found in 9.1% (7/77). Bifurcation of the celiac trunk into splenic and left gastric artery (splenogastric trunk) was observed in one specimen (1.3%), whereas the common hepatic artery emerged directly from the aorta. Absence of the celiac trunk was also found in two individuals (2.6%). The celiac trunk presented additional branches (lumbar and inferior phrenic arteries) in 5.2% (4/77). The median level of origin of the celiac trunk was at the upper third of L1 (22.7% to 17/75). The total length of the celiac trunk ranged from 1.1 to 5.0 cm, whereas the mean length was 2.8 cm (standard deviation = 0.80 cm, standard error of mean = 0.09 cm) irrespective of the existence of variations. The mean length of the celiac arteries which formed a false tripod was found to be larger than those of the arteries which formed a true tripod but only a weak statistically significant difference was established (P = 0.073). Clin. Anat. 26:741–750, 2013. © 2012 Wiley Periodicals, Inc.     

Anatomic variation of the celiac trunk with special reference to hepatic artery patterns

Based on a large homogeneous sample from a Japanese population, anatomic variations in the celiac trunk (CT) and the hepatic artery were studied. Previously we analyzed the branching mode of the CT in 450 Japanese cadavers. In order to maximize the database on the CT and hepatic artery, we examined the anatomy of these arteries in 524 cadavers, a total of 974 cases. A total of 89.8% of cases showed the classical trifurcation of the CT. The typical normal pattern of the CT and the hepatic artery was confirmed in 66.6% and 72.4% of the cadavers, respectively. Variant left and right hepatic arteries were observed in 11.0% and 4.9%, respectively. A variant anatomy involving both the left and right hepatic arteries was found in 1.5%. A common hepatosplenic trunk and a gastrohepatic trunk were seen in 4.4% and 0.3%, respectively. A common hepatic artery (CHA) arising from the superior mesenteric artery (SMA) or directly from the aorta was present in 3.5% or 0.5%, respectively. A hepatosplenomesenteric trunk and a celiomesenteric trunk were encountered in 0.7%, respectively. This anatomical update of the CT and the hepatic artery can be useful for transplantation and general surgeons, as well as vascular radiologists in this area.     

Hepatomesenteric trunk

Abstract An hepatomesenteric trunk, formed by the common hepatic and superior mesenteric arteries, was found in a 50-year-old male cadaver. The left gastric and splenic arteries arose as a common trunk, the gastrosplenic trunk, from the abdominal aorta; no typical celiac trunk was present. In addition, the hepatomesenteric trunk passed posterior to the portal vein. A knowledge of variations of the common hepatic artery may be important in pancreaticoduodenectomy, as well as during hepatic artery infusion chemotherapy.     

The anterior visceral branches of the abdominal aorta and their relationship to the renal arteries

Variations in the anatomy of the abdominal aorta and its branches are of interest as vessel geometry not only determines flow dynamics, but is also crucial in the pathogenesis of vascular disease. The relationship between the anterior visceral and renal arteries is important when undertaking diagnostic arteriography and endovascular interventions. To examine these relationships, the length of the abdominal aorta was determined and measurements taken of the position of origin of the celiac artery, superior mesenteric artery (SMA), inferior mesenteric artery (IMA) and renal arteries, as well as the three-dimensional projection of each vessel from the aorta. The mean level of bifurcation of the aorta was at the lower third of the body of L4, with the celiac artery, SMA, renal arteries and IMA arising at the level of the T12/L1 intervertebral disc, upper third of the body of L1, lower third of the body of L1 and lower third of the body of L3, respectively. The horizontal projection of the celiac artery, SMA and IMA was to the left of the midline; in the sagittal plane, the celiac artery and SMA projected anteriorly and the IMA posteriorly; in the coronal plane all vessels projected inferiorly, with the SMA to the right and the IMA to the left. The celiac artery, SMA and both renal arteries all arise from the proximal half of the abdominal aorta within 45 mm of each other, with the origins of the renal arteries being remarkably consistent. It is concluded that the celiac artery and SMA are both useful landmarks for determining the position of the renal arteries.