人膈肌内神经分支分布

目的：探讨人膈的神经支配和肌内神经分支分布特点。方法：改良Sihler’s肌内神经分支染色法。结果：(1)一侧膈神经入肌后一般分为3—4支(3支型4例,4支型2例),1支(前支)向前内侧走行,支配胸部,1～2支(前外侧支)向外侧走行,支配肋部,最后1支(后支)最粗大,向后下走行,分为后外侧支和后脚支,分别支配膈中心腱外侧叶后外侧的肋部和腰部,各级神经的分支在肌束中部密集排列成神经丛。(2)6例标本均未发现左侧或右侧膈神经越过中线至对侧。(3)2例带肋间肌的标本肉眼未见有肋间神经分支进入膈。结论：(1)左、右膈神经分布于膈,未见左右侧膈神经重叠支配和优势支配。(2)膈神经的终末分支在肌束中部密集排列形成似“肾形”的神经丛带。     

A review of the thoracic splanchnic nerves and celiac ganglia

Anatomical variation of the thoracic splanchnic nerves is as diverse as any structure in the body. Thoracic splanchnic nerves are derived from medial branches of the lower seven thoracic sympathetic ganglia, with the greater splanchnic nerve comprising the more cranial contributions, the lesser the middle branches, and the least splanchnic nerve usually T11 and/or T12. Much of the early anatomical research of the thoracic splanchnic nerves revolved around elucidating the nerve root level contributing to each of these nerves. The celiac plexus is a major interchange for autonomic fibers, receiving many of the thoracic splanchnic nerve fibers as they course toward the organs of the abdomen. The location of the celiac ganglia are usually described in relation to surrounding structures, and also show variation in size and general morphology. Clinically, the thoracic splanchnic nerves and celiac ganglia play a major role in pain management for upper abdominal disorders, particularly chronic pancreatitis and pancreatic cancer. Splanchnicectomy has been a treatment option since Mallet‐Guy became a major proponent of the procedure in the 1940s. Splanchnic nerve dissection and thermocoagulation are two common derivatives of splanchnicectomy that are commonly used today. Celiac plexus block is also a treatment option to compliment splanchnicectomy in pain management. Endoscopic ultrasonography (EUS)‐guided celiac injection and percutaneous methods of celiac plexus block have been heavily studied and are two important methods used today. For both splanchnicectomies and celiac plexus block, the innovation of ultrasonographic imaging technology has improved efficacy and accuracy of these procedures and continues to make pain management for these diseases more successful. Clin. Anat. 23:512–522, 2010. © 2010 Wiley‐Liss, Inc.     

Morphological study of the ansa cervicalis and the phrenic nerve

Morphological features of ansa cervicalis and phrenic nerve were studied in 106 cadavers. Ansa cervicalis was located medial to the internal jugular vein in 63% (medial type) and lateral to the vein in 33.7% (lateral type). Ansa cervicalis was derived from a combination of C1-C4 spinal segments, with C1-C3 being the most frequent pattern (87.5%). In >60% the ansa was bilaterally symmetrical. The distribution of medial and lateral types was equal on left and right sides of the body. The segmental composition of the inferior root was higher in the medial type and also on the left side of the body. In the lateral type the branches that formed the inferior root frequently (75%) formed a common trunk before joining the superior root, but in 74.8% of the medial type they joined the superior root independently. The phrenic nerve was derived from C4 and C5 in 52%. The C4 segment was present in the phrenic nerve in all cases except one. Additional phrenic components that pass anterior to the subclavian vein were defined as accessory phrenic nerves and found in 28.7%, while those passing posterior to the same vein were defined as secondary phrenic nerves (19.8%). Most of the accessory phrenic nerves contained a C5 segment and the nerve to subclavius was the commonest source. Various relationships between the ansa cervicalis and the phrenic nerve are investigated and, based on these findings, two separate classifications for the two nerves are suggested.     

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.     

The communicating branch of the 4th cervical nerve to the brachial plexus: the double constitution, anterior and posterior, of its fibers

Twenty-four adult cadavers (48 sides) were used to investigate the incidence of a branch arising from the ventral ramus of the fourth cervical nerve (C4) with the phrenic nerve and subsequently joining the brachial plexus. Six brachial plexuses with spinal cords and phrenic nerves were dissected under a surgical microscope to investigate localization of fibers contained in the C4 branch to the brachial plexus. The incidence of the C4 branch was 23% (11/48 sides). Branches from C4 to the brachial plexus divided into anterior and posterior divisions on four sides (4/6 sides). On two sides, the branch did not divide but consisted entirely of an anterior division (2/6 sides). In the brachial plexus, anterior division fibers of the C4 branch were intertwined with fibers from the anterior divisions of the ventral rami of the fifth and sixth cervical nerves. They then passed to the suprascapular nerve and the anterior division of the superior trunk (6/6 sides). On the other hand, posterior division fibers of the C4 branch were intertwined with fibers from the posterior divisions of the ventral rami of the fifth and sixth cervical nerves. They then passed to the suprascapular nerve (2/6 sides) and the posterior division of the superior trunk (4/6 sides). The anterior division of the C4 branch received fibers from the ventral rootlets of the entire fourth cervical segment, whereas the posterior division received fibers from the ventral rootlets of the caudal half of the fourth cervical segment only. The fact that the suprascapular nerve received fibers from both the anterior and posterior divisions of the C4 branch was considered to support our claim that the human suprascapular nerve belongs to both the anterior and posterior divisions of the brachial plexus.     

Variations in the source of origin of inferior phrenic artery: a cadaveric study

Introduction: The right and left inferior phrenic arteries perfuse the diaphragm. They may originate either from the aorta, celiac trunk, or from the renal artery. Most textbooks of human anatomy give little information regarding the functional anatomy of the inferior phrenic artery. In the past few years, however, more articles have been published regarding the arterial supply in cases of hepatocellular carcinoma. The inferior phrenic artery is seen as an important source of collateral arterial supply to hepatocellular carcinoma, the hepatic artery being the main source. Materials and methods: A cadaveric study was conducted in the Anatomy Department of Bangalore Medical College during the years 2009–2011. Manual dissection was done to identify the inferior phrenic arteries, and their origins were traced. Results: The inferior phrenic artery arose from the aorta in 53.125%, celiac trunk in 28.125%, renal artery in 15.625%, and the superior mesenteric artery in 3.125% of the 32 cadavers studied. The right inferior phrenic artery arose from aorta in 56.25%, celiac trunk in 18.75%, renal artery in 18.75%, and superior mesenteric artery in 6.25% cases. The left inferior phrenic artery arose from aorta in 50%, from celiac trunk in 37.5%, and the rest arose (12.5%) from the renal artery. Discussion: The results were compared with those of earlier studies so that such findings could be applied in the treatment of hepatocellular carcinoma. The significance of this information is due to the fact that an unresectable hepatocellular carcinoma can be treated by transcatheter embolization of the right inferior phrenic artery, in case it is involved.     

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。     

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.     

部分膈神经与喉返神经前支吻接治疗双侧喉麻痹的显微外科解剖

借助SXP-I型手术显微镜,观察测量了30例成人膈神经(颈段)的起源、长度、位置和血供,以及喉返神经前支在喉内的主要分支,结合组织学、AchE组织化学方法,观察了膈神经,喉返神经前支的横截面积,神经束、有髓纤维和运动纤维的数目;提出了用部分膈神经与喉返神经前支吻接结合喉返神经侧肌支切断植入环杓后肌的方法以治疗双侧喉返神经损伤引起喉麻痹的手术设想。     

大鼠膈神经移位迷走神经支配心脏的实验解剖学研究

目的：为大鼠膈神经移位迷走神经支配心脏提供显微解剖学依据。方法：20只健康雄性SD大鼠在10倍手术显微镜下解剖双侧膈神经、迷走神经及其分支。用游标卡尺（精确度为0．02mm）测量膈神经分支直径、长度，迷走神经各段的直径、长度及其与膈神经起始端的距离。结果：（1）大鼠膈神经分支有胸骨支、前外侧支、后支，迷走神经分支有咽支、喉前神经、返神经、心支和胸腹腔支。（2）大鼠膈神经主干起始端直径为（0．22±0．04）mm，其与迷走神经咽支、喉前神经、左侧返神经、右侧返神经、心支、锁骨上水平部的距离分别是（8．46±0．06）mm、（35．98±0．06）mm、（25．66±0．04）mm、（22．88±0．06）mm、（42．06±0．04）mm、（2．46±0．82）mm。结论：迷走神经锁骨上水平发出的主干与膈神经主干起始端较接近，可以与膈神经直接缝合。     

胃上动脉的应用解剖及其临床意义

本文调查64具尸体左膈下动脉的返(胃)支.其出现率为45.3%.成人平均长21.2mm,起始部平均外径1.2mm。该支动脉分布于胃底后壁和贲门及食管腹段后壁.根据动脉命名原则,作者建议命名为胃上动脉(superior gastric aftery).并探讨其在临床上的意义.     

Innervation of human soft palate muscles

Our objective was to determine the branching and distribution of the motor nerves supplying the human soft palate muscles. Six adult specimens of the soft palate in continuity with the pharynx, larynx, and tongue were processed with Sihler's stain, a technique that can render large specimens transparent while counterstaining their nerves. The cranial nerves were identified and dissection followed their branches as they divided into smaller divisions toward their terminations in individual muscles. The results showed that both the glossopharyngeal (IX) and vagus (X) nerves have three distinct branches, superior, middle, and inferior. Only the middle branches of each nerve contributed to the pharyngeal plexus to which the facial nerve also contributed. The pharyngeal plexus was divided into two parts, a superior innervating the palatal and neighboring muscles and an inferior innervating pharyngeal constrictors. The superior branches of the IX and X nerves contributed innervation to the palatoglossus, whereas their middle branches innervated the palatopharyngeus. The palatoglossus and palatopharyngeus muscles appeared to be composed of at least two neuromuscular compartments. The lesser palatine nerve not only supplied the palatal mucosa and palatine glandular tissue but also innervated the musculus uvulae, palatopharyngeus, and levator veli palatine. The latter muscle also received its innervation from the superior branch of X nerve. The findings would be useful for better understanding the neural control of the soft palate and for developing novel neuromodulation therapies to treat certain upper airway disorders such as obstructive sleep apnea.     

The morphogenesis of the renal plexus: Renal artery and sympathetic fibers

To examine the origin and development of the renal plexus and its relationship to the renal vessels in embryos and early human fetuses. Serial sections of 34 human embryos (stages 16 to 23 of Carnegie, 4 or 5–8 weeks) and 38 fetuses (9–19 weeks) were analyzed. Throughout the embryonic period, the kidney was not innervated by the renal plexus. Those nerves appeared at the beginning of the early fetal period (9 weeks) as branches given off by the immature autonomic abdominal plexus. The renal nerves started to approach to the kidney during the early fetal period at 9–10 weeks of development. They were distributed in close proximity to the renal arteries and their branches. They were observed first with the settlement of the renal veins. The renal artery is present as a branch of the abdominal aorta at stage 19 (between 6 and 7 weeks) prior to development of the renal plexus. The renal veins were not present during the embryonic period but appeared at the start of the fetal period, along with the renal nerves that emerged from segmented sympathetic para‐aortic bodies (SPBs). Clin. Anat. 32:272–276, 2019. © 2018 Wiley Periodicals, Inc.     

Anatomical study of the pancreas in the house musk shrew (Suncus murinus), with special reference to the blood supply and innervation

To examine the macroscopic structure, blood supply, and innervation of the pancreas in the house musk shrew (Suncus murinus), we performed gross anatomical dissection and whole-mount immunostaining of the autonomic nerve of Suncus pancreases based on neurofilament protein (NFP) immunoreactivity. The adult Suncus pancreas is clearly separated into right and left lobes that are not fused. The right lobe of the Suncus pancreas is located in the dorsum of the duodenum and to the right of the common bile duct independently. The right lobe is supplied by branches of the superior mesenteric artery, and is innervated by branches that originate from the superior mesenteric plexus and run along the arterial branches of the superior mesenteric artery. The left lobe occupies 9/10 of the entire pancreas and is located to the left of the common bile duct. It is supplied mainly by branches of the splenic and common hepatic arteries, and is innervated by branches that originate from the celiac plexus and run along the splenic and common hepatic arteries. According to previous studies on the blood supply and innervation of the human pancreas, the right and left lobes of the Suncus pancreas correspond to the pancreatic parts derived from the ventral and dorsal pancreatic buds. The current results suggest that the Suncus pancreas is a suitable experimental model for studying the development of the human pancreas.     

The gross anatomy of the extrathoracic course of the intercostobrachial nerve

Recent reports emphasize the importance of preserving the intercostobrachial nerve (ICBN) during surgical procedures (i.e., mastectomy, axillary clearance). However, a limited number of scientific reports explore the surgical anatomy of this nerve. We dissected 100 adult human formalin-fixed cadavers (200 axillae). In all the cadavers the ICBN was present with variant contributions from intercostal nerves T1, T2, T3, and T4. The arrangements of the ICBN were typed as I through VIII. The components of Type I (45% or 90 of our specimens) included a branch to the posterior antebrachial cutaneous nerve, a branch to the anterior and lateral parts of the axilla, a branch to the medial side of the arm, and a branch to the medial antebrachial cutaneous nerve. Type II (25%) describes the ICBN arising from T2 and giving off a branch to the brachial plexus. In Type III (10%), lateral cutaneous branches of T2 and T3 fuse as a common trunk and then split immediately after exiting the intercostal space to form an ICBN. In type IV (5%), T2 and T3 join distally to form an ICBN that ends as its terminal branches. Type V (5%): T3 joins T2 from the same intercostal space proximally, with Type VI (3%) showing a very proximal branching of the sensory terminal nerves. Type VII (5%) displayed a contribution from T3 and a branch to the brachial plexus with multiple terminating branches. A contribution from T3 and T4 and a branch to the brachial plexus with multiple branches of termination comprised Type VIII (2%).     

Anatomical Study of the Brachial Plexus in the Common Marmoset (Callithrix Jacchus)

To elucidate the forelimb phylogeny of primates, anatomical analysis of the brachial plexus in platyrrhines is beneficial. In the present study, six brachial plexuses and the surrounding arteries of four common marmosets were dissected. In five specimens, the brachial plexus consisted of five ventral rami from the fifth cervical nerve (C5) to the first thoracic nerve (T1). In one specimen, the ventral ramus of the fourth cervical nerve joined with the brachial plexus. In five specimens, the upper trunk was composed of C5 and the sixth cervical nerve (C6). In one specimen, the ventral division of C6 merged with the ventral branch of the middle trunk to constitute the lateral cord. The seventh cervical nerve constituted the middle trunk, and the eighth cervical nerve and T1 formed the lower trunk in all specimens. The lateral cord gave rise to the musculocutaneous nerve, and the remaining component merged with the medial cord. The confluence of the lateral and medial cords immediately bifurcated into the median and ulnar nerves. These branching patterns of the musculocutaneous, median, and ulnar nerves were consistent and similar to the human counterparts. In the dorsal division, the single posterior cord as observed in the human brachial plexus was not observed. The axillary artery did not pass between the medial and lateral roots of the median nerve, and the axillary artery bifurcated into the brachial artery and the superficial brachial artery. Anat Rec, 300:1299–1306, 2017. © 2017 Wiley Periodicals, Inc.     

Nerve communication between the glossopharyngeal nerve,external carotid plexus and the superficial cervical ansa: human autopsy case

The authors encountered a very rare human autopsy case in which the supernumerary branch of the glossopharyngeal nerve and a nerve branch arising from the external carotid plexus communicated with the superficial cervical ansa. This anomaly was observed on the left side of a 71-year-old male cadaver during the gross anatomical seminar at Niigata University in 2004. The nerve fascicle and fiber analyses indicated that the supernumerary branch of the glossopharyngeal nerve separated cranial to the branches to the pharyngeal constrictor muscles, carotid sinus and stylopharyngeal muscle and sent the nerve fibers to the muscular branches to the platysma and the cutaneous branches to the cervical region. Additionally, it was shown that the branch arising from the external carotid plexus sent the nerve fibers to the cutaneous branch to the cervical region. Although the external carotid plexus is primarily postganglionic sympathetic fibers originating from the superior cervical ganglion, the vagus and glossopharyngeal nerves gave off branches connecting to the plexus, and therefore it was not possible to determine the origins of this branch of the external carotid plexus. The present nerve fascicle analysis demonstrates that the supernumerary branch of the glossopharyngeal nerve, which innervated the platysma, did not share any nerve components with the branches to the pharyngeal constrictor muscles, carotid sinus and stylopharyngeal muscle, suggesting that this supernumerary branch may be categorized into the different group from these well-known branches.     

Nerves in the intersphincteric space of the human anal canal with special reference to their continuation to the enteric nerve plexus of the rectum

In the intersphincteric space of the anal canal, nerves are thought to “change” from autonomic to somatic at the level of the squamous‐columnar epithelial junction of the anal canal. To compare the nerve configuration in the intersphincteric space with the configuration in adjacent areas of the human rectum, we immunohistochemically assessed tissue samples from 12 donated cadavers, using antibodies to S100, neuronal nitric oxide synthase (nNOS), and tyrosine hydroxylase (TH). Antibody to S100 revealed a clear difference in intramuscular nerve distribution patterns between the circular and longitudinal muscle layers of the most inferior part of the rectum, with the former having a plexus‐like configuration, while the latter contained short, longitudinally running nerves. Most of the intramural ganglion cells in the anal canal were restricted to above the epithelial junction, but some were located just below that level. Near or at the level of the epithelial junction, the nerves along the rectal adventitia and Auerbach's nerve plexus joined to form intersphincteric nerves, with all these nerves containing both nNOS‐positive parasympathetic and TH‐positive sympathetic nerve fibers. Thus, it was histologically difficult to distinguish somatic intersphincteric nerves from the autonomic Auerbach's plexus. In the intersphincteric space, the autonomic nerve elements with intrapelvic courses seemed to “borrow” a nerve pathway in the peripheral branches of the pudendal nerve. Injury to the intersphincteric nerve during surgery may result in loss of innervation in the major part of the internal anal sphincter. Clin. Anat. 26:843–854, 2013. © 2013 Wiley Periodicals, Inc.