DOCSLIB.ORG

NOTES: BLOOD VESSELS – Arteries and Veins ARTERIAL SYSTEM Major Arteries Exiting the Heart: ● PULMONARY ARTERIES (From Heart to Lungs)

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
NOTES: BLOOD VESSELS – Arteries and Veins ARTERIAL SYSTEM Major Arteries Exiting the Heart: ● PULMONARY ARTERIES (From Heart to Lungs) NOTES: BLOOD VESSELS – Arteries and Veins ARTERIAL SYSTEM Major Arteries exiting the heart: ● PULMONARY ARTERIES (from heart to lungs) ● AORTA AORTA: ● the aorta is the largest artery (diameter) ● the aorta can be divided into the: *ASCENDING AORTA (as it emerges from the heart) *AORTIC ARCH *DESCENDING AORTA Principal branches of the AORTA: ● the major branches are the: *CORONARY ARTERIES (branch off from the base of the ascending aorta) *BRACHIOCEPHALIC (branch of the aortic arch) *LEFT COMMON CAROTID (branch of the aortic arch) *LEFT SUBCLAVIAN (branch of the aortic arch) Principal branches of the AORTA: ● the descending aorta gives rise to the: *THORACIC AORTA and *ABDOMINAL AORTA ● the abdominal aorta gives rise to the: *R and L RENAL arteries (go to the kidneys ) *R and L COMMON ILIAC arteries Arteries to the Neck, Head, and Brain ● the brachiocephalic artery branches into the: R SUBCLAVIAN and R COMMON CAROTID ● the L and R common carotid arteries diverge into the: *EXTERNAL CAROTID ARTERY and * INTERNAL CAROTID ARTERY Arteries to the Shoulder and Arm ● the subclavian artery becomes the: *AXILLARY ARTERY (wall of chest ) – which becomes the: *BRACHIAL ARTERY (upper arm ) – which branches into the: *ULNAR ARTERY (parallels the ulna ) and the *RADIAL ARTERY (parallels the radius ) **as the radial artery nears the wrist, it approaches the surface and provides a convenient vessel for taking the “pulse” (RADIAL PULSE ) Arteries to the Pelvis and Legs **RECALL: the abdominal aorta branches into the R and L common iliac arteries ● each common iliac artery divides into an: *INTERNAL ILIAC ARTERY *EXTERNAL ILIAC ARTERY (main blood supply to lower limbs ) Arteries to the Pelvis and Legs ● the external iliac artery becomes the: *FEMORAL ARTERY – which becomes the: *POPLITEAL ARTERY (knee joint ) ● the popliteal artery divides into the: *ANTERIOR and POSTERIOR TIBIAL ARTERIES VENOUS SYSTEM Characteristics of Venous Pathways: veins return blood to the heart many veins are hard to follow/identify b/c they connect in irregular pathways the larger veins typically parallel the arteries (and have the same names as their arterial counterparts) (e.g.: renal vein parallels the renal artery ; common iliac vein parallels the common iliac artery, etc.) Major Veins entering the heart: ● PULMONARY VEINS (from lungs to heart ) ● SUPERIOR VENA CAVA and INFERIOR VENA CAVA (both drain into the R atrium ) Veins from the Brain, Head, and Neck: ● JUGULAR VEINS : EXTERNAL JUGULAR (R and L): drain blood from the face, scalp, and superficial neck -drain into the R and L SUBCLAVIAN VEINS INTERNAL JUGULAR (R and L): larger than external; drain blood from the brain, deep face/neck -drain into the R and L BRACHIOCEPHALIC VEINS **all of these vessels then merge and give rise to the SUPERIOR VENA CAVA R atrium! Veins from the Arm and Shoulder: *veins here generally parallel the arteries in each region: RADIAL VEIN & ULNAR VEIN BRACHIAL VEIN AXILLARY VEIN SUBCLAVIAN VEIN BRACHIOCEPHALIC VEIN Veins from the Abdominal Cavity: ● RENAL VEINS : drain the kidneys ● HEPATIC VEINS : drain the liver ● carry blood to the INFERIOR VENA CAVA Veins from the Legs and Pelvis: *veins here generally parallel the arteries in each region: ANT. & POST. TIBIAL VEINS POPLITEAL VEIN FEMORAL VEIN EXTERNAL ILIAC VEIN (which joins with the INTERNAL ILIAC VEIN) COMMON ILIAC VEIN Also from the legs… **GREAT (GREATER) SAPHENOUS VEIN : longest vein in the body; runs upward along the medial side of the leg and thigh; penetrates deep into the thigh and joins with the femoral artery Great Saphenous Vein.
Load more

Recommended publications
  • Ipsilateral Subclavian Steal in Association with Aberrant Origin of the Left Vertebral Artery from the Aortic Arch
    411 Ipsilateral Subclavian Steal in Association with Aberrant Origin of the Left Vertebral Artery from the Aortic Arch John Holder1 Five cases are reported of left subclavian steal syndrome associated with anomalous Eugene F. Binet2 origin of the left vertebral artery from the aortic arch. In all five instances blood flow at Bernard Thompson3 the origin of the left vertebral artery was in an antegrade direction contrary to that usually reported in this condition. The distal subclavian artery was supplied via an extensive collateral network of vessels connecting the vertebral artery to the thyro­ cervical trunk. If a significant stenosis or occlusion is present within the left subc lavi an artery proximal to the origin of the left vertebral artery, the direction of the bl ood fl ow within the vertebral artery will reverse toward the parent vessel (retrograde flow). This phenomenon occurs when a negative pressure gradient of 20-40 torr exists between the vertebral-basilar artery junction and th e vertebral-subc lavian artery junction [1-3]. We describe five cases of subclavian steal confirmed by angiography where a significant stenosis or occlusion of the left subclavian artery was demonstrated in association with anomalous origin of th e left vertebral artery directly from the aortic arch. In all five cases blood flow at the origin of the left vertebral artery was in an antegrade direction contrary to that more commonly reported in the subclavian steal syndrome. Materials and Methods The five patients were all 44- 58-year-old men. Three sought medical attention for symptoms specificall y related to th e left arm .
    [Show full text]
  • Heart Vein Artery
    1 PRE-LAB EXERCISES Open the Atlas app. From the Views menu, go to System Views and scroll down to Circulatory System Views. You are responsible for the identification of all bold terms. A. Circulatory System Overview In the Circulatory System Views section, select View 1. Circulatory System. The skeletal system is included in this view. Note that blood vessels travel throughout the entire body. Heart Artery Vein 2 Brachiocephalic trunk Pulmonary circulation Pericardium 1. Where would you find the blood vessels with the largest diameter? 2. Select a few vessels in the leg and read their names. The large blue-colored vessels are _______________________________ and the large red-colored vessels are_______________________________. 3. In the system tray on the left side of the screen, deselect the skeletal system icon to remove the skeletal system structures from the view. The largest arteries and veins are all connected to the _______________________________. 4. Select the heart to highlight the pericardium. Use the Hide button in the content box to hide the pericardium from the view and observe the heart muscle and the vasculature of the heart. 3 a. What is the largest artery that supplies the heart? b. What are the two large, blue-colored veins that enter the right side of the heart? c. What is the large, red-colored artery that exits from the top of the heart? 5. Select any of the purple-colored branching vessels inside the rib cage and use the arrow in the content box to find and choose Pulmonary circulation from the hierarchy list. This will highlight the circulatory route that takes deoxygenated blood to the lungs and returns oxygenated blood back to the heart.
    [Show full text]
  • Prep for Practical II
    Images for Practical II BSC 2086L "Endocrine" A A B C A. Hypothalamus B. Pineal Gland (Body) C. Pituitary Gland "Endocrine" 1.Thyroid 2.Adrenal Gland 3.Pancreas "The Pancreas" "The Adrenal Glands" "The Ovary" "The Testes" Erythrocyte Neutrophil Eosinophil Basophil Lymphocyte Monocyte Platelet Figure 29-3 Photomicrograph of a human blood smear stained with Wright’s stain (765). Eosinophil Lymphocyte Monocyte Platelets Neutrophils Erythrocytes "Blood Typing" "Heart Coronal" 1.Right Atrium 3 4 2.Superior Vena Cava 5 2 3.Aortic Arch 6 4.Pulmonary Trunk 1 5.Left Atrium 12 9 6.Bicuspid Valve 10 7.Interventricular Septum 11 8.Apex of The Heart 9. Chordae tendineae 10.Papillary Muscle 7 11.Tricuspid Valve 12. Fossa Ovalis "Heart Coronal Section" Coronal Section of the Heart to show valves 1. Bicuspid 2. Pulmonary Semilunar 3. Tricuspid 4. Aortic Semilunar 5. Left Ventricle 6. Right Ventricle "Heart Coronal" 1.Pulmonary trunk 2.Right Atrium 3.Tricuspid Valve 4.Pulmonary Semilunar Valve 5.Myocardium 6.Interventricular Septum 7.Trabeculae Carneae 8.Papillary Muscle 9.Chordae Tendineae 10.Bicuspid Valve "Heart Anterior" 1. Brachiocephalic Artery 2. Left Common Carotid Artery 3. Ligamentum Arteriosum 4. Left Coronary Artery 5. Circumflex Artery 6. Great Cardiac Vein 7. Myocardium 8. Apex of The Heart 9. Pericardium (Visceral) 10. Right Coronary Artery 11. Auricle of Right Atrium 12. Pulmonary Trunk 13. Superior Vena Cava 14. Aortic Arch 15. Brachiocephalic vein "Heart Posterolateral" 1. Left Brachiocephalic vein 2. Right Brachiocephalic vein 3. Brachiocephalic Artery 4. Left Common Carotid Artery 5. Left Subclavian Artery 6. Aortic Arch 7.
    [Show full text]
  • Pelvic Anatomyanatomy
    PelvicPelvic AnatomyAnatomy RobertRobert E.E. Gutman,Gutman, MDMD ObjectivesObjectives UnderstandUnderstand pelvicpelvic anatomyanatomy Organs and structures of the female pelvis Vascular Supply Neurologic supply Pelvic and retroperitoneal contents and spaces Bony structures Connective tissue (fascia, ligaments) Pelvic floor and abdominal musculature DescribeDescribe functionalfunctional anatomyanatomy andand relevantrelevant pathophysiologypathophysiology Pelvic support Urinary continence Fecal continence AbdominalAbdominal WallWall RectusRectus FasciaFascia LayersLayers WhatWhat areare thethe layerslayers ofof thethe rectusrectus fasciafascia AboveAbove thethe arcuatearcuate line?line? BelowBelow thethe arcuatearcuate line?line? MedianMedial umbilicalumbilical fold Lateralligaments umbilical & folds folds BonyBony AnatomyAnatomy andand LigamentsLigaments BonyBony PelvisPelvis TheThe bonybony pelvispelvis isis comprisedcomprised ofof 22 innominateinnominate bones,bones, thethe sacrum,sacrum, andand thethe coccyx.coccyx. WhatWhat 33 piecespieces fusefuse toto makemake thethe InnominateInnominate bone?bone? PubisPubis IschiumIschium IliumIlium ClinicalClinical PelvimetryPelvimetry WhichWhich measurementsmeasurements thatthat cancan bebe mademade onon exam?exam? InletInlet DiagonalDiagonal ConjugateConjugate MidplaneMidplane InterspinousInterspinous diameterdiameter OutletOutlet TransverseTransverse diameterdiameter ((intertuberousintertuberous)) andand APAP diameterdiameter ((symphysissymphysis toto coccyx)coccyx)
    [Show full text]
  • Vascular Density and Distribution in Neocortex
    Zurich Open Repository and Archive University of Zurich Main Library Strickhofstrasse 39 CH-8057 Zurich www.zora.uzh.ch Year: 2019 Vascular density and distribution in neocortex Schmid, Franca ; Barrett, Matthew J P ; Jenny, Patrick ; Weber, Bruno Abstract: An amazingly wide range of complex behavior emerges from the cerebral cortex. Much of the information processing that leads to these behaviors is performed in neocortical circuits that span throughout the six layers of the cortex. Maintaining this circuit activity requires substantial quantities of oxygen and energy substrates, which are delivered by the complex yet well-organized and tightly-regulated vascular system. In this review, we provide a detailed characterization of the most relevant anatomical and functional features of the cortical vasculature. This includes a compilation of the available data on laminar variation of vascular density and the topological aspects of the microvascular system. We also review the spatio-temporal dynamics of cortical blood flow regulation and oxygenation, many aspects of which remain poorly understood. Finally, we discuss some of the important implications of vascular density, distribution, oxygenation and blood flow regulation for (laminar) fMRI. DOI: https://doi.org/10.1016/j.neuroimage.2017.06.046 Posted at the Zurich Open Repository and Archive, University of Zurich ZORA URL: https://doi.org/10.5167/uzh-146003 Journal Article Accepted Version The following work is licensed under a Creative Commons: Attribution-NonCommercial-NoDerivatives 4.0 International (CC BY-NC-ND 4.0) License. Originally published at: Schmid, Franca; Barrett, Matthew J P; Jenny, Patrick; Weber, Bruno (2019). Vascular density and distribution in neocortex.
    [Show full text]
  • Vessels and Circulation
    CARDIOVASCULAR SYSTEM OUTLINE 23.1 Anatomy of Blood Vessels 684 23.1a Blood Vessel Tunics 684 23.1b Arteries 685 23.1c Capillaries 688 23 23.1d Veins 689 23.2 Blood Pressure 691 23.3 Systemic Circulation 692 Vessels and 23.3a General Arterial Flow Out of the Heart 693 23.3b General Venous Return to the Heart 693 23.3c Blood Flow Through the Head and Neck 693 23.3d Blood Flow Through the Thoracic and Abdominal Walls 697 23.3e Blood Flow Through the Thoracic Organs 700 Circulation 23.3f Blood Flow Through the Gastrointestinal Tract 701 23.3g Blood Flow Through the Posterior Abdominal Organs, Pelvis, and Perineum 705 23.3h Blood Flow Through the Upper Limb 705 23.3i Blood Flow Through the Lower Limb 709 23.4 Pulmonary Circulation 712 23.5 Review of Heart, Systemic, and Pulmonary Circulation 714 23.6 Aging and the Cardiovascular System 715 23.7 Blood Vessel Development 716 23.7a Artery Development 716 23.7b Vein Development 717 23.7c Comparison of Fetal and Postnatal Circulation 718 MODULE 9: CARDIOVASCULAR SYSTEM mck78097_ch23_683-723.indd 683 2/14/11 4:31 PM 684 Chapter Twenty-Three Vessels and Circulation lood vessels are analogous to highways—they are an efficient larger as they merge and come closer to the heart. The site where B mode of transport for oxygen, carbon dioxide, nutrients, hor- two or more arteries (or two or more veins) converge to supply the mones, and waste products to and from body tissues. The heart is same body region is called an anastomosis (ă-nas ′tō -mō′ sis; pl., the mechanical pump that propels the blood through the vessels.
    [Show full text]
  • Cardiovascular System Summary Notes the Cardiovascular System
    Cardiovascular System Summary Notes The cardiovascular system includes: The heart, a muscular pump The blood, a fluid connective tissue The blood vessels, arteries, veins and capillaries Blood flows away from the heart in arteries, to the capillaries and back to the heart in the veins There is a decrease in blood pressure as the blood travels away from the heart Arterial branches of the aorta supply oxygenated blood to all parts of the body Deoxygenated blood leaves the organs in veins Veins unite to form the vena cava which returns the blood to the heart Pulmonary System This is the route by which blood is circulated from the heart to the lungs and back to the heart again The pulmonary system is exceptional in that the pulmonary artery carries deoxygenated blood and the pulmonary vein carries oxygenated blood Hepatic Portal Vein There is another exception in the circulatory system – the hepatic portal vein Veins normally carry blood from an organ back to the heart The hepatic portal vein carries blood from the capillary bed of the intestine to the capillary bed of the liver As a result, the liver has three blood vessels associated with it Arteries and Veins The central cavity of a blood vessel is called the lumen The lumen is lined with a thin layer of cells called the endothelium The composition of the vessel wall surrounding the endothelium is different in arteries, veins and capillaries Arteries carry blood away from the heart Arteries have a thick middle layer of smooth muscle They have an inner and outer layer of elastic fibres Elastic
    [Show full text]
  • The Variations of the Subclavian Artery and Its Branches Ahmet H
    Okajimas Folia Anat. Jpn., 76(5): 255-262, December, 1999 The Variations of the Subclavian Artery and Its Branches By Ahmet H. YUCEL, Emine KIZILKANAT and CengizO. OZDEMIR Department of Anatomy, Faculty of Medicine, Cukurova University, 01330 Balcali, Adana Turkey -Received for Publication, June 19,1999- Key Words: Subclavian artery, Vertebral artery, Arterial variation Summary: This study reports important variations in branches of the subclavian artery in a singular cadaver. The origin of the left vertebral artery was from the aortic arch. On the right side, no thyrocervical trunk was found. The two branches which normally originate from the thyrocervical trunk had a different origin. The transverse cervical artery arose directly from the subclavian artery and suprascapular artery originated from the internal thoracic artery. This variation provides a short route for posterior scapular anastomoses. An awareness of this rare variation is important because this area is used for diagnostic and surgical procedures. The subclavian artery, the main artery of the The variations of the subclavian artery and its upper extremity, also gives off the branches which branches have a great importance both in blood supply the neck region. The right subclavian arises vessels surgery and in angiographic investigations. from the brachiocephalic trunk, the left from the aortic arch. Because of this, the first part of the right and left subclavian arteries differs both in the Subjects origin and length. The branches of the subclavian artery are vertebral artery, internal thoracic artery, This work is based on a dissection carried out in thyrocervical trunk, costocervical trunk and dorsal the Department of Anatomy in the Faculty of scapular artery.
    [Show full text]
  • Cat Dissection
    Cat Dissection Muscular Labs Tibialis anterior External oblique Pectroalis minor Sartorius Gastrocnemius Pectoralis major Levator scapula External oblique Trapezius Gastrocnemius Semitendinosis Trapezius Latissimus dorsi Sartorius Gluteal muscles Biceps femoris Deltoid Trapezius Deltoid Lumbodorsal fascia Sternohyoid Sternomastoid Pectoralis minor Pectoralis major Rectus abdominis Transverse abdominis External oblique External oblique (reflected) Internal oblique Lumbodorsal Deltoid fascia Latissimus dorsi Trapezius Trapezius Trapezius Deltoid Levator scapula Deltoid Trapezius Trapezius Trapezius Latissimus dorsi Flexor carpi radialis Brachioradialis Extensor carpi radialis Flexor carpi ulnaris Biceps brachii Triceps brachii Biceps brachii Flexor carpi radialis Flexor carpi ulnaris Extensor carpi ulnaris Triceps brachii Extensor carpi radialis longus Triceps brachii Deltoid Deltoid Deltoid Trapezius Sartorius Adductor longus Adductor femoris Semimembranosus Vastus Tensor fasciae latae medialis Rectus femoris Vastus lateralis Tibialis anterior Gastrocnemius Flexor digitorum longus Biceps femoris Tensor fasciae latae Semimembranosus Semitendinosus Gluteus medius Gluteus maximus Extensor digitorum longus Gastrocnemius Soleus Fibularis muscles Brachioradiallis Triceps (lateral and long heads) Brachioradialis Biceps brachii Triceps (medial head) Trapezius Deltoid Deltoid Levator scapula Trapezius Deltoid Trapezius Latissimus dorsi External oblique (right side cut and reflected) Rectus abdominis Transversus abdominis Internal oblique Pectoralis
    [Show full text]
  • The Vertebral Artery in the Vascular Lab: What Does It Mean?
    The Vertebral Artery in the Vascular Lab: What Does It Mean? Caron Rockman MD Frances and Joseph Ritroto Professor of Surgery Program Director, Vascular Surgery New York University Langone Medical Center Disclosures •None Division of Vascular and Endovascular Surgery Subclavian Steal Occlusion of proximal Subclavian Art Vertebral artery supplies retrograde flow Posterior brain receives decreased flow 55 years + Men > Women more than 2:1 LSA affected 3x more than RSA Division of Vascular and Endovascular Surgery Subclavian Steal Causes: - Arteriosclerosis of subclavian artery (>95% cases) - Embolism - Takayasu’s Arteritis -Dissecting Aneurysm Risk Factors: (similar to CAD) -Smoking -Hypertension -Hyperlipidemia -Hypertension Division of Vascular and Endovascular Surgery Symptoms of Subclavian Steal Vertebrobasilar Insufficiency (posterior circulation symptoms) Light headedness or dizziness Ataxia or Vertigo Visual Disturbance Headache Syncope Confusion Division of Vascular and Endovascular Surgery Symptoms of Subclavian Steal Subclavian Insufficiency Arm weakness, coldness Numbness or “tingling” Arm Claudication with exercise Symptoms can be exacerbated with: Vigorous exercise Sudden turning of head to affected side Division of Vascular and Endovascular Surgery Signs of Subclavian Steal Diminished pulses (radial/ulnar) Discrepant blood pressures in upper extremities (>20mmHg) (Pitfall with bilateral disease) Subclavian Bruit 7 Division of Vascular and Endovascular Surgery Subclavian steal on Duplex Exam Incomplete steal •Striking deceleration of velocity in mid or late systole •High grade stenosis of subclavian rather than occlusion Complete Steal •Complete reversal of flow within the vertebral artery Division of Vascular and Endovascular Surgery Vertebral Retrograde Flow • Reversal of flow in the vertebral artery is a common finding identified on cerebrovascular duplex ultrasound. • The clinical significance and natural history of patients presenting with this finding, however, is poorly understood.
    [Show full text]
  • Surgical Anatomy of the Common Iliac Veins During Para-Aortic and Pelvic Lymphadenectomy for Gynecologic Cancer
    Original Article J Gynecol Oncol Vol. 25, No. 1:64-69 http://dx.doi.org/10.3802/jgo.2014.25.1.64 pISSN 2005-0380·eISSN 2005-0399 Surgical anatomy of the common iliac veins during para-aortic and pelvic lymphadenectomy for gynecologic cancer Kazuyoshi Kato, Shinichi Tate, Kyoko Nishikimi, Makio Shozu Department of Gynecology, Chiba University School of Medicine, Chiba, Japan See accompanying editorial by Lee on page 1. Objective: Compression of the left common iliac vein between the right common iliac artery and the vertebrae is known to be associated with the occurrence of left iliofemoral deep vein thrombosis (DVT). In this study, we described the variability in vascular anatomy of the common iliac veins and evaluated the relationship between the degree of iliac vein compression and the presence of DVT using the data from surgeries for gynecologic cancer. Methods: The anatomical variations and the degrees of iliac vein compression were determined in 119 patients who underwent systematic para-aortic and pelvic lymphadenectomy during surgery for primary gynecologic cancer. Their medical records were reviewed with respect to patient-, disease-, and surgery-related data. Results: The degrees of common iliac vein compression were classified into three grades: grade A (n=28, 23.5%), with a calculated percentage of 0%-25% compression; grade B (n=47, 39.5%), with a calculated percentage of 26%-50% compression; and grade C (n=44, 37%), with a calculated percentage of more than 50% compression. Seven patients (5.9%) had common iliac veins with anomalous anatomies; three were divided into small caliber vessels, two with a flattened structure, and two had double inferior vena cavae.
    [Show full text]
  • Co-Existence of the Double Inferior Vena Cava with Complex Interiliac
    Folia Morphol. Vol. 77, No. 1, pp. 151–155 DOI: 10.5603/FM.a2017.0074 C A S E R E P O R T Copyright © 2018 Via Medica ISSN 0015–5659 www.fm.viamedica.pl Co-existence of the double inferior vena cava with complex interiliac venous communication and aberrant common hepatic artery arising from superior mesenteric artery: a case report V. Chentanez, N. Nateniyom, T. Huanmanop, S. Agthong Department of Anatomy, Faculty of Medicine, King Chulalongkorn Memorial Hospital, Chulalongkorn University, Bangkok, Thailand [Received: 19 June 2017; Accepted: 31 July 2017] Variations of the arterial and venous system of the abdomen and pelvis have im- portant clinical significance in hepatobiliary surgery, abdominal laparoscopy, and radiological intervention. A case of double inferior vena cava (IVC) with complex interiliac communication and variation of the common hepatic artery (CHA) arising from superior mesenteric artery (SMA) in a 79-year-old male cadaver is presented. Both IVCs ascended on either side of the abdominal aorta. The left-sided IVC crossed anterior to the aorta at the level of the left renal vein. The union of both IVCs was at the level just above the right renal vein. The diameter of right-sided IVC, left-sided IVC and the common IVC were 16.73 mm, 21.57 mm and 28.75 mm, respectively. In the pelvic cavity, the right common iliac vein was formed by a union of right external and internal iliac veins while the formation of left common iliac vein was from the external iliac vein and two internal iliac veins. An interiliac vein ran from right internal iliac vein to left common iliac vein with an additional communicating vein running from the middle of this interiliac vein to the right common iliac vein.
    [Show full text]