DOCSLIB.ORG

The Human Body: Anatomical Regions, Directions, and Body

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
The Human Body: Anatomical Regions, Directions, and Body THE HUMAN BODY : ANATOMICAL REGIONS , DIRECTIONS , AND BODY CAVITIES TEMPILE COLLEGE - - - TEM PLE HUTTO TAYLOR Overview of Anatomy and Physiology •• AnatomyAnatomy – the study of the structure of body parts and their relationships to one another – Gross or macroscopic – Microscopic – Developmental •• PhysiologyPhysiology – the study of the function of the body’s structural machinery GROSS ANATOMY •• RegionalRegional – all structures in one part of the body (such as the abdomen or leg) •• SystemicSystemic – gross anatomy of the body studied by system MICROSCOPIC ANATOMY •• CytologyCytology – study of the cell •• HistologyHistology – study of tissues PHYSIOLOGY •• ConsidersConsiders thethe operationoperation ofof specificspecific organorgan systemssystems – Renal – kidney function – Neurophysiology – workings of the nervous system – Cardiovascular – operation of the heart and blood vessels •• FocusesFocuses onon thethe functions ofof thethe body,body, oftenoften atat thethe cellularcellular oror molecularmolecular levellevel PHYSIOLOGY • Understanding physiology also requires a knowledge of physics, which explains electrical currents, blood pressure, and the way muscle uses bone for movement PRINCIPLE OF COMPLEMENTARITY • Function always reflects structure • What a structure can do depends on its specific structure!! LEVELS OF STRUCTURAL ORGANIZATION I Smooth muscle cell Molecules 2 Cellular level Cells are made up of molecules Atoms 01 Chemical level Atoms combine to Smooth form molecules muscle tissue Hear 3 Tissue level Cardiovascular t Tissues consist of system similar types of cells Blood vessels Epithelial tissue Smooth Blood muscle vessel tissue (organ) 6 Organismal level Connective The human organism is tissue made up of many organ systems 04 Organ level Organs are made up of 5 Organ system level different types of tissues Organ systems consist of different organs that work together closely Figure 1.1 LEVELS OF STRUCTURAL ORGANIZATION •• ChemicalChemical – atoms combined to form molecules •• CellularCellular – cells are made of molecules •• TissueTissue – consists of similar types of cells •• OrganOrgan – made up of different types of tissues •• OrganOrgan systemsystem – consists of different organs that work closely together •• OrganismalOrganismal – made up of the organ systems ANATOMICAL POSITION • Body erect • Feet slightly apart • Palms facing forward • Thumbs point away from body Figure 1.7a DIRECTIONAL TERMS •• SuperiorSuperior andand inferiorinferior – toward and away from the head, respectively •• Anterior andand posteriorposterior – toward the front and back of the body •• Medial,Medial, lateral,lateral, andand intermediateintermediate – toward the midline, away from the midline, and between a more medial and lateral structure DIRECTIONAL TERMS •• ProximalProximal andand distaldistal – closer to and farther from the origin of the body •• SuperficialSuperficial andand deepdeep – toward and away from the body surface Table 1.1 DIRECTIONAL TERMS ABLE 1.11 Orientati0'~1and Directional Terms Term Definition Example Superior ,(cranial) Toward lie head e11d or The head is s perior to the abdom e up per pa rt of a s ructrne or the body: above I ferior (caudal} Away from the ead end or The ave I is inferior to the chi toward · e lower part of a structure or t e body; be­ ow An erior ,(ventral)* Toward or a rie front of The breastbone is ant ,eri or o trie spine the body; in frorit of Posterior (dorsa )* Tow.ardor at the back of The heart is. posterior to t e breastbon-e e body; be ind Me dial Toward or a1!: the midline The heart is media I to the arm of the body; on t e inner side of "W'here~!J. the term!;; ve.n fi;lf en.cl ..i.nterior ..ire SlJTionym,ous . in h1.1 m.m!;;, tl,i !;; is not the case rn fo r-l egg,e,,;;l .mim~ls. li<;'lltra,r s,pe~iii' .;..illy refer!;; to e "lbe lfy .. of a vertebrate .ammal aJ11d thus is the ' ferior :s,.mface o ' four-legged animals. L' ewise, althoug ttie dorsal and p □ slte rmr surfo1.ces .a re ~e same, in umans. the term dorsal spe,cifically fe.rs to a a n,ima 's back.. IJIS, tna dorsail surfa ~e of · ou -leg oo nimals cs the -r superror su fac:,e, . DIRECTIONAL TERMS Table 1.1 I BLE 1.1 Orientation and o,irectionalll 'Terms Term Defin "ti,on Example L,neral Away rom 'the - idl"ne e ar s a,re late rail to the -est o f he· body; on I e ou-er s ide o ' lmerme di ate Betv~ee a · ore medial The collarbone is i rnrm edia1 e between and a mo re latera I the b-eastbone and s.hou Ider s iructiu r-e Proxi al Cl-oser w the origin o' · the The e Ib-ow is proxim a I to the wris body part o r t he po i1n , of attachmem o-f ai lim b w the body t ru k D ist.al F 61 1 her fro m the origin of a The knee is dis ail to -he h igh body at o r the point of a tt~chm en of ai lim b -o the body trnill k Supe ci~I (ex er­ Toward or a - the body The .sik: in. is supe id~ I , o he ske 1-e ail a I} surface muscles D,e@'p (i ntema I) Away from th@ body surface: ore i nte mail BODY PLANES •• SagittalSagittal – divides the body into right and left parts •• MidsagittalMidsagittal oror medialmedial – sagittal plane that lies on the midline •• FrontalFrontal oror coronalcoronal – divides the body into anterior and posterior parts •• TransverseTransverse oror horizontalhorizontal (cross section) – divides the body into superior and inferior parts •• ObliqueOblique sectionsection – cuts made diagonally BODY PLANES Figure 1.8 Fron •. I [pl ne . taJ, Fronlal section ·1hrough (b) Tran _ · · sedion lhfouah t'. c) IM dian torso torso !s11pe1ior ym w) (mi'dsagittal) section ANATOMICAL VARIABILITY •• HumansHumans varyvary slightlyslightly inin bothboth externalexternal andand internalinternal anatomyanatomy • Over 90% of all anatomical structures match textbook descriptions, but: – Nerves or blood vessels may be somewhat out of place – Small muscles may be missing • ExtremeExtreme anatomicalanatomical variationsvariations areare seldomseldom seenseen BODY CAVITIES 1ranial caviily -----;:., (c,onta1ins brain) Dorsal body ,cavity -.---1ho1r,ack cavity (contains heart: and lungs) -----Diaphragm Vertebral! cavlity ---------= (contains .spi1naf ,c,o'rd) Ab ctomlnall cavlity (oonta1ins digestive viiscer.a) Key Dorsal body ,cavity ~ :;.----Pe'lvi·c caviily (contains bl!add'e:r, rep'r,oducUve ■ Ventral body cavity org:arns, and 1rectum) Figure 1.9a fa)- Lat.eral v· ew BODY CAVITIES •• DorsalDorsal cavitycavity protects the nervous system, and is divided into two subdivisions – Cranial cavity is within the skull and encases the brain – Vertebral cavity runs within the vertebral column and encases the spinal cord •• Ventral cavitycavity houses the internal organs (viscera), and is divided into two subdivisions: - Thoracic and Abdominopelvic cavities BODY CAVITIES Figure 1.9b l! cavity ----------~ Pericardia! cavity wl1hln ------:-====~~ ~ =­ Uie medlastl mum Ven·tral body cavity (ttloraci c ,aind Abdom·nall caviity --------:-­ abdomii1nopelvic (contai ms d1ige.stive v1iscera)1 Abdomiinopelviic cavi'IIJies) C8iVity Pelvic cavity--------~=-~ (contains b!ladlder, teptodu:cUve organs, Key; andl tectiuli!n) ■ IDorsal body caviity ■ Ventral body caviity BODY CAVITIES •• ThoracicThoracic cavitycavity is subdivided into pleural cavities, the mediastinum, and the pericardial cavity – Pleural cavities – each houses a lung – Mediastinum – contains the pericardial cavity, and surrounds the remaining thoracic organs – Pericardial cavity – encloses the heart BODY CAVITIES •• TheThe abdominopelvicabdominopelvic cavitycavity isis separatedseparated from thethe superiorsuperior thoracicthoracic cavitycavity byby thethe domedome-shaped-shaped diaphragmdiaphragm • It is composed of two subdivisions – Abdominal cavity – contains the stomach, intestines, spleen, liver, and other organs – Pelvic cavity – lies within the pelvis and contains the bladder, reproductive organs, and rectum OTHER BODY CAVITIES •• OralOral andand digestivedigestive – mouth and cavities of the digestive organs •• NasalNasal –located within and posterior to the nose •• OrbitalOrbital – house the eyes •• MiddleMiddle earear – contain bones (ossicles) that transmit sound vibrations •• SynovialSynovial – joint cavities ABDOMINOPELVIC REGIONS • Umbilical • Epigastric • Hypogastric • Right and left iliac or inguinal ,, Riglht Left hypocli'tondrd ao Ep,igastric lh)'lpoe '.hondlriac • Right and left lumbar regi·on 1~ ion regio1n • Right and left Left hypochondriac Rig t Umbi1llical lumbar 1reg1io11 lt1mbar regi'o1n reg•loni Fl i'ghrt ii iac Hrypogastric llefl: l1lllac (ringuiina ) (pubic) (lrngu lrnal), region region reg om Figure 1.11a ORGANS OF THE ABDOMINOPELVIC REGIONS .~--Transverse colon ......,,,.,_.....,,,. of llarge iintestine rirng colon of large iintesti ne ~ -i!----- IDesoerndlirng1col1c::m of llarge irrntestine ....J;,-- I1niitiall part of sig mo 1d colon Figure 1.11b ABDOMINOPELVIC QUADRANTS • Right upper (RUQ) • Left upper (LUQ) • Right lower (RLQ) • Left lower (LLQ) Right up,per--tTs =;ii .........~~~~ - Left up,per quadrant q1uad1rant Right lower ----11-,__..,_ liti't-. ,,.......,---1--....+-""'+- Left lower quadrant q1uadrant Figure 1.12 QUESTIONS? Figure 1.12 .
Load more

Recommended publications
  • Blank Body Cavity Diagram
    Blank Body Cavity Diagram Laurie pretermit her lat scot-free, she patronise it wrongly. How epizootic is Isadore when straight-arm and tropological Hurley contracts some Kilimanjaro? Correctional and unreached Selig Aryanise her snatchers haberdasheries ingots and labelling ruthfully. It occurs more often in people with light coloured skin who have had a high exposure to sunlight. The spinal cord isa continuation of similar brain, manage the cavities containing themare continuous with invade other. In the eye, bipolar neurons form the middle layer of the retina. From four key choices, select another body. In the marriage, This is a_____view? There was an error loading the necessary resources. Thedeltoid tuberosityis a roughened, Vshaped region located on the lateral side in the middle of the humerus shaft. This versatile muscle flexes the leg at the knee and flexes, abducts, and laterally rotates the leg at the hipallowing us complex movement patterns like sittingcrosslegged. Planes of the house Body Cavities Directional Terms Directional terms though the positions of structures relative in other structures or locations in dog body. Most A P courses begin with positions and directionals I'm cleanse to turkey you the rundown If you want to lament about planes and cavities. Both cavities body cavity contains organs and arm. Ligaments to cavities but not properly cared for. From sliding anteriorly. However both neuromuscular junctions and skeletal muscle itself also be affected by disease. The body cavity! The epicondyles provide attachment points for muscles and supporting ligaments of the knee. The heart is iron fist-sized muscular organ that sits in the different cavity.
    [Show full text]
  • 1.6 Organization Within the Human Body ___/202 Points
    Name _______________________________________________________________ Date ______________ Lab _____ Pd _____ Unit 1 Chapter Levels of Organization within the Human Body ____/202 points organization 1.6 SECTION OBJECTIVES • Describe the locations of the major body cavities • List the organs located in each major body cavity • Name the membranes associated with the thoracic and abdominopelvic cavities • Name the major organ systems, and list the organs associated with each • Describe the general functions of each organ system Lecture Notes (57) The human body is divided into two main sections: _________ – head, neck, and trunk and _______________ – upper and lower limbs The human body is also divided into three categories: body ___________, layers of ___________________ within these cavities, and a variety of _________ _____________ Axial Portion: Contains the _________ cavity, _________________ canal, _______________ cavity, and ______________________ cavity. The thoracic and abdominopelvic cavities separated by the _______________. The organs within the cavity are called _______. ______________ cavity: _________________: stomach, intestines, liver, spleen, and kidneys. ______________: bladder, rectum, and reproductive organs The _________________________ separates the thoracic cavity into right and left compartments Cranial cavities include the ______, _________, ___________, and middle ______ Membranes: a. _________________ –membranes attached to the wall or lines the cavity (pariet = wall) b. _______________ - membrane that covers organ
    [Show full text]
  • The Digestive System
    69 chapter four THE DIGESTIVE SYSTEM THE DIGESTIVE SYSTEM The digestive system is structurally divided into two main parts: a long, winding tube that carries food through its length, and a series of supportive organs outside of the tube. The long tube is called the gastrointestinal (GI) tract. The GI tract extends from the mouth to the anus, and consists of the mouth, or oral cavity, the pharynx, the esophagus, the stomach, the small intestine, and the large intes- tine. It is here that the functions of mechanical digestion, chemical digestion, absorption of nutrients and water, and release of solid waste material take place. The supportive organs that lie outside the GI tract are known as accessory organs, and include the teeth, salivary glands, liver, gallbladder, and pancreas. Because most organs of the digestive system lie within body cavities, you will perform a dissection procedure that exposes the cavities before you begin identifying individual organs. You will also observe the cavities and their associated membranes before proceeding with your study of the digestive system. EXPOSING THE BODY CAVITIES should feel like the wall of a stretched balloon. With your skinned cat on its dorsal side, examine the cutting lines shown in Figure 4.1 and plan 2. Extend the cut laterally in both direc- out your dissection. Note that the numbers tions, roughly 4 inches, still working with indicate the sequence of the cutting procedure. your scissors. Cut in a curved pattern as Palpate the long, bony sternum and the softer, shown in Figure 4.1, which follows the cartilaginous xiphoid process to find the ventral contour of the diaphragm.
    [Show full text]
  • Human Anatomy and Physiology
    LECTURE NOTES For Nursing Students Human Anatomy and Physiology Nega Assefa Alemaya University Yosief Tsige Jimma University In collaboration with the Ethiopia Public Health Training Initiative, The Carter Center, the Ethiopia Ministry of Health, and the Ethiopia Ministry of Education 2003 Funded under USAID Cooperative Agreement No. 663-A-00-00-0358-00. Produced in collaboration with the Ethiopia Public Health Training Initiative, The Carter Center, the Ethiopia Ministry of Health, and the Ethiopia Ministry of Education. Important Guidelines for Printing and Photocopying Limited permission is granted free of charge to print or photocopy all pages of this publication for educational, not-for-profit use by health care workers, students or faculty. All copies must retain all author credits and copyright notices included in the original document. Under no circumstances is it permissible to sell or distribute on a commercial basis, or to claim authorship of, copies of material reproduced from this publication. ©2003 by Nega Assefa and Yosief Tsige All rights reserved. Except as expressly provided above, no part of this publication may be reproduced or transmitted in any form or by any means, electronic or mechanical, including photocopying, recording, or by any information storage and retrieval system, without written permission of the author or authors. This material is intended for educational use only by practicing health care workers or students and faculty in a health care field. Human Anatomy and Physiology Preface There is a shortage in Ethiopia of teaching / learning material in the area of anatomy and physicalogy for nurses. The Carter Center EPHTI appreciating the problem and promoted the development of this lecture note that could help both the teachers and students.
    [Show full text]
  • Circulatory System
    11/7/2014 Circulatory System 1 11/7/2014 Diffusion is insufficient for transporting substances over long distances It takes 1 second for glucose to diffuse from 100 micro meters It will take 3 hours to diffuse 1 mm! Circulatory systems solves this problem by ensuring that no substances has to diffuse very far toenter or leave the cell! And it connects the cells to the organs that exchange molecules. Transport in small invertebrates Sponges Cnidarians Flatworms 2 11/7/2014 Transport in invertebrates Roundworms Fluid contained within the body cavity of pseudocoelome functions to transport nutrients and wastes but these animals do not have a heart or blood vessels. Open Circulatory System blood is pumped from the heart through blood vessels but then it leaves the blood vessels and enters body cavities, where the organs are bathed in blood. Mollusks and arthropods: (except cephalopods) have an open circulatory system. 3 11/7/2014 Open Circulatory System Arthopods The coelom carries blood (hemolymph). It is called a hemocoel The blood of insects is colorless because it lacks respiratory pigments; it functions to carry nutrients, not gases. Crustaceans and some arachnids have hemocyanin a protein with copper, not within a cell Animals with open circulatory systems generally have limited activity due to limitations in the oxygen delivery capability Insects are able to be active because gas exchange is via a tracheal system. Closed Circulatory System Blood is contained within blood vessels. Valves prevent the backflow of blood within the blood vessels. This type of circulatory system is found in vertebrates and several invertebrates including annelids, squids and octopuses 4 11/7/2014 Closed Circulatory System Earthworms have a dorsal and ventral blood vessel that runs the length of the animal.
    [Show full text]
  • Medical Term Lay Term(S)
    MEDICAL TERM LAY TERM(S) ABDOMINAL Pertaining to body cavity below diaphragm which contains stomach, intestines, liver, and other organs ABSORB Take up fluids, take in ACIDOSIS Condition when blood contains more acid than normal ACUITY Clearness, keenness, esp. of vision - airways ACUTE New, recent, sudden ADENOPATHY Swollen lymph nodes (glands) ADJUVANT Helpful, assisting, aiding ADJUVANT Added treatment TREATMENT ANTIBIOTIC Drug that kills bacteria and other germs ANTIMICROBIAL Drug that kills bacteria and other germs ANTIRETROVIRAL Drug that inhibits certain viruses ADVERSE EFFECT Negative side effect ALLERGIC REACTION Rash, trouble breathing AMBULATE Walk, able to walk -ATION -ORY ANAPHYLAXIS Serious, potentially life threatening allergic reaction ANEMIA Decreased red blood cells; low red blood cell count ANESTHETIC A drug or agent used to decrease the feeling of pain or eliminate the feeling of pain by general putting you to sleep ANESTHETIC A drug or agent used to decrease the feeling of pain or by numbing an area of your body, local without putting you to sleep ANGINA Pain resulting from insufficient blood to the heart (ANGINA PECTORIS) ANOREXIA Condition in which person will not eat; lack of appetite ANTECUBITAL Area inside the elbow ANTIBODY Protein made in the body in response to foreign substance; attacks foreign substance and protects against infection ANTICONVULSANT Drug used to prevent seizures ANTILIPIDEMIC A drug that decreases the level of fat(s) in the blood ANTITUSSIVE A drug used to relieve coughing ARRHYTHMIA Any change from the normal heartbeat (abnormal heartbeat) ASPIRATION Fluid entering lungs ASSAY Lab test ASSESS To learn about ASTHMA A lung disease associated with tightening of the air passages ASYMPTOMATIC Without symptoms AXILLA Armpit BENIGN Not malignant, usually without serious consequences, but with some exceptions e.g.
    [Show full text]
  • Organogenesis Part 2 ______
    Organogenesis Part 2 ___________________________________ ___________________________________ V. Lateral Plate Mesoderm VI. Endoderm ___________________________________ VII. Development of the Tetrapod Limb VIII. Sex Determination ___________________________________ ___________________________________ ___________________________________ ___________________________________ V. Lateral Plate Mesoderm ___________________________________ ___________________________________ paraxial mesoderm chordamesoderm intermediate mesoderm ___________________________________ ___________________________________ ___________________________________ lateral plate mesoderm ___________________________________ ___________________________________ Lateral Plate Mesoderm ___________________________________ Terminology: - Somatopleure: somatic mesoderm plus ectoderm ___________________________________ - Splanchnopleure: splanchnic mesoderm plus endoderm - Coelom: body cavity forms between them ___________________________________ ___________________________________ ___________________________________ ___________________________________ ___________________________________ Lateral Plate Mesoderm ___________________________________ • The Coelom: ___________________________________ – eventually left and right cavities fuse into one ___________________________________ – runs from neck to anus in vertebrates – portioned off by folds of somatic mesoderm ___________________________________ • pleural cavity: surrounds the thorax and lungs • pericardial cavity: surrounds the
    [Show full text]
  • A Model of the Peritoneal Cavity for Use in Internal Dosimetry
    A Model of the Peritoneal Cavity for Use in Internal Dosimetry E. E. Watson, M. 0. Stabin, J. L. Davis@, and K. F. Eckerman Oak Ridge Associated Universities, and Oak Ridge National Laboratory, Oak Ridge, Tennessee Several therapeutic and diagnostic techniques involveinjectionof radioactive material into the pentoneal cavity. Estimation of the radiation dose to the surface of the pertioneum or to surrounding organs is hampered by the lack of a suitable source region in the phantom commonly used for such calculations. We have modified the Fisher-Snyder phantom to include a region representing the peritoneal cavity which may be employed to estimate such radiation doses. A geometric model is described which is coordinated with the existing organ regions in the phantom. Specific absorbed fractions (derived by Monte Carlo techniques) for photon emissions originatingwithinthe cavity are listed. Photon S-values for several radionuclides which have been administered intraperitoneally are shown. Dose conversion factors for electrons irradiating the pentoneal cavity wall, from either a thin plane or volume source of activity within the cavity, are also given for several nuclides. J Nucl Med30:2002—2011,1989 or many years, one method used for controlling the dose must be based on existing source regions which recurrent effusions that result from malignant disease will not model the activity distribution very accurately has been the intraperitoneal injection of radioactive (e.g., small intestine). materials (1—3). More recently, technetium-99m- We have developed a mathematic model of the per (99mTc) labeled materials such as microspheres have itoneal cavity that permits standard Monte Carlo tech been injected intraperitoneally to evaluate the patency niques to be used to derive specific absorbed fractions of LeVeen peritoneovenous shunts (PVS) and to deter for photons to the major target organs of a modified mine the distribution of radioactive materials used for version of the Fisher-Snyder phantom (13), which in therapy (4—10).
    [Show full text]
  • Day 6 Urogenital System
    Day 6 Urogenital System: Urinary System The structures of the reproductive and urinary systems are often considered together as the urogenital systems, since they have common embryological origins. However, the emphasis in this dissection is on identifying the structures of the urinary tract with only a few references to contiguous reproductive structures. The anatomy of the reproductive system is studied in the next section. Identifying Organs of the Urinary System 1. Obtain your dissection specimen and place it on your dissection tray. Reflect the abdominal viscera (most importantly the small intestine) to locate the kidneys high on the dorsal body wall. Note that the kidneys in the cat, as well as in the human are retroperitoneal (behind the peritoneum). 2. Carefully remove the peritoneum, and clear away the bed of fat that invests the kidneys. Then locate the adrenal (suprarenal) glands that lie superiorly and medial to the kidneys. 3. Identify the renal artery (red latex injected), the renal vein (blue latex injected), and the ureter at the hilus region of the kidney. (You may find two renal veins leaving one kidney in the cat but not in humans). 4. Trace the ureters to the urinary bladder, a smooth muscular sac located superiorly to the small intestine. If your cat is a female, be careful not to confuse the ureters with the urine tubes, which lie superior to the bladder in the same general region. See Figure D8.1. Observe the sites where the ureters enter the bladder. How would you describe the entrance point anatomically? 5. Cut through the bladder wall, and examine the region of the uretheral exit to see if you can discern any evidence of the internal sphincter.
    [Show full text]
  • Body Cavities, Mesenteries & Diaphragm
    Body Cavities, Mesenteries & Diaphragm Speaker:陳玉怜 Peritoneal cavity Pleural cavity Pericardial cavity 3 week paraxial ectoderm mesoderm *extraembryonic * coelom *chorionic cavity lateral mesoderm (yolk sac) 18 day embryo lateral mesoderm * intraembryonic coelom: cardiogenic area & lateral mesoderm * * intraembryonic 20 day coelom *Intraembryonic coelom horseshoe-shaped cavity -Curve future pericardial cavity -Limbs future pleural & peritoneal cavities * intraembryonic coelom * Distal part of each limb -- at the lateral edges of the embryonic disc -- extraembryonic coelom * early in the 4th week Folding of the embryo Tail fold Head fold pericardial coelom Lateral fold Lateral fold * 22 d Intraembyonic coelom & Embryonic Foldings ~26 days * * dorsal mesentery ventral mesentery except where it is attached to caudal foregut (future stomach & proximal duodenum) ~28 days 19 D 20 D End of 4 week Embryonic body cavity • Somatic mesoderm parietal wall future parietal layer of peritoneum • Splanchnic mesoderm visceral wall future visceral layer of peritoneum Pericardioperitoneal Canal Pericardioperitoneal Canals ~24 days -- Each lies lateral to foregut (future esophagus) and dorsal to septum transversum (primordial central tendon of diaphragm). • In lateral wall of each pericardioperitoneal canal: -*cranial ridge: pleuropericardial fold pleuropericardial membrane (contain common cardinal veins) - caudal ridge: pleuroperitoneal fold pleuroperitoneal membrane (diaphragm) 5 wks 6 wks • During the 7th week, pleuropericardial membranes fuse with
    [Show full text]
  • B6A-7 Circulate.Pdf
    Circulatory Systems Circulatory Systems Circulatory Systems Circulatory Systems Functions: • Transportation – Water & electrolytes (salts) – Dissolved gases— O2 & CO2 – Nutrients Cardiovascular – Wastes System – Chemical messengers (hormones) – Defense (immune) systems – Repair (clotting) factors • Thermoregulation Lymphatic • Hydraulics System Circulatory Systems Size & System Development • Ciliated Body Cavity • Diffusion is sufficient for small Open Circulatory System • organisms w/ low volumes & • Closed Circulatory System metabolic demands (e.g. protozoans and micrometazoans). Hemocoel Cnidarians & Platyhelmintheans Ciliated Body Cavity • gastrovascular system – ciliated digestive cavity w/ branching extensions. Heyer Circulatory Systems Echinoderms • water vascular system Vascular System Components – ciliated coelom w/ extensions (dermal branchae & tube feet) • Four components are for respiration. –1) circulatory fluids – Important –2) vessels hydraulic functions –3) pump –4) valves • Vasculature (vessels) may form open or closed circulatory system Open Circulatory Systems Open Circulatory Systems • In arthropods & most molluscs. • 4-part system - what are those parts? • Dorsal heart pumps • circulatory fluids mix w/ interstial fluids of hemolymph out body cavity. vessels into body cavity (= hemocoel) • Hence, “blood” is called hemolymph. • Hemocoel partially compartmentalized into sinuses • Hemolymph returns to heart via ostia or veins. Open Circulatory Systems Dorsal Vessel as Pump Limitations of Open Systems • Whole dorsal vessel
    [Show full text]
  • Cell Biology of Ureter Development
    BRIEF REVIEW www.jasn.org Cell Biology of Ureter Development † Adrian S. Woolf* and Jamie A. Davies *School of Biomedicine, University of Manchester, Manchester Academic Health Science Centre and Manchester Children’s Hospital, Manchester, United Kingdom; and †Centre for Integrative Physiology, Hugh Robson Building, University of Edinburgh, Edinburgh, United Kingdom ABSTRACT The mammalian ureter contains two main cell types: a multilayered water-tight ep- The nephric (or Wolffian) ducts (NDs) ithelium called the urothelium, surrounded by smooth muscle layers that, by gen- are a pair of epithelial tubes, each of which erating proximal to distal peristaltic waves, pump urine from the renal pelvis toward runs along the edge of the intermediate the urinary bladder. Here, we review the cellular mechanisms involved in the de- mesoderm near the body cavity. Each velopment of these tissues, and the molecules that control the process. We consider ND gives rise to a ureteric precursor, the the relevance of these biologic findings for understanding the pathogenesis of ureteric bud (UB), which grows into human ureter malformations. metanephric mesenchymal (MM) cells condensing out of intermediate meso- J Am Soc Nephrol 24: 19–25, 2013. doi: 10.1681/ASN.2012020127 derm. Normally, a single bud emerges from each ND near its distal (caudal) Molecule Abbreviation Box end, a precision facilitating optimal ALK Activin receptor-like kinase (growth factor receptor) interaction between the UB and MM, AngII Angiotensin II (growth factor) which are required to generate a single BMP Bone morphogenetic protein (growth factor) ureter-kidney functional unit of normal DLGH Discs-large homolog (intracellular scaffolding protein) 1–3 ERK Extracellular signal-regulated kinase (intracellular signaling molecule) shape and internal structure.
    [Show full text]