DOCSLIB.ORG

The Appendicular Skeleton Visual Worksheet

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
The Appendicular Skeleton Visual Worksheet Biology 201:The Appendicular Skeleton 1) Label the diagram of the pectoral girdle below. Use the terms from Word Bank A to label the blue boxes (anatomical terms of location) and the terms from Word Bank B to label the gray boxes (individual structures). Some terms may be used more than once. Word Bank A Anterior view of pectoral girdle Lateral Posterior Posterior view of pectoral girdle Anterior Inferior Superior view of clavicle Inferior view of clavicle Word Bank B Scapula Coracoclavicular ligament Glenohumeral joint Clavicle Rib Acromial end Costoclavicular ligament Sternal end Vertebrae Acromioclavicular joint Source Lesson: Pectoral Girdle: Bones & Functions 2) Label the diagram below. Some terms may be used more than once. Lateral border Infraspinous fossa Acromion Suprascapular notch Inferior angle Medial border Coracoid process Superior angle Subscapular fossa Supra spinous fossa Glenoid cavity Superior border Spine Source Lesson: Pectoral Girdle: Bones & Functions 3) Label the diagram below. Some terms may be used more than once. Radial fossa Medial epicondyle Surgical neck Coronoid process of ulna Greater tubercle Trochlea Lesser tubercle Head Capitulum Head of radius Intertubercular groove (sulcus) Coronoid fossa Head of radius Deltoid tuberosity Body (shaft) Lateral supracondylar ridge Anatomical neck Lateral epicondyle Olecranon fossa Olecranon of ulna Source Lesson: Upper Limb: Divisions, Bones & Functions 4) Label the diagram below. Some terms may be used more than once. Ulnar notch of the radius Styloid process of radius Coronoid process Radius Radial notch of the ulna Head of ulna Head of radius Proximal radioulnar joint Distal radioulnar joint Olecranon process Neck of radius Interosseous membrane Radial tuberosity Styloid process of ulna Trochlear notch Ulna Source Lesson: Upper Limb: Divisions, Bones & Functions 5) Label the bones of the hand. Use the terms from Word Bank A to label the blue boxes and the terms from Word Bank B to label the gray boxes. Some terms may be used more than once. Word Bank A Carpals Phalanges Metacarpals Word Bank B Ring Finger Distal Piriform Ulna Little finger Triquetrum Trapezium Head Base Thumb (pollex) Lunate Proximal Index finger Trapezoid Hamate Shaft Capitate Middle finger Scaphoid Radius Source Lesson: Upper Limb: Divisions, Bones & Functions 6) Label the diagram below. Some terms may be used more than once. Lesser sciatic notch Inferior ramus of pubis Pubic body Ischial ramus Iliac fossa Ischial spine Posterior inferior iliac spine Ischial tuberosity Ilium Ischial body Obturator foramen Acetabulum Pubis Anterior superior iliac spine Ischium Auricular surface Greater sciatic notch Articular surface of pubis Posterior superior iliac spine Iliac crest Arcuate line Anterior inferior iliac spine Superior ramus of pubis Ischiopubic ramus Source Lesson: Pelvic Girdle & Pelvis: Regions, Bones & Ligaments 7) Label the diagram below. Ischiopubic ramus Hip bone Coccyx Sacrum Acetabulum Ischial tuberosity Sacroiliac joint Pubic symphysis Obturator foramen Sacral promontory Pelvic brim Source Lesson: Pelvic Girdle & Pelvis: Regions, Bones & Ligaments 8) Fill in the table below with the bones in the region listed. Tarsals Fibula Femur Patella Phalanges Tibia Metatarsals Lower Limb Region Bones in the Region Thigh 1) Femur Leg 2) Tibia 3) Fibula 4) Patella Ankle & Foot 5) Tarsals 6) Metatarsals 7) Phalanges Source Lesson: Lower Limb: Divisions, Bones & Functions 9) Label the anatomy of the knee. Some terms may be used more than once. Tibial plateau Femur Fibula Patella Medial condyle Tibia Lateral condyle Source Lesson: Lower Limb: Divisions, Bones & Functions 10) Label the diagram below. Navicular Fibula Metatarsal bones Tibia Proximal Cuneiform bones Tarsals Distal Phalanges Calcaneus Talus Cuboid Medial Metatarsals Source Lesson: Lower Limb: Divisions, Bones & Functions 11) Label the diagram below. Some terms may be used more than once. Tibial tuberosity Lateral condyle Tibia Medial condyle Anterior border Soleal line Interosseous membrane Fibula Head of fibula Lateral malleolus Medial malleolus Articular surface Source Lesson: Lower Limb: Divisions, Bones & Functions 12) Label the image below. Some terms may be used more than once. Lateral epicondyle Patella Neck Femur Head Tibia Adductor tubercle Greater trochanter Lesser trochanter Patellar groove Intertrochanteric crest Body of femur Intertrochanteric line Medial epicondyle Linea aspera Fibula Source Lesson: Lower Limb: Divisions, Bones & Functions 13) Label the diagram below. Some terms may be used more than once. Femur Pubic symphysis Os coxae Ilipubic eminence Fibula Patella Ischial tuberosity Ankle mortise Tibia Source Lesson: Lower Limb: Divisions, Bones & Functions 14) Label the image below. Some terms may be used more than once. Calcaneal tuberosity Facet for lateral malleolus Medial cuneiform Talus Facet for medial malleolus Calcaneus Sustentaculum tali Cuboid Trochlea of the Talus Navicular Intermediate cuneiform Lateral cuneiform Source Lesson: Lower Limb: Divisions, Bones & Functions 15) Label the diagram. Some terms may be used more than once. Distal phalange First metatarsal Fifth metatarsal Middle phalange Middle phalange Proximal phalange Source Lesson: Lower Limb: Divisions, Bones & Functions .
Load more

Recommended publications
  • List: Bones & Bone Markings of Appendicular Skeleton and Knee
    List: Bones & Bone markings of Appendicular skeleton and Knee joint Lab: Handout 4 Superior Appendicular Skeleton I. Clavicle (Left or Right?) A. Acromial End B. Conoid Tubercle C. Shaft D. Sternal End II. Scapula (Left or Right?) A. Superior border (superior margin) B. Medial border (vertebral margin) C. Lateral border (axillary margin) D. Scapular notch (suprascapular notch) E. Acromion Process F. Coracoid Process G. Glenoid Fossa (cavity) H. Infraglenoid tubercle I. Subscapular fossa J. Superior & Inferior Angle K. Scapular Spine L. Supraspinous Fossa M. Infraspinous Fossa III. Humerus (Left or Right?) A. Head of Humerus B. Anatomical Neck C. Surgical Neck D. Greater Tubercle E. Lesser Tubercle F. Intertubercular fossa (bicipital groove) G. Deltoid Tuberosity H. Radial Groove (groove for radial nerve) I. Lateral Epicondyle J. Medial Epicondyle K. Radial Fossa L. Coronoid Fossa M. Capitulum N. Trochlea O. Olecranon Fossa IV. Radius (Left or Right?) A. Head of Radius B. Neck C. Radial Tuberosity D. Styloid Process of radius E. Ulnar Notch of radius V. Ulna (Left or Right?) A. Olecranon Process B. Coronoid Process of ulna C. Trochlear Notch of ulna Human Anatomy List: Bones & Bone markings of Appendicular skeleton and Knee joint Lab: Handout 4 D. Radial Notch of ulna E. Head of Ulna F. Styloid Process VI. Carpals (8) A. Proximal row (4): Scaphoid, Lunate, Triquetrum, Pisiform B. Distal row (4): Trapezium, Trapezoid, Capitate, Hamate VII. Metacarpals: Numbered 1-5 A. Base B. Shaft C. Head VIII. Phalanges A. Proximal Phalanx B. Middle Phalanx C. Distal Phalanx ============================================================================= Inferior Appendicular Skeleton IX. Os Coxae (Innominate bone) (Left or Right?) A.
    [Show full text]
  • Bones of Upper & Lower Limbs
    Bones of Upper & Lower Limbs "Revision" Anatomy Team 434 Color Index: If you have any complaint or ▪ Important Points suggestion please don’t ▪ Helping notes hesitate to contact us on: [email protected] ▪ Explanaon New Terms General Term Meaning Condyle Large, rounded articular Processes that Facet Smooth, flat surface helps to form joints Head Enlarged portion at an end of a bone (Articulation) Ramus Branch or extension of a bone Crest Narrow ridge Epicondyle Linea Process on or above a condyle Narrow ridge (less prominent than a crest) Processes that (line) provide for the attachment of Spine Sharp or pointed process (spinous process) muscles and ligaments Large, irregularly shaped process (found only on the femur) Trochanter (Projection) Tubercle Small, knoblike process Tuberosity Large, knoblike process (rough) New Terms General Term Meaning Notch An indentaCon, (incision) on an edge or surface Fissure Narrow opening Fontanel Membrane-covered spaces between skull bones Interosseous border Between bones (the place where the two parallel bones aach together by the interosseous membrane) Depressions or openings (may provide Foramen Round opening passageways for blood Sinus Interior cavity vessels and nerves) Fovea Pit-like depression Meatus Tube-like passage Fossa Shallow depression Sulcus"groove" Long, narrow depression Alveolus A pit or socket (tooth socket) The Upper Limb Upper Limbs Characteristic features Bones - Subcutaneous.” lying under the skin “ Clavicle - medial (Sternal) end is enlarged & triangular. ⅔ and convex - lateral (Acromial) end is flattened. ⅓ and concave - A triangular Flat bone (Irregular). Pectoral - It has Three Processes (1)Spine(2) Acromion(3) Coracoid Girdle - Three Borders: Superior, Medial (Vertebral) & Lateral (Axillary the Scapula thickest part of the bone).
    [Show full text]
  • Comparison of Hip Structure Analysis and Grip Strength Between Femoral Neck and Basicervical Fractures Yong-Han Cha1 and Jun-Il Yoo2*
    Cha and Yoo BMC Musculoskeletal Disorders (2021) 22:461 https://doi.org/10.1186/s12891-021-04363-w RESEARCH Open Access Comparison of hip structure analysis and grip strength between femoral neck and basicervical fractures Yong-Han Cha1 and Jun-Il Yoo2* Abstract Background: The purpose of this study was to analyze differences in geometrical properties of the proximal femur and predict the occurrence of basicervical fractures through a comparative study of femoral neck and basicervical fractures in patients undergoing hip structural analysis (HSA). Methods: All patients with hip fractures who were at least 65 years old and admitted to our hospital between March 2017 and December 2019 were eligible for this study. During the study period, 149 femur neck fractures (FNF) and basicervical fractures (intertrochanteric fractures of A31.2) were included in this study. Fifty-nine patients were included in the final analysis. Factors considered to be important confounders affecting the occurrence of basicervical hip fractures were chosen for propensity-score analysis. A logistic model with basicervical hip fracture as the outcome and age, sex, weight, spinal T-score, hip T-score, and vitamin D levels as confounders was used to estimate the propensity score. Results: The cross-sectional moment of inertia (CSMI) of the intertrochanter was significantly lower in patients with basicervical hip fracture (HF) than in patients with FNF (p = 0.045). However, there was no significant differences in any other HSA variable between the two groups. Receiver operating characteristic (ROC) analysis showed that cutoff point for HSA was 100 for hip axis length (HAL) (AUC = 0.659, p < 0.001) and 5.712 for CSMI of the intertrochanter (AUC = 0.676, p < 0.001).
    [Show full text]
  • Morphometric Examination of the Proximal Femur in the Hip Joint
    Experimental and Applied Medical Science 1, 3: 82 - 88, 2020. DOI 10.46871/eams.2020.11 Morphometric Examination of the Proximal Femur in the Hip Joint Adem Tokpınar1*, Seher Yılmaz1, Rabia Kurt Tokpınar2, Şükrü Ateş1, Mücahit Emin Kandur3, Mehtap Nisari4 1Yozgat Bozok University, Faculty of Medicine, Department of Anatomy, Yozgat, Turkey. 2Yozgat Bozok University, Faculty of Medicine, Department of Obstetrics and Gynecology, Yozgat, Turkey. 3Erciyes University, Faculty of Medicine, Kayseri, Turkey. 4Erciyes University, Faculty of Medicine, Department of Anatomy, Erciyes University, Kayseri, Turkey. Abstract It is located between the femur, hip and knee. It is the heaviest, longest and strongest bone in the body. As the age progresses, osteoporosis develops and proximal femur fractures can be seen. Today, hip fractures are among the most common cases. Surgical interventions for the region are quite common. In our study, measurements were made on dry bone with a calliper and proximal femur morphometry was examined in eight parameters. The mean head of femoris diameter was found to be 42.75±6.14 mm in the right femurs and 43.83±4.03 mm in the left femurs. Intertrochanteric line length was measured as 56.78±5.22 mm in the right femurs and 57.65±9.97 mm in the left femurs. The results are similar to the literature. In other studies, it was observed that some parameters related to the proximal femur were not standardized. We think that our study will have an important contribution in standardizing the values obtained in dry bone studies. In addition, head to femoris diameter and neck of femoris length are important parameters in surgical interventions to be performed on the proximal femur.
    [Show full text]
  • The Lower Limb II
    The Lower Limb II Anatomy RHS 241 Lecture 3 Dr. Einas Al-Eisa Tibia •The larger & medial bone of the leg • Functions: ¾Attachment of muscles ¾Transfer of weight from femur to skeleton of the foot ¾Articulations Articulations • Only the tibia articulates with the distal end of femur to form the knee joint • Both the tibia & fibula articulate with the talus to form the ankle joint • The proximal & distal ends of the tibia & fibula articulate together to form the tibiofibular joints Tibia Proximal end: Shaft: Distal end: Condyles Three surfaces Distal surface Tibial tuberosity (ant, med, lat) Medial malleolus Tibia • Medial & lateral condyles: articulate with the corresponding condyle of the femur • Tibial tuberosity: the attachment site of the patellar tendon • Anterior surface of the shaft: shin bone • Distal end: articulate with the talus to form part of the ankle joint Surface Anatomy Palpate on a living knee: • Patella: base, margins, apex • Anterior margins of the medial & lateral condyles • Approximate level of the “Knee Joint Line” Fibula • Slender • Lateral bone of the leg • Non-weight bearing • Mainly for the attachment of lateral leg muscles Fibula • Head: articulate with the tibia to form the proximal tibiofibular joint • Shaft: for attachment of muscles • Latreal malleolus: articulate with the tibia to form the distal tibiofibular joint, and with the talus contributing to the ankle joint Surface anatomy Palpate the following: • Medial tibial condyle • Tibial tuberosity • Head of fibula • Shin bone • Medial malleolus • Lateral
    [Show full text]
  • Bones of Upper Limb
    BONES OF UPPER & LOWER LIMBS Khaleel Alyahya, PhD, MEd King Saud University College of Medicine @khaleelya OBJECTIVES At the end of the lecture, students should be able to: o List the different bones of the the upper and lower limbs. o List the characteristic features of each bone in both. o Differentiate between bones of right and left sides. o List the articulations between the different bones. o Learn some clinical significances associated with the upper and lower limbs. UPPER LIMBS BONES OF UPPER LIMB It consists of the following: o Pectoral Girdle • Clavicle • Scapula o Arm • Humerus o Forearm • Radius & Ulna o Wrist • Carpal bones o Hand • Metacarpals & Phalanges PECTORAL GIRDLE It composed of Two bones: o Clavicle o Scapula It is very light and it allows the upper limb to have exceptionally free movement. CLAVICLE It is considered as a long bone but it has no medullary (bone marrow) cavity. Its medial (Sternal) end is enlarged & triangular. Its lateral (Acromial) end is flattened. The medial 2/3 of the body (shaft) is convex forward. The lateral 1/3 is concave forward. These curves give the clavicle its appearance of an elongated capital (S) It has two surfaces: • Superior: smooth as it lies just deep to the skin. • Inferior: rough because strong ligaments bind it to the 1st rib. Functions: • It serves as a rigid support to keep upper limb suspended away from the trunk. • Transmits forces from the upper limb to the axial skeleton. • Provides attachment for muscles. • Forms a boundary of the cervicoaxillary canal for protection of the neurovascular bundle of the UL.
    [Show full text]
  • Abnormal Ossified Structures Around the Hip Joint and Its Clinical Implications
    International Journal of Research in Medical Sciences Chakravarthi KK et al. Int J Res Med Sci. 2017 Dec;5(12):5391-5395 www.msjonline.org pISSN 2320-6071 | eISSN 2320-6012 DOI: http://dx.doi.org/10.18203/2320-6012.ijrms20175461 Original Research Article Abnormal ossified structures around the hip joint and its clinical implications Kosuri Kalyan Chakravarthi1*, Siddaraju K. S.2, Nelluri Venumadhav3, Sangeeta Atamaram Bali4 1Department of Anatomy, Varun Arjun Medical College, Banthra-Shajahanpu, Uttar Pradesh, India 2Department of Anatomy, KMCT Medical College, Manassery, Calicut, Kerala, India 3Department of Anatomy, Melaka Manipal Medical College (MMMC), Manipal University, Manipal, Karnataka, India 4Department of Anatomy, Varun Arjun Medical College, Banthra-Shajahanpu, Uttar Pradesh, India Received: 06 October 2017 Accepted: 09 November 2017 *Correspondence: Dr. Kosuri Kalyan Chakravarthi, E-mail: [email protected] Copyright: © the author(s), publisher and licensee Medip Academy. This is an open-access article distributed under the terms of the Creative Commons Attribution Non-Commercial License, which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited. ABSTRACT Background: The hip joint is the body’s second largest weight-bearing joint forms a connection from the lower limb to the pelvic girdle. It is formed by an articulation between the pelvic acetabulum and the head of the femur. Ankylosis or fusion of the joint, ossification of the adjacent ligaments and calcific tendinitis of adjacent muscles can decrease the mobility of the joint. The study was undertaken to evaluate the incidence of abnormal ossified structures around the hip joint. Methods: This study was carried out on 228 dry human hip bones (right- 114 and left-114) and 228 dry human femur bones (right- 114 and left-114) irrespective of age and sex at Varun Arjun medical college-Banthra, UP, KMCT Medical College, Manassery-Calicut and Melaka Manipal Medical College-Manipal.
    [Show full text]
  • Morphological Variation of the Proximal Femur in Selected Skeletal Remains
    MORPHOLOGICAL VARIATION OF THE PROXIMAL FEMUR IN SELECTED SKELETAL REMAINS A Thesis by Jessica Lynn Brown B.S. Michigan State University, 2002 Submitted to the College of Liberal Arts and Sciences and the faculty of the Graduate School of Wichita State University in partial fulfillment of the requirements for the degree of Master of Arts May 2006 MORPHOLOGICAL VARIATION OF THE PROXIMAL FEMUR IN SELECTED SKELETAL REMAINS I have examined the final copy of this thesis for form and content and recommend that it be accepted in partial fulfillment of the requirements for the degree of Master of Arts with a major in Anthropology. __________________________________________ Peer H. Moore-Jansen, Ph.D., Committee Chair We have read this thesis and recommend its acceptance: __________________________________________ Robert Lawless, Ph.D., Committee Member __________________________________________ John Carter, Ph.D., Committee Member ii DEDICATION To My Family and Friends iii ACKNOWLEDGEMENTS Funding for this research came from three generous sources. Dr. Todd Fenton provided me with the opportunity to experience Albania’s past and present in two separate field seasons. The Moore-Jansen Scholarship and the Nancy Berner Fund through the Anthropology Department at Wichita State University provided financial support to study the Hamann-Todd collection in Cleveland. The expense of travel and accommodations during data collection during all of these experiences was greatly appreciated by these considerate awards. I would like to thank all the members of my thesis committee, Dr. Peer Moore-Jansen, Dr. Robert Lawless, and Dr. John Carter for their comments and suggestions. Throughout this process Dr. Peer Moore-Jansen provided invaluable guidance on how to conduct and report meaningful research, which will stay with me always.
    [Show full text]
  • Ischial Tuberosity
    IN THE NAME OF GOD Musculoskeletal system For parasmedicine student By Dr. Saeednia ANATOMY OF SKELETAL SYSTEM LOWER LIMB THE BONES OF THE LOWER LIMB : THE HIP BONE : It is a large bone It is formed of 3 bones : THE ILIUM THE ISCHIUM THE PUPIS There is a large opening below the acetabulum called the obturator foramen Anatomical position THE HIP BONE THE ILIUM: is the upper expanded part of the hip bone consists of: The sup. border called the iliac crest Small part that attach to pubis and ischum in acetabulum Ant. border post. border Med. Border Gluteal surface (obturator foramen – acetabulum) Iliac surface Sacropelvic serface The iliac crest lies between the Ant .Sup. Iliac Spine & the Post. Sup. Iliac Spine ant. 2/3 is thick & convex outward & has inner & outer lips with an intermediate rough area in between the post. 1/3 is thin & convex inward & has 2 sloping surfaces separated by bony ridge A bony prominence called the tubercle of the iliac crest is on the outer lip 5 cm behind the ant. Sup. Iliac spine. The ant. border From Ant .Sup. Iliac Spine to acetabulum The post. border From Post. Sup. Iliac Spine to Post. Inf. Iliac Spine then form the greater sciatic notch then be continuous with the post. border of the ischium. ISCHIUM : Post. forms lower & post. part of the hip bone Consists: body Lat. ramus pelvic body Ant. Sup. ( post. Part of acetabulum) Inf. (Ischial tubrosity ) post. border of the body is continuous above with the post border of the ilium forming the lower part of the greater sciatic notch, then project to form the ischial spine, & then form the lesser sciatic notch before it form the ischial tuberosity .
    [Show full text]
  • Intertrochanteric Fractures
    Surgical Management of Hip Fractures: An Evidence-based Review of the Literature. II: Intertrochanteric Fractures Kevin Kaplan, MD Abstract Ryan Miyamoto, MD Treatment of intertrochanteric hip fracture is based on patient Brett R. Levine, MD medical condition, preexisting degenerative arthritis, bone quality, Kenneth A. Egol, MD and the biomechanics of the fracture configuration. A critical review of the evidence-based literature demonstrates a preference Joseph D. Zuckerman, MD for surgical fixation in patients who are medically stable. Stable fractures can be successfully treated with plate-and-screw implants and with intramedullary devices. Although unstable fractures may theoretically benefit from load-sharing intramedullary implants, this result has not been demonstrated in the current evidence- based literature. ntertrochanteric hip fractures are treatment, although prosthetic re- Dr. Kaplan is Sports Medicine Fellow, Iextracapsular fractures of the placement is occasionally indicated. Kerlan Jobe Orthopaedic Clinic, Los proximal femur involving the area The major difficulty stems from the Angeles, CA. Dr. Miyamoto is Sports between the greater and lesser tro- combination of the presence of often Medicine Fellow, Steadman Hawkins chanter. Such fractures that extend osteopenic bone and the adverse bio- Clinic, Vail, CO. Dr. Levine is Adult into the area distal to the lesser tro- mechanics of many intertrochan- Reconstructive Surgeon, Department of chanter are described as having a teric fracture patterns. Other factors Orthopaedic Surgery, Rush University subtrochanteric component. The affecting the choice of fixation in- Medical Center, Chicago, IL. Dr. Egol is intertrochanteric region has an clude preexisting hip symptoms, the Chief of Fracture Service, Department of abundant blood supply, which presence of osteoarthritis, bone qual- Orthopaedic Surgery, NYU–Hospital for makes fractures in this area much ity, degree of comminution, and the Joint Diseases, New York, NY.
    [Show full text]
  • The Anterior Capsule of the Hip Joint Is a Major Hindrance to the Surgical
    The Anterior Capsule of the Hip Joint Is a Major Hindrance to the Surgical Treatment of Basicervical Intertrochanteric Fractures: A Single Center, Retrospective Observational Study Won Chul Shin Pusan National University Yangsan Hospital Jae Hoon Jang Pusan National University Hospital Seok Jin Jung Pusan National University Hospital Nam Hoon Moon ( [email protected] ) Pusan National University Hospital Research Article Keywords: hip joint capsule, basicervical intertrochanteric fracture, nonunion, proximal femoral nail antirotation Posted Date: December 9th, 2020 DOI: https://doi.org/10.21203/rs.3.rs-114007/v1 License: This work is licensed under a Creative Commons Attribution 4.0 International License. Read Full License Page 1/16 Abstract Background: The basicervical intertrochanteric fracture has recently received considerable attention as one of the major risk factors for failure of internal xation. We aimed to analyze the anatomical characteristics of basicervical intertrochanteric fractures related to their surgical outcomes using three-dimensional computed tomography (3D CT) and to determine the causes for the high failure rate of surgery. Methods: Between May 2015 and October 2019, 226 patients with intertrochanteric fracture of the femur including 58 basicervical types who were treated with femoral nail were evaluated. Following data were collected to nd out the risk factors for surgical failure: fracture patterns (unstable or basicervical type), tip apex distance, type of postoperative reduction (acceptable or unacceptable), and continuity of anterior capsule for logistic regression analysis to determine the risk factors for surgical failures Results: Union was achieved in 215 patients (95.1%), with 11 surgical failures (4.9%), including 10 non-unions (4.6%) and 1 osteonecrosis of the femoral head (0.4%).
    [Show full text]
  • Medd 421 Anatomy Project ~
    MEDD 421 ANATOMY PROJECT ~ KURT MCBURNEY, ASSISTANT TEACHING PROFESSOR - IMP NICHOLAS BYERS - SMP PETER BAUMEISTER - SMP Proof of Permission for Cadaveric Photos LABORATORY 1 ~ OSTEOLOGY INDEX Acetabular labrum Gluteal surface Metatarsals (1-5) Acetabulum Greater sciatic notch Navicular Anterior intercondylar area Greater Trochanter Neck of Fibula Anterior superior iliac spine (ASIS) Head of Femur Neck of Talus Calcaneal Tuberosity Head of Fibula Obturator foramen Calcaneus Head of Talus Patellar Surface Cuboid Iliac crest Phalanges Cuneiform Intercondylar eminence Phalanges (medial, intermediate, and lateral) Ischial spine Posterior superior iliac spine (PSIS) Femoral Condyles Ischial tuberosity Round ligament of the head of the femur Femoral Epicondyles Lateral Malleolus Shaft Fovea Capitis Lesser sciatic notch Sustentaculum tali Neck of Femur Linea Aspera Talus Gerdy’s tubercle Lunate surface Tarsus Medial / Lateral Tibial Condyles Tibial tuberosity Medial Malleolus Trochlear surface OSTEOLOGY: THE FOOT Structures in View: Calcaneus Talus Cuboid Navicular Cuneiform (Medial specific) Metatarsals (5th specific) Phalanges Calcaneus Structures in View: Sustentaculum Tali Calcaneal Tuberosity (Insertion of Achilles) Talus Structures in View: Head Neck Trochlear Surface (Not the spring) Metatarsals Structures in View: Head Shaft Base First Metatarsal Fifth Metatarsal Phalanges Structures in View: Proximal Distal Proximal Middle Distal Femur (anterior) Structures in View: Patellar Surface Medial Epicondyle Lateral Epicondyle Medial Condyle
    [Show full text]