The Axial Skeletons of Sunghir 1, 2, and 3

2014 ◽  
Author(s):  
Erik Trinkaus ◽  
Alexandra P. Buzhilova ◽  
Maria B. Mednikova ◽  
Maria V. Dobrovolskaya
Keyword(s):  
Radiocarbon Dating ◽  
Cervical Vertebrae ◽  
Costal Cartilage ◽  
Lumbar Vertebrae ◽  
Axial Skeleton ◽  
Age At Death ◽  
Vertebral Bodies ◽  
Length Scaling

Given their burial positions, on their backs with the trunks and limbs extended, the Sunghir 1 to 3 individuals should have retained major portions of their axial skeletons. This is the case for Sunghir 2 and 3, both of whom retain all of the cervical vertebrae, most of their thoracic and lumbar vertebrae, and major portions of their sacra. Sunghir 2 preserves portions of 23 of the 24 ribs, and Sunghir 3 retains at least a small piece of each of her 24 ribs. Moreover her left fifth and sixth ribs lack only their costal cartilage surfaces. Only Sunghir 3 preserves any elements of the sternum, two partial and separated sternebral segments. In contrast, despite the apparent presence of major portions of the axial skeleton in situ, little remains of the Sunghir 1 vertebrae, ribs, or sternum. The cervical vertebrae are absent, unless pieces of them are mixed with the collection of what appear to be thoracic and lumbar fragments. Only two vertebrae remain reasonably intact, the T1 and T2. There are eight pieces of vertebral bodies, one of which has a pathological growth (chapter 17). The ribs consist of small pieces, except for a largely intact left first rib. Although evident in the in situ photographs, nothing remains of the manubrium. There is also a piece of distal middle rib, which is of use for the age-at-death assessment. Some of the vertebral and rib pieces have been sacrificed over the years for direct radiocarbon dating (e.g., Kuzmin et al. 2004). Others pieces, heavily fissured and hence probably descending into fragments during excavation, were only partially retained. There are nonetheless a few aspects of the Sunghir axial skeletons, beyond age assessments (chapter 6), the pathological lesions on the Sunghir 1 vertebrae (chapter 17), use of the sacra in the pelves (chapter 14), and body length scaling for Sunghir 2 and 3 (chapter 11), that are of interest.

The locomotor system

2013 ◽  
Author(s):  
Martin E. Atkinson
Keyword(s):  
Vertebral Column ◽  
Cervical Vertebrae ◽  
Lumbar Vertebrae ◽  
Posterior Wall ◽  
Axial Skeleton ◽  
Intervertebral Discs ◽  
Central Canal ◽  
The Body ◽  
Thoracic Vertebrae ◽  
Locomotor System

The locomotor system comprises the skeleton, composed principally of bone and cartilage, the joints between them, and the muscles which move bones at joints. The skeleton forms a supporting framework for the body and provides the levers to which the muscles are attached to produce movement of parts of the body in relation to each other or movement of the body as a whole in relation to its environment. The skeleton also plays a crucial role in the protection of internal organs. The skeleton is shown in outline in Figure 2.1A. The skull, vertebral column, and ribs together constitute the axial skeleton. This forms, as its name implies, the axis of the body. The skull houses and protects the brain and the eyes and ears; the anatomy of the skull is absolutely fundamental to the understanding of the structure of the head and is covered in detail in Section 4. The vertebral column surrounds and protects the spinal cord which is enclosed in the spinal canal formed by a large central canal in each vertebra. The vertebral column is formed from 33 individual bones although some of these become fused together. The vertebral column and its component bones are shown from the side in Figure 2.1B. There are seven cervical vertebrae in the neck, twelve thoracic vertebrae in the posterior wall of the thorax, five lumbar vertebrae in the small of the back, five fused sacral vertebrae in the pelvis, and four coccygeal vertebrae—the vestigial remnants of a tail. Intervertebral discs separate individual vertebrae from each other and act as a cushion between the adjacent bones; the discs are absent from the fused sacral vertebrae. The cervical vertebrae are small and very mobile, allowing an extensive range of neck movements and hence changes in head position. The first two cervical vertebrae, the atlas and axis, have unusual shapes and specialized joints that allow nodding and shaking movements of the head on the neck. The thoracic vertebrae are relatively immobile. combination of thoracic vertebral column, ribs, and sternum form the thoracic cage that protects the thoracic organs, the heart, and lungs and is intimately involved in ventilation (breathing).

scholarly journals Anatomo-radiographic description of the axial skeleton of the crab-eating fox (Cerdocyon thous)

2012 ◽  
Vol 32 (suppl 1) ◽  
pp. 01-03 ◽  
Author(s):  
Janaína D. Barisson ◽  
Cristiane H. Louro ◽  
Sheila J.T. Dias ◽  
Flávio S. Jojima ◽  
Murilo S. Ferreira ◽  
...  
Keyword(s):  
Cervical Vertebrae ◽  
Spinous Process ◽  
Lumbar Vertebrae ◽  
Axial Skeleton ◽  
The Other ◽  
Domestic Dog ◽  
Thoracic Vertebrae ◽  
The Third ◽  
Caudal Vertebrae ◽  
Cerdocyon Thous

The aim of this study was to describe the axial skeleton of a wild Brazilian carnivorous, the crab-eating fox (Cerdocyon thous). Five specimens of crab-eating fox were previously unfrozen for radiographic exams and their bones went through dissection and chemical maceration. This animal presents seven cervical vertebrae, and from the third on, they become shorter and wider than the other ones e the spinous process was makeable from the fifth cervical vertebrae on. There are thirteen thoracic vertebrae and the spinous process of the lumbar vertebrae, which are seven, decreases from the fifth on. The sacrum is formed by two vertebrae and there are twenty or twenty one caudal vertebrae. It can be concluded that the crab-eating fox axial skeleton is similar to that of the domestic dog.

Why Cervical Vertebrae Do Not Fracture – A Biomechanical Approach Using Loading Tests on Human Vertebrae of A 79-Year-Old Body Donor.

2020 ◽  
pp. 1-6
Keyword(s):  
Volume Fraction ◽  
Bone Structure ◽  
Cervical Vertebrae ◽  
Testing Machine ◽  
Quantitative Computed Tomography ◽  
Lumbar Vertebrae ◽  
Elderly Subjects ◽  
Ageing Society ◽  
Trabecular Thickness ◽  
Vertebral Bodies

Abstract Purpose: Bone structure alters with increasing age. Material and structural properties are both important for bone strength. Despite having an ageing society, there is a paucity of data from elderly subjects in terms of these parameters. The aim of the present study was to conduct comparative examinations of the structure and material properties of the cervical spine (CS), the thoracic spine (TS) and the lumbar spine (LS), in order to identify both structural and biomechanical differences between the segments of the spine. Methods: We examined central bone cylinders of vertebral bodies C1 to L5 from a 79-year-old body donor in regards to their bone volume fraction (BVF), trabecular thickness (Tb.Th.), separation (Tb.Sp.), trabecular orientation (SMI) and degree of anisotropy (DA). Samples were obtained from all vertebrae with a Jamshidi needle®, and were prepared with a damp cloth in an Eppendorf reaction vessel (1.5 ml). The investigations were performed with a micro-CT device (SKYSCAN 1172, RJL Micro & Analytic GmbH, Germany). Existing deformities and fractures were registered with quantitative computed tomography (QCT). The load tests of the vertebral bodies C1 to L5 were performed on a servo-hydraulic testing machine (MTS 858, MTS Systems Cooperation, Eden Prairie, USA). Results: Regarding BVF (p=0.003), Tb.Th. (p=0.041) and SMI (p=0.012) statistically significant differences were found in the different spinal column sections. The force per area was significantly higher in the CS than in the TS and LS (CS vs. TS, p=0.022; CS vs. LS, p<0.001; TS vs. LS, p=0.012). Conclusion: Due to their unique microarchitecture cervical vertebrae are less prone to fractures than thoracic and lumbar vertebrae. Among the reasons are the higher BVF and Tb.Th. of the cervical vertebrae compared to other vertebrae. Furthermore, the SMI of the CS has more plates than rods. Thus, the CS is characterized by specific features, whose causes must be determined in further investigations.

scholarly journals Orthopaedic manifestations of pseudoachondroplasia

2019 ◽  
Vol 13 (4) ◽  
pp. 409-416 ◽  
Author(s):  
D. S. Weiner ◽  
J. Guirguis ◽  
M. Makowski ◽  
S. Testa ◽  
L. Shauver ◽  
...  
Keyword(s):  
Matrix Protein ◽  
Protein Gene ◽  
Lumbar Vertebrae ◽  
Gene Mutations ◽  
Axial Skeleton ◽  
Long Bones ◽  
Age Group ◽  
Level Of Evidence ◽  
Vertebral Bodies ◽  
Comp Gene

Purpose In 1959, Maroteaux and Lamy initially designated pseudoachondroplasia as a distinct dysplasia different from achondroplasia the most common form of skeletal dysplasia. Pseudoachondroplasia is caused by a mutation in the collagen oligomeric matrix protein gene (COMP) gene on chromosome 19p13.1-p12 encoding the COMP. The COMP gene mutations result in rendering the articular and growth plate cartilages incapable of withstanding routine biomechanical loads with resultant deformity of the joints. The purpose of the study was to characterize the typical orthopaedic findings in pseudoachondroplasia. Methods The charts and radiographs of 141 patients with pseudoachondroplasia were analyzed. This cohort, to our knowledge, represents the largest group of patients describing the typical orthopaedic manifestations of pseudoachondroplasia. Results Patients with pseudoachondroplasia have normal craniofacial appearance with normal intelligence. Short stature is not present at birth and generally appears by two to four years of age. The condition is a form of spondyloepiphyseal dysplasia and the long bones are characterized by dysplastic changes in the epiphysis, metaphysis and vertebral bodies. Radiographically the long bones have altered the appearance and structure of the epiphyses with small irregularly formed or fragmented epiphyses or flattening. The metaphyseal regions of the long bones show flaring, widening or ‘trumpeting’. The cervical (89%) and thoracic and lumbar vertebrae show either platyspondyly, ovoid, ‘cod-fish’ deformity or anterior ‘beaking’. Kyphosis (28%), scoliosis (58%) and lumbar lordosis (100%) are commonly seen. The femoral head and acetabulum are severely dysplastic (100%). The knees show either genu valgum (22%), genu varum (56%) or ‘windswept’ deformity (22%). Conclusion Most commonly these distortions of the appendicular and the axial skeleton lead to premature arthritis particularly of the hips and often the knees not uncommonly in the 20- to 30-year-old age group. Level of Evidence: III

scholarly journals An Anatomical and Radiographic Study on the Vertebral Column of the Two-Toed Sloth (Choloepus hoffmanni)

2021 ◽  
Vol 39 (2) ◽  
pp. 1-18
Author(s):  
Maripaz Chinchilla-Barboza ◽  
Siam Chiquillo-Vergara ◽  
Valeria Delgado-Álvarez ◽  
Susan Gutiérrez-Gutiérrez ◽  
Johnny Steven Mora-Aleman ◽  
...  
Keyword(s):  
Vertebral Column ◽  
Cervical Vertebrae ◽  
Lumbar Vertebrae ◽  
Axial Skeleton ◽  
Variable Number ◽  
Medical Attention ◽  
Thoracic Vertebrae ◽  
Radiographic Study ◽  
Proper Understanding ◽  
Caudal Vertebrae

The Choloepus Hoffmani is a mammal belonging to the Xenarthra superorder; xenarthrans are distributed from North to South America. It is common for these animals to require medical attention at wildlife rescue centers after being attacked by domestic animals or run over by cars. A proper understanding of this species’ anatomy is vital in order to be able to offer them a proper level of clinical attention. This publication aims to describe the spine’s anatomical and radiographic characteristics of the Choloepus Hoffmani. Four individuals were used in this research; the spine bones were cleaned by boiling and maceration. In the results, it was possible to observe how the postcranial axial skeleton in the sloths is made up by five of distinctive vertebra types. In the spine were found: six cervical vertebrae, a variable number of thoracic vertebrae, xenarthrous lumbar vertebrae, and a fusion between the sacrum and coxal bone. Finally, four underdeveloped caudal vertebrae were also identified in a small stump-like tail. Radiographically, no pathologies were observed in the alignment or structure of the spine. In conclusion, the present study described both the osteology alongside the anatomical radiography of the vertebral column of the Choloepus hoffmani, highlighting the particularities that are not found in domestic mammals and other members of the Xenarthra superorder. Information of this kind is relevant for forensic wildlife analysis, alongside aiding the treatment of animals in this species who suffered lesions in their spine.

Gout in the Axial Skeleton

2009 ◽  
Vol 36 (3) ◽  
pp. 609-613 ◽  
Author(s):  
RUKMINI M. KONATALAPALLI ◽  
PAUL J. DEMARCO ◽  
JAMES S. JELINEK ◽  
MARK MURPHEY ◽  
MICHAEL GIBSON ◽  
...  
Keyword(s):  
Facet Joint ◽  
Case Reports ◽  
Case Series ◽  
Lumbar Vertebrae ◽  
Axial Skeleton ◽  
Ct Images ◽  
Common Finding ◽  
Appendicular Skeleton ◽  
Pars Interarticularis ◽  
A Prospective Study

Objective.Gout typically affects the peripheral joints of the appendicular skeleton and rarely involves the axial joints. The literature on axial gout is limited to case reports and case series. This preliminary study was conducted to identify the frequency and characteristics of axial gout.Methods.Six hundred thirty medical records with ICD codes 274.0, 274.82, and 274.9 for peripheral gout were reviewed. Ninety-two patients had clinical or crystal-proven gout, of which 64 had prior computed tomography (CT) images of the spine performed for various medical reasons. These CT images were reviewed for features of axial gout, which include vertebral erosions mainly at the discovertebral junction and the facet joints, deposits of tophi, and erosions in the vertebral body, epidural space, ligamentum flavum and pars interarticularis.Results.Nine of the 64 patients had radiographic changes suggestive of axial gout. Lumbar vertebrae were most commonly involved, with facet joint erosions being the most common finding. Isolated involvement of the sacroiliac joints was seen in 2 patients. Axial gout had been diagnosed clinically in only one patient.Conclusion.Radiologic changes of axial gout were more common than recognized clinically, with a frequency of 14%. Since not all patients had CT images, it is possible that the frequency of axial involvement was even greater. A prospective study is needed to further define this process.

scholarly journals Effect of unilateral pulsed jet lavage prior to vertebroplasty on the intravertebral pressure and cement distribution

2020 ◽  
Author(s):  
Jun Yan ◽  
Qiaohui Liu ◽  
Yanping Zheng ◽  
Ziqun Liu ◽  
Xinyu Liu ◽  
...  
Keyword(s):  
Bone Cement ◽  
Lumbar Vertebrae ◽  
Compression Fracture ◽  
Cement Leakage ◽  
Control Group ◽  
Pulsed Jet ◽  
Jet Lavage ◽  
Average Maximum ◽  
Cement Distribution ◽  
Vertebral Bodies

Abstract Background: Percutaneous vertebroplasty is the most common treatment for osteoporotic vertebral compression fracture. However, the morbidity of vertebroplasty-related complications, such as cement leakage, remains high. We tested a new technique of unilateral pulsed jet lavage and investigated its effect on the intravertebral pressure and bone cement distribution. Methods: Thirty lumbar vertebrae (L1-L5) from six cadaver spines were randomly allocated into two groups (with and without irrigation). Prior to vertebroplasty, pulsed jet lavage was performed through one side of the pedicle by using a novel cannula with two concentric conduits to remove the fat and bone marrow of the vertebral bodies in the group with irrigation. The control group was not irrigated. Then, standardized vertebroplasty was performed in the vertebral bodies in both groups. Changes in the intravertebral pressure during injection were recorded. Computed tomography (CT) was performed to observe the cement distribution and extravasations, and the cement mass volume (CMV) was calculated. Results: During cement injection, the average maximum intravertebral pressure of the unirrigated group was higher than that of the irrigated group (4.92kPa versus 2.22kPa, P<0.05). CT scans showed a more homogeneous cement distribution with less CMV (3832 mm 3 vs. 4344 mm 3 , P<0.05) and less leakage rate (6.7% vs. 46.7%, P<0.05) in the irrigated group than in the control group. Conclusions: Unilateral pulsed jet lavage can reduce intravertebral pressure and lower the incidence of cement leakage during vertebroplasty. An enhanced bone cement distribution can also be achieved through this lavage system.

scholarly journals A comparison of erect weight-bearing and non-weight-bearing radiography of the cervical spine in non-trauma patients

2021 ◽  
Author(s):  
Bimali S. Weerakoon ◽  
Nimali N. Karunaratne ◽  
Winitha S. Jayasundara
Keyword(s):  
Imaging System ◽  
Computed Radiography ◽  
Cervical Vertebrae ◽  
Weight Bearing ◽  
Cervical Region ◽  
Trauma Patients ◽  
Imaging Procedure ◽  
Significant Difference ◽  
Vertebral Bodies ◽  
Fair Poor

Introduction: Various positioning techniques are utilized to enhance the visualization of lower cervical vertebrae on lateral radiographs. However, the effectiveness of these techniques still remains unclear. This study was conducted to determine the effect of the weight-bearing (WB) technique in visualizing lower cervical vertebrae and cervicothoracic junction (C7-T1) on standing lateral cervical radiographs of adult non-trauma patients. The study was conducted using both computed radiography (CR) and digital radiography (DR) systems.Methods: Forty-four CR (29 WB and 15 non-WB – NWB) and 61 DR (26 WB and 35 NWB) lateral C-spine radiographs were prospectively evaluated to assess the visible number of cervical vertebral bodies and C7-T1 junction. The instructions given by the radiographer to the patient for the imaging procedure were also assessed on the Likert scale (very good, good, fair, poor, very poor).Results: There was no significant difference (p > 0.05) in the visualization of the number of vertebral bodies between the two techniques of WB and NWB for CR or DR. Further, no significant relationship (p > 0.05) was observed between the WB technique and the visualization of C7-T1 junction in DR systems. However, a significant difference was identified for CR (p = 0.012). The instruction given to the patient significantly correlated with the visibility of the lower C-spine region within each group of WB and NWB in both imaging systems.Conclusions: The visibility of the number of vertebral bodies in the lower C-spine region in either CR or DR systems did not demonstrate any enhancement with the WB technique. Regardless of the imaging system or techniques used, adequate instructions given to the patient before and during the imaging procedure of C-spine lateral radiography demonstrated a significant improvement in visualizing the lower C-spine region. In this preliminary study, the application of erect WB radiography technique in evaluating the lower cervical region of adult non-trauma patients gives limited advantage.

UNDULATORY SWIMMING: HOW TRAVELING WAVES ARE PRODUCED AND MODULATED IN SUNFISH (LEPOMIS GIBBOSUS)

1994 ◽  
Vol 192 (1) ◽  
pp. 129-145 ◽  
Author(s):  
J Long ◽  
M Mchenry ◽  
N Boetticher
Keyword(s):  
Muscle Activation ◽  
Axial Skeleton ◽  
The Body ◽  
Lepomis Gibbosus ◽  
Axial Muscle ◽  
Locomotor Muscles ◽  
Undulatory Swimming ◽  
Swimming Kinematics ◽  
Tail Beat

We have developed an experimental procedure in which the in situ locomotor muscles of dead fishes can be electrically stimulated to generate swimming motions. This procedure gives the experimenter control of muscle activation and the mechanical properties of the body. Using pumpkinseed sunfish, Lepomis gibbosus, we investigated the mechanics of undulatory swimming by comparing the swimming kinematics of live sunfish with the kinematics of dead sunfish made to swim using electrical stimulation. In electrically stimulated sunfish, undulatory waves can be produced by alternating left&shy;right contractions of either all the axial muscle or just the precaudal axial muscle. As judged by changes in swimming speed, most of the locomotor power is generated precaudally and transmitted to the caudal fin by way of the skin and axial skeleton. The form of the traveling undulatory wave &shy; as measured by tail-beat amplitude, propulsive wavelength and maximal caudal curvature &shy; can be modulated by experimental control of the body's passive stiffness, which is a property of the skin, connective tissue and axial skeleton.

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