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Books on the topic 'Computed tomography imaging'

Author: Grafiati
Published: 4 June 2021
Last updated: 14 March 2023

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1

Whole-body computed tomography. 2nd ed. Blackwell Scientific Publications, 1993.

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2

Imaging dopamine. Cambridge University Press, 2009.

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3

T, Lee Joseph K., and Sagel Stuart S. 1940-, eds. Computed body tomography with MRI correlation. 4th ed. Lippincott Williams & Wilkins, 2005.

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4

F, Cattin, and Dietemann J. L. 1951-, eds. Computed tomography of the pituitary gland. Springer-Verlag, 1986.

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5

J, De Feyter Pim, ed. Computed tomography of the coronary arteries. Taylor & Francis, 2005.

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6

Wolfgang, Weinrich, ed. Neuroanatomy and cranial computed tomography. Thieme, 1986.

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7

Computed tomography of congenital brain malformations. W.H. Green, 1985.

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8

Blodgett, Todd M. Specialty imaging. Amirsys, 2009.

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9

1945-, Haaga John R., and Alfidi Ralph J. 1932-, eds. Computed tomography of the whole body. 2nd ed. Mosby, 1988.

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10

Kenneth, Miles, Eastwood James D, and König Matthias, eds. Multidetector computed tomography in cerebrovascular disease: CT perfusion imaging. Informa Healthcare, 2007.

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11

T, Lee Joseph K., ed. Computed body tomography with MRI correlation. 3rd ed. Lippincott-Raven, 1998.

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12

1930-, Stanford William, and Rumberger John A, eds. Ultrafast computed tomography in cardiac imaging: Principles and practice. Futura Pub. Co., 1992.

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13

A, Zerhouni Elias, Siegelman Stanley S. 1932-, and Naidich David P, eds. Computed tomography and magnetic resonance of the thorax. 2nd ed. Raven Press, 1991.

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14

Miles, Kenneth. Multi-Detector Computed Tomography in Oncology: CT Perfusion Imaging. Taylor & Francis Ltd., 2007.

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15

1944-, Scott William W., Magid Donna, and Fishman Elliot K, eds. Computed tomography of the musculoskeletal system. Churchill Livingstone, 1987.

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16

L, Van Heertum Ronald, and Tikofsky Ronald S, eds. Cerebral SPECT imaging. 2nd ed. Raven Press, 1995.

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17

Rodriquez, Miriam. Computed tomography, magnetic resonance imaging and positron emission tomography in non-Hodgkin's lymphoma. Munksgaard, 1998.

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18

J, Megibow Alec, and Balthazar Emil J, eds. Computed tomography of the gastrointestinal tract. Mosby, 1986.

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19

K, Fishman Elliot, and Jones Bronwyn, eds. Computed tomography of the gastrointestinal tract. Churchill Livingstone, 1988.

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20

L, Wastie Martin, and Rockall Andrea G, eds. Diagnostic imaging. 5th ed. Blackwell Pub., 2004.

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21

L, Wastie Martin, and Rockall Andrea G, eds. Diagnostic imaging. 6th ed. John Wiley & Sons, 2009.

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22

Peter, Armstrong. Diagnostic imaging. 4th ed. Blackwell Science, 1998.

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23

GeoX, 2010 (2010 New Orleans La ). Advances in computed tomography for geomaterials. ISTE, 2010.

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24

GeoX, 2010 (2010 New Orleans La ). Advances in computed tomography for geomaterials. ISTE, 2010.

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25

von, Schulthess Gustav Konrad, and Schulthess Gustav Konrad von, eds. Clinical molecular anatomic imaging: PET, PET/CT, and SPECT/CT. Lippincott Williams & Wilkins, 2003.

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26

Markus, Schwaiger, ed. Cardiac positron emission tomography. Kluwer Academic, 1996.

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27

1953-, Challa Sudha, and Society of Nuclear Medicine (1953- ), eds. PET tumor imaging. Society of Nuclear Medicine, 1999.

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28

A, Robb Richard, ed. Three-dimensional biomedical imaging. CRC Press, 1985.

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29

Molecular imaging: Radiopharmaceuticals for PET and SPECT. Springer-Verlag, 2009.

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30

Grant, D., J. Husband, and T. Seear. Imaging Protocols in Computed Tomography. Hodder & Stoughton Educational Division, 1992.

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31

Hide, Geoff, and Jennifer Humphries. Computed tomography. Oxford University Press, 2013. http://dx.doi.org/10.1093/med/9780199642489.003.0069.

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Computed tomography (CT), along with its cross-sectional partner MRI, continues to evolve apace. Although MRI retains the larger role in the musculoskeletal system due to its unparalleled soft tissue contrast and, not least, its lack of ionizing radiation, CT offers significant advantages in many areas. Imaging acute trauma is more rapid with CT, allowing 'whole body' assessment of patients following polytrauma, and CT is more useful than MRI in demonstrating the configuration of fractures, aiding surgical planning. CT can clearly identify cortical bone and areas of calcification, making the diagnosis of tarsal coalitions straightforward and facilitating the diagnosis and characterization of bone tumours such as osteoid osteoma and chondroid lesions. CT arthrography supplements standard imaging with intra-articular contrast to allow the detection of subtle joint abnormalities, and CT can demonstrate needles precisely within bone and soft tissue to enable the performance of complex image-guided procedures. Developments in CT have been especially rapid in the past decade and although this has particularly impacted on cardiac imaging, other areas of medicine, including rheumatology, have benefited. High multislice scanners can obtain data for a volume of tissue allowing reconstruction of slices with exceptional detail in any plane, and can rapidly image large areas of the body such as the spine. CT is responsible for a large proportion of the population's medical radiation exposure. Although techniques allowing reduction in dose continue to advance, radiologists and referrers retain responsibility to ensure that requests for CT examinations are necessary and justifiable.
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32

Teoh, Eugene, and Michael Weston. Computed tomography. Edited by Michael Weston. Oxford University Press, 2017. http://dx.doi.org/10.1093/med/9780199659579.003.0133.

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Over the last two decades, the exponential use of CT in the assessment of the urological patient has been fuelled by the advent of multidetector thin slice CT and supersession of intravenous urography by CT urography. The latter may be considered as a one-stop imaging investigation for haematuria, with increased detection of urinary tract cancers and urolithiasis alike. Multi-planar reformats are made possible with the use of thin slices, allowing clear delineation of other pathologies such as urinary tract injury, and can aid PCNL planning. Outside of this spectrum, unenhanced CT of the kidneys, ureters, and bladder has established its role in assessment of the patient with symptoms of renal colic, with the scope to detect pathology outside of the urinary tract. Renal CT has been developed for the characterization of renal masses, accompanied by the now well-established Bosniak renal cyst classification system.
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33

Cumming, Paul. Imaging Dopamine. Cambridge University Press, 2009.

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34

Cumming, Paul. Imaging Dopamine. Cambridge University Press, 2009.

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35

Cumming, Paul. Imaging Dopamine. Cambridge University Press, 2009.

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36

Cumming, Paul. Imaging Dopamine. Cambridge University Press, 2009.

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37

Cumming, Paul. Imaging Dopamine. Cambridge University Press, 2009.

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38

Teoh, Eugene, and Michael J. Weston. Computed tomography. Edited by Christopher G. Winearls. Oxford University Press, 2015. http://dx.doi.org/10.1093/med/9780199592548.003.0014.

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Computed tomography (CT) has increased in use exponentially for the assessment of patients with renal tract pathology. This has been promoted by the availability of multidetector thin-slice CT so that intravenous urography has been superseded by CT urography. The latter may be considered as a ‘one-stop’ imaging investigation for haematuria, with increased detection of both urinary tract cancers and urolithiasis. Multiplanar reformats are made possible with the use of thin slices, allowing clear delineation of other pathologies such as urinary tract injury. In the transplant recipient, protocols have been developed for the assessment of more immediate complications such as thrombotic and stenotic disease. During follow-up, CT continues to inform the management of post-transplant lymphoproliferative disorder and other immunosuppressant-related complications. Unenhanced CT of the urinary tract has established its role in assessment of patients with renal colic, with the ability to detect pathology outside of the urinary tract. Renal CT has been developed for the characterization of renal masses, accompanied by the now well-established Bosniak renal cyst classification system. As the usefulness of CT increases, clear awareness of safety issues has to be maintained. These include the administration of intravenous iodinated contrast medium in higher-risk patient groups, particularly those with renal impairment. The radiation burden that comes with CT poses an added risk to the patient that should not be ignored. This necessitates clear referral guidelines for its use, which should be applied in careful balance with the global assessment of the patient.
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39

Stirrup, James, Michelle Williams, Russell Bull, and Ed Nicol, eds. Cardiovascular Computed Tomography. Oxford University Press, 2019. http://dx.doi.org/10.1093/med/9780198809272.001.0001.

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Recent years have seen a marked increase in cardiovascular computed tomography (CT) imaging, with the technique now integrated into many imaging guidelines, including those published by NICE. Rapid clinical and technological progress has created a need for guidance on the practical aspects of CT image acquisition, analysis, and interpretation. The Oxford Specialist Handbook of Cardiovascular CT, now revised for the second edition by practising international experts with many years of hands-on experience, is designed to fulfil this need. The handbook is a practical guide on performing, analysing, and interpreting cardiovascular CT scans, covering all aspects from patient safety to optimal image acquisition to differential diagnoses of tricky images. The format is designed to be accessible and is laid out in easy to navigate sections. It is meant as a quick-reference guide, to live near the CT scanner, workstation, or on the office shelf.
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40

Hayashi, Daichi, Ali Guermazi, and Frank W. Roemer. Radiography and computed tomography imaging of osteoarthritis. Oxford University Press, 2016. http://dx.doi.org/10.1093/med/9780199668847.003.0016.

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Osteoarthritis (OA) is the most prevalent joint disorder in the elderly worldwide and there is still no effective treatment, other than joint arthroplasty for end-stage OA, despite ongoing research efforts. Imaging is essential for assessing structural joint damage and disease progression. Radiography is the most widely used first-line imaging modality for structural OA evaluation. Its inherent limitations should be noted including lack of ability to directly visualize most OA-related pathological features in and around the joint, lack of sensitivity to longitudinal change and missing specificity of joint space narrowing, and technical difficulties regarding reproducibility of positioning of the joints in longitudinal studies. Magnetic resonance imaging (MRI) is widely applied in epidemiological studies and clinical trials. Computed tomography (CT) is an important additional tool that offers insight into high-resolution bony anatomical details and allows three-dimensional post-processing of imaging data, which is of particular importance for orthopaedic surgery planning. However, its major disadvantage is limitations in the assessment of soft tissue structures compared to MRI. CT arthrography can be useful in evaluation of focal cartilage defects or meniscal tears; however, its applicability may be limited due to its invasive nature. This chapter describes the roles and limitations of both conventional radiography and CT, including CT arthrography, in clinical practice and OA research. The emphasis is on OA of the knee, but other joints are also mentioned where appropriate.
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41

E, Clouse Melvin, and Wallace Sidney 1929-, eds. Lymphatic imaging: Lymphography, computed tomography, and scintigraphy. 2nd ed. William & Wilkins, 1985.

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42

T, Lee Joseph K., Sagel Stuart S. 1940-, and Stanley Robert J. 1937-, eds. Computed body tomography with MRI correlation. 2nd ed. Raven Press, 1989.

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43

Carter, Deborah. Computed Tomography: Advances in Research and Applications. Nova Science Publishers, Incorporated, 2017.

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44

Malajikian, Krikor, and Daniel Finelli. Basics of Computed Tomography. Oxford University Press, 2016. http://dx.doi.org/10.1093/med/9780199908004.003.0003.

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Computed tomography (CT)-guidance is typically used when precise needle placement is essential for a successful procedure. It uses ionizing radiation, which could pose risks to the patient and operating staff if proper technique is not used. The performing physician should adhere to all principles of minimizing radiation exposure to the patient and clinicians. Common CT-guided imaging procedures include facet injections, nerve root injections, sacroiliac joint injections, intradiscal procedures, vertebroplasty/sacroplasty, and image-guided ablation of painful bone lesions. Computed tomography is also the imaging modality of choice for aspiration of deep paraspinal soft tissues in addition to disc space or bone biopsy in acute discitis/osteomyelitis. In fluoroscopic-guided knee or shoulder joint injections, CT arthrography is a useful adjunct to better assess anatomy when MRI is contraindicated. When imaging the postoperative spine, CT myelography has some advantages over MRI, and CT is also superior to MRI in assessing par intra-articularis defects or spondylolysis.
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45

Molecular Anatomic Imaging. Lippincott Williams & Wilkins, 2015.

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46

3D Computed Tomography Virtual Intravascular Endoscopy. Nova Science Publishers Inc, 2013.

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47

Computed Tomography of the Body With Magnetic Resonance Imaging: Thorax and Neck (Computed Tomography of the Body). 2nd ed. W.B. Saunders Company, 1992.

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48

Zülch, K. J. Cerebral Infarct: Pathology, Pathogenesis, and Computed Tomography. Springer, 2011.

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49

Zülch, K. J. Cerebral Infarct: Pathology, Pathogenesis, and Computed Tomography. Springer London, Limited, 2012.

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50

Gamsu, Gordon, Harry K. Genant, and Albert A. Moss. Computed Tomography of the Body: Abdomen, Volume 3 (Computed Tomography of the Body). 2nd ed. Saunders, 1991.

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