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Books on the topic 'Lungs Cancer Imaging'

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Author: Grafiati
Published: 10 December 2022
Last updated: 28 January 2023

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1

Ravenel, James G., ed. Lung Cancer Imaging. New York, NY: Springer New York, 2013. http://dx.doi.org/10.1007/978-1-60761-620-7.

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2

1948-, Müller Nestor Luiz, and Naidich David P, eds. High-resolution CT of the lung. 2nd ed. Philadelphia: Lippincott-Raven, 1996.

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3

1948-, Müller Nestor Luiz, and Naidich David P, eds. High-resolution CT of the lung. New York: Raven Press, 1992.

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4

1948-, Müller Nestor Luiz, and Naidich David P, eds. High-resolution CT of the lung. 3rd ed. Philadelphia: Lippincott Williams & Wilkins, 2001.

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5

1948-, Müller Nestor Luiz, and Naidich David P, eds. High-resolution CT of the lung. 4th ed. Philadelphia: Wolters Kluwer/Lippincott Williams & Wilkins Health, 2008.

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6

Medical tests sourcebook: Basic consumer health information about preventive care guidelines, routine health screenings, home-use tests, blood, stool, and urine tests, genetic testing, biopsies, endoscopic exams, and imaging tests, such as X-ray, ultrasound, computed tomography (ct), and nuclear and magnetic resonance imaging (MRI) exams; along with facts about diagnostic tests for allergies, cancer, diabetes, heart and lung disease, infertility, osteoporosis, sleep problems, and other specific conditions, a glossary of related terms, and directories of additional resources. 4th ed. Detroit, MI: Omnigraphics, 2011.

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7

Medical tests sourcebook: Basic consumer health information about preventive care guidelines, routine health screenings, home-use tests, blood, stool, and urine tests, genetic testing, biopsies, endoscopic exams, and imaging tests, such as X-ray, ultrasound, computed tomography (CT), and nuclear and magnetic resonance imaging (MRI) exams; along with facts about diagnostic tests for allergies, cancer, diabetes, heart and lung disease, infertility, osteoporosis, sleep problems, and other specific conditions, a glossary of related terms, and directories of additional resources. Detroit, MI: Omnigraphics, Inc., 2015.

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8

Ravenel, James G. Lung Cancer Imaging. Humana, 2016.

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9

Ravenel, James G. Lung Cancer Imaging. Humana, 2013.

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10

Ravenel, James G. Lung Cancer Imaging. Humana Press, 2013.

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11

Cancer Imaging, Volume 1: Lung and Breast Carcinomas (Cancer Imaging) (Cancer Imaging). Academic Press, 2007.

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12

Imaging Of Lung Cancer. W.B. Saunders Company, 2012.

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13

Lynch, David A. Chest Imaging. Elsevier - Health Sciences Division, 2015.

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14

Hayat, M. A. Cancer Imaging, Volume 1-2. Academic Press, 2007.

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15

Suri, Jasjit, and Ayman El-Baz. Lung Imaging and Cadx Two Volume Set. Taylor & Francis Group, 2019.

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16

Board on Health Care Services, National Cancer Policy Forum, Sharyl J. Nass, National Academies of Sciences, Engineering, and Medicine, and Health and Medicine Division. Implementation of Lung Cancer Screening: Proceedings of a Workshop. National Academies Press, 2017.

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17

Board on Health Care Services, National Cancer Policy Forum, Sharyl J. Nass, National Academies of Sciences, Engineering, and Medicine, and Health and Medicine Division. Implementation of Lung Cancer Screening: Proceedings of a Workshop. National Academies Press, 2017.

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18

Board on Health Care Services, National Cancer Policy Forum, Sharyl J. Nass, National Academies of Sciences, Engineering, and Medicine, and Health and Medicine Division. Implementation of Lung Cancer Screening: Proceedings of a Workshop. National Academies Press, 2017.

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19

Agrawal, Archi, and Venkatesh Rangarajan. PET/CT in Lung Cancer. Springer International Publishing AG, 2018.

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20

Diagnosis and Staging of Lung Cancer: A Minimally Invasive Approach. McGraw-Hill Education, 2013.

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21

Quantitative imaging tools for lung cancer drug assessment. Hoboken, NJ: John Wiley & Sons, 2008.

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22

Desai, Sujal R., David M. Hansell, Susan J. Copley, and Zelena A. Aziz. Thoracic Imaging. Oxford University Press, 2012.

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23

Hansell, David M., Sue Copley, and Jeffrey P. Kanne. Thoracic Imaging. Taylor & Francis Group, 2014.

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24

Hansell, David M., Sue Copley, and Nestor L. Müller. Thoracic Imaging. Taylor & Francis Group, 2005.

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25

1940-, Hayat M. A., ed. Lung and breast carcinomas. Amsterdam: Elsevier, Academic Press, 2008.

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26

Baer, Thomas M., ed. Cancer Research and Prevention Monograph / Edition 1. Wiley, John & Sons, Incorporated, 2008.

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27

(Foreword), L. W. Brady, H. P. Heilmann (Foreword), M. Molls (Foreword), and Branislav Jeremic (Editor), eds. Advances in Radiation Oncology in Lung Cancer (Medical Radiology / Radiation Oncology). Springer, 2005.

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28

EL-BAZ, Suri. Lung Cancer and Imaging. Institute of Physics Publishing, 2019.

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29

Desai, Sujal R. Lung Cancer (Contemporary Issues in Cancer Imaging). Cambridge University Press, 2007.

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30

Hayat, M. A. Cancer Imaging: Lung and Breast Carcinomas. Elsevier Science & Technology Books, 2007.

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31

Suri, Jasjit S., and Ayman El-Baz. Detection Systems in Lung Cancer and Imaging. Institute of Physics Publishing, 2021.

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32

El-Baz, Ayman, and Jasjit S. Suri. Detection Systems in Lung Cancer and Imaging. Iop Publishing Ltd, 2021.

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33

Malik, Tariq M. Back Pain: It’s Not Always Arthritis. Oxford University Press, 2018. http://dx.doi.org/10.1093/med/9780190271787.003.0029.

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Back pain is prevalent in adults, and most often its cause is nonspecific and benign. Imaging and interventions are not always helpful and they are generally expensive and low yield. However, in about 10% or fewer cases, a specific etiology is found. A patient history, physical examination, and testing are the methods for finding the cause. Back pain from malignancy must also be considered. Prolonged survival from better chemotherapy has increased the incidence of metastases to bone, especially the spine. Common sources of spinal metastases are cancers of the prostate, kidneys, thyroid, breast, and lungs. The primary treatment is to address the malignancy. Pain from spinal tumors can be treated with chemotherapy, radiotherapy, radiofrequency, or vertebral augmentation therapy. The chapter reviews the epidemiology of spinal cancer pain, evaluation of malignant spinal pain, and what the interventional pain physician can offer patients to alleviate their pain.
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34

Pinheiro dos Santos, Wellington, Juliana Carneiro Gomes, Maíra Araújo de Santana, and Valter Augusto de Freitas Barbosa, eds. Intelligent Diagnosis of Lung Cancer and Respiratory Diseases. BENTHAM SCIENCE PUBLISHERS, 2022. http://dx.doi.org/10.2174/97898150505091220101.

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Intelligent Diagnosis of Lung Cancer and Respiratory Diseases presents information about diseases of the respiratory system and the relevant diagnostic imaging techniques. The book focuses on intelligent diagnostic imaging systems. The first section of the book deals with the physiological underpinnings of 3 major diseases that affect the respiratory system: tuberculosis, lung cancer and COVID-19. This section also explains the basic principles of artificial Intelligence that support the diagnosis of these diseases. The next section presents applications of intelligent systems to support the imaging diagnosis of COVID-19 and lung cancer, with emphasis on digital health and telemedicine approaches. Each chapter is organized into a readable format, and is accompanied with a detailed bibliographical information for further reading. This book is a reference for everyone seeking to understand how artificial intelligence can provide solutions for diagnostic support systems by processing and analyzing radiological images to improve early diagnosis and, consequently, lung disease prognosis.
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35

Lee, Christoph I. Chest Radiograph Screening for Lung Cancer. Oxford University Press, 2016. http://dx.doi.org/10.1093/med/9780190223700.003.0043.

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This chapter, found in the cancer screening and management section of the book, provides a succinct synopsis of a key study examining the efficacy of chest radiography for screening for lung cancer. This summary outlines the study methodology and design, major results, limitations and criticisms, related studies and additional information, and clinical implications. Researchers reported that annual chest radiograph screening over a 4-year period did not decrease lung cancer mortality compared with usual care after 13 years of follow-up, and that chest x-rays are not an effective screening test for lung cancer. In addition to outlining the most salient features of the study, a clinical vignette and imaging example are included in order to provide relevant clinical context.
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36

Lee, Christoph I. Low-Dose CT Screening for Lung Cancer. Oxford University Press, 2016. http://dx.doi.org/10.1093/med/9780190223700.003.0044.

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This chapter, found in the cancer screening and management section of the book, provides a succinct synopsis of a key study examining the efficacy of low-dose computed tomography screening for lung cancer. This summary outlines the study methodology and design, major results, limitations and criticisms, related studies and additional information, and clinical implications. The study showed that annual low-dose CT screening among high-risk individuals decreases lung cancer mortality. While the rate of false positives was nearly 3 times higher for those screened by low-dose CT compared to chest radiography, complications from invasive diagnostic evaluation after positive screens were rare. In addition to outlining the most salient features of the study, a clinical vignette and imaging example are included in order to provide relevant clinical context.
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37

Cassidy, Jim, Donald Bissett, Roy A. J. Spence OBE, Roy A. J. Spence OBE, Miranda Payne, and Gareth Morris-Stiff. Biomarkers and cancer. Oxford University Press, 2018. http://dx.doi.org/10.1093/med/9780199689842.003.0040.

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Biomarkers and cancer defines these markers and outlines their role in diagnosis, prognosis, prediction of response, and response assessment of a variety of cancers. Established biomarkers are reviewed, and the potential for development of new biomarkers offered by the dramatic progress in both the understanding of molecular biology and the development of laboratory techniques is emphasised. The field of signal transduction has already proved fruitful, with identification of markers allowing successful targeted therapy in a range of cancers. Progress is anticipated also in tumour imaging, with developments in both MRI and PET. Areas of clinical interest are summarised for breast, lung, colorectal, renal, and CNS malignancies.
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38

Naidich, David P., Nestor L Müller, and W. Richard Webb. High-Resolution CT of the Lung. 3rd ed. Lippincott Williams & Wilkins, 2000.

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39

Lee, Christoph I. Management of Lung Nodules Detected by CT. Oxford University Press, 2016. http://dx.doi.org/10.1093/med/9780190223700.003.0045.

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This chapter, found in the cancer screening and management section of the book, provides a succinct synopsis of a key study examining the management of lung nodules detected by computed tomography and their risk of developing into lung cancer. This summary outlines the study methodology and design, major results, limitations and criticisms, related studies and additional information, and clinical implications. Virtual colonoscopy, using a primary 3D approach for polyp detection, was shown to be a minimally invasive procedure that is an accurate method for screening average-risk individuals. The likelihood of a clinically significant adenoma being missed on virtual colonoscopy was extremely low given the high negative predictive value. In addition to outlining the most salient features of the study, a clinical vignette and imaging example are included in order to provide relevant clinical context.
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40

GonzÁlez, Amy Berrington de, André Bouville, Preetha Rajaraman, and Mary Schubauer-Berigan. Ionizing Radiation. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780190238667.003.0013.

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Ionizing radiation is a universal carcinogen due to its ability to induce cancer in most organs following exposure at any age, including in utero. Several organs are especially radiosensitive, particularly when exposure occurs in childhood. These include the female breast, thyroid, brain, and red bone marrow. Very few cancers, notably cervical and Hodgkin lymphoma, do not seem to be related to ionizing radiation, for unknown reasons. For most cancers (lung may be the exception) the relative risk decreases with attained age and time since exposure. Currently the main sources of radiation exposure to the general population involve very low-dose (<50 mGy) natural background exposure (including residential radon) and medical exposures, such as computed tomography (CT) scans. Natural background exposure varies by location but is generally stable over time. Medical exposure has been increasing in many countries due to the expanded use of advanced imaging technologies.
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41

Hoyles, Rachel K., and Athol U. Wells. Respiratory system. Oxford University Press, 2013. http://dx.doi.org/10.1093/med/9780199642489.003.0020.

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Pulmonary involvement is common in the connective tissue diseases (CTDs) and is associated with significant morbidity and mortality. Improved management of systemic disease has led to increasing numbers of surviving patients with clinically significant pulmonary disease. Screening for pulmonary complications highlights the frequency of subclinical involvement. In this chapter, the pulmonary manifestations of the more common CTDs are detailed, including rheumatoid arthritis (RA), systemic sclerosis (SSc), systemic lupus erythematosus (SLE), polymyositis/dermatomyositis (PM/DM), Sjögren's syndrome (SS), and, more briefly, ankylosing spondylitis (AS). A broad spectrum of pulmonary disorders are seen in association with the CTDs or the drugs used to treat the underlying disorder, including interstitial lung disease, pulmonary infections, airways disease, pulmonary nodules, pleural disease, chest wall pathology and pulmonary vascular disease; the discussion is stratified by pulmonary complication. In many cases, two or more pulmonary manifestations of CTD coexist or there are other concurrent diseases such as asthma and lung cancer, resulting in potentially confusing mixed imaging and pulmonary function abnormalities. This chapter presents a comprehensive approach to the investigation, screening, prognostic evaluation, and treatment decisions in pulmonary disease associated with the CTDs.
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42

Al-Nahhas, Adil, and Imene Zerizer. Nuclear medicine. Oxford University Press, 2013. http://dx.doi.org/10.1093/med/9780199642489.003.0070.

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The application of nuclear medicine techniques in the diagnosis and management of rheumatological conditions relies on its ability to detect physiological and pathological changes in vivo, usually at an earlier stage compared to structural changes visualized on conventional imaging. These techniques are based on the in-vivo administration of a gamma-emitting radionuclide whose distribution can be monitored externally using a gamma camera. To guide a radionuclide to the area of interest, it is usually bound to a chemical label to form a 'radiopharmaceutical'. There are hundreds of radiopharmaceuticals in clinical use with different 'homing' mechanisms, such as 99 mTc HDP for bone scan and 99 mTc MAA for lung scan. Comparing pre- and posttherapy scans can aid in monitoring response to treatment. More recently, positron emission tomography combined with simultaneous computed tomography (PET/CT) has been introduced into clinical practice. This technique provides superb spatial resolution and anatomical localization compared to gamma-camera imaging. The most widely used PET radiopharmaceutical, flurodeoxyglucose (18F-FDG), is a fluorinated glucose analogue, which can detect hypermetabolism and has therefore been used in imaging and monitoring response to treatment of a variety of cancers as well as inflammatory conditions such as vasculitis, myopathy, and arthritides. Other PET radiopharmaceuticals targeting inflammation and activated macrophages are becoming available and could open new frontiers in PET imaging in rheumatology. Nuclear medicine procedures can also be used therapeutically. Beta-emitting radiopharmaceuticals, such as yttrium-90, invoke localized tissue damage at the site of injection and can be used in the treatment of synovitis.
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