PET in the Evaluation of Alzheimer's Disease and Related Disorders

Part I Imaging Applications in Current Clinical Practice

• 1 Clinical Evaluation of Dementia and When to Perform PET.
• 2 Clinical Interpretation of Brain PET Scans: Performing Visual Assessments, Providing Quantifying Data, and Generating Integrated Reports.
• 3 FDG PET in the Evaluation of Mild Cognitive Impairment and Early Dementia.
• 4 PET and SPECT in the Evaluation of Patients with Central Motor Disorders.

Part II Emerging Approaches Using PET.

• 5 Microstructural Imaging of Neurodegenerative Changes.
• 6 Amyloid Imaging with PET in Alzheimer’s Disease, Mild Cognitive Impairment, and Clinically Unimpaired Subjects.

Part III Atlas.

• 7 Interpretive Practice Atlas.

Index.

Among all the clinical indications for which radiologists, nuclear medicine physicians, neurologists, neurosurgeons, psychiatrists (and others examining disorders of the brain) order and read brain PET scans, demand is greatest for those pertaining to dementia and related disorders. This demand is driven by the sheer prevalence of those conditions, coupled with the fact that the differential diagnosis for causes of cognitive impairment is wide and often difficult to distinguish clinically. The conceptual framework by which evaluation and management of dementia is guided has evolved considerably during the last decade. Although we still are far from having ideal tests or dramatic cures for any of the established causes of dementia, our options have expanded with respect to both the diagnostic and therapeutic tools now available. In the first chapter of this book, the contribution and limitations of different elements of the clinical examination for diagnosis of cognitive symptoms are described, and the roles of structural and functional neuroimaging in the clinical workup are given context.

The clinical utility of brain positron emission tomography (PET), as with other imaging modalities, depends in part on how accurately and fully the information inherently represented in the scans is appreciated and relayed in the interpretation of the images. Even highly trained imaging specialists are challenged by this since, for example, neuroradiologists are generally far more familiar with computed tomography (CT) and magnetic resonance (MR) studies of the brain than with PET studies, and specialists in PET and PET/CT facilities tend to be much more experienced with oncology studies than with dedicated brain studies performed for the evaluation of neurologic disorders. To help meet this challenge, the second chapter offers practical instruction on adopting a systematic method for visual analysis of scans, describes how quantification with clinically available and friendly software tools can be employed to assist with analysis, and then illustrates a straightforward approach for integrating the qualitative and quantitative findings in meaningful interpretations. An Atlas in the final section of this book complements Chapter 2 by providing interpretive practice for many real (and clinically realistic) cases, to which the tools outlined in the second chapter can be directly applied.

The most frequent causes of dementia are neurodegenerative disorders, with Alzheimer’s disease being the most common. By the time patients are symptomatic with these disorders, they have undergone significant distinct alterations in brain metabolism. The increasing use of brain PET stems from the high sensitivity of this imaging tool in identifying those alterations. The third chapter looks at the full spectrum of changes in glucose metabolism detectable with PET in monitoring the course of cognitive decline, beginning before the emergence of the first neurologic symptoms, in people who are predisposed to developing problems, in some cases many years into the future. Progressive changes observed with PET in the brains of patients who experience very mild symptoms, to those who meet criteria for having mild cognitive impairment, to those suffering from full-blown dementia, are described, as is the role of PET in the differential diagnosis of the underlying cause for the dysfunction. 

Neurodegenerative diseases often impact not only on cognitive function, but also on motor function. The two neurologic domains can be affected in isolation, but frequently a mixed presentation of symptoms occurs. For example, approximately one third of Alzheimer’s patients eventually experience parkinsonian symptoms and, conversely, a similar proportion of patients with Parkinson’s disease develop significant cognitive impairment. Other conditions, such as dementia with Lewy bodies, may be characterized at an early stage by both motor and cognitive problems. Chapter 4 examines neuronuclear imaging studies explicitly aimed at illuminating changes in the brain associated with movement disorders. Their potential utility with respect to drug development, as well as in direct clinical application, is explained. 

Although the most commonly performed clinical PET studies by far are carried out with [18F]fluorodeoxyglucose (FDG) as the imaged radiotracer, substantial advances have occurred in the development of other radiotracers with which to probe brain processes associated with neurodegenerative disease. Chapter 5 describes work that is making it possible to observe and measure the molecular participants of such processes as they accumulate, or are lost from, living brain tissue. In the setting of Alzheimer-related changes, one molecular participant in particular, the ?-amyloid of extracellular plaques constituting one of the histopathologic hallmarks of Alzheimer’s disease, has attracted substantial attention in both industry and academic scientific settings. Following the introduction of this area of investigation in the fifth chapter, Chapter 6 is devoted to expanding on the scientific implications and clinical potential of radiotracers being developed to localize and measure ?-amyloid deposits occurring in the brain. In the latter chapter, particular attention is given to characterizing ?-amyloid deposition in older people who would not be considered cognitively impaired by standard clinical criteria.

PET scans, particularly with FDG, have demonstrated diagnostic and prognostic utility in evaluating patients with cognitive impairment and in distinguishing among primary neurodegenerative disorders and other etiologies for cognitive decline. Since the diagnostic capabilities of this medical technology have outpaced therapeutic advances, a look into the future of PET requires concomitant consideration of the future of therapeutic strategies for addressing the underlying conditions. As preventive and specific disease-modifying treatments are developed, early detection of accurately diagnosed neuropathologic processes, facilitated by appropriate use of PET and other neuroimaging technologies, can be expected to increasingly impact on the enormous human toll currently exacted by these disorders.

Book Details

• Hardcover: 229 pages
• Publisher: Springer; 1 edition (April 1, 2009)
• Language: English
• ISBN-10: 0387764194
• ISBN-13: 978-0387764191
• Product Dimensions: 9.4 x 6.2 x 0.6 inches

List Price: $149.00 

 

Kramer: Positron Emission Tomography Computed Tomography: A Disease-Oriented Approach

PET/CT epitomizes a marriage made in imaging heaven. The ability of PET to image cellular metabolism combined with the anatomic detail of CT represents a transformational approach to imaging neoplasia and other diseases. The task of PET/CT image interpretation is also challenging. This stems from the need to be highly skilled in both nuclear medicine and body/brain imaging. The impact of this technology hasbeen enormous in cancer, Alzheimer’s disease, and epilepsy; now representing an integral component of the standard workup and management of these patients.
This book aims to provide a thorough understanding of the technical demands involved in combining CT and FDG PET: patient preparation, acquisition techniques including potential pitfalls and limitations, and the basics of instrumentation and physics needed for developing cogent technical approaches. Technical advances and controversies including the use of CT contrast and, when clinically relevant, newer radiopharmaceuticals (beyond the most clinically available 18F-2-deoxy-fluoro-D-glucose or FDG) are addressed briefly.

Molecular Imaging: Radiopharmaceuticals for PET and SPECT

Radioisotope-based molecular imaging probes provide unprecedented insight into biochemistry and function involved in both normal and disease states of living systems, with unbiased in vivo measurement of regional radiotracer activities offering very high specificity and sensitivity. No other molecular imaging technology including functional magnetic resonance imaging (fMRI) can provide such high sensitivity and specificity at a tracer level. The applications of this technology can be very broad ranging from drug development, pharmacokinetics, clinical investigations, and finally to routine diagnostics in radiology. The design and the development of radiopharmaceuticals for molecular imaging studies using PET/MicroPET or SPECT/MicroSPECT are a unique challenge.
This book is intended for a broad audience and written with the main purpose of educating the reader on various aspects including potential clinical utility, limitations of drug development, and regulatory compliance and approvals.

PET-CT Beyond FDG: A Quick Guide to Image Interpretation

At present, more than 95% of PET studies worldwide are performed in oncologic patients, using F-18 Fluorodeoxyglucose (FDG). But, despite its high diagnostic accuracy in determining the pivotal role in the restaging (and staging) of the neoplasm, FDG is handicapped by false negative and positive results, creating limitations in the differential diagnosis of cancer. Moreover, PET-FDG shares with all the other diagnostic techniques the inability to answer all the questions of the oncologist, the surgeon, and the radiotherapist. It cannot function alone, either in the diagnostic field, or in giving all the information connected with prognosis and pursue a “tailored strategy” for each patient. Therefore, despite its primary role, there is a wide range of indications in oncologic patients that other radiotracers may be useful.
Although [¹⁸F]fluorodeoxyglucose (FDG) generally shows an excellent performance as a cancer-imaging agent when using PET-CT, there are some settings in which other radiopharmaceuticals offer advantages. Such non-FDG tracers are now gaining widespread acceptance not only in research but also in clinical practice.

Hybrid PET-CT and SPECT-CT Imaging: A Teaching File

With clinical cases related to multiple clinical entities presented in depth, Hybrid PET-CT and SPECT-CT Imaging: A Teaching File by Dominique Delbeke and Ora Israel is designed to be a teaching manual and everyday companion for our colleagues working in private practice, for residents training in nuclear medicine or radiology, for medical students, and for physicians whose specialties carry over into molecular imaging with radiopharmaceuticals.
The first two chapters cover the technical aspects of hybrid imaging and a historical perspective of the development of this technology. Recommendations for patient preparation and acquisition protocols, with special emphasis on physiologic variants, pitfalls, and artifacts follow. The next 15 chapters are devoted to clinical applications in oncology, according to specific malignant diseases and patient populations. The final three chapters present relatively new clinical applications of hybrid imaging in the field of cardiology, skeletal, and infectious diseases.
Each chapter begins with a succinct summary of the recent literature for the specific clinical application. This is followed by a series of case presentations ranging from the simple to the more complex in an attempt to simulate clinical practice. Images are presented in PET/SPECT stand-alone, CT stand-alone, and fused-images format in order to highlight the advantages and incremental value of the hybrid technology in the cases selected. At the end of each chapter, up-to-date references allow the reader to follow in greater depth the rapidly expanding volume of knowledge.
Contents 
Part I General
I.1 History and Principles of Hybrid Imaging
I.2 Normal Distribution, Variants, Pitfalls, and Artifacts
Part II Clinical Applications in Oncology
II.1 Tumors of the Central Nervous System
II.2 Hybrid Imaging of Head and Neck Malignancies
II.3 Lung Cancer
II.4 Breast Cancer
II.5 Colorectal Cancer
II.6 18F-FDG PET/CT in Tumors of the Gastrointestinal Tract: Esophageal and Gastric Cancer and Gastrointestinal Stromal Tumors (GIST)
II.7 Hepatobiliary and Pancreatic Malignancies
II.8 Gynecological Tumors
II.9 Hybrid Imaging in Malignancies of the Urinary Tract, Prostate, and Testicular Cancers
II.10 Thyroid Cancer
II.11 Endocrine Tumors
II.12 Lymphoma
II.13 Melanoma
II.14 Malignancy of the Bone: Primary Tumors, Lymphoma, and Skeletal Metastases
II.15 Pediatric Applications for PET/CT and SPECT/CT
Part III Other Clinical Applications
III.1 Cardiac Hybrid Imaging (PET/CT and SPECT/CT): Assessment of CAD
III.2 Hybrid Imaging of Benign Skeletal Diseases
III.3 Infectious and Inflammatory Diseases
Subject Index 

Product Details

• Hardcover: 762 pages
• Publisher: Springer; 1st  edition (November 23, 2009)
• Language: English
• ISBN-10: 0387928197
• ISBN-13: 978-0387928197
• Product Dimensions: 10.1 x 6.9 x 1.5 inches

Basics of PET Imaging - Physics, Chemistry, and Regulations 2nd Edition (Springer) 2010

Since the publication of this book in 2005, the growth of positron emission tomography (PET) and PET/CT modality has been phenomenal with the discovery of efficient detectors and the addition of sophisticated scanners and powerful software. Because of the vast advancement and changes in technology, and also with great appreciation of the success of the first edition, the author thought a second edition of the book would be appropriate.
The book is revised to again fulfill the needs of nuclear medicine professionals such as physicians, technologists, and residents, along with students for their board examination and training. The contents of the book have been kept at the basic level as was in the first edition.
The organization of the book essentially has remained the same. Some chapters have been revised very extensively, while others have only minor changes. No change has been made in Chap. 1 as it is based on basic physics. Extensive revision has been made in Chaps. 2 and 3 to include up-to-date information on detectors, scanners, and data collection. Chapter 4 in the original edition has been divided into Chaps. 4 and 5 to allow for a separate chapter on “Storage, Display, and PACS.” Chapter 6 has been updated with new information on NEMA standards on acceptance tests of PET scanners. New PET radionuclides and the list of current available cyclotrons have been added to Chap. 7. Chapter 8 includes a section on Compounding of PET Radiopharmaceuticals, in addition to several new PET radiopharmaceuticals. New regulations concerning the use of PET radiopharmaceuticals, the licensing of physicians and technologists, and the accreditation of PET facilities to be eligible for reimbursement for PET procedures are all included in Chap. 9. Chapter 10 has been revised, focusing on the issues of current reimbursement issues for PET studies. Only minor changes have been made in Chaps. 11 and 12 to include up-to-date information. Questions have been added at the end of each chapter, as appropriate, to reflect the changes in contents.

Contents:
1. Radioactive Decay and Interaction of Radiation with Matter
2. PET Scanning Systems
3. Data Acquisition and Corrections
4. Image Reconstruction
5. Storage, Display, and PACS
6. Performance Characteristics of PET Scanners
7. Cyclotron and Production of PET Radionuclides
8. Synthesis of PET Radiopharmaceuticals
9. Regulations Governing PET Radiopharmaceuticals
10. Reimbursement for PET Procedures
11. Design and Cost of PET Center
12. Procedures for PET Studies
Appendix A. Abbreviations Used in the Text
Appendix B. Terms Used in the Text
Appendix C. Units and Constants
Appendix D. Estimated Absorbed Doses from Intravenous Administration of 18F-FDG and 82Rb-RbCl
Appendix E. Evaluation of Tumor Uptake of 18F-FDG by PET
Appendix F. Answers to Selected Questions
Index

Product Details

• Hardcover: 314 pages
• Publisher: Springer; 2nd edition (March 15, 2010)
• Language: English
• ISBN-10: 1441908048
• ISBN-13: 978-1441908049
• Product Dimensions: 9.2 x 6.1 x 0.8 inches

Patient Preparation for PET Imaging

Patients are instructed to fast for at least 4 hours before the PET appointment. Glucose containing drinks and intravenous (IV) glucose must be avoided at least 4 hours before FDG injection as well. The fasting state lowers the serum glucose level so that FDG has less competition for uptake by the tumor. Muscle uptake is also minimized by fasting through lowering the serum insulin level. Low FDG uptake in the muscles improves the tumor to background ratio and the image quality. 

High glucose level in diabetic patients can also decrease the image quality. It is well known that high glucose level decreases the tumor intensity on FDG PET and that lesions might be missed. However, while a normal glucose level in diabetic patients before FDG injection is desirable, it often cannot be achieved. Therefore, from a practical stand point, it may be reasonable to perform the scan even with a high glucose level and interpret the findings. Should the images be “diagnostic enough,” and, for instance, the patient be upstaged, the low quality of images may not matter. A repeat scan should be considered, when a false-negative scan is suspected (for example, rising CA-125 in a patient with ovarian cancer, high glucose level, and negative FDG PET). 

Mettler Essentials of Nuclear Medicine Imaging 5th edition

• Ch. 1 Radioactivity, Radionuclides, and Radiopharmaceuticals.
• Ch. 2 Instrumentation.
• Ch. 3 Quality Control.
• Ch. 4 Cerebrovascular System.
• Ch. 5 Thyroid, Parathyroid, and Salivary Glands.
• Ch. 6 Cardiovascular System.
• Ch. 7 Respiratory System.
• Ch. 8 Gastrointestinal Tract. .
• Ch. 9 Skeletal System.
• Ch. 10 Genitourinary System and Adrenal Glands.
• Ch. 11 Conventional Neoplasm Imaging and Radioimmunotherapy.
• Ch. 12 Genitourinary System.
• Ch. 13 Inflammation and Infection Imaging.
• Ch. 14 Legal Requirements and Radiation Safety.
• Self Evaluation Section.
• Unknown Case Sets.
• Answers to Unknown Case Sets.

Appendices.

• A. Characteristics of Radionuclides for Imaging Therapy.
• B-1. Radioactivity Conversion Table for International System (SI) Units (Becquerels to Curies).
• B-2. Radioactivity Conversion Table for International System (SI) Units (Curies to Becquerels).
• C-1. Technetium 99m Decay and Generation Tables.
• C-2. Iodine 131 and Strontium 89 Decay Charts.
• D. Injection Techniques and Pediatric Dosage.
• E. Sample Techniques for Nuclear Imaging.
• F. Non-radioactive Pharmaceuticals in Nuclear Medicine.
• G. Pregnancy and Breastfeeding.
• H-1. General Considerations for Patients Receiving Radionuclide Therapy.
• H-2. Special Considerations and Requirements for Iodine 131 Therapy.
• I. Emergency Procedures for Radioactive Spills.

Index.

Essentials of Nuclear Medicine Imaging 5th edition by Fred A. Mettler and Milton J. Guiberteau has established itself as the best introduction to nuclear imaging techniques. It is practical, yet comprehensive, covering physics, instrumentation, quality control, and legal requirements. The 5th Edition features a new color format, with many user-friendly features such as "Pearls and Pitfalls." More than 600 pictures in digital-quality resolution depict imaging of each body system. A series of Unknown Case Sets, with answers, help test your knowledge.


Book features:

• Includes helpful appendices including Injection Techniques, Pediatric Dosages, Non-radioactive Pharmaceuticals, and many more.
• Presents important "Pearls and Pitfalls" in each chapter.

New in this edition:

• Features a new full-color format making information easy to read and find.
• Covers new techniques such as PET/CT, cardiac-gated SPECT, and tumor-specific radionuclides.
• Provides full-chapter coverage of hot topics such as:
• Cerebrovascular System.
• Cardiovascular System.
• Conventional Neoplasm Imaging and Radioimmunotherapy.
• Positron Emission Tomography Imaging.
• Includes seven complete Unknown Case Sets for self-testing.

About the Authors

• Fred A. Mettler, Jr., MD, MPH, Professor and Chair, Department of Radiology and Nuclear Medicine, University of New Mexico Health Sciences Center, Albuquerque, NM. 
• Milton J. Guiberteau, MD, Professor of Clinical Radiology, University of Texas Medical School at Houston; Chairman, Department of Radiology, St. Joseph's Hospital, Houston, TX.

Book Details

• Hardcover: 592 pages
• Publisher: Saunders; 5 edition (November 23, 2005)
• Language: English
• ISBN-10: 0721602010
• ISBN-13: 9780721602011
• Product Dimensions: 10 x 8 x 0.8 inches

List Price: $106.00