Description
A must-read for anyone working in electronics in the healthcare sector This one-of-a-kind book addresses state-of-the-art integrated circuit design in the context of medical imaging of the human body. It explores new opportunities in ultrasound, computed tomography (CT), magnetic resonance imaging (MRI), nuclear medicine (PET, SPECT), emerging detector technologies, circuit design techniques, new materials, and innovative system approaches. Divided into four clear parts and with contributions from a panel of international experts, Medical Imaging systematically covers: * X-ray imaging and computed tomography-X-ray and CT imaging principles; Active Matrix Flat Panel Imagers (AMFPI) for diagnostic medical imaging applications; photon counting and integrating readout circuits; noise coupling in digital X-ray imaging * Nuclear medicine-SPECT and PET imaging principles; low-noise electronics for radiation sensors * Ultrasound imaging-Electronics for diagnostic ultrasonic imaging * Magnetic resonance imaging-Magnetic resonance imaging principles; MRI technology Krzysztof Iniewski, PhD, manages R&D chip development activities at Redlen Technologies. Previously, he was an associate professor in the electrical engineering and computer engineering department of the University of Alberta, where he conducted research on low-power wireless circuits and systems. His research interests are in VLSI circuits for medical and security applications. Dr. Iniewski has published over 100 international journal or conference papers, and holds eighteen international patents. PART I: X-RAY IMAGING AND COMPUTED TOMOGRAPHY. Chapter 1: “XRay and CT Imaging Principles” (Kris Iniewsk:). Chapter 2: “Active Matrix Flat Panel Imagers (AMFPI) for Diagnostic Medical Imaging Applications”.(Karim Karim). Chapter 3: “Photon Counting and Integrating Readout Circuits” (Edgar Kraft and Ivan Peric). Chapter 4: “Noise Coupling in Digital X-ray Imaging” (Jan Thim and B”rje Norlin borje). PART II: NUCLEAR MEDICINE (SPECT AND PET). Chapter 5: “SPECT and PET Imaging Principles” (Anna Celler). Chapter 6: “Low-Noise Electronics for Radiation Sensors” (Gianluigi De Geronimo). PART III: ULTRASOUND IMAGING. Chapter 7: “Electronics for Diagnostic Ultrasonic Imaging” (Robert Wodnicki, Bruno Haider and Kai E. Thomenius). PART IV: MAGNETIC RESONANCE IMAGING. Chapter 8: “Magnetic Resonance Imaging Principles” (Piotr Kozlowski). Chapter 9: “MRI Technology: Circuits and Challenges for Receiver Coil Hardware” (Nicola de Zanche).
