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035   $a(DE-He213)978-3-658-05337-6
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100   $a20140312d2014      u|         0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 10$aField Free Line Magnetic Particle Imaging /$fby Marlitt Erbe
205   $a1st ed. 2014.
210  1$aWiesbaden :$cSpringer Fachmedien Wiesbaden :$cImprint: Springer Vieweg,$d2014.
215   $a1 online resource (175 p.)
225 1 $aAktuelle Forschung Medizintechnik ? Latest Research in Medical Engineering,$x2625-9354
300   $aDescription based upon print version of record.
311   $a3-658-05336-4 
320   $aIncludes bibliographical references.
327   $a""Preface by the Series Editor""; ""Geleitwort""; ""Acknowledgements""; ""Abstract""; ""Kurzfassung""; ""Contents""; ""List of Figures""; ""List of Tables""; ""CHAPTER 1 Introduction""; ""1.1 Motivation""; ""1.2 Implemented Devices""; ""1.3 Publications""; ""1.4 Structuring""; ""CHAPTER 2 Magnetic Particle Imaging""; ""2.1 Medical Applications""; ""2.2 Fingerprint of the MPI Tracer""; ""2.2.1 Composition of SPIO Nanoparticles""; ""2.2.2 Phenomenology of Superparamagnetism""; ""2.2.3 Magnetic Moment""; ""2.2.4 Magnetization""; ""2.2.5 Langevin Theory of Paramagnetism""
327   $a""2.2.6 Distribution of SPIO Nanoparticle Core Diameters""""2.2.7 Anisotropy Effects""; ""2.3 Signal Reception""; ""2.4 Signal Encoding The Drive Field""; ""2.5 Spatial Encoding The Selection Field""; ""2.6 The System Function""; ""2.6.1 System Function in Time Space""; ""2.6.2 System Function in Frequency Space""; ""2.6.3 Measurement-based System Function""; ""2.6.4 Model-based System Function""; ""2.6.5 Hybrid Approach""; ""2.6.6 1D System Function for Ideal Conditions""; ""2.7 Reconstruction""; ""2.8 MPI Signal Chain""
327   $a""CHAPTER 3 Introduction of a Field Free Line for Magnetic Particle Imaging""""3.1 Motivation""; ""3.1.1 Increased Sensitivity""; ""3.1.2 FFL versus FFP Imaging: a Simulation Study""; ""3.1.3 Efficient Radon-based Reconstruction Algorithms""; ""3.2 The FFL Field and Trajectory""; ""3.3 The FFL Scanner Design""; ""3.4 Field Free Line Imaging Techniques""; ""3.4.1 Preliminaries: Static Field Free Line Generation""; ""3.4.2 Field Free Line Projection Imaging""; ""3.4.3 Dynamic Field Free Line Imaging""; ""CHAPTER 4 Theory of Magnetic Field Free Line Generation""; ""4.1 FFP Field Generation""
327   $a""4.2 On Axis FFL Field Generation""""4.3 FFL Field Rotation""; ""4.4 Current Considerations""; ""4.5 FFL Field Translation""; ""CHAPTER 5 A Field Free Line Field Demonstrator""; ""5.1 Introduction""; ""5.2 Materials and Methods""; ""5.2.1 FFL Field Demonstrator Construction""; ""5.2.2 FFL Field Demonstrator Electromagnetic Coils""; ""5.2.3 FFL Field Demonstrator Measurement Process""; ""5.3 Results""; ""5.3.1 FFL Rotation""; ""5.3.2 FFL Translation""; ""5.3.3 Magnetic Field Quality""; ""5.4 Discussion""
327   $a""CHAPTER 6 Scanner Efficiency and Magnetic Field Quality Analysis for Different Coil Topologies""""6.1 Dynamic FFL Selection Field Generation""; ""6.1.1 Coil Topologies for Dynamic FFL Selection Field Generation""; ""6.1.2 Current Optimization""; ""6.1.3 Magnetic Field Quality""; ""6.1.4 Electrical Power Consumption""; ""6.1.5 Summary""; ""6.1.6 Experimental Validation""; ""6.1.7 Discussion""; ""6.2 FFL Drive Field Generation""; ""CHAPTER 7 Efficient Reconstruction Algorithms""; ""7.1 Theory""; ""7.1.1 Magnetic Fields""; ""7.1.2 Particle Magnetization""; ""7.1.3 Induced Signal""
327   $a""7.1.4 Signal Transformations""
330   $aMarlitt Erbe provides a detailed introduction into the young research field of Magnetic Particle Imaging (MPI) and field free line (FFL) imaging in particular. She derives a mathematical description of magnetic field generation for FFL imaging in MPI. To substantiate the simulation studies on magnetic FFL generation with a proof-of-concept, the author introduces the FFL field demonstrator, which provides the world?s first experimentally generated rotated and translated magnetic FFL field complying with the requirements for FFL reconstruction. Furthermore, she proposes a scanner design of considerably enhanced magnetic field quality and efficiency. The author discusses the influence of magnetic field quality optimization on the image quality achieved using efficient Radon-based reconstruction methods, which arise for a line detection scheme, and based on this optimized design, presents a dynamic FFL scanner assembly. Contents Introduction of a Field Free Line for Magnetic Particle Imaging Magnetic Field Free Line Generation A Field Free Line Field Demonstrator Scanner Efficiency and Magnetic Field Quality Analysis Efficient Reconstruction Algorithms A Dynamic Field Free Line Imaging Device Target Groups Academics and practitioners in the fields of magnetic particle imaging, computed tomography, and medical imaging; radiologists and physicians. The Author Marlitt Erbe earned her doctoral degree at the Institute of Medical Engineering, University of Lübeck, under the supervision of Prof. Thorsten M. Buzug. The Editor The series Aktuelle Forschung Medizintechnik is edited by Thorsten M. Buzug.
410  0$aAktuelle Forschung Medizintechnik ? Latest Research in Medical Engineering,$x2625-9354
606   $aBiomedical engineering
606   $aComputer simulation
606   $aMedical physics
606   $aRadiation
606   $aBiomedical Engineering and Bioengineering$3https://scigraph.springernature.com/ontologies/product-market-codes/T2700X
606   $aSimulation and Modeling$3https://scigraph.springernature.com/ontologies/product-market-codes/I19000
606   $aMedical and Radiation Physics$3https://scigraph.springernature.com/ontologies/product-market-codes/P27060
615  0$aBiomedical engineering.
615  0$aComputer simulation.
615  0$aMedical physics.
615  0$aRadiation.
615 14$aBiomedical Engineering and Bioengineering.
615 24$aSimulation and Modeling.
615 24$aMedical and Radiation Physics.
676   $a003.3
676   $a629.045
700   $aErbe$b Marlitt$4aut$4http://id.loc.gov/vocabulary/relators/aut$0755807
906   $aBOOK
912   $a9910300327603321
996   $aField Free Line Magnetic Particle Imaging$91523107
997   $aUNINA