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Rapid Scanning of the Fourier PlanePrinciples of MR Diffusion-Weighted Imaging, Voxel-Based Morphometry, Cortical Thickness, and MR Spectroscopy; Diffusion Sequences; Stejskal and Tanner Sequences; How to Obtain a Diffusion Map?; How to Obtain a Tractography?; Sources of Artifacts in Diffusion-Weighted MRI; Voxel-Based Morphometry and Cortical Thickness; Magnetic Resonance Spectroscopy (MRS); Localized Spectroscopy and In Vivo Spectroscopic Imaging; ``Monovoxel ́́MRS; Metabolic Imaging by Spectrometry; Physiochemical Parameters; Chemical Shift; Spectral Characteristics
NMR Signal, Spectral Resolution, and CouplingMeasurement of pH; Magnetization Transfer; In Vivo Spectrometry; Spectrometry of Phosphorus 31 of Muscle Tissue; Proton Spectroscopy of Healthy and Pathological Brain Tissue; Diagnostic Role of MRS and Therapeutic Follow-Up; Imaging of Proton Chemical Shift; References; Chapter 2: Brief Overview of Functional Imaging Principles; Physiological and Physical Bases of BOLD Response; Brief Survey of Basic fMRI Design and Processing; Resting-State Functional Connectivity; Effective Connectivity; Graph Theory; Machine Learning in Neuroimaging
Conclusion and Perspectives in Clinical NeuroimagingReferences; Chapter 3: Clinical Utility of Resting State Functional MRI; Translational fMRI: Aims, Challenges, and Opportunities; Resting State Networks; rsfMRI and Memory in mTLE; rsfMRI and Memory in Other Patients with MTL Damage; Hippocampal Parcellation and Connectivity; rsFC and Language in TLE; Newer Metrics: Graph Theory and Dynamic Functional Connectivity; Caveats and Limitations; Conclusions; References; Chapter 4: The Neuroimaging of Stroke: Structural and Functional Advances; Introduction; Brain Connectivity from MRI Data
Insights into Stroke Mechanisms from Functional and Effective Connectivity StudiesInsights into Stroke Mechanisms from Structural Connectivity Studies; Conclusion; References; Chapter 5: New Insights in Brain Tumor Magnetic Resonance Investigation; The BOLD Issue; A Conceptual Approach Using BOLD: Resting State fMRI; New Standards for Brain Tumor Investigation; From Biometabolic Model to the Genomic profile Through the Metabolic Signal; New ``Metabolic ́́Contrasts: CEST Imaging or Molecular Imaging; Improving Data Analysis and Quantitation from Spectroscopy
NMR Signal, Spectral Resolution, and CouplingMeasurement of pH; Magnetization Transfer; In Vivo Spectrometry; Spectrometry of Phosphorus 31 of Muscle Tissue; Proton Spectroscopy of Healthy and Pathological Brain Tissue; Diagnostic Role of MRS and Therapeutic Follow-Up; Imaging of Proton Chemical Shift; References; Chapter 2: Brief Overview of Functional Imaging Principles; Physiological and Physical Bases of BOLD Response; Brief Survey of Basic fMRI Design and Processing; Resting-State Functional Connectivity; Effective Connectivity; Graph Theory; Machine Learning in Neuroimaging
Conclusion and Perspectives in Clinical NeuroimagingReferences; Chapter 3: Clinical Utility of Resting State Functional MRI; Translational fMRI: Aims, Challenges, and Opportunities; Resting State Networks; rsfMRI and Memory in mTLE; rsfMRI and Memory in Other Patients with MTL Damage; Hippocampal Parcellation and Connectivity; rsFC and Language in TLE; Newer Metrics: Graph Theory and Dynamic Functional Connectivity; Caveats and Limitations; Conclusions; References; Chapter 4: The Neuroimaging of Stroke: Structural and Functional Advances; Introduction; Brain Connectivity from MRI Data
Insights into Stroke Mechanisms from Functional and Effective Connectivity StudiesInsights into Stroke Mechanisms from Structural Connectivity Studies; Conclusion; References; Chapter 5: New Insights in Brain Tumor Magnetic Resonance Investigation; The BOLD Issue; A Conceptual Approach Using BOLD: Resting State fMRI; New Standards for Brain Tumor Investigation; From Biometabolic Model to the Genomic profile Through the Metabolic Signal; New ``Metabolic ́́Contrasts: CEST Imaging or Molecular Imaging; Improving Data Analysis and Quantitation from Spectroscopy