Preface
Acknowledgments
Chapter 1: The Clinical Application of Brain Imaging
- Access to brain imaging
- Advantages of using brain imaging in the clinic
- Clues Regarding the Extent of an Injury
- Clues Regarding the Type of Injury
- Clues to the Location of Injury or Pathology
- Clues regarding prognosis and expected functional outcome
- Clues regarding the time course for recovery
- Concrete Information for Families
- Limitations: What Neuroimaging Often Does Not Provide the Clinician.
- Brain imaging does not measure a patient's functioning
- Brain imaging may not provide information about electrochemical processes
- Brain imaging does not provide direct visualization of microscopic injury
- Brain scans often do not provide information regarding the etiology of damage
- Brain Scans do Not Treat the Patient
- Showing damage on brain images may not be recommended
- What to do when the patient or family members ask to see the brain scans.
- What to request when writing orders for brain imaging
- Radiologist Reports
- Anatomy versus Functioning
Chapter 2: Viewing and Interpreting Brain Scans
- Orientation and Image Plane
- Axial or Horizontal Orientation
- Axial Reformatting with varying slice angles
- Coronal Orientation
- Sagittal Orientation
- When right is left and left is right
- Basic Clinical Interpretation
- The appearance of brain tissue on different types of brain scans
- Interpreting findings on a variety of scans
- Use several image types or sequences when assessing for pathology
- Know what to look for, but also be conservative in your interpretation.
- Symmetry as a guide to interpreting brain scans
- Evaluating head position in the scanner
- Look at the eyes
- Look at the bones of the skull
- Look at the bilateral structures that are commonly symmetrical
- Caution is warranted when using symmetry as a guide.
- Multiple pathologies can produce asymmetry of the brain
- Artifacts can produce asymmetry on an image
- Ventricular dilation and compression
- How much ventricular dilation can a person sustain without symptoms?
- Obstructive (non-communicating) Hydrocephalus
- Communicating Hydrocephalus
- Normal Pressure Hydrocephalus (hydrocephalus ex vacuo).
- Transependymal Edema
- Ventricular Asymmetry
- Steroid Use
- Guide to the General Appearance of Different Tissues on Brain Images
- Developmental changes evident on neuroimaging
- Myelination
- Temporal effects on the appearance of brain scans
- Caution when assessing atrophy
- Temporal Effects Due to Progression of an illness
- Know what the imaging should look like prior to viewing
- Diagnostic Pitfalls of Neuroimaging
- Being too focused, or not focused enough
- Missing what is missing
- Missing Pathology in the Neutral Gray
- Stop Searching After Finding an Obvious Abnormality
- Consider all possible causes for a particular " appearance
- Pitfalls of knowing the neuropathology and anatomy of the injury
- Quality of brain imaging
- DICOM Viewers
- Comparing scans acquired on different occasions
- Presentation of simultaneous images
Chapter 3: Imaging Based Neuroanatomy
- Reference Lines
- Primary anatomical landmarks
- Ventricles
- Meningeal Layers
- Dura and dural reflections (folds)
- Falx cerebri
- Tentorium cerebelli
- Dural Venous Sinuses
- Arachnoid Layer
- Arachnoid Cisterns
- Superior Cistern
- Interpeduncular or Basal Cistern
- Pia Mater
- White Matter Pathways
- Centrum Semiovale
- Corpus Callosum
- Coronal Orientation
- Sagittal Orientation
- Axial Orientation
- Pathology to the Corpus Callosum
- Cingulum
- Corona Radiata
- Internal Capsule
- The anterior limb of the internal capsule
- The genu of the internal capsule
- The posterior limb of the internal capsule
- Internal Capsule Injury
- Optic Tract and Radiations
- Optic Chiasm
- Optic Radiations (geniculostriate tract)
- Examples of visual field impairments
- Homonymous Right Hemianopia
- Homonymous Left Hemianopia
- Quadranopia: loss of approximately a quarter visual field
- Scotoma: visual field loss other than a half or quarter
- Forebrain
- Telencephalon
- Cerebral Cortex
- Lobes of the Brain
- Identifying areas of cortex on brain images
- Frontal and Parietal lobes
- Central Sulcus - Inferior Margin
- Central Sulcus - Middle Section
- Central Sulcus - Superior Margin
- Temporal Lobes
- Occipital Lobes
- Limbic system or lobe (Allocortex)
- Hippocampi (L: seahorse)
- Axial
- Coronal
- Sagittal
- Amygdala (L: almond)
- Axial
- Coronal
- Sagittal
- Mammillary Bodies
- Basal Ganglia
- Basal Ganglia on Brain Imaging
- LEVEL: Body of the lateral ventricles
- LEVEL: Foramen of Monro
- LEVEL: Third Ventricle
- Diencephalon
- Thalamus
- Thalami on brain imaging:
- Hypothalamus
- Hypothalamus on brain imaging:
- Epithalamus
- Pineal Body - "
- Pineal on brain imaging.
- Pituitary Gland - Hypophysis
- Pituitary on brain imaging.
- Adenomas-Suprasellar craniopharyngioma
- Mesencephalon
- Midbrain
- Red nuclei
- Substantia nigra (Latin: black substance)
- Substantia Nigra on brain imaging
- Reticular formation
- Central gray/periaqueductal gray
- Corpora quadrigemini (Latin: quadruplet bodies)
- Corpora quadrigemini on brain imaging
- General Location of the Midbrain Structures
- Hindbrain
- Metencephalon
- Pons
- Pons on brain imaging
- Cerebellum
- Myelencephalon
- Medulla oblongata
- Vascular System
- The internal carotid and vertebral artery distributions to the brain.
- Right and Left Internal Carotid Distribution
- Right and left vertebral artery and basilar distribution
- Circle of Willis
- Watershed area
- Appendix 3-1
Chapter 4: Brain Imaging Techniques
- Image Quality
- Spatial resolution
- Contrast Resolution
- Noise
- What type of scan to use?
- Types of Imaging
- Static Brain Imaging
- Ultrasound
- Computer Axial Tomography (CAT/CT)
- Absorption of x-rays
- Safety Concerns with CT
- Contrast CT Imaging
- Computed Tomography Angiography/Venography (CTA/CTV)
- Computed Tomography Ventriculography/Cisternography
- CT - Perfusion Studies
- CT Noise and Artifacts
- Quantum Noise
- Electronic Noise
- Computational Noise
- CT Artifacts
- Metallic Artifacts
- Streak Artifacts
- Angiography/Digital Subtraction Angiography (DSA)
- Phases of Angiography
- Three Dimensional Angiography
- MRI - Magnetic Resonance Imaging
- Safety Concerns of MRI
- Problems with higher strength magnet systems
- Three-Dimensional Imaging
- Reformatting of MRI images
- Re-slicing images using a thinner thickness and different slice angle
- Cutting windows into an image
- Signal Strength and Contrast on MRI
- MRI Noise
- MRI artifacts
- Motion Artifacts - MRI
- Metallic Objects
- MR Sequences
- T1 spin-lattice sequences
- 3D Ultrafast Gradient Echo T1 Images (FSPGR, BRAVO, MPRAGE)
- T2 spin-echo (spin-spin) sequences
- T2* " spin-echo (spin-spin) sequences
- T2 Cube Sequences
- Proton Density (PD) or Spin-density sequences
- Fluid Attenuated Inversion Recovery (FLAIR) sequences
- Gradient Echo (GRE) sequences
- Gradient Echo - Echo-Planar Sequences
- Susceptibility Weighted MR Imaging (SWI)
- Propeller Sequences
- Fast imaging employing steady state acquisition (FIESTA) sequences
- MRI - Contrast Enhanced Imaging
- Magnetic Resonance Angiography (MRA)
- Two and Three-Dimensional Time of Flight Sequences (3D-TOF)
- Contrast Enhanced Magnetic Resonance Angiograpy/Venography (CE-MRA/MRV)
- Hybrid Brain Imaging
- Diffusion Weighted MRI (DWI)
- Apparent Diffusion Coefficient Maps (ADC)
- Temporal Changes to Diffusion Images
- How to use DWI and ADC maps to assess diffusion.
- Diffusion Tensor Imaging - Fractional Anisotropy and Tractography
- Structural FA maps
- Color-coded structural fractional anisotropy maps
- Color Structural FA Maps.
- DTI-Tractography
- Clinical application of diffusion tensor imaging
- DTI as a marker of axonal injury
- Cerebral Perfusion MRI (PWI)
- Magnetic Resonance Spectroscopy (MRS)
- Functional Brain Imaging
- Positron Emission Tomography (PET)
- Combined Positron Emission Tomography and CT (PET-CT) or MRI (PET-MRI)
- Single Photon Emission Computed Tomography (SPECT)
- Functional Magnetic Resonance Imaging (fMRI)
- Magnetic Encephalopathy (MEG-MSI)
- Ictal MEG-MSI
- Limitations of MEG-MSE
- MEG-fMRI combination
- General Concerns regarding the clinical use of functional brain imaging
- A person is not a normalized population
- Is the " area a region of processing or a transmission hub?
- Local activation versus global or distributed activation
- Simple task paradigms are not the same as complex real-life activities
- Neuropathology can change metabolic functioning
- Functional imaging techniques are indirect measures of neural activity
- Neural activation functions at the sub-millisecond level
- The problem of Type I (false positive) Error
- The problem of nonindependence
- Time required to complete a study
- Interpretation of functional imaging data
- The benefit of using multiple functional imaging techniques for each patient
Chapter 5: Neuroimaging of Traumatic Brain Injuries
- Focal Injury, Diffuse Injury or A Combination?
- Post Traumatic Hemorrhages
- Epidural Hemotoma/Hemorrhage (EDH)
- Subdural Hematoma/Hemorrhage (SDH)
- Examples of subdural hematomas/hemorrhages
- Subarachnoid Hematoma/Hemorrhage
- Examples of subarachnoid hematomas/hemorrhages
- Intraparenchymal Hemorrhages
- Petechial Hemorrhages
- Diffuse Axonal Injury
- Hemorrhagic Contusions
- Contra Coup Injuries
- Common locations for hemorrhagic and non-hemorrhagic contusions.
- Subcortical Hemorrhages
- Post Traumatic Pneumocephalus
- Post Traumatic Hypoxic Ischemic Encephalopathy
- Laminar necrosis due to hypoxic ischemic infarction
- Second Impact Syndrome
- Intraventricular Hemorrhages
- Post-traumatic Vasospasm
- Intracerebral edema
- Midline shift and asymmetric compression of the ventricles
- Loss of gray-white differentiation
- Blast injuries
- Imaging Changes Over Time Following Severe Traumatic Brain Injury
- Penetrating Injuries
- Penetration by Bone or Debris
- Gunshot Wounds
- Low Velocity Penetrating Injuries
- Low Velocity, Small Caliber Gunshot Wounds
- Low Velocity, Large Caliber Gunshot Wounds
- High velocity penetrating injuries
- High Velocity, Small Caliber Gunshot Wounds
- High Velocity, Large Caliber Gunshot Wounds
- Shotgun Injuries
- Non-Accidental Trauma (NAT)
- Suspected non-accidental trauma, but not non-accidental trauma
Chapter 6: Non-Traumatic Brain Injuries
- Infections Of The Brain
- Meningitis
- Encephalitis and Cerebritis
- Meningoencephalitis
- Abscess
- Empyema
- Stroke and Vascular Pathologies
- Imaging non-traumatic hemorrhagic strokes - cerebral vascular accident (CVA)
- Hemorrhagic Cavernomas
- Bleeding Disorders Resulting in Spontaneous Hemorrhage
- Non-hemorrhagic and embolic ischemic strokes
- Blockage of Venous Flow
- Loss of Internal Carotid Flow Without Stroke Related Symptoms
- Diffuse Hypoxic Encephalopathy
- Watershed Infarctions
- White Matter Disorders
- Multiple Sclerosis (MS)
- Acute Disseminated Encephalomyalitis (ADEM)
- Toxic Damage to White Matter
- Neoplasm
- Diffuse, infiltrating and non-enhancing tumor
- Diffuse, infiltrating and contrast-enhancing tumor
- Encapsulated non-enhancing cystic tumor
- Encapsulated contrast-enhancing tumor
- Hydrocephalus due to Tumor Growth
- Neurodevelopmental Disorders
- Cortical dysplasia
- Agenesis of the Corpus Callosum (ACC)
- Polymicrogyria
- Anencephaly
- Holoprosencephaly
- Schizencephaly
- Multiple Neurodevelopmental Conditions
- Parasitic Disorders
Chapter 7: Brain Atlas
Index
Bibliography