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Functional Imaging Techniques

Functional Imaging Techniques. Perfusion Diffusion fMRI Spectroscopy Real-Time Cardiac Motion / Perfusion Microscopy. Perfusion & Diffusion. Perfusion of tissues via capillary bed permits delivery of O 2 & nutrients to cells & removal of waste products.

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Functional Imaging Techniques

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  1. Functional Imaging Techniques Perfusion Diffusion fMRI Spectroscopy Real-Time Cardiac Motion / Perfusion Microscopy

  2. Perfusion & Diffusion Perfusion of tissues via capillary bed permits delivery of O2& nutrients to cells & removal of waste products. Diffusion relates to random motion of H2O molecules in tissues. Interaction w/ local cellular structures produces anisotropic, directionally-dependent diffusion.

  3. Perfusion Weighted Imaging • Measure of quality of vascular supply to tissue • Regional blood volume & flow • Mean transit time • Tissue Activity • Since vascular supply usually related to metabolism • Tagging water in arterial blood during acquisition • Endogenous: Spin labeling • Saturated blood just upstream of ROI serves as tracer • EPI used • Weak SNR • Exogenous: Gd contrast • Exploits magnetic susceptibility of Gd • T2 or T2* weighting EPI • Quality of injection & timing of acquisition critical

  4. Unenhanced sagittal T1-W MRI shows continuous inversion arterial spin-tagging technique. Spin Labeling Solid lines: imaging slice Dashed line: tagging plane where H2O protons in inflowing arterial blood are magnetically tagged by RF inversion pulse. Quantitative estimates of cerebral blood flow can be obtained by measuring signal changes between tagged images & baseline untagged images.

  5. Result Multiple slices of brain obtained using multi-slice arterial spin-tagging MR perfusion imaging technique. Images show quantitative cerebral blood flow maps. Displayed are five of 10 slice locations extending from level of mid lateral ventricle to level of supraventricular white matter. Artifacts from high flow in superior sagittal sinus are noted anteriorly and, to lesser extent, posteriorly. Total imaging time was approximately 5 min

  6. Non-Contrast CTT T2W MR Gd Contrast 43 yoman w/ acute onset left-sided weakness & visual changes; found to have left homonmoushemianopsia Increased signal right calcarine cortex Negative finding for cortical infarction MTT Map CBV Map DWI MR ↑CBV ↑MTT ↓CBV Larger area of perfusion deficit; infarction core w/ surrounding tissue at risk ↑ transit time, corresponding to infarction core w/ surrounding tissue @ risk Larger area of signal abnormality, consistent w/ infarction

  7. Perfusion Images Pre-injection Post-injection

  8. Time Intensity Curve Tissue Concentration-Time Curve Time Signal Curve Cerebral Blood Volume EPI Time Series Area Cerebral Blood Flow Height Arterial Input Function Tissue Response Function Mean Transit Time Area/Height Deconvolve

  9. Perfusion Uses • Evaluate ischemia disease • Areas of ↓perfusion on CBV map  stroke • Malignancy of neoplasms • ↑Tissue metabolism/perfusion • ↑Perfusion on CBV map • Characteristic patterns seen in • Hepatocellular carcinoma • Metastases • Hemangiomas • Evaluation of tissue viability & metabolism of vascular organs • Heart • Visceral structures • Brain • Renal Artery Stenosis

  10. w/in extracellular space w/in intracellular space Restricted vs. Free Diffusion Water molecules w/in intravascular space Restricted Diffusion High cellularity. Reduced extracellular space & cell membranes act as barrier to water movement Free Diffusion Low cellularity (relative ↑ in space) & defective cell membrane (movement allowed between extra/intra cellular spaces) allows freer water movement

  11. 2 Types of DW images • Diffusion/Trace images • Normal • More H2O mobility ↑ signal loss • Injury • ↓ water mobility • Brighter than normal tissues • Apparent Diffusion Coefficient (ADC) Maps • Requires ≥ 2 acquisitions w/ different DWI parameters • Post processing calculates ADC for each voxel • Low ADC • High signal intensity on calculated image • Restricted diffusion

  12. Strong gradients applied symmetrically about refocusing pulse •  Signal difference based on mobility & directionality of H2O diffusion DWI Pulse Sequence 180° 90° Signal T2-weighted SE RF Diffusion-sensitizing gradients Signal Static molecules Moving water molecules

  13. Sensitive indicator for early detection of ischemic injury • Drastic ↓ of ADC compared to unimpaired tissue • Can show irreversible & reversible Ischemic lesions • Potential for discriminating salvageable tissue from irreversible damage Ischemia Diffusion Coefficient Map DWI Acute ischemic stroke lesion In early stroke, soon after ischemia onset but before infarct, cells swell & absorb water from extra-cellular space. Since cells full of large molecules & membranes diffusion restricted ↓ADC

  14. Directional Effects • Diffusion gradient can be applied along all 3 axes • All together, or Individually • Sensitize sequence to restricted diffusion along a particular axis • Example: • White Matter tracts take specific courses through brain & spinal cord • Anisotropic tissue • May enable imaging of certain WM diseases • Diffusion Tensor Imaging In this image, the axons are colored according to orientation. Fibers running between the front and back are blue, those between right and left are red, and those running between the brain's interior and exterior are green.

  15. DWI Uses • Currently: • Brain after infarction • Differentiate: • Malignant from benign lesions • Tumor from edema & infarction • Neonatal brains • Difficult to distinguish infarction & myelinating brain • Map out myelination patterns in pre-term infants • Additional areas being explored: • Characterizing • Liver lesions • Breast & prostate tumors • Differentiating between • Mucin-producing pancreatic tumors & other tumors • Pathological & traumatic fractures • Imaging • Skeletal muscle injury • Left ventricular damage after myocardial infarction • Assessing bone bruising • Overlaying DWI onto T1W images • combine structural & functional data

  16. Diffusion-Perfusion Mismatch DWI PWI Blood Volume Lesion has reduced CBV T2-wt Early stroke not seen Diffusion-wt Clear depiction of lesion Blood Volume Large perfusion deficit Blood Volume Reduced flow around lesion Apparent Diffusion Acute stroke has low ADC

  17. fMRI

  18. Mechanism • Exploit differences in magnetic susceptibility between oxyhemoglobin & deoxyhemoglobin • Oxyhemoglobin • Oxygen bound to hemoglobin • Magnetic properties of Fe largely suppressed • Diamagnetic • DeoxyHb • Paramagnetic • ↑ T2* decay • Endogenous contrast agent

  19. Cerebral Metabolism • @ rest • Venous blood contains equal parts oxy- & deoxyhemoglobin • During Exercise • Metabolism↑ • ↑O2 needed • Concentration of oxyhemoglobin↓ • Brain • Very sensitive to ↓ concentrations of oxyhemoglobin • ↑Blood flow to local vasculature accompanies neural activity • Local ↓ in deoxyhemoglobin • Because↑ blood flow occurs without ↑in O2 extraction

  20. BOLD • Blood Oxygenation Level Dependent acquisition • Multiple images acquired • before stimulus • during repeated stimulus • Post-stimulus data sets Pre-stimulus data sets • Metabolic activity resulting from repeated task-induced stimulus • Repetitions to ↑SNR • If resulting signal > correlation threshold, color overlay placed on gray scale anatomic image • Pulse Sequences • High speed & T2*-weighting required • EPI • As little as 50 ms for 64 x 64 matrix • GRE • ↑ Spatial resolution • Much longer exam time • Cooperative subjects

  21. Applications • Research • Neuropsychological studies • Cognitive studies • Clinical practice • Localizing functional regions of motricity / language for pre-operational purposes before neurosurgical excision • Determine hemispheric dominance of language • (calculate laterality index) • Assess possibilities of functional recuperation • Evaluation of stroke, pain, epilepsy, behavioral problems • Predict tubular necrosis in kidneys & Mesenteric ischemia

  22. fMRI Alternating R/L finger tapping Black curve show correlated BOLD signals (Right) Red indicates right finger tap, Blue left.

  23. MR Spectroscopy MRS of Brain

  24. Description • In vivo exploration of molecular composition of tissue • Identifies metabolites in physiological /pathological processes • Proton () • Most commonly used • Highest SNR • 10-15 min added onto conventional scan • Sodium () • Phosphorus ()

  25. Mechanism • Metabolite frequencies differ slightly • Slightlydifferent resonance frequencies due to electron cloud shielding • Frequency shift α magnet strength • Exploiting chemical shift to determine relative quantity of chemical • Relative metabolite concentrations plotted • Relative intensities vs. frequency shift • Area under peaks = quantity of metabolite

  26. Example Spectrum Spectrum obtained in healthy liver shows frequencylocations of H2O & lipid peaks. Byconvention, x-axis plotted as downward shift relative to H2Ofrequency. frequency (ppm)

  27. Frequency Shift • Differs for each magnetic field intensity • @1.5 T metabolite frequencies range from 63 – 64 MHz • Scale changed to ppm • Allows comparison for different magnet strengths • Reduces large unwieldy numbers to more manageable size • Calculated by: • [Metabolite frequency Reference frequency] Operating frequency of MR • Reference often water • 4.26 ppm • Advantages of higher field strengths (3.0 vs. 1.5 T) • Better separation of peaks • Higher SNR

  28. Water/Fat Suppression • Conventional MRI • Total signal from all protons used • MRS need to suppress fat & water • These peaks are huge compared to other metabolites • ̴10,000x higher • Other peaks invisible on same scale • Suppression techniques • CHESS (chemical shift) • STIR (inversion recovery) • Often area evaluated is away from fat structures • only water needs to be suppressed

  29. Brain MRS Metabolites

  30. Metabolite Peak Ratios Tumor metabolites: ↑Cell turnover causes ↑Cho concentration Corresponding ↓of NAA peak caused by loss of healthy glioneural structures Cr peak may also ↓, depending on energy status of tumor Lipid peak sign of hypoxia-likelihood of high-grade malignancy

  31. Single Voxel MRS • Single voxel sampling area • Volume ~1 cm³ • STEAM • Stimulated Echo Acquisition Mode • 90° excitation pulse, 90° refocusing pulse • W/ gradients to define each voxel dimension • ↓ TE & superior voxel boundaries • ↓ SNR • PRESS • Point Resolved Spectroscopy • 90° excitation pulse, 180° refocusing pulse in each direction • FT voxel data • Separates composite signal into individual frequencies

  32. MRS Uses • Serially monitor biochemical changes in • Tumors • Stroke • Epilepsy • Metabolic disorders • Infections • Neurodegenerative diseases • Plan therapy • Biopsy guidance • Aid in prognosis

  33. Examples Normal brain Melanoma metastasis Lung metastasis Lung metastasis Grade 2 glioma Grade 2 glioma Grade 3 glioma Grade 3 glioma Grade 4 glioma Grade 4 glioma Grade 4 glioma Center of grade 4 glioma • Spectra from • normal brain tissue • brain metastases • necrosis • gliomas of different grades

  34. Prostate Imaging

  35. Glioma Grade 2 Grade 3 Grade 4 Spectra w/ metabolic abnormalities shaded those w/ peaks corresponding to lactate or lipid marked with “∗”

  36. Multiple Sclerosis

  37. Multi-voxel MRS • Multiple voxels defined using CSI • Volume ~1cm³ • 1, 2, or 3 planes overs rectangular block of several cm • MRSI • Magnetic Resonance Spectroscopic Imaging • Signal intensity of 1 metabolite color coded for each voxel • According to concentration • Generated parameter maps superimposed on anatomic MRI • SVS performed 1stto make initial diagnosis • SNR high • All metabolites represented

  38. Right Frontal Anaplastic Oligoastrocytoma Non-enhancing right frontal mass ElevatedrTBV compared w/ contralateral normal tissue increase decrease Post contrast T1-weighted Relative CBV NAA/Cr ratio Cho/Cr ratio

  39. MR Microscopy Comparison of MR microscopy & conventional pathology sections

  40. Uses • Pathology applications • Study models of disease, toxicology, effects of drug therapies • SNR↓ as voxel size↓ • Very high field required • Dedicated ultra-small coils • Clinical • Bone & joint imaging • Esp. hyaline cartilage

  41. In vivo μMR in vivo MR microscopic image of human forearm skin acquired using a 1.5 T whole body imagerDepth resolution: 38 µm, measurement time: 7 min Patellar cartilage

  42. Interventional MRI • Advantages • Intra-operative acquisition of MR images w/out moving patients • Image-guided stereotaxy w/out pre-op imaging • Real-time tracking of instruments • Precise location area under examination • Continual monitoring of procedure in 3D • Challenges • Expensive • Surgical instruments • Non-ferromagnetic • Produce minimum susceptibility artifacts • Anesthetic & monitoring equipment must be MR safe

  43. Equipment

  44. Uses • Liver imaging & tumor ablation • Using laser therapy • Ablation via heat • Using cryotherapy • Ablation via extreme cold • MRI only technique that can discriminate different tissue temperatures • T1 & T2 temperature dependent • Interstitial Laser Therapy (ILT) • Laser energy delivered percutaneously to various depths in tissue • EPI used for real-time intraoperative assessment of heat distribution • Breast imaging & benign lump excision • Orthopedic & kinematic studies • Congenital hip dislocation manipulation & correction • Biopsies • Functional endoscopic sinus surgery

  45. END

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