Functional aspects of anatomical imaging techniques

Functional aspects of anatomical imaging techniques Nilendu Purandare Associate Professor & Consultant Radiologist Tata Memorial Centre

Functional/metabolic/molecular imaging (radioisotope scanning) PET SPECT Perfusion,flow Metabolsim (glucose, AA) Receptor expression Hypoxia,Apoptosis Anatomical imaging techniques Ultrasonography CT scan MRI Location Size/dimensions Density Morphology Spatial relations

Oncology / tumor imaging

Functional imaging Tumors Metabolism (glucose, amino acid) Proliferation Hypoxia PET Angiogenesis Apoptosis Image receptors

Functional imaging Tumors Metabolism (glucose, amino acid) Angiogenesis Proliferation Perfusion Hypoxia Diffusion characteristics Angiogenesis Metabolite quantification Apoptosis Hypoxia Image receptors CT/MR

Tumor imaging Angiogenesis Perfusion Diffusion characteristics CT/MR Metabolite quantification Hypoxia

Angiogenesis (DCE MRI and CT Perfusion) Physiological imaging (ultrafast imaging) Follows the early enhancement kinetics of contrast within first few minutes of IV bolus injection (TIC). Depicts tissue vascularisation, capillary permeability, perfusion, volume of interstitial space, thus indirectly tissue cellularity.

Angiogenesis (CT Perfusion) Assesses physiological parameters Blood flow (BF) Blood volume (BV) Mean transit time (MTT) Capillary permeability (CP/PS) In vivo markers of micro vessel density and angiogenesis

Angiogenesis (CT Perfusion) De-convolution based analysis technique Operative derived ROI are placed on artery and representative portion of the tumor for input functions Functional maps of perfusion parameters obtained

Angiogenesis (CT Perfusion)

Angiogenesis (CT Perfusion) Rectal Cancer : response to neo-adjuvant therapy

MR Perfusion / DSC MRI (Brain tumors) SI Time

MR Perfusion / DSC MRI (Brain tumors) Cerebral blood volume Cerebral blood flow Mean Transit Time Time to Peak

MR Perfusion / DSC MRI (Brain tumors) Establish the diagnosis of tumor Pre- operative assessment of tumor histology Guide tumor biopsy Assessment of true lesion extent Monitoring response to therapy (surrogate marker)

Hyperperfusion Possible glioma

Delineation of true tumor extent

Radiation Necrosis Vs tumor recurrence

Angiogenesis (bone & soft tissue tumors) Dynamic contrast enhanced (DCE) MRI Tissue characterization (vascularity & perfusion) Identifying viable areas to biopsy Staging of local extent Monitoring response to therapy (surrogate marker) (K-trans, tissue permeability)

Advanced techniques : DCE MR- Curve types

Advanced techniques : MRI Dynamic contrast enhanced (DCE) MRI Tissue characterization Highly perfused and vascularised tumor with small volume interstitial space Type IV curve-malignant

Advanced techniques : MRI DCE MRI : Ideal site for biopsy Highly vascularised, highly perfused viable portion of tumor (Synovial Sarc) Avoid edema, necrosis, normal tissue

Advanced techniques : MRI DCE MRI : Surrogate marker of response to chemo Rx MFH

Advanced techniques : MRI DCE MRI : Residual/recurrent tumor from post Rx change Gradual slope pseudonodule Bx- negative for malignancy

Tumor imaging Angiogenesis Perfusion Diffusion characteristics Metabolite quantification Hypoxia

Diffusion weighted imaging (DWI) Measures the motion of water molecules in the intra & extravascular spaces Motion of water molecules is more restricted in tissues with high cellularity, intact cell membranes and reduced intracellular space Malignant tumors in general have high cellularity and thus more restricted diffusion. Quantitatively ADC values are used to study diffusion restriction

Diffusion weighted imaging (DWI) A B C D E F

Diffusion weighted imaging (DWI)

Diffusion weighted imaging (DWI)

Diffusion weighted imaging (DWI) Synovial sarcoma post surgery Enhancing nodule at surgery site ADC map- restricted diffusion Local recurrence

Tumor imaging Angiogenesis Perfusion Diffusion characteristics Metabolite quantification Hypoxia

Metabolite quantification MR spectroscopy Maps metabolite signal intensity from tissues (choline, creatinine, lipids, NAA, lactate, citrate) Detects increased levels of choline Marker of cell membrane turnover- feature of malignancy Proton (H1) MR spectroscopy is used.

Normal Brain spectrum

Glioma spectrum

Metabolite quantification-mr spectroscopy Radiation Necrosis Vs tumor recurrence

Metabolite quantification MR spectroscopy : Response evaluation

Tumor imaging Angiogenesis Perfusion Diffusion characteristics Metabolite quantification Hypoxia

BOLD (Blood oxygen level dependant imaging) BOLD MR detects hypoxic subfraction and patients suitable for hypoxia modifying agents. Provide a means of evaluating changes in tumor oxygenation in response to chemotherapy Used for Brain, breast, pancreatic and prostate cancers BOLD-MRI images are more likely to reflect on acute (perfusion-related) tissue hypoxia.

BOLD

Functional techniques Tumor imaging Metabolism (glucose, amino acid) Proliferation Hypoxia Angiogenesis Apoptosis Image receptors PET CT MRI Size & Volume Angiogenesis Perfusion Diffusion characteristics Metabolite quantification Hypoxia

Neurology

Diffusion weighted imaging (DWI) Measures the motion of water molecules in the intra & extravascular spaces Motion of water molecules is more restricted in tissues with high cellularity, intact cell membranes and reduced intracellular space Infarcts show restricted diffusion in a few hours Quantitatively ADC values are used to study diffusion restriction

Central irreversible infarcted tissue core Neurology Significance of penumbra Peripheral region of ischaemic but salvagable tissue called penumbra

Comparison of Diffusion & Perfusion Abnormalities Mismatch State of the art imaging of acute stroke

Comparison of Diffusion & Perfusion Abnormalities Match State of the art imaging of acute stroke

2 hours after deficit CBF MTT 7 days later

3 hours

3 hours after deficit 7 days later Penumbra is reversed after endovascular clot retrieval & revascularisation

Functional MRI ( F MRI) BOLD

Functional MRI ( F MRI) Defined cognitive task Increased neuronal activity Localized vasodilatation and increase in blood flow Increase in dimagnetic oxyhemoglobin Signal response

Epilepsy: cortical dysplasia

Epilepsy: cortical dysplasia, fmri

Cardiology

Cardiology MRI (Myocardial perfusion) use the first pass of an intravenously injected Gd contrast agent at rest and during administration of a vasodilator (i.e. adenosine ) to depict hemodynamically significant coronary artery stenosis MRI (Cardiac Viability) Contrast enhanced CMR is a newly established technique for infarct assessment. Regions of myocardial infarction exhibit high signal intensity (contrast enhancement) on T1 weighted images after administration of contrast such as gadolinium based agents.

MR Perfusion Top panel: Subendocardial infarct, prominent perfusion defects larger than infarct on stress MR Bottom panel: Matched stress and rest defects, no infarction, CA is normal- artifactual

MRI: Viability 58 yrs old man (EF-20%) Dilated cardiomyopathy Thinning of inferior wall on still images Late ce- MRI shows transmural enhancement suggesting old MI In chronic CAD patients, myocardial enhancement in areas of dysfunctional myocardium corresponds closely to fixed defects on thallium SPECT, and areas of flow-metabolism matched defects on FDG-PET scans, histologically representing scarred or fibrotic tissue

Color Doppler Ultrasound Estimates blood flow and velocity Locate and grade vascular stenosis 2D echo Pumping function (ejection fraction)

Summary CT/MRI (DCE MRI, DWI, spectroscopy, BOLD) Oncology Angiogenesis (perfusion), diffusion, metabolites, hypoxia Neurology Functional maps, CBF,CBV, MTT (epilepsy, stroke) Cardiology Myocardial perfusion, viability

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