Biomedical Imaging: Magnetic Resonance Imaging - Basics

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Biomedical Imaging: Magnetic Resonance Imaging - Basics www.itk.ppke.hu Nuclei line up with magnetic moments either in a parallel (lower energy level) or anti-parallel configuration (higher energy level). In body tissues more line up in parallel creating a small additional magnetization M in the direction of B0. B0 Nuclei spin axis not parallel to B0 field direction. Nuclear magnetic moments precess about B0. 2019.04.19.. TÁMOP – 4.1.2-08/2/A/KMR-2009-0006 TÁMOP – 4.1.2-08/2/A/KMR-2009-0006

Radiofrequency Pulses Biomedical Imaging: Magnetic Resonance Imaging - Basics www.itk.ppke.hu Radiofrequency Pulses A radiofrequency (RF) pulse at the Larmor frequency will be absorbed This higher energy state tips the spin, so it is no longer aligned to the field An RF pulse at any other frequency will not influence the nuclei, only resonance frequency 2019.04.19.. TÁMOP – 4.1.2-08/2/A/KMR-2009-0006 TÁMOP – 4.1.2-08/2/A/KMR-2009-0006

Biomedical Imaging: fMRI - the BOLD method www.itk.ppke.hu Functional Magnetic Resonance Imaging Functional Magnetic Resonance Imaging (fMRI) refers to different types of specialized MRI scans with a common goal: to measure the dynamics of local neural activity in the brain or spinal cord of humans or other animals. methods: endogenous or exogenous contrast agents can be used to directly or indirectly detect neural action. Blood-oxygen-level dependent imaging (BOLD) is the most frequently used technique, where the contrast agent is the blood deoxyhemoglobin. 2019.04.19.. TÁMOP – 4.1.2-08/2/A/KMR-2009-0006 TÁMOP – 4.1.2-08/2/A/KMR-2009-0006

Biomedical Imaging: fMRI - the BOLD method www.itk.ppke.hu Activity dependent changes in deoxy- and oxyhemoglobin levels Quite distinct changes in oxygenated(Hb) and deoxygenated hemoglobin(dHb) following neuronal activation. Unlike weak deoxygenated hemoglobin signal spatial pattern of oxygenated hemoglobin does not reflect the pattern of neuronal activity Hb Relative concentration dHb 14 Time 2019.04.19.. TÁMOP – 4.1.2-08/2/A/KMR-2009-0006 TÁMOP – 4.1.2-08/2/A/KMR-2009-0006

Biomedical Imaging: fMRI - the BOLD method www.itk.ppke.hu Depending on blood oxygen level: deoxyHb is paramagnetic, increases local inhomogeneity of magnetic field oxyHb diamagnetic local homogeneity of magnetic field increased Oxygen and Field homogeneity 2019.04.19.. TÁMOP – 4.1.2-08/2/A/KMR-2009-0006 TÁMOP – 4.1.2-08/2/A/KMR-2009-0006

Biomedical Imaging: fMRI - the BOLD method www.itk.ppke.hu How to detect BOLD contrast signal Signal decay is sensitive to magnetic field inhomogeneities => Sensitive to signal difference based on deoxyHB concentration Optimal read-out time: When signal difference is highest between different deoxyHB levels TE=25-35ms at 3Tesla (depends on anatomical region as well) activation Rest TE TE optimal 2019.04.19.. TÁMOP – 4.1.2-08/2/A/KMR-2009-0006 TÁMOP – 4.1.2-08/2/A/KMR-2009-0006

Biomedical Imaging: fMRI - the BOLD method www.itk.ppke.hu Link between BOLD and neural activity: Neurovascular coupling Metabolic changes Blood flow Vasodilators Local concentration of deoxy- hemoglobin Local neuronal activity Vasoconstrictors Blood volume Diffuse projections Field inhomogeneity BOLD signal 2019.04.19.. TÁMOP – 4.1.2-08/2/A/KMR-2009-0006 TÁMOP – 4.1.2-08/2/A/KMR-2009-0006

Biomedical Imaging: fMRI - the BOLD method www.itk.ppke.hu Neuronal Origins of BOLD: proof of concept BOLD response correlates primarily with Local Field Potential that reflects activity in the neuropil(dendritic activity) Increased neuronal activity results in increased MR (T2*) signal LFP: Local Field Potential MUA: Multi-Unit Activity SDF: Spike-Density Function Logothetis Journal of Neuroscience, 2003, 2019.04.19.. TÁMOP – 4.1.2-08/2/A/KMR-2009-0006 TÁMOP – 4.1.2-08/2/A/KMR-2009-0006

Biomedical Imaging: fMRI - the BOLD method www.itk.ppke.hu Metabolic rates of the different components of neuronal activity  Attwell and Laughlin J of Cerebral Blood Flow & Metabolism (2001) 2019.04.19.. TÁMOP – 4.1.2-08/2/A/KMR-2009-0006 TÁMOP – 4.1.2-08/2/A/KMR-2009-0006

Biomedical Imaging: fMRI - the BOLD method www.itk.ppke.hu Gradient EPI: disadvantages Low contrast and spatial resolution Serious distortions near to air/tissue borders (e.g. amygdala/inner ear) High water-fat shift Signal instability over time 2019.04.19.. TÁMOP – 4.1.2-08/2/A/KMR-2009-0006 TÁMOP – 4.1.2-08/2/A/KMR-2009-0006

Biomedical Imaging: fMRI - the BOLD method www.itk.ppke.hu Spatial Resolution and specificity of BOLD response In general: high spatial resolution because changes in BOLD response rely on changes in perfusion of capillaries (ø 5-10µm) Influencing factors: Voxel size (depending on region to scan 1-5mm) - attention! reduced voxel size  reduced signal compared with noise and increased acquisition time, but less diversity in tissue content Concordance of neural activity and vascular response Arteries are fully oxygenated Venous blood has increased proportion of dHb Difference between Hb and dHb states is greater for veins Therefore BOLD is the result of venous blood changes Signal can arise from larger and more distant blood vessels!!! 2019.04.19.. TÁMOP – 4.1.2-08/2/A/KMR-2009-0006 TÁMOP – 4.1.2-08/2/A/KMR-2009-0006

Biomedical Imaging: fMRI - the BOLD method www.itk.ppke.hu Temporal resolution of fMRI Typical sampling time of a volume: 2-3sec Temporal resolution is inversely related to Spatial resolution Imaging volume size TE (sensitivity to BOLD) Stimuli can be detected: Minimum duration : < 16 ms Minimum onset diff: 100 ms to 2 sec Above 2 sec, linear summation of responses Below 2 sec: nonlinear interactions 2019.04.19.. TÁMOP – 4.1.2-08/2/A/KMR-2009-0006 TÁMOP – 4.1.2-08/2/A/KMR-2009-0006

Biomedical Imaging: fMRI - the BOLD method www.itk.ppke.hu Stability of the BOLD signal Low frequency drifts and temporal autocorrelation is an inherent characteristic 2019.04.19.. TÁMOP – 4.1.2-08/2/A/KMR-2009-0006 TÁMOP – 4.1.2-08/2/A/KMR-2009-0006

Biomedical Imaging: fMRI - the BOLD method www.itk.ppke.hu Peak Rise Initial Dip Initial dip Baseline Undershoot Undershoot -5 Baseline 5 25 (msec) Stimulus: S1 Peak Sustained response Rise Initial Dip Initial dip Baseline Undershoot -5 Baseline 5 25 (msec) Stimuli: S1 S2 S3……………….SN Undershoot 2019.04.19.. TÁMOP – 4.1.2-08/2/A/KMR-2009-0006 TÁMOP – 4.1.2-08/2/A/KMR-2009-0006

Biomedical Imaging: fMRI - the BOLD method www.itk.ppke.hu Initial Dip (Hypo-oxic Phase) Initial Dip (1-2sec) may result from initial oxygen extraction before later over compensatory response Transient increase in oxygen consumption, before change in blood flow Menon et al., 1995; Hu, et al., 1997 Shown by optical imaging studies Malonek & Grinvald, 1996 Smaller amplitude than main BOLD signal 10% of peak amplitude (e.g., 0.1% signal change) Potentially more spatially specific Oxygen utilization may be more closely associated with neuronal activity than perfusion response 2019.04.19.. TÁMOP – 4.1.2-08/2/A/KMR-2009-0006 TÁMOP – 4.1.2-08/2/A/KMR-2009-0006

Biomedical Imaging: fMRI - the BOLD method www.itk.ppke.hu Rise (Hyperoxic Phase) Results from vasodilation of arterioles, resulting in a large increase in cerebral blood flow Inflection point can be used to index onset of processing Peak – Overshoot Over-compensatory response More pronounced in BOLD signal measures than flow measures Overshoot found in blocked designs with extended intervals Signal saturates after ~10s of stimulation 2019.04.19.. TÁMOP – 4.1.2-08/2/A/KMR-2009-0006 TÁMOP – 4.1.2-08/2/A/KMR-2009-0006

Biomedical Imaging: fMRI - the BOLD method www.itk.ppke.hu Sustained Response Blocked design analyses rest upon presence of sustained response Comparison of sustained activity vs. baseline Statistically simple, powerful Problems Difficulty in identifying magnitude of activation Little ability to describe form of hemodynamic response May require detrending of raw time course Undershoot Cerebral blood flow more locked to stimuli than cerebral blood volume Increased blood volume with baseline flow leads to decrease in MR signal More frequently observed for longer-duration stimuli (>10s) Short duration stimuli may not evidence May remain for 10s of seconds 2019.04.19.. TÁMOP – 4.1.2-08/2/A/KMR-2009-0006 TÁMOP – 4.1.2-08/2/A/KMR-2009-0006

Biomedical Imaging: fMRI - the BOLD method Issues: what are we actually measuring? www.itk.ppke.hu Inputs or Outputs? BOLD responses correspond to intra-cortical processing and inputs, not outputs Aligned with previous findings related to high activity and energy expenditure in processing and modulation Excitation or inhibition circuits? Excitation increases blood flow, but inhibition might too – ambiguous data Neuronal deactivation is associated with vasoconstriction and reduction in blood flow (hence reduction in BOLD signal) And what about the awake, but resting brain? Challenges in interpreting BOLD signal Presence of the signal without neuronal spiking 2019.04.19.. TÁMOP – 4.1.2-08/2/A/KMR-2009-0006 TÁMOP – 4.1.2-08/2/A/KMR-2009-0006

Biomedical Imaging: fMRI - the BOLD method Issues: what are we actually measuring? www.itk.ppke.hu 90.000 to 100.000 neurons per 1mm3 of brain tissue 109 synapses, depending on cortical thickness What is in a Voxel? Volume of 55mm3 Using a 9-16 mm2 plane resolution and slice thickness of 5-7 mm Only 3% of vessels and the rest are….(be prepared!!) 5.5 million neurons 2.2-5.5 x 1010 synapses 22km of dendrites 220km of axons 2019.04.19.. TÁMOP – 4.1.2-08/2/A/KMR-2009-0006 TÁMOP – 4.1.2-08/2/A/KMR-2009-0006

Biomedical Imaging: fMRI - the BOLD method www.itk.ppke.hu Relative vs. Absolute Measures BOLD fMRI provides relative change over time Signal measured in “arbitrary MR units” Percent signal change over baseline Direct longitudinal or intersubject comparisons are impossible within subject interregional (different cortical areas) comparisons : only qualitative or indirect Arterial spin labeling (another type of fMRI method discussed later) or PET provides absolute signal Measures biological quantity in real units CBF: cerebral blood flow CMRGlc: Cerebral Metabolic Rate of Glucose CMRO2: Cerebral Metabolic Rate of Oxygen CBV: Cerebral Blood Volume 2019.04.19.. TÁMOP – 4.1.2-08/2/A/KMR-2009-0006 TÁMOP – 4.1.2-08/2/A/KMR-2009-0006

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