Stimulus-induced Rotary Saturation (SIRS): A potential method for the detection of neuronal currents with MRI

Witzel, Thomas; Lin, Fa‐Hsuan; Rosen, Bruce R.; Wald, Lawrence L.

doi:10.1016/j.neuroimage.2008.05.010

Cited by 49 publications

(57 citation statements)

References 34 publications

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“…4B is calculated to be approximately 0.46 nT, based on the level of attenuation and the field map in Fig. 1E, which agrees well with previous sensitivity characterizations (39).…”

Section: Resultssupporting

confidence: 89%

“…As has been shown previously (39), many issues related to cancellation of accumulated phase in phase contrast techniques can be resolved by using a rotating-frame resonant mechanism, termed stimulus-induced resonant saturation (SIRS), to generate current-induced contrast. SIRS builds upon earlier work (38), in which a prepolarized sample is simultaneously placed in an ultralow field (ω H ¼ 40-4; 000 Hz) and an orthogonal magnetic field designed to mimic the oscillating fields of interest.…”

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confidence: 99%

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Magnetic resonance imaging of oscillating electrical currents

Halpern-Manners

Bajaj

Teisseyre

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

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Functional MRI has become an important tool of researchers and clinicians who seek to understand patterns of neuronal activation that accompany sensory and cognitive processes. However, the interpretation of fMRI images rests on assumptions about the relationship between neuronal firing and hemodynamic response that are not firmly grounded in rigorous theory or experimental evidence. Further, the blood-oxygen-level-dependent effect, which correlates an MRI observable to neuronal firing, evolves over a period that is 2 orders of magnitude longer than the underlying processes that are thought to cause it. Here, we instead demonstrate experiments to directly image oscillating currents by MRI. The approach rests on a resonant interaction between an applied rf field and an oscillating magnetic field in the sample and, as such, permits quantitative, frequency-selective measurements of current density without spatial or temporal cancellation. We apply this method in a current loop phantom, mapping its magnetic field and achieving a detection sensitivity near the threshold required for the detection of neuronal currents. Because the contrast mechanism is under spectroscopic control, we are able to demonstrate how ramped and phase-modulated spin-lock radiation can enhance the sensitivity and robustness of the experiment. We further demonstrate the combination of these methods with remote detection, a technique in which the encoding and detection of an MRI experiment are separated by sample flow or translation. We illustrate that remotely detected MRI permits the measurement of currents in small volumes of flowing water with high sensitivity and spatial resolution. current imaging | EEG | magnetoencephalography I n some cases, including living neural tissue, electric charges moving within the sample produce oscillating magnetic fields that can be visualized by MRI methods. The imaging of current distributions by MRI has developed significantly over the last 20 years, with early applications being directed toward the imaging of current density and conductivity in model systems (1, 2) and later in vivo (3-5). However, the primary focus in the development of current imaging is the possibility of directly imaging neuronal currents.While the currents generated by a single neuron are far too small to measure, detectable magnetic field changes on the order of 0.1-1 nT (6) may result from synchronized postsynaptic currents in a large number of neurons. The frequency of oscillatory neural activity is also extremely significant. In addition to the previously demonstrated importance of alpha wave (∼10 Hz) processes (7), a body of recent work has identified the importance of brain activity in the gamma and high gamma frequency ranges (25-250 Hz) (8-10) to the synchronization of anatomically distant centers. To date, most successful approaches to the mapping of these frequencies have involved the implantation of electrodes in direct contact with the brain, usually during a surgical procedure. A noninvasive measurement of oscillating c...

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“…4B is calculated to be approximately 0.46 nT, based on the level of attenuation and the field map in Fig. 1E, which agrees well with previous sensitivity characterizations (39).…”

Section: Resultssupporting

confidence: 89%

mentioning

confidence: 99%

Magnetic resonance imaging of oscillating electrical currents

Halpern-Manners

Bajaj

Teisseyre

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

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“…This chemical exchange is influenced by pH and metabolite concentration (e.g., glucose and glutamate) (Jin et al., 2011; Kettunen, Gröhn, Silvennoinen, Penttonen, & Kauppinen, 2002), which have been shown to change in response to neural activation prior to changes in blood flow (Belanger, Allaman, & Magistretti, 2011). T1ρ relaxation is also sensitive to stimulus‐induced rotary saturation (SIRS), which may directly measure neuronal currents (Witzel, Lin, Rosen, & Wald, 2008). Thus, quantification of T1ρ relaxation temporally is hypothesized to provide a means to detect an early, localized, and nonhemodynamic tissue response to brain activation.…”

Section: Introductionmentioning

confidence: 99%

Relationship altered between functional T1ρ and BOLD signals in bipolar disorder

et al. 2017

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IntroductionFunctional neuroimaging typically relies on the blood‐oxygen‐level–dependent (BOLD) contrast, which is sensitive to the influx of oxygenated blood following neuronal activity. A new method, functional T1 relaxation in the rotating frame (fT1ρ) is thought to reflect changes in local brain metabolism, likely pH, and may more directly measure neuronal activity. These two methods were applied to study activation of the visual cortex in participants with bipolar disorder as compared to controls.MethodsThirty‐nine participants with bipolar disorder and 32 healthy controls underwent functional neuroimaging during a flashing checkerboard paradigm. Functional images were acquired in alternating blocks of BOLD and fT1ρ. Linear mixed‐effect models were used to examine the relationship between these two functional imaging modalities and to test whether that relationship was altered in bipolar disorder.Results BOLD and fT1ρ signal were strongly related in visual and cerebellar areas during the task in controls. The relationship between these two measures was reduced in bipolar disorder within the visual areas, cerebellum, striatum, and thalamus.ConclusionsThese results support a distinct mechanisms underlying BOLD and fT1ρ signals. The weakened relationship between these imaging modalities may provide a novel tool for measuring pathology in bipolar disorder and other psychiatric illnesses.

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“…One challenge of detecting the neuronal current using conventional SE-EPI and GE-EPI sequences is that these sequences do not specifically target neuronal current signals; they also detect signals from other sources, for example physiological noise, the susceptibility effect and changes due to diffusion. One approach to avoid these interfering signals is to image neuronal currents using the stimulus-induced resonance saturation (SIRS) method (Witzel et al, 2008), which is a resonance mechanism in a rotating-frame. SIRS targets NMFs that oscillate at a specific frequency range.…”

Section: Nc-mri Experimentsmentioning

confidence: 99%

“…SIRS uses a spin-lock method to shift the NMFs to a longitudinal magnetization before a conventional SE or GE sequence is used to measure it (see Figure 3-8). In the spin-lock module, the oscillatory NMFs are used as a "RF" pulse to rotate the magnetization away from a spin-lock magnetic field ( sl B ) in a frame rotating at the Larmor frequency around the imaging field (see Figure 3-8 and also (Witzel et al, 2008)). This mechanism is similar to the application of an RF pulse to rotate the magnetization away from the imaging field, except that it occurs in a rotating frame.…”

Section: Nc-mri Experimentsmentioning

confidence: 99%

Realistic models for detection of neuronal currents with magnetic resonance imaging

Du¹

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A great challenge facing brain research is to "see" neurons in action at high spatial and temporal resolution in the living human brain. While existing non-invasive techniques, such as electroencephalography (EEG), magnetoencephalography (MEG), and functional magnetic resonance imaging (fMRI), have either poor spatial or temporal resolution, neuronal current MRI (nc-MRI) may hold the potential to revolutionize cognitive neuroscience by imaging neuronal activity at high temporal and spatial resolutions.However, the implementation of nc-MRI using existing instrumentation is yet to be convincingly demonstrated.In this project, I investigated the feasibility of nc-MRI via computer simulations. To allow realistic neuronal current simulations, the laminar cortex model (LCM) was first developed.The LCM incorporates the laminar architecture of the cerebral cortex into a continuum cortex model (previously developed by Wright et al.) to simulate the collective activity of cortical neurons. As validations, the LCM has been used to simulate the local field potentials (LFP) of the primary visual cortex. The LCM produced spontaneous LFPs exhibited frequency-inverse (1/f) power spectrum behaviour. The LCM also captured the fundamental as well as the high order harmonics under intermittent light stimulation.To model neuronal currents, I decomposed the neuronal activity simulated by the LCM into action potentials and postsynaptic potentials. The geometries of dendrites and axons were generated dynamically to account for neuronal morphology diversity. Magnetic fields produced by action potentials and postsynaptic potentials were calculated for the cases of spontaneous and stimulated cortical activity, from which the nc-MRI signal was determined. The MRI signal magnitude change was found to be below currently detectable levels (< 0.1 part-per-million), but signal phase change was potentially detectable (in the order of 0.1 milli-radian). Furthermore, nc-MRI signals were sensitive to temporal and spatial variations in neuronal activity and independent of the intensity of neuronal activation. Synchronous neuronal activity produces large phase changes, up to 1 milliradian, and the signal phase oscillated with neuronal activity.Based on the computer simulation results, I proposed to image oscillatory neuronal currents using a multi-echo spin echo (MESE) and a synchronised multi-echo gradient recalled echo (MEGRE) sequences. A MESE sequence can accumulate phase changes for multiple neuronal activity oscillation periods through applying radio-frequency (RF) -Iexcitation pulses at the times when neuronal magnetic fields change sign. MEGRE sequence could be used to extract neuronal current signal from noisy MRI signals, because neuronal current signal but not blood-oxygen-level dependent (BOLD) effect or noise, varies with neuronal oscillation. Because a MEGRE sequence is capable of acquiring MRI signals at a series of closely-spaced time points, the inherent oscillation of neuronal current signals may potentially be deduced from ...

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Stimulus-induced Rotary Saturation (SIRS): A potential method for the detection of neuronal currents with MRI

Cited by 49 publications

References 34 publications

Magnetic resonance imaging of oscillating electrical currents

Magnetic resonance imaging of oscillating electrical currents

Relationship altered between functional T1ρ and BOLD signals in bipolar disorder

Realistic models for detection of neuronal currents with magnetic resonance imaging

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