Intrinsic signal changes accompanying sensory stimulation: functional brain mapping with magnetic resonance imaging.

Ogawa, Satoshi; Tank, David W.; Menon, Ravi S.; Ellermann, Jutta; Kim, Seong‐Gi; Merkle, Hellmut; Uğurbil, Kâmil

doi:10.1073/pnas.89.13.5951

Cited by 3,146 publications

(1,798 citation statements)

References 14 publications

Supporting

Mentioning

1,744

Contrasting

Unclassified

Order By: Relevance

“…[18][19][20] These physiological parameters can change during brain activation, and they provide the main signal sources detected by two of the most popular neuroimaging modalities: positron emission tomography (PET) [24][25][26][27] and functional magnetic resonance imaging (fMRI). [28][29][30][31][32][33][34][35] In general, cerebral bioenergetics underlying brain function is not readily accessible noninvasively, and how we probe it (technically) can influence our findings (the outcomes). 36 For instance, many conclusions resulting from in vitro or ex vivo studies may not be valid in the living brain.…”

Section: H Relaxation In Watermentioning

confidence: 99%

In vivo17O NMR approaches for brain study at high field

et al. 2005

View full text Add to dashboard Cite

17 O is the only stable oxygen isotope that can be detected by NMR. The quadrupolar moment of 17 O spin (I ¼ 5/2) can interact with local electric field gradients, resulting in extremely short T 1 and T 2 relaxation times which are in the range of several milliseconds. One unique NMR property of 17 O spin is the independence of 17 O relaxation times on the magnetic field strength, and this makes it possible to achieve a large sensitivity gain for in vivo 17 O NMR applications at high fields.In vivo 17 O NMR has two major applications for studying brain function and cerebral bioenergetics. The first application is to measure the cerebral blood flow (CBF) through monitoring the washout of inert H 2 17 O tracer in the brain tissue following an intravascular bolus injection of the 17 O-labeled water. The second application, perhaps the most important one, is to determine the cerebral metabolic rate of oxygen utilization (CMRO 2 ) through monitoring the dynamic changes of metabolically generated H O is a stable oxygen isotope that has a magnetic moment and can be detected by NMR. Compared with nuclei such as 1 H, 31 P and 13 C that are commonly used for most in vivo MR applications, 17 O has a spin quantum number of greater than ½ (I ¼ 5/2) and possesses an electric quadrupolar moment. The natural abundance of 17 O is only 0.037%, which is almost 30 times lower than that of 13 C and 2700 times lower than that of 1 H. Moreover, the magnetogyric ratio ( ) of 17 O, which is proportional to the Larmor frequency, is 7.4 times lower than that of 1 H.

show abstract

Section: H Relaxation In Watermentioning

confidence: 99%

In vivo17O NMR approaches for brain study at high field

et al. 2005

View full text Add to dashboard Cite

show abstract

“…Such changes form the basis of imaging techniques such as blood oxygenation level dependent (BOLD) functional magnetic resonance imaging (fMRI) (Bandettini et al, 1992;Ogawa et al, 1992). BOLD fMRI is a key tool in neuroscience because it provides a powerful non-invasive way of mapping the regional activity of the brain during the performance of sensory, motor or cognitive tasks.…”

Section: Introductionmentioning

confidence: 99%

Real-time electrochemical monitoring of brain tissue oxygen: A surrogate for functional magnetic resonance imaging in rodents

et al. 2010

View full text Add to dashboard Cite

Long-term in-vivo electrochemistry (LIVE) enables real-time monitoring and measurement of brain metabolites. In this study we have simultaneously obtained blood oxygenation level dependent (BOLD) fMRI and amperometric tissue O 2 data from rat cerebral cortex, during both increases and decreases in inspired O 2 content. BOLD and tissue O 2 measurements demonstrated close correlation (r = 0.7898) during complete (0%) O 2 removal, with marked negative responses occurring ca. 30 s after the onset of O 2 removal. Conversely, when the inspired O 2 was increased (50, 70 and 100% O 2 for 1 min) similar positive rapid changes (ca. 15 s) in both the BOLD and tissue O 2 signals were observed. These findings demonstrate, for the first time, the practical feasibility of obtaining real-time metabolite information during fMRI acquisition, and that tissue O 2 concentration monitored using an O 2 sensor can serve as an index of changes in the magnitude of the BOLD response. As LIVE O 2 sensors can be used in awake animals performing specific behavioural tasks the technique provides a viable animal surrogate of human fMRI experimentation.

show abstract

“…The most commonly used fMRI approach was introduced in 1992 [2][3][4] and is based on imaging the regional alterations in deoxyhemoglobin that accompany changes in neuronal activity. Magnetic resonance techniques can also generate functional maps that are based on changes in tissue perfusion [3,5 -8] or cerebral blood volume (CBV) [9][10][11] that are coupled to neuronal activity; in the case of CBV, this involves use of contrast agents that remain in the vasculature for long periods.…”

mentioning

confidence: 99%