Diffuse optical imaging of brain activation: approaches to optimizing image sensitivity, resolution, and accuracy

Boas, David A.; Dale, Anders M.; Franceschini, Maria Angela

doi:10.1016/j.neuroimage.2004.07.011

Cited by 634 publications

(562 citation statements)

References 133 publications

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“…During forepaw stimulation the electrodes near the primary somatosensory cortex (SI) resolve the characteristic SEP components, which correspond to SI activation. DOI has been used to measure hemodynamic evoked responses in several cortical areas in both humans and animals (Boas et al, 2004;Durduran et al, 2004;Gibson et al, 2005;Hillman et al, 2007;Hoshi, 2003;Obrig and Villringer, 1997;Villringer and Chance, 1997). Previously, we have shown that in rats we are able to detect evoked hemodynamic responses both spatially and temporally equivalent to fMRI (Culver et al, 2005;Culver et al, 2003;Siegel et al, 2003).…”

Section: Introductionmentioning

confidence: 93%

Coupling between somatosensory evoked potentials and hemodynamic response in the rat

Franceschini

Nissilä

et al. 2008

NeuroImage

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We studied the relationship between somatosensory evoked potentials (SEP) recorded with scalp electroencephalography (EEG) and hemoglobin responses recorded non-invasively with diffuse optical imaging (DOI) during parametrically varied electrical forepaw stimulation in rats. Using these macroscopic techniques we verified that the hemodynamic response is not linearly coupled to the somatosensory evoked potentials, and that a power or threshold law best describes the coupling between SEP and the hemoglobin response, in agreement with the results of most invasive studies. We decompose the SEP response in three components (P1, N1, and P2) to determine which best predicts the hemoglobin response. We found that N1 and P2 predict the hemoglobin response significantly better than P1 and the input stimuli (S). Previous electrophysiology studies reported in the literature show that P1 originates in layer IV directly from thalamocortical afferents, while N1 and P2 originate in layers I and II and reflect the majority of local cortico-cortical interactions. Our results suggest that the evoked hemoglobin response is driven by the cortical synaptic activity and not by direct thalamic input. The N1 and P2 components, and not P1, need to be considered to correctly interpret neurovascular coupling.

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Section: Introductionmentioning

confidence: 93%

Coupling between somatosensory evoked potentials and hemodynamic response in the rat

Franceschini

Nissilä

et al. 2008

NeuroImage

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“…We benefited both advantages in the development of our fNIRS system. For review and discussion over existing methods and systems, see (Strangman et al, 2002a, Hoshi, 2003, Obrig and Villringer, 2003, Boas et al, 2004, Wolf et al, 2007.…”

Section: Instrumentationmentioning

confidence: 99%

Task complexity relates to activation of cortical motor areas during uni- and bimanual performance: A functional NIRS study

Holper

Biallas²,

Wolf³

2009

NeuroImage

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Task complexity relates to activation of cortical motor areas during uni-and bimanual performance: a functional NIRS study Holper, L; Biallas, M; Wolf, M Holper, L; Biallas, M; Wolf, M (2009 AbstractHand motor tasks are frequently used to assess impaired motor function in neurology and neurorehabilitation. Assessments can be varied by means of hand laterality, i.e. unimanual or bimanual performance, as well as by means of task complexity, i.e. different degrees ranging from simple to complex sequence tasks. The resulting functional activation in human primary motor cortex (M1) has been studied intensively by traditional neuroimaging methods.Previous studies using functional near-infrared spectroscopy (fNIRS) investigated simple hand motor tasks. However, it is unknown whether fNIRS can also detect changes in response to increasing task complexity. Our hypothesis was to show that fNIRS could detect activation changes in relation to task complexity in uni-and bimanual tasks.Sixteen healthy right-handed subjects performed five finger-tapping tasks: unimanual left and right, simple and complex tasks as well as bimanual complex tasks. We found significant We report for the first time that fNIRS detects oxygenation changes in relation to task complexity during finger-tapping. The study aims to contribute to the establishment of fNIRS as a neuroimaging method to assess hand motor function in clinical settings where traditional neuroimaging methods cannot be applied.

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“…It is well known that the wavelength pairs 830 and 750 nm, or 830 and 690 nm are best suited because the wavelengths in these pairs lie above and below the isobestic point of 805 nm, where oxyhemoglobin and deoxy-hemoglobin have the same intrinsic absorption coefficient. 20 The above wavelength pairs minimize random wavelength dependent measurement errors as well as systematic errors arising from inaccuracies in model parameters. 20 With this in mind, laser diodes of wavelengths 685 ͑close to 690 nm͒ and 830 nm are used as diodes of these wavelengths are readily available.…”

Section: A Transmittermentioning

confidence: 99%

“…20 The above wavelength pairs minimize random wavelength dependent measurement errors as well as systematic errors arising from inaccuracies in model parameters. 20 With this in mind, laser diodes of wavelengths 685 ͑close to 690 nm͒ and 830 nm are used as diodes of these wavelengths are readily available. As detailed in Sec.…”

Section: A Transmittermentioning

confidence: 99%

A near infrared instrument to monitor relative hemoglobin concentrations of human bone tissue in vitro and in vivo

Aziz

Khambatta

Vaithianathan

et al. 2010

Review of Scientific Instruments

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A continuous wave near infrared instrument has been developed to monitor in vivo changes in the hemoglobin concentration of the trabecular compartment of human bone. The transmitter uses only two laser diodes of wavelengths 685 and 830 nm, and the receiver uses a single silicon photodiode operating in the photovoltaic mode. The functioning of the instrument and the depth of penetration of the near infrared signals was determined in vitro using tissue-equivalent phantoms. The instrument achieves a depth of penetration of approximately 2 cm for an optode separation of 4 cm and, therefore, has the capacity to interrogate the trabecular compartment of human bone. The functioning of the instrument was tested in vivo to evaluate the relative oxy-hemoglobin ͑HbO 2 ͒ and deoxy-hemoglobin ͑Hb͒ concentrations of the proximal tibial bone of apparently healthy, normal weight, adult subjects in response to a 3 min on, 5 min off, vascular occlusion protocol. The traces of the relative Hb and HbO 2 concentrations obtained were reproducible in controlled conditions. The instrument is relatively simple and flexible, and offers an inexpensive platform for further studies to obtain normative data for healthy cohorts, and to evaluate disease-specific performance characteristics for cohorts with vasculopathies of bone.

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Diffuse optical imaging of brain activation: approaches to optimizing image sensitivity, resolution, and accuracy

Cited by 634 publications

References 133 publications

Coupling between somatosensory evoked potentials and hemodynamic response in the rat

Coupling between somatosensory evoked potentials and hemodynamic response in the rat

Task complexity relates to activation of cortical motor areas during uni- and bimanual performance: A functional NIRS study

A near infrared instrument to monitor relative hemoglobin concentrations of human bone tissue in vitro and in vivo

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