Quantitative evaluation of the relative contribution ratio of cerebral tissue to near-infrared signals in the adult human head: a preliminary study

Kohri, Shunji; Hoshi, Yoko; Tamura, Mamoru; Kato, Chietsugu; Kuge, Yuji; Tamaki, Nagara

doi:10.1088/0967-3334/23/2/306

Cited by 77 publications

(42 citation statements)

References 21 publications

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“…fNIRS signals from Ch1 with 6.0 mm source-detector distance are supposed to reflect hemodynamic activity confined within the scalp, whereas fNIRS signals from the extra-scalp layers, such as the brain, gradually increase in channels with larger source-detector distance (i.e., Ch 2–5) (Kohri et al, 2002). That is, fNIRS signals in channels with larger source-detector distances include both hemodynamic responses in the scalp and other layers, including the brain.…”

Section: Methodsmentioning

confidence: 99%

Cerebral functional imaging using near-infrared spectroscopy during repeated performances of motor rehabilitation tasks tested on healthy subjects

Ishikuro

Urakawa

Takamoto

et al. 2014

Front. Hum. Neurosci.

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To investigate the relationship between the frontal and sensorimotor cortices and motor learning, hemodynamic responses were recorded from the frontal and sensorimotor cortices using functional near infrared spectroscopy (NIRS) while healthy subjects performed motor learning tasks used in rehabilitation medicine. Whole-head NIRS recordings indicated that response latencies in the anterior dorsomedial prefrontal cortex (aDMPFC) were shorter than in other frontal and parietal areas. Furthermore, the increment rate of the hemodynamic responses in the aDMPFC across the eight repeated trials significantly correlated with those in the other areas, as well as with the improvement rate of task performance across the 8 repeated trials. In the second experiment, to dissociate scalp- and brain-derived hemodynamic responses, hemodynamic responses were recorded from the head over the aDMPFC using a multi-distance probe arrangement. Six probes (a single source probe and 5 detectors) were linearly placed 6 mm apart from each of the neighboring probes. Using independent component analyses of hemodynamic signals from the 5 source-detector pairs, we dissociated scalp- and brain-derived components of the hemodynamic responses. Hemodynamic responses corrected for scalp-derived responses over the aDMPFC significantly increased across the 8 trials and correlated with task performance. In the third experiment, subjects were required to perform the same task with and without transcranial direct current stimulation (tDCS) of the aDMPFC before the task. The tDCS significantly improved task performance. These results indicate that the aDMPFC is crucial for improved performance in repetitive motor learning.

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Section: Methodsmentioning

confidence: 99%

Cerebral functional imaging using near-infrared spectroscopy during repeated performances of motor rehabilitation tasks tested on healthy subjects

Ishikuro

Urakawa

Takamoto

et al. 2014

Front. Hum. Neurosci.

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“…The geometries of the sulci and the boundary between the gray and white matter layers were shown to have a negligible effect on the optical path length. More recently, Kohri et al (2002) reported that, in human heads in vivo, the estimated contribution of cerebral tissue to optical signals increased from 33% to 55-69% as the interoptode distance increased from 2 cm to 3 cm to 4 cm. Other in vivo investigations, using scalp ischemia and cerebral oligemia (reduction of blood supply) to manipulate extraand intracerebral hemodynamics independently, have reached similar conclusions (Germon, Kane, Manara, & Nelson, 1994;Germon et al, 1998Germon et al, , 1999.…”

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confidence: 99%

Illuminating the Black Box: Investigating Prefrontal Cortical Hemodynamics during Exercise with Near-Infrared Spectroscopy

Ekkekakis¹

2009

Journal of Sport and Exercise Psychology

172

171

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Near-infrared spectroscopy (NIRS) presents an appealing option for investigating hemodynamic changes in the cerebral cortex during exercise. This review examines the physical basis of NIRS and the types of available instruments. Emphasis is placed on the physiological interpretation of NIRS signals. Theories from affective neuroscience and exercise psychobiology, including Davidson's prefrontal asymmetry hypothesis, Dietrich's transient hypofrontality hypothesis, and Ekkekakis's dual-mode model, are reviewed, highlighting the potential for designing NIRS-based tests in the context of exercise. Findings from 28 studies involving acute bouts of exercise are summarized. These studies suggest that the oxygenation of the prefrontal cortex increases during mild-to-moderate exercise and decreases during strenuous exercise, possibly proximally to the respiratory compensation threshold. Future studies designed to test hypotheses informed by psychological theories should help elucidate the significance of these changes for such important concepts as cognition, affect, exertion, and central fatigue.Keywords: near-infrared spectroscopy, prefrontal asymmetry, exercise intensity, affective responsesOne of the benefits of neuroscience for psychology, according to Peter Lang (1994), is that it can help "limit inference and . . . keep our cognitive theories away from empty boxology" (p. 219). In other words, neuroscientific knowledge can steer psychological theorizing in the right direction (and away from the wrong direction) by suggesting what is possible (and what is impossible) at the level of the nervous system. For example, is "mind over muscle" true? Some may believe so. In fact, some have argued so. But is this really possible? Does the central nervous system have the necessary anatomical features and neurophysiological functions that would permit, for example, consciousness to become completely impervious to afferent muscular cues or volition to exert unlimited control over muscular contractions? Having an understanding of what the brain "does" during exercise could help reformulate, refine, or place important boundary conditions on these and numerous other theoretical propositions.The author is with the Department of Kinesiology, Iowa State University, Ames, IA. 506Ekkekakis Unfortunately, the progress made by exercise neuroscience has been slow (Dishman, 2005). In particular, knowledge of what happens in the brain during a bout of exercise remains sketchy. A relatively small number of animal studies have provided insights into areas implicated in cardiovascular and locomotor control. However, most psychologists would probably be more interested in the function of the frontal lobes, where animal-to-human inferences are limited or impossible, given the dramatic interspecies differences in that particular region. In psychological research, the puzzle of the function of the various subdivisions of the frontal cortex is systematically and painstakingly being solved using the imaging tools of modern human neuroscience. For e...

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“…Importantly, we could identify the The some studies indicate that the optical paths length and the sensitivity to surface layer oxygenation are influenced by the source-detector distance [38,39]. Kohri et al [40] reported that the contribution of cerebral tissue to optical signals were related to the source-detector distance (20 mm; 33 %, 30 mm; 55 %, 40 mm; 69 %), indicating that increasing the detector distance increases effective optical path length within brain tissue. However, there is a large variation in individual correction factor (Table 2), indicating that the effect of the source-detector distance (15 vs. 30 mm) on the contribution of cerebral tissue to optical signals varied widely in each subject.…”

Section: Discussionmentioning

confidence: 99%

Near-infrared spectroscopy determined cerebral oxygenation with eliminated skin blood flow in young males

Hirasawa

Kaneko

Tanaka

et al. 2015

J Clin Monit Comput

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We estimated cerebral oxygenation during handgrip exercise and a cognitive task using an algorithm that eliminates the influence of skin blood flow (SkBF) on the near-infrared spectroscopy (NIRS) signal. The algorithm involves a subtraction method to develop a correction factor for each subject. For twelve male volunteers (age 21 ± 1 yrs) +80 mmHg pressure was applied over the left temporal artery for 30 s by a custom-made headband cuff to calculate an individual correction factor. From the NIRS-determined ipsilateral cerebral oxyhemoglobin concentration (O2Hb) at two source-detector distances (15 and 30 mm) with the algorithm using the individual correction factor, we expressed cerebral oxygenation without influence from scalp and scull blood flow. Validity of the estimated cerebral oxygenation was verified during cerebral neural activation (handgrip exercise and cognitive task). With the use of both source-detector distances, handgrip exercise and a cognitive task increased O2Hb (P < 0.01) but O2Hb was reduced when SkBF became eliminated by pressure on the temporal artery for 5 s. However, when the estimation of cerebral oxygenation was based on the algorithm developed when pressure was applied to the temporal artery, estimated O2Hb was not affected by elimination of SkBF during handgrip exercise (P = 0.666) or the cognitive task (P = 0.105). These findings suggest that the algorithm with the individual correction factor allows for evaluation of changes in an accurate cerebral oxygenation without influence of extracranial blood flow by NIRS applied to the forehead.

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Quantitative evaluation of the relative contribution ratio of cerebral tissue to near-infrared signals in the adult human head: a preliminary study

Cited by 77 publications

References 21 publications

Cerebral functional imaging using near-infrared spectroscopy during repeated performances of motor rehabilitation tasks tested on healthy subjects

Cerebral functional imaging using near-infrared spectroscopy during repeated performances of motor rehabilitation tasks tested on healthy subjects

Illuminating the Black Box: Investigating Prefrontal Cortical Hemodynamics during Exercise with Near-Infrared Spectroscopy

Near-infrared spectroscopy determined cerebral oxygenation with eliminated skin blood flow in young males

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