Coregistering functional near-infrared spectroscopy with underlying cortical areas in infants

Lloyd‐Fox, Sarah; Richards, John E.; Blasi, Anna; Murphy, Declan; Elwell, Clare E.; Johnson, Mark H.

doi:10.1117/1.nph.1.2.025006

Cited by 97 publications

(145 citation statements)

References 55 publications

(78 reference statements)

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“…2) [see Materials and Methods for details on the magnetic resonance (MR)-fNIRS coregistration method (31) and selection of our analysis window]. We considered changes in oxygenation for trials where a predictive auditory stimulus was presented but the visual stimulus unexpectedly was omitted (unexpected visual omissions or A+V− trials) and to trials where both an auditory and visual stimulus were presented (A+V+ trials, consistent with overall exposure) ( Fig.…”

Section: Resultsmentioning

confidence: 99%

Top-down modulation in the infant brain: Learning-induced expectations rapidly affect the sensory cortex at 6 months

Emberson

Richards

Aslin

2015

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

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162

210

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Recent theoretical work emphasizes the role of expectation in neural processing, shifting the focus from feed-forward cortical hierarchies to models that include extensive feedback (e.g., predictive coding). Empirical support for expectation-related feedback is compelling but restricted to adult humans and nonhuman animals. Given the considerable differences in neural organization, connectivity, and efficiency between infant and adult brains, it is a crucial yet open question whether expectation-related feedback is an inherent property of the cortex (i.e., operational early in development) or whether expectation-related feedback develops with extensive experience and neural maturation. To determine whether infants' expectations about future sensory input modulate their sensory cortices without the confounds of stimulus novelty or repetition suppression, we used a cross-modal (audiovisual) omission paradigm and used functional near-infrared spectroscopy (fNIRS) to record hemodynamic responses in the infant cortex. We show that the occipital cortex of 6-month-old infants exhibits the signature of expectation-based feedback. Crucially, we found that this region does not respond to auditory stimuli if they are not predictive of a visual event. Overall, these findings suggest that the young infant's brain is already capable of some rudimentary form of expectation-based feedback.O ver the past two decades, theoretical focus has shifted from predominantly feed-forward hierarchies of cortical function, where sensory cortex propagates information to higher level analyzers on the way to decision and motor control areas, to models in which feedback connections to lower-level cortical regions allow extensive top-down functional modulation based on expectation (1). An influential model for incorporating feedback is predictive coding, which compares expectations or predictions to input at each level of the processing hierarchy (2-4). There is extensive and compelling evidence for expectation-based modulation even at the earliest levels of sensory processing in both humans (5-7) and nonhuman animals (8). Because complex, naturalistic sensory input is characterized by temporal, spatial, and contextual regularities, the ability to modulate early sensory function as a result of expectations is believed to support adaptive perceptual abilities (4).Empirical evidence for expectation-based feedback, however, is restricted to adult humans and nonhuman animals. With their extensive experience, adults already have developed sophisticated internal models of the environment and have a highly interconnected brain and efficient neural processing. Comparatively, human infants are born with a demonstratively immature behavioral repertoire, have underdeveloped sensorimotor and cognitive capacities, and lack sophisticated internal models of the environment. These internal models undergo substantial postnatal development even in the early sensory cortex. For example, spontaneous activity of primary visual cortex (V1) in ferrets converges with e...

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Section: Resultsmentioning

confidence: 99%

Top-down modulation in the infant brain: Learning-induced expectations rapidly affect the sensory cortex at 6 months

Emberson

Richards

Aslin

2015

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

Self Cite

162

210

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“…By using a standardized scalp map of fNIRS channel locators to underlying anatomy [15], and the head measurements and photographs taken in the current study we estimated the location of activation in the condition with 3 second occlusion centered over the pSTS/TPJ region, and for the 6 second occlusion across a wider region of the cortex including the pSTS/TPJ, aSTG and IFG.…”

Section: Resultsmentioning

confidence: 99%

Using fNIRS to Study Working Memory of Infants in Rural Africa

Begus

Lloyd‐Fox

Halliday

et al. 2016

Advances in Experimental Medicine and Biology

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A pilot study was conducted to assess the feasibility of using fNIRS as an alternative to behavioral assessments of cognitive development with infants in rural Africa. We report preliminary results of a study looking at working memory in 12-16-month-olds and discuss the benefits and shortcomings for the potential future use of fNIRS to investigate the effects of nutritional insults and interventions in global health studies.

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“…There are several ways to resolve this problem [94]. One common approach is to position probes using the International 10–20 system for EEG recording and employ cranio-cerebral correspondences to localize activation [95,96]. Finally, although spatial resolution of fNIRS is better than that of ERP/EEG, it is inferior to that of fMRI.…”

Section: A Developmental Neuroscience Approach To Object Individuationmentioning

confidence: 99%

“…(B) The location of the nine measurement channels in the fNIRS studies, placed relative to 10–20 coordinates on a schematic of an infant’s head. Cranio-cerebral maps ([95], also see [96]) suggest that channels 1 to 3 fall in the anterior temporal cortex, channels 4 and 5 in the posterior temporal cortex, channels 6 and 7 in the posterior parietal cortex, and channels 8 and 9 in the occipital cortex. (C) An infant participating in an fNIRS study.…”

Section: Figurementioning

confidence: 99%

Object processing in the infant: lessons from neuroscience

Wilcox

Biondi

2015

Trends in Cognitive Sciences

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Object identification is a fundamental cognitive capacity that forms the basis for more complex thought and behavior. The adult cortex is organized into functionally distinct visual object-processing pathways that mediate this ability. Insights into the origin of these pathways have begun to emerge through the use of neuroimaging techniques with infant populations. The outcome of this work supports the view that, from the early days of life, object-processing pathways are organized in a way that resembles that of the adult. At the same time, theoretically important changes in patterns of cortical activation are observed during the first year. These findings lead to a new understanding of the cognitive and neural architecture that supports infants’ emerging object-processing capacities.

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Coregistering functional near-infrared spectroscopy with underlying cortical areas in infants

Cited by 97 publications

References 55 publications

Top-down modulation in the infant brain: Learning-induced expectations rapidly affect the sensory cortex at 6 months

Top-down modulation in the infant brain: Learning-induced expectations rapidly affect the sensory cortex at 6 months

Using fNIRS to Study Working Memory of Infants in Rural Africa

Object processing in the infant: lessons from neuroscience

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