From Acoustic Segmentation to Language Processing: Evidence from Optical Imaging

During language acquisition in infancy and when learning a foreign language, the segmentation of the auditory stream into words and phrases is a complex process. Intuitively, learners use “anchors” to segment the acoustic speech stream into meaningful units like words and phrases. Regularities on a segmental (e.g., phonological) or suprasegmental (e.g., prosodic) level can provide such anchors. Regarding the neuronal processing of these two kinds of linguistic cues a left-hemispheric dominance for segmental and a right-hemispheric bias for suprasegmental information has been reported in adults. Though lateralization is common in a number of higher cognitive functions, its prominence in language may also be a key to understanding the rapid emergence of the language network in infants and the ease at which we master our language in adulthood. One question here is whether the hemispheric lateralization is driven by linguistic input per se or whether non-linguistic, especially acoustic factors, “guide” the lateralization process. Methodologically, functional magnetic resonance imaging provides unsurpassed anatomical detail for such an enquiry. However, instrumental noise, experimental constraints and interference with EEG assessment limit its applicability, pointedly in infants and also when investigating the link between auditory and linguistic processing. Optical methods have the potential to fill this gap. Here we review a number of recent studies using optical imaging to investigate hemispheric differences during segmentation and basic auditory feature analysis in language development

High-Resolution Optical Functional Mapping of the Human Somatosensory Cortex

Non-invasive optical imaging of brain function has been promoted in a number of fields in which functional magnetic resonance imaging (fMRI) is limited due to constraints induced by the scanning environment. Beyond physiological and psychological research, bedside monitoring and neurorehabilitation may be relevant clinical applications that are yet little explored. A major obstacle to advocate the tool in clinical research is insufficient spatial resolution. Based on a multi-distance high-density optical imaging setup, we here demonstrate a dramatic increase in sensitivity of the method. We show that optical imaging allows for the differentiation between activations of single finger representations in the primary somatosensory cortex (SI). Methodologically our findings confirm results in a pioneering study by Zeff et al. (2007) and extend them to the homuncular organization of SI. After performing a motor task, eight subjects underwent vibrotactile stimulation of the little finger and the thumb. We used a high-density diffuse-optical sensing array in conjunction with optical tomographic reconstruction. Optical imaging disclosed three discrete activation foci one for motor and two discrete foci for vibrotactile stimulation of the first and fifth finger, respectively. The results were co-registered to the individual anatomical brain anatomy (MRI) which confirmed the localization in the expected cortical gyri in four subjects. This advance in spatial resolution opens new perspectives to apply optical imaging in the research on plasticity notably in patients undergoing neurorehabilitation

Focal Retrograde Amnesia: Voxel-Based Morphometry Findings in a Case without MRI Lesions

Focal retrograde amnesia (FRA) is a rare neurocognitive disorder presenting with an isolated loss of retrograde memory. In the absence of detectable brain lesions, a differentiation of FRA from psychogenic causes is difficult. Here we report a case study of persisting FRA after an epileptic seizure. A thorough neuropsychological assessment confirmed severe retrograde memory deficits while anterograde memory abilities were completely normal. Neurological and psychiatric examination were unremarkable and high-resolution MRI showed no neuroradiologically apparent lesion. However, voxel-based morphometry (VBM)-comparing the MRI to an education-, age-and sex-matched control group (n = 20) disclosed distinct gray matter decreases in left temporopolar cortex and a region between right posterior parahippocampal and lingual cortex. Although the results of VBM-based comparisons between a single case and a healthy control group are generally susceptible to differences unrelated to the specific symptoms of the case, we believe that our data suggest a causal role of the cortical areas detected since the retrograde memory deficit is the preeminent neuropsychological difference between patient and controls. This was paralleled by grey matter differences in central nodes of the retrograde memory network. We therefore suggest that these subtle alterations represent structural correlates of the focal retrograde amnesia in our patient. Beyond the implications for the diagnosis and etiology of FRA, our results advocate the use of VBM in conditions that do not show abnormalities in clinical radiological assessment, but show distinct neuropsychological deficits

Non-gait Related Benefits of Auditory Cueing in Parkinson's Disease

AbstractParkinson's disease (PD) is a neurodegenerative disorder that targets mainly dopaminergic neurons of the basal ganglia. PD is characterized by motor symptoms typically leading to dysfunctional gait. External rhythmic auditory cues have shown beneficial effects on gait kinematics in PD patients. These effects are likely to be mediated by a general-purpose neuronal network including a cerebello-thalamo-cortical circuit involved in stimulus-driven allocation of attention (i.e., by entrainment), temporal prediction, and sensorimotor synchronization. This implies that the benefits of auditory rhythmical cueing may extend beyond gait functions, a possibility which has not been assessed so far. In the current study, we investigate whether auditory cueing has a positive effect on perceptual and motor timing. Fifteen PD patients were submitted to a standard auditory cueing program (3 times/week for 30min, for one month). Gait performance was evaluated using motion capture. In addition, motor (via tapping tasks) and perceptual timing abilities were assessed using the Battery for the Assessment of Auditory Sensorimotor and Timing Abilities (BAASTA). The patients were evaluated before the program, immediately after, and one month after the therapy. Their performance was compared to that of healthy age-matched controls. Improved gait kinematics was observed as a result of the therapy and persisted one month later. Interestingly, these benefits extended to timing abilities. Improved duration discrimination, enhanced detection of misaligned sounds to the beat of music and benefits in paced tapping to a metronome were observed. Our findings indicate that the effects of auditory cueing in PD extend to both perceptual and motor timing. Sensorimotor coupling is likely to foster brain plasticity leading to non-gait related effects. These findings raise the possibility of applying cueing therapy for the rehabilitation of timing and motor functions in other basal ganglia disorders (e.g., Huntington's disease, stroke)

Nahinfrarotspektroskopie des Gehirns

Die Arbeit stellt die optische Methode der Nahinfraotspektroskopie (NIRS) in der Anwendung zur Messung von Oxygenierungsänderungen am Kopf des Erwachsenen dar. Dabei werden zunächst methodische Aspekte behandelt. Dies schließt (i) die Frage ein ob Änderungen des Redox-Status der Cytochromoxidase mit der NIRS bestimmt werden können; (ii) diskutiert die Ergebnisse zur Darstellbarkeit schneller optischer Signale, wie sie in invasiven Studien als Korrelat der elektrophysiologisch messbaren neuronalen Prozesse bekannt sind und (iii) richtet sich auf die bessere Definition des Messvolumens, sowohl im Sinne einer zweidimensionalen Bildgebung der Oxygenierungs-änderungen an der Hirnoberfläche als auch die Möglichkeiten zu einer Tiefenauflösung. Bezüglich der grundlegenden physiologischen Fragestellungen thematisiert die Arbeit im zweiten Teil Fragestellungen der neuro-vaskulären Kopplung. Dies ist die Frage, wie sich die neuronale, elektrophysiologisch meßbare Aktivität von Neuronen in eine hämodynamische Antwort übersetzt. Hier sind die Einordnung der NIRS-Befunde in ein Modell der vaskulären Antwort aber auch gleichzeitige Messungen mit elektrophysiologischen Methoden und weiteren vaskulär-basierten Methoden, insbesondere der funktionellen Kernspintomographie, Fokus. Schließlich stellt die Arbeit die klinischen Perspektiven in der Neurologie dar, wie sie sich besonders für die vaskulären Erkrankungen des Gehirns aber auch für Fragestellungen bei Epilepsie und Migräne ergeben.We here present a optical method, near-infrared spectroscopy (NIRS), and its application for non-invasive measurement of oxygenation changes in the adult head. The first part deals with methodological aspects of NIRS. This includes (i) the question whether changes of cytochrome-oxidase redox state can be monitored by NIRS; (ii) the discussion of study results investigating the non-invasive detectability of fast optical signals , known to reflect electrophysiological changes in invasive animal preparations; (iii) and finally the issue how the sampling volume can be better defined, and with respect to a two-dimensional imaging approach of cortical oxygenation changes and the methodological options to achieve a depth resolution. In a second chapter we then focus on the underlying physiological issues mainly raising questions concerning neuro-vascular coupling. Neuro-vascular coupling means the translation of neuronal activity, as can be measured by electrophysiological methods, into the haemodynamic response. Here the focus is on how the results of functional NIRS studies can be interpreted in the light of a model of the vascular response. Also the simultaneous assessment of electrophysiological parameters or the parameters of other methods based on the vascular response, especially fMRI, are dealt with in this chapter. Finally the here presented work gives perspectives of potential clinical applications of the method. This primarily means the application in stroke and other vascularly diseases in neurology, but also includes questions in the clinical fields of epilepsy and migraine

Functional near-infrared spectroscopy in pediatric clinical research: Different pathophysiologies and promising clinical applications

International audienceOver its 30 years of existence, functional near-infrared spectroscopy (fNIRS) has matured into a highly versatile tool to study brain function in infants and young children. Its advantages, amongst others, include its ease of application and portability, the option to combine it with electrophysiology, and its relatively good tolerance to movement. As shown by the impressive body of fNIRS literature in the field of cognitive developmental neuroscience, the method's strengths become even more relevant for (very) young individuals who suffer from neurological, behavioral, and/or cognitive impairment. Although a number of studies have been conducted with a clinical perspective, fNIRS cannot yet be considered as a truly clinical tool. The first step has been taken in this direction by studies exploring options in populations with well-defined clinical profiles. To foster further progress, here, we review several of these clinical approaches to identify the challenges and perspectives of fNIRS in the field of developmental disorders. We first outline the contributions of fNIRS in selected areas of pediatric clinical research: epilepsy, communicative and language disorders, and attention-deficit/hyperactivity disorder. We provide a scoping review as a framework to allow the highlighting of specific and general challenges of using fNIRS in pediatric research. We also discuss potential solutions and perspectives on the broader use of fNIRS in the clinical setting. This may be of use to future research, targeting clinical applications of fNIRS in children and adolescents