Susanne Weis

Intrasubject reproducibility of presurgical language lateralization and mapping using fMRI.

Background: fMRI is becoming a standard tool for the presurgical lateralization and mapping of brain areas involved in language processing. However, its within-subject reproducibility has yet to be fully explored. Objective: To evaluate within-test and test–retest reliability of language fMRI in consecutive patients undergoing evaluation for epilepsy surgery. Methods: Thirty-four unselected patients were investigated once (within-test reliability) and 12 patients twice (test–retest reliability). The imaging series consisted of an alternating 25-second synonym judgment condition with a 25-second letter-matching condition repeated 15 times. Reproducibility of activation maps of the first and second half of session 1 or activation maps of sessions 1 and 2 was evaluated by comparing one global and three regional lateralization indexes (Broca’s area, remaining prefrontal cortex, temporoparietal area) and on a voxel-by-voxel basis (intraclass correlation coefficient, percentage overlap, correlation of t-values). Results: Global and regional language lateralization was achieved with high reliability within and across sessions. Reproducibility was evenly distributed across both hemispheres but not within each hemisphere. Frontal activations were more reliable than temporoparietal ones. Depending on the statistical threshold chosen, the voxel-by-voxel analysis revealed a mean overlap of activations derived from the first and second investigation of up to 48.9%. Conclusion: Language fMRI proved sufficiently reliable for the determination of global and regional lateralization of language representation in individual unselected patients with epilepsy.

Hippocampal activation in patients with mild cognitive impairment is necessary for successful memory encoding

Background: Episodic memory enables us to consciously recollect personally experienced past events. Memory performance is reduced in patients with mild cognitive impairment (MCI), an at-risk condition for Alzheimer’s disease (AD). Patients and methods: We used functional MRI (fMRI) to compare brain activity during memory encoding in 29 healthy elderly subjects (mean age 67.7 (SD 5.4) years) and 21 patients with MCI (mean age 69.7 (SD 7.0) years). Subjects remembered a list of words while fMRI data were acquired. Later, they had to recognise these words among a list of distractor words. The use of an event related paradigm made it possible to selectively analyse successfully encoded items in each individual. We compared activation for successfully encoded words between healthy elderly subjects and patients with MCI. Results: The main intergroup difference was found in the left hippocampus and surrounding medial temporal lobe (MTL) regions for the patients with MCI compared with healthy subjects during successful encoding. Conclusion: These results suggest that in patients with MCI, an increase in MTL activation is necessary for successful memory encoding. Hippocampal activation may help to link newly learned information to items already stored in memory. Increased activation in MTL regions in MCI may reflect a compensatory response to the beginning of AD pathology.

Network for auditory intrinsic alertness: a PET study.

Intrinsic alertness designates the internal (cognitive) control of wakefulness and arousal; typical tasks to assess optimal levels of intrinsic alertness are simple reaction time (RT) measurements without preceding warning stimuli. Until now, cerebral networks subserving alertness after visual and somatosensory stimulation have been reported. Studies concerning other intensity aspects of alertness like sustained attention and vigilance, on the other hand, have been performed in the auditory modality, too. In a 15O-butanol PET-activation study in 10 right-handed young healthy male volunteers an intrinsic alertness network was studied for the auditory modality. In contrast with a sensorimotor control condition we found an extended predominantly right-hemisphere network similar to those reported for other sensory modalities including frontal, cingular, inferior parietal, temporal and thalamic structures, when subjects waited for and rapidly responded to a 1000 Hz tone signal by pressing a response key with the right-hand thumb. There were, however, some differences in the topography of the frontal, temporal and thalamic activations between auditory and visual stimulation which are discussed with respect to similar results for auditory vigilance and auditory selective attention tasks reported in the literature.

The effect of word concreteness on recognition memory

Concrete words that are readily imagined are better remembered than abstract words. Theoretical explanations for this effect either claim a dual coding of concrete words in the form of both a verbal and a sensory code (dual-coding theory), or a more accessible semantic network for concrete words than for abstract words (context-availability theory). However, the neural mechanisms of improved memory for concrete versus abstract words are poorly understood. Here, we investigated the processing of concrete and abstract words during encoding and retrieval in a recognition memory task using event-related functional magnetic resonance imaging (fMRI). As predicted, memory performance was significantly better for concrete words than for abstract words. Abstract words elicited stronger activations of the left inferior frontal cortex both during encoding and recognition than did concrete words. Stronger activation of this area was also associated with successful encoding for both abstract and concrete words. Concrete words elicited stronger activations bilaterally in the posterior inferior parietal lobe during recognition. The left parietal activation was associated with correct identification of old stimuli. The anterior precuneus, left cerebellar hemisphere and the posterior and anterior cingulate cortex showed activations both for successful recognition of concrete words and for online processing of concrete words during encoding. Additionally, we observed a correlation across subjects between brain activity in the left anterior fusiform gyrus and hippocampus during recognition of learned words and the strength of the concreteness effect. These findings support the idea of specific brain processes for concrete words, which are reactivated during successful recognition.

Estradiol Modulates Functional Brain Organization during the Menstrual Cycle: An Analysis of Interhemispheric Inhibition

According to the hypothesis of progesterone-mediated interhemispheric decoupling (Hausmann and Güntürkün, 2000), functional cerebral asymmetries (FCAs), which are stable in men and change during the menstrual cycle in women, are generated by interhemispheric inhibition of the dominant on the nondominant hemisphere. The change of lateralization during the menstrual cycle in women might indicate that sex hormones play an important role in modulating FCAs. We used functional magnetic resonance imaging to examine the role of estradiol in determining cyclic changes of interhemispheric inhibition. Women performed a word-matching task, while they were scanned twice during the cycle, once during the menstrual and once during the follicular phase. By use of a connectivity analysis we found that the inhibitory influence of left-hemispheric language areas on homotopic areas of the right hemisphere is strongest during the menses, resulting in a pronounced lateralization. During the follicular phase, due to rising estradiol levels, inhibition and thus functional cerebral asymmetries are reduced. These results reveal a powerful neuromodulatory action of estradiol on the dynamics of functional brain organization in the female brain. They may further contribute to the ongoing discussion of sex differences in brain function in that they help explain the dynamic part of functional brain organization in which the female differs from the male brain.

Neural Integration of Iconic and Unrelated Coverbal Gestures: A Functional MRI Study

Gestures are an important part of interpersonal communication, for example by illustrating physical properties of speech contents (e.g., “the ball is round”). The meaning of these so‐called iconic gestures is strongly intertwined with speech. We investigated the neural correlates of the semantic integration for verbal and gestural information. Participants watched short videos of five speech and gesture conditions performed by an actor, including variation of language (familiar German vs. unfamiliar Russian), variation of gesture (iconic vs. unrelated), as well as isolated familiar language, while brain activation was measured using functional magnetic resonance imaging. For familiar speech with either of both gesture types contrasted to Russian speech‐gesture pairs, activation increases were observed at the left temporo‐occipital junction. Apart from this shared location, speech with iconic gestures exclusively engaged left occipital areas, whereas speech with unrelated gestures activated bilateral parietal and posterior temporal regions. Our results demonstrate that the processing of speech with speech‐related versus speech‐unrelated gestures occurs in two distinct but partly overlapping networks. The distinct processing streams (visual versus linguistic/spatial) are interpreted in terms of “auxiliary systems” allowing the integration of speech and gesture in the left temporo‐occipital region. Hum Brain Mapp, 2009.

Neural interaction of speech and gesture: Differential activations of metaphoric co-verbal gestures

Gestures are an important part of human communication. However, little is known about the neural correlates of gestures accompanying speech comprehension. The goal of this study is to investigate the neural basis of speech-gesture interaction as reflected in activation increase and decrease during observation of natural communication. Fourteen German participants watched video clips of 5 s duration depicting an actor who performed metaphoric gestures to illustrate the abstract content of spoken sentences. Furthermore, video clips of isolated gestures (without speech), isolated spoken sentences (without gestures) and gestures in the context of an unknown language (Russian) were additionally presented while functional magnetic resonance imaging (fMRI) data were acquired. Bimodal speech and gesture processing led to left hemispheric activation increases of the posterior middle temporal gyrus, the premotor cortex, the inferior frontal gyrus, and the right superior temporal sulcus. Activation reductions during the bimodal condition were located in the left superior temporal gyrus and the left posterior insula. Gesture related activation increases and decreases were dependent on language semantics and were not found in the unknown-language condition. Our results suggest that semantic integration processes for bimodal speech plus gesture comprehension are reflected in activation increases in the classical left hemispheric language areas. Speech related gestures seem to enhance language comprehension during the face-to-face communication.

Neural correlates of narrative shifts during auditory story comprehension

The ability to segment continuous linguistic information online into larger, meaningful units is a key element in narrative comprehension. Narrative shifts, i.e. transitions between individual units, are postulated to continuously update the mental situation model. Their cerebral correlates, however, have hardly been investigated. Under highly naturalistic conditions this study seeks to identify the neural correlates of implicit processing of narrative shifts during continuous speech comprehension. 16 male native German speakers listened passively to a German novella for 23 min while BOLD signal was recorded with fMRI. Text comprehension was tested in a short post-scan interview asking for critical episodes of the story. Narrative shifts were defined on the basis of a macropropositional analysis. Compared to listening to text passages of the narrative that neither contained narrative shifts nor structurally similar linguistic control events (i.e., sentence boundaries), narrative shifts evoked increased BOLD signal changes in the right temporal gyrus, precuneus and posterior/middle cingulate cortex bilaterally. When narrative shifts were contrasted with sentence boundaries, activation in the right precuneus and cingulate cortex remained significant. The results strengthen the relevance of medial parietal structures for natural language comprehension. More precisely, the precuneus and posterior cingulate appear to be the neural substrate for updating mental story representations and can be regarded as critical parts of a more complex, distributed neural network underlying story comprehension.

Neural correlates of verbal episodic memory in patients with MCI and Alzheimer's disease––a VBM study

The hippocampus is a key area for episodic memory processes. Hippocampal atrophy is a hallmark feature of Alzheimers disease (AD). We used a new and automatized morphometric technique to better characterize brain atrophy in subjects with different levels of cognitive deficit.

Processing of sub-syllabic speech units in the posterior temporal lobe: an fMRI study.

The objective of this study was to investigate phonological processing in the brain by using sub-syllabic speech units with rapidly changing frequency spectra. We used isolated stop consonants extracted from natural speech consonant-vowel (CV) syllables, which were digitized and presented through headphones in a functional magnetic resonance imaging (fMRI) paradigm. The stop consonants were contrasted with CV syllables. In order to control for general auditory activation, we used duration- and intensity-matched noise as a third stimulus category. The subjects were seventeen right-handed, healthy male volunteers. BOLD activation responses were acquired on a 1.5-T MR scanner. The auditory stimuli were presented through MR compatible headphones, using an fMRI paradigm with clustered volume acquisition and 12 s repetition time. The consonant vs. noise comparison resulted in unilateral left lateralized activation in the posterior part of the middle temporal gyrus and superior temporal sulcus (MTG/STS). The CV syllable vs. noise comparison resulted in bilateral activation in the same regions, with a leftward asymmetry. The reversed comparisons, i.e., noise vs. speech stimuli, resulted in right hemisphere activation in the supramarginal and superior temporal gyrus, as well as right prefrontal activation. Since the consonant stimuli are unlikely to have activated a semantic-lexical processing system, it seems reasonable to assume that the MTG/STS activation represents phonetic/phonological processing. This may involve the processing of both spectral and temporal features considered important for phonetic encoding.