Auditory motion direction encoding in auditory cortex and high-level visual cortex

The aim of this functional magnetic resonance imaging (fMRI) study was to identify human brain areas that are sensitive to the direction of auditory motion. Such directional sensitivity was assessed in a hypothesis-free manner by analyzing fMRI response patterns across the entire brain volume using a spherical-searchlight approach. In addition, we assessed directional sensitivity in three predefined brain areas that have been associated with auditory motion perception in previous neuroimaging studies. These were the primary auditory cortex, the planum temporale and the visual motion complex (hMT/V5+). Our whole-brain analysis revealed that the direction of sound-source movement could be decoded from fMRI response patterns in the right auditory cortex and in a high-level visual area located in the right lateral occipital cortex. Our region-of-interest-based analysis showed that the decoding of the direction of auditory motion was most reliable with activation patterns of the left and right planum temporale. Auditory motion direction could not be decoded from activation patterns in hMT/V5+. These findings provide further evidence for the planum temporale playing a central role in supporting auditory motion perception. In addition, our findings suggest a cross-modal transfer of directional information to high-level visual cortex in healthy humans.

BOLD correlates of edge detection in human auditory cortex

Edges are important cues defining coherent auditory objects. As a model of auditory edges, sound on- and offset are particularly suitable to study their neural underpinnings because they contrast a specific physical input against no physical input. Change from silence to sound, that is onset, has extensively been studied and elicits transient neural responses bilaterally in auditory cortex. However, neural activity associated with sound onset is not only related to edge detection but also to novel afferent inputs. Edges at the change from sound to silence, that is offset, are not confounded by novel physical input and thus allow to examine neural activity associated with sound edges per se. In the first experiment, we used silent acquisition functional magnetic resonance imaging and found that the offset of pulsed sound activates planum temporale, superior temporal sulcus and planum polare of the right hemisphere. In the planum temporale and the superior temporal sulcus, offset response amplitudes were related to the pulse repetition rate of the preceding stimulation. In the second experiment, we found that these offset-responsive regions were also activated by single sound pulses, onset of sound pulse sequences and single sound pulse omissions within sound pulse sequences. However, they were not active during sustained sound presentation. Thus, our data show that circumscribed areas in right temporal cortex are specifically involved in identifying auditory edges. This operation is crucial for translating acoustic signal time series into coherent auditory objects.

Amaurosis fugax mit erhöhten Akutphasenproteinen

Case report of a 66-year-old woman with episodes of amaurosis fugax and hemicranic headache with otherwise normal ophthalmologic and neurological examinations and normal imaging. While ESR was in the normal range for patient's age, acute phase proteins (C-reactive protein and fibrinogen) were elevated. Giant cell arteritis was proved by temporal artery biopsy. Giant cell arteritis should be considered as an important differential diagnosis of amaurosis fugax even in patients with normal ESR. Acute phase protein testing can give relevant diagnostic information.

Jazz drummers recruit language-specific areas for the processing of rhythmic structure

Rhythm is a central characteristic of music and speech, the most important domains of human communication using acoustic signals. Here, we investigated how rhythmical patterns in music are processed in the human brain, and, in addition, evaluated the impact of musical training on rhythm processing. Using fMRI, we found that deviations from a rule-based regular rhythmic structure activated the left planum temporale together with Broca's area and its right-hemispheric homolog across subjects, that is, a network also crucially involved in the processing of harmonic structure in music and the syntactic analysis of language. Comparing the BOLD responses to rhythmic variations between professional jazz drummers and musical laypersons, we found that only highly trained rhythmic experts show additional activity in left-hemispheric supramarginal gyrus, a higher-order region involved in processing of linguistic syntax. This suggests an additional functional recruitment of brain areas usually dedicated to complex linguistic syntax processing for the analysis of rhythmical patterns only in professional jazz drummers, who are especially trained to use rhythmical cues for communication.

Zur neuen Relevanz des sozialen Kontexts für das Wahlverhalten. Antwort auf die kritischen Anmerkungen von Franz Urban Pappi

Wir antworten auf die Kritik an unserem Artikel (Ackermann u. Traunmüller 2014) und argumentieren, dass Theorien über die abnehmende Bedeutung sozial-struktureller Merkmale für das Wahlverhalten fehlgeleitet sind. Stattdessen interessiert uns die gehaltvollere Frage, wie und unter welchen Bedingungen sie politisch wirksam werden. Diese Theorieperspektive öffnet den Blick für regionale und temporale Variation sozialer Einflussprozesse, welche gängigen Ansichten zum Cleavage-Voting widersprechen. Wir unterstützen unser Argument, indem wir demonstrieren, dass soziale Kontexte für das individuelle Wahlverhalten heutzutage wichtiger sind als noch vor Jahrzehnten. Abschließend diskutieren wir weiterführende Implikationen für soziale Kontextanalysen des Wahlverhaltens.