Publications

Abstract

The cognate effect refers to translation equivalents with similar form between languages—i.e., cognates, such as “band” (English) and “banda” (Spanish)—being processed faster than words with dissimilar forms—such as, “cloud” and “nube.” Substantive literature supports this claim, but is mostly based on orthographic similarity and tested in the visual modality. In a previous study, we found an inhibitory orthographic similarity effect in the auditory modality—i.e., greater orthographic similarity led to slower response times and reduced accuracy. The aim of the present study is to explain this effect. In doing so, we explore the role of the speaker's accent in auditory word recognition and whether native accents lead to a mismatch between the participants' phonological representation and the stimulus. Participants carried out a lexical decision task and a typing task in which they spelled out the word they heard. Words were produced by two speakers: one with a native English accent (Standard American) and the other with a non-native accent matching that of the participants (native Spanish speaker from Spain). We manipulated orthographic and phonological similarity orthogonally and found that accent did have some effect on both response time and accuracy as well as modulating the effects of similarity. Overall, the non-native accent improved performance, but it did not fully explain why high orthographic similarity items show an inhibitory effect in the auditory modality. Theoretical implications and future directions are discussed.

Abstract

There is increasing evidence that long-lasting morphologic and
functional consequences can be present in the human visual system
after repetitive mild traumatic brain injury (r-mTBI). The exact lo-
cation and extent of the damage in this condition are not well un-
derstood. Using a recently developed mouse model of r-mTBI, we
assessed the effects on the retina and optic nerve using histology and
immunohistochemistry, electroretinography (ERG), and spectral-
domain optical coherence tomography (SD-OCT) at 10 and 13 weeks
after injury. Control mice received repetitive anesthesia alone (r-sham).
We observed decreased optic nerve diameters and increased cellularity
and areas of demyelination in optic nerves in r-mTBI versus r-sham
mice. There were concomitant areas of decreased cellularity in the
retinal ganglion cell layer and approximately 67% decrease in brain-
specific homeobox/POU domain protein 3AYpositive retinal ganglion
cells in retinal flat mounts. Furthermore, SD-OCT demonstrated a de-
tectable thinning of the inner retina; ERG demonstrated a decrease in
the amplitude of the photopic negative response without any change in
a- or b-wave amplitude or timing. Thus, the ERG and SD-OCT data
correlated well with changes detected by morphometric, histologic,
and immunohistochemical methods, thereby supporting the use of
these noninvasive methods in the assessment of visual function and
morphology in clinical cases of mTBI.

Abstract

he current study examined the interaction of fearful, angry,
happy, and neutral expressions with left, straight, and
right eye gaze directions. Human participants viewed
faces consisting of various expression and eye gaze
combinations while event-related potential (ERP) data
were collected. The results showed that angry expressions
modulated the mean amplitude of the P1, whereas fearful
and happy expressions modulated the mean amplitude of
the N170. No influence of eye gaze on mean amplitudes for
the P1 and N170 emerged. Fearful, angry, and happy
expressions began to interact with eye gaze to influence
mean amplitudes in the time window of 200–400 ms.
The results suggest early processing of expression
influence ERPs independent of eye gaze, whereas
expression and gaze interact to influence later
ERPs.