The Impact of Therapist Credentials on Perceptions of the Psychotherapist

Objective. The aim of the present study was to assess whether providing credential information about therapists from an online source would have an impact on perceptions of psychotherapists comparable to when such information is conveyed in physical settings. Method. Participants viewed two emulated psychotherapist websites, one in which credential information was included and another without these credential details. After viewing each website, participants rated the perceived skills and empathy of the therapist. Results. Analysis revealed that therapists were viewed as more expert when professional credentials were provided. Therapists were also viewed as more empathic with credential included, but only when the therapist was racially similar to the participant. Conclusion. This evidence suggests that providing credential information in online formats can serve to enhance positive perceptions of psychotherapists. Consistently so for perceptions of expertness, and conditionally for perceptions of empathy. Therefore, it is recommended that therapists provide this information to clients online whenever possible

A Causal, Data-Driven Approach to Modeling the Kepler Data

Astronomical observations are affected by several kinds of noise, each with its own causal source; there is photon noise, stochastic source variability, and residuals coming from imperfect calibration of the detector or telescope. The precision of NASA Kepler photometry for exoplanet science---the most precise photometric measurements of stars ever made---appears to be limited by unknown or untracked variations in spacecraft pointing and temperature, and unmodeled stellar variability. Here we present the Causal Pixel Model (CPM) for Kepler data, a data-driven model intended to capture variability but preserve transit signals. The CPM works at the pixel level so that it can capture very fine-grained information about the variation of the spacecraft. The CPM predicts each target pixel value from a large number of pixels of other stars sharing the instrument variabilities while not containing any information on possible transits in the target star. In addition, we use the target star's future and past (auto-regression). By appropriately separating, for each data point, the data into training and test sets, we ensure that information about any transit will be perfectly isolated from the model. The method has four hyper-parameters (the number of predictor stars, the auto-regressive window size, and two L2-regularization amplitudes for model components), which we set by cross-validation. We determine a generic set of hyper-parameters that works well for most of the stars and apply the method to a corresponding set of target stars. We find that we can consistently outperform (for the purposes of exoplanet detection) the Kepler Pre-search Data Conditioning (PDC) method for exoplanet discovery.Comment: Accepted for publication in the PAS

Identification of proteins similar to AvrE type III effector proteins from Arabidopsidis thaliana genome with partial least squares

Type III effector proteins are injected into host cells through type III secretion systems. Some effectors are similar to host proteins to promote pathogenicity, while others lead to the activation of disease resistance. We used partial least squares alignment-free bioinformatics methods to identify proteins similar to AvrE proteins from Arabidopsidis thaliana genome and identified 61 protein candidates. Using information from Genevestigator, Arabidopsidis GEB, KEGG, (GEO: accession number GSE22274), and AraCyc databases, we highlighted 16 protein candidates from Arabidopsidis genome for further investigation.Keywords: Partial least squares, Type III effectors, AvrE, and ArabidopsisAfrican Journal of Biotechnology Vol. 12(39), pp. 5804-580

Tighter Bounds on Directed Ramsey Number R(7)

Tournaments are orientations of the complete graph, and the directed Ramsey number $R(k)$ is the minimum number of vertices a tournament must have to be guaranteed to contain a transitive subtournament of size $k$, which we denote by $TT_k$. We include a computer-assisted proof of a conjecture by Sanchez-Flores that all $TT_6$-free tournaments on 24 and 25 vertices are subtournaments of $ST_{27}$, the unique largest TT_6-free tournament. We also classify all $TT_6$-free tournaments on 23 vertices. We use these results, combined with assistance from SAT technology, to obtain the following improved bounds: $34 \leq R(7) \leq 47$