Orthogonal-view Microscope for the Biomechanics Investigations of Aquatic Organisms.

Microscopes are essential for the biomechanical and hydrodynamical investigation of small aquatic organisms. We report a do-it-yourself microscope (GLUBscope) that enables the visualization of organisms from two orthogonal imaging planes - top and side views. Compared to conventional imaging systems, this approach provides a comprehensive visualization strategy of organisms, which could have complex shapes and morphologies.

What Predicts Undergraduate Students' Decision to Pursue a Career in Biomedical/Behavioral Research within an Upper-Division Research Training Program? A Study of Trainees' Science Identity and Educational Outcomes.

This study examined how science identity and positive educational outcomes relate to student trainees' decision to pursue a research career in health-related sciences, within the context of a two-year research training program that prepares diverse undergraduate students for a research career. In analyses using the evaluation data, science identity and one of the positive educational outcomes significantly predicted trainees' decision to pursue a research career in biomedical and behavioral sciences. In general, students with stronger science identity and interest in pursuing research in academia exhibited a firmer decision to pursue a research career in sciences.

Is Science Identity a Predictor or an Outcome of Learning Research Skills? Analyses of Evaluation Data from a Training Program to EnhanceResearch Career Preparation of Diverse Undergraduate Students.

This study examined the role of science identity in a two-year upper-division research training program that prepares diverse undergraduate students for a research career. Using the annual year-end student evaluation data, we examined whether science identity is a predictor or an outcome of learning that enhances career preparation in biomedical research. Results showed that science identity is a predictor of learning in our trainees.

Multiscale modelling of the radical-induced chemistry of acetohydroxamic acid in aqueous solution.

Acetohydroxamic acid (AHA) is a small organic acid with a wide variety of industrial, biological, and pharmacological applications. A deep fundamental molecular level understanding of the mechanisms responsible for the radical-induced reactions of AHA in these environments is necessary to predict and control their behaviour and elucidate their interplay with other attendant chemical species, for example, the oxidative degradation products of AHA. To this end, we present a comprehensive, multiscale computer model for interrogating the radical-induced degradation of AHA in acidic aqueous solutions.