Predilections of Allied Healthcare Professionals toward an Ideal Interprofessional Education Program via Conjoint Analysis

To shape competent healthcare professionals, a working educational system that facilitates multiprofessional and interprofessional partnership should be in place to foster and deliver better outcomes efficiently, enhancing the quality of healthcare education. Interprofessional Education (IPE) is learning and teaching approach where two or more healthcare professions learn with, from, and about each other. To meet the objective, academic reform that encompasses silos and profession centrism has to be instituted. This study delved into the proclivity of medical and paramedical professionals towards a curricular program that concretizes and strengthens interprofessional collaboration in practice via Conjoint Analysis. Orthogonal Array was employed to elucidate validity and applicability of the five attributes namely Content, Participants, Setting, Teaching Methods, and Format. One hundred allied healthcare professionals representing 25 countries from three international universities participated in the study. Results revealed that setting was the major factor considered when choosing an IPE program with a relative importance of 43.7%.  It was followed by content with a relative importance of 15.8%.  Trailing behind were teaching methods (14.5%) and participants (13.1%), respectively. The stakeholders’ perspectives will serve as a benchmark for a program to be implemented on the Philippine context in line with the ASEAN integration which is currently being embraced

Controlled Experiments of Hillslope Coevolution at the Biosphere 2 Landscape Evolution Observatory: Toward Prediction of Coupled Hydrological, Biogeochemical, and Ecological Change

Understanding the process interactions and feedbacks among water, porous geological media, microbes, and vascular plants is crucial for improving predictions of the response of Earth’s critical zone to future climatic conditions. However, the integrated coevolution of landscapes under change is notoriously difficult to investigate. Laboratory studies are limited in spatial and temporal scale, while field studies lack observational density and control. To bridge the gap between controlled laboratory and uncontrollable field studies, the University of Arizona built a macrocosm experiment of unprecedented scale: the Landscape Evolution Observatory (LEO). LEO comprises three replicated, heavily instrumented, hillslope-scale model landscapes within the environmentally controlled Biosphere 2 facility. The model landscapes were designed to initially be simple and purely abiotic, enabling scientists to observe each step in the landscapes’ evolution as they undergo physical, chemical, and biological changes over many years. This chapter describes the model systems and associated research facilities and illustrates how LEO allows for tracking of multiscale matter and energy fluxes at a level of detail impossible in field experiments. Initial sensor, sampler, and soil coring data are already providing insights into the tight linkages between water flow, weathering, and microbial community development. These interacting processes are anticipated to drive the model systems to increasingly complex states and will be impacted by the introduction of vascular plants and changes in climatic regimes over the years to come. By intensively monitoring the evolutionary trajectory, integrating data with mathematical models, and fostering community-wide collaborations, we envision that emergent landscape structures and functions can be linked, and significant progress can be made toward predicting the coupled hydro-biogeochemical and ecological responses to global change

Highly sampled measurements in a controlled atmosphere at the Biosphere 2 Landscape Evolution Observatory

Land-atmosphere interactions at different temporal and spatial scales are important for our understanding of the Earth system and its modeling. The Landscape Evolution Observatory (LEO) at Biosphere 2, managed by the University of Arizona, hosts three nearly identical artificial bare-soil hillslopes with dimensions of 11x30 m(2) (1m depth) in a controlled and highly monitored environment within three large greenhouses. These facilities provide a unique opportunity to explore these interactions. The dataset presented here is a subset of the measurements in each LEO's hillslopes, from 1 July 2015 to 30 June 2019 every 15minutes, consisting of temperature, water content and heat flux of the soil (at 5cm depth) for 12 co-located points; temperature, relative humidity and wind speed above ground at 5 locations and 5 different heights ranging from 0.25m to 9-10m; 3D wind at 1 location; the four components of radiation at 2 locations; spatially aggregated precipitation rates, total subsurface discharge, and relative water storage; and the measurements from a weather station outside the greenhouses.Open access journalThis item from the UA Faculty Publications collection is made available by the University of Arizona with support from the University of Arizona Libraries. If you have questions, please contact us at [email protected]

Highly Sampled Measurements in a Controlled Atmosphere at the Biosphere 2 Landscape Evolution Observatory

Land-atmosphere interactions at different temporal and spatial scales are important for our understanding of the Earth system and its modeling. The Landscape Evolution Observatory (LEO) at Biosphere 2 managed by the University of Arizona host three nearly identical artificial bare-soil hillslopes with dimensions of 30m x 11m and 1m average depth in a controlled and highly monitored environment under a large greenhouse. These facilities provide a unique opportunity to explore these interactions. This dataset contains, for each one of the three replicate hillslopes, 15-minute measurements from July 1, 2015 to June 30, 2019 of temperature, water content and heat flux of the soil at a depth of 5cm for 12 co-located points; temperature, relative humidity and wind speed above ground at 5 different locations over each hillslope and 5 different heights ranging from 0.25m to 9-10m; 3D wind components at 1 location; the 4 components of radiation at 2 different locations; precipitation rates; and the measurements of an automatic weather station outside the greenhouse

Interarchive : Archivarische Praktiken und Handlungsräumr im zeitgenössischen Kunstfeld = Interarchive : Archival Practices and Sites in the Contemporary Art Field

The archive is examined as facility and metaphor in this publication documenting the exhibition-project “Interarchiv” organised by Obrist and Feldmann in co-operation with the Kunstraum der Universität Lüneburg. In the book’s three sections, the first documents the exhibition and its organisation, the second contains reflections on the archive from different disciplinary perspectives, and the third presents 63 instances of contemporary archiving practices in the field of art. Texts in German and English, with three in French and German. Biographical notes. Circa 500 bibl. ref