RESUMEN
Harmonizing measures across studies can facilitate comparisons and strengthen the science, but procedures for establishing common data elements are rarely documented. We detail a rigorous, 2-year process to harmonize measures across the Prevention And Treatment through a Comprehensive Care Continuum for HIV-affected Adolescents in Resource Constrained Settings (PATC3H) consortium, consisting of eight federally-funded studies. We created a repository of measured constructs from each study, classified and selected constructs for harmonization, and identified survey instruments. Measures were harmonized for implementation science, HIV prevention and care, demographics and sexual behavior, mental health and substance use, and economic assessment. Importantly, we present our harmonized implementation science constructs. A common set of implementation science constructs have yet to be recommended in the literature for low-to-middle-income countries despite increasing recognition of their importance to delivering and scaling up effective interventions. Drawing on RE-AIM (Reach Effectiveness Adoption Implementation Maintenance) and the Implementation Outcomes Framework, items were harmonized for staff/administrators and study participants to measure reach, adoption, implementation, maintenance, feasibility, acceptability, appropriateness, and fidelity. The process undertaken to harmonize measures and the codified set of implementation science measures developed by our consortium can inform future data harmonization efforts, critical to strengthening the replication and generalizability of findings while facilitating collaborative research-especially in resource-limited settings. We conclude with recommendations for research consortia, namely ensuring representation from all study teams and research priorities; adopting a flexible, transparent, and systematic approach; strengthening the literature on implementation science harmonization; and being responsive to life events (e.g., COVID-19). Supplementary Information: The online version contains supplementary material available at 10.1007/s43477-022-00042-7.
RESUMEN
Xi-cam is an extensible platform for data management, analysis and visualization. Xi-cam aims to provide a flexible and extensible approach to synchrotron data treatment as a solution to rising demands for high-volume/high-throughput processing pipelines. The core of Xi-cam is an extensible plugin-based graphical user interface platform which provides users with an interactive interface to processing algorithms. Plugins are available for SAXS/WAXS/GISAXS/GIWAXS, tomography and NEXAFS data. With Xi-cam's `advanced' mode, data processing steps are designed as a graph-based workflow, which can be executed live, locally or remotely. Remote execution utilizes high-performance computing or de-localized resources, allowing for the effective reduction of high-throughput data. Xi-cam's plugin-based architecture targets cross-facility and cross-technique collaborative development, in support of multi-modal analysis. Xi-cam is open-source and cross-platform, and available for download on GitHub.
RESUMEN
Compared to monometallic nanocrystals (NCs), bimetallic ones often exhibit superior properties due to their wide tunability in structure and composition. A detailed understanding of their synthesis at the atomic scale provides crucial knowledge for their rational design. Here, exploring the Pt-Sn bimetallic system as an example, we study in detail the synthesis of PtSn NCs using in situ synchrotron X-ray scattering. We show that when Pt(II) and Sn(IV) precursors are used, in contrast to a typical simultaneous reduction mechanism, the PtSn NCs are formed through an initial reduction of Pt(II) to form Pt NCs, followed by the chemical transformation from Pt to PtSn. The kinetics derived from the in situ measurements shows fast diffusion of Sn into the Pt lattice accompanied by reordering of these atoms into intermetallic PtSn structure within 300 s at the reaction temperature (â¼280 °C). This crucial mechanistic understanding enables the synthesis of well-defined PtSn NCs with controlled structure and composition via a seed-mediated approach. This type of in situ characterization can be extended to other multicomponent nanostructures to advance their rational synthesis for practical applications.