Carbon emissions of clinical trials have been one of the contributors to global emissions. However, the clinical research industry, particularly contract research organisations (CROs) engaged in trials, has received little attention in the existing literature regarding their carbon footprint. This research examines the sustainable practices implemented by leading global CROs and how these practices influence scope 1 and 2 CO2 emissions. The findings show that increasing the number of sustainability initiatives is insufficient to achieve a measurable reduction in emissions. At the same time, whilst some sustainable practices, such as building upgrades and real estate improvements, lead to a reduction in scope 1 and 2 emissions, others, such as equipment upgrades, are associated with higher emissions. The study, therefore, uncovers a counterintuitive finding—that renewable energy practices showed a positive correlation with emissions. This may be viewed as a paradox, although it serves as a critical warning against measuring sustainability by the quantity of initiatives, rather than their quality or ultimate effect. By assessing the impact of organisational environmental practices on emissions, the study contributes to knowledge by providing a more nuanced understanding of the effectiveness of environmentally sustainable business strategies adopted by CROs.
Modafinil (MF) is a clinically approved wake-promoting agent with emerging anti-inflammatory and anti-fibrotic effects, although its upstream molecular target has remained undefined. Here, we identify adenosine deaminase (ADA) as a previously unrecognized target mediating the therapeutic actions of MF. Its S- and R-isomers (MF-S and MF-R) robustly increased intracellular cAMP levels in fibroblasts with efficacy comparable to NECA, despite minimal direct binding to adenosine receptors, and suppressed KCa3.1 channel activity via a PKA–dependent mechanism. MF-S markedly upregulated CD39 and CD73, leading to increased adenosine availability. Pharmacological inhibition of CD73 with AB680 abolished MF-S–induced increases in cAMP and Epac levels and reversed suppression of TGFβ–induced collagen expression. Consistently, MF-S attenuated canonical profibrotic signaling by inhibiting TGFβ–induced Smad4 upregulation. In vivo, MF-S significantly reduced hypertrophic scarring in a rabbit ear model, with efficacy comparable to Contratubex. Mechanistically, MF-S directly inhibited purified ADA at subnanomolar concentrations and suppressed cellular ADA activity in fibroblast and immune cells. Collectively, these findings establish ADA inhibition as a key upstream mechanism by which MF enhances adenosine–cAMP signaling to suppress inflammation and fibrosis, highlighting MF and its isomers as promising therapeutic candidates for inflammatory and fibrotic diseases.
Escalating atmospheric CO2 levels and the consequent climate crisis have become urgent imperatives for advancing efficient carbon capture technologies. Porous carbon adsorbents stand out as a leading candidate in this field, owing to their inherently high specific surface areas, tailorable pore architectures, and cost advantages over conventional solid adsorbents. This review focuses on recent progress in the rational engineering of porous carbons for boosted CO2 capture performance, with a particular emphasis on three complementary modification pathways: pore structure refinement, surface functional group regulation, and metal oxide incorporation. We begin by clarifying the distinct mechanisms of CO2 physisorption and chemisorption on carbonaceous surfaces, while also elucidating how key operating parameters (temperature, pressure) and real-world flue gas components (e.g., water vapor, SO2) modulate adsorption behavior. Critical evaluation is then given to strategies for enhancing three core performance metrics—CO2 uptake capacity, selectivity over N2, and cyclic stability—including the construction of sub-nanometer micropores (<0.8 nm) for efficient low-pressure CO2 capture, the introduction of nitrogen- and oxygen-containing moieties to strengthen dipole–quadrupole interactions with CO2 molecules, and the loading of alkaline metal oxides (e.g., MgO, CaO) to enable reversible chemisorption, which is especially beneficial under humid conditions. Finally, we outline the key challenges that hinder the practical application of porous carbon adsorbents, such as the design of hierarchical pores for both high uptake and fast mass transfer, the precise control of heteroatom doping sites and concentrations, and the mitigation of competitive adsorption in complex multicomponent flue gases. Corresponding future research priorities are also proposed, with a focus on scalable and sustainable synthesis routes using biomass or waste precursors. Ultimately, this review seeks to provide targeted insights for the rational design of high-performance porous carbon adsorbents, thereby accelerating their deployment in sustainable CO2 capture systems.
The objective of this study is to conduct a review of recycled-carbon-fibre (rCF) wind turbine blades’ feasibility, through a comparison of global and Australian wind sector waste, and a comparison of virgin-carbon-fibre (vCF) with rCF wind turbine blades’ greenhouse-gas GHG-emissions, and, recommend an approach for carbon-fibre CF-use in the fledgling Australian offshore wind industry, based on global-warning-potential GWP. This study assesses the life-cycle GHG-emissions of virgin-carbon-fibre wind turbine blades versus recycled-carbon-fibre wind turbine blades, in both non-structural and structural configurations. All production, use and recycling is assessed in terms of a West Australian context, in which the functional unit is three turbine blades used on an onshore wind farm, towards potential applicability for (as yet, non-existent) offshore WA fields. An approach incorporating a GaBi/Sphera database-study provides a timely screening/preliminary study, in which it was found that non-structural recycled carbon fibre wind turbine blades had very similar GHG emission levels compared to standard virgin carbon fibre blades, with sensitivity analysis revealing that in worst-case scenarios, non-structural carbon fibre has higher GHG emissions. Structurally recycled carbon fibre blades performed significantly better than standard virgin carbon fibre wind turbine blades with a 56% reduction in GHG emissions; savings were not affected significantly by parameter changes during sensitivity analysis. It is evident that recycled-carbon-fibre can significantly reduce wind turbine blades’ GWP and contribute to the circular economy in the fledgling West Australian offshore-wind-turbine sector.
Youth engagement in agriculture has emerged as a critical issue for sustainable agri-food systems, yet policies remain fragmented and uneven across countries. This paper presents a comparative case study of four national contexts to assess how governments address or neglect the challenges young people face in the agricultural sector. Using a desk-based review of policy documents, reports, and secondary literature, this study critically compares the policy environments of Uganda, Cameroon, Nigeria, and Italy. It explores the role of youth in agriculture and rural development by identifying gaps in institutional support, policy coherence and access to resources, while also highlighting areas of innovation and promising practices. This paper develops a conceptual framework to capture the key aspects necessary to increase youth participation in agriculture and rural development. The framework emphasises the importance of integrated strategies combining structural access, system-level integration, youth agency, and institutional capacity. Overall, this cross-country analysis aims to enhance the understanding of youth-in-agriculture policy environments, providing a roadmap for future policy-making and the development of sustainable rural communities.
