Acoustic waves can affect two important components of multi-rotor drones, more formally called multi-rotor unmanned aerial vehicles (UAV). The first is located in the electronic board, the so-called IMU (Inertial Measurement Unit), which can be influenced by intense sound waves at resonant frequency. The second is the motor-propeller unit of drones. Multi-rotor drones generate low-frequency acoustic emissions during flight; if external acoustic waves achieve resonance with these blade-induced vibrations, they can cause structural fatigue or mechanical failure in the motor-propeller unit. The paper addresses the following issues: first, the influence of resonant frequency sound waves on these two design elements and their performance evaluation; second, the feasibility of an integrated counter-UAV system comprising acoustic Direction of Arrival (DoA) estimation and Blade Passage Frequency (BPF) detection; and third, a new solution for a long-range directional sound effector. This proposed solution includes determining the operating frequency as the 3rd to 5th harmonics of the BPF. Furthermore, it introduces a new concept that, instead of using a standard array of sound drivers, utilizes a limited quantity of powerful drivers arranged skeletally according to a Vicsek fractal topology. This configuration generates a powerful, needle-like acoustic beam capable of delivering effective mechanical disruption multi-rotor drones at long ranges.
Tight junctions (TJs), once viewed as static paracellular seals, are now recognized as dynamic master regulators of tumor plasticity, microenvironment remodeling, and metastasis. This comprehensive review synthesizes emerging knowledge redefining TJs as versatile signaling and mechanobiological hubs. Beyond simply facilitating EMT through barrier dissolution, TJs coordinate every stage of the metastatic cascade. The review highlights how critical proteins like ZO-1 form liquid-liquid phase-separated (LLPS) condensates to nucleate junctional assembly, which is a well-characterized biophysical event, while also evaluating the proposed, yet less empirically validated, roles of these condensates in broader mechanosensing and signaling cascades. The review also evaluates classic transmembrane-to-nuclear relays, such as the ZO-1-ZONAB axis, and discusses the emerging concept of TJ-NR cross-talk, in which claudin-mediated adhesion has been proposed to modulate SFK activity and subsequent nuclear receptor phosphorylation in specific oncogenic contexts, linking cell adhesion to transcriptional plasticity. Furthermore, TJs orchestrate organotropic colonization, support the survival of circulating tumor cell clusters by resisting hemodynamic stress, and engage in mechanical cross-talk to remodel the stiffened tumor extracellular matrix. This shifting concept transforms TJs into promising clinical targets for precise network-level interference and overcoming therapeutic resistance in advanced malignancies.
Microsporidia are a group of obligate intracellular fungal pathogens with extremely wide host ranges. Among these, zoonotic microsporidia such as Encephalitozoon hellem, Encephalitozoon cuniculi, and Enterocytozoon bieneusi can infect humans as well as other animals, causing recurrent diarrhea, hepatitis, and even death in immune-compromised individuals. The abilities of zoonotic microsporidia to regulate their hosts are essential to their survival and thriving within hosts. The manipulations of zoonotic microsporidia on hosts are employed in multiple ways, including metabolic modulation, immune suppression, signaling pathway regulations, and epigenetic modification. This review focuses on pathogen-host interactions between zoonotic microsporidia and their hosts, and compares their regulatory characteristics with those of typical fungal pathogens such as Candida albicans. In summary, unraveling the regulatory strategies of zoonotic microsporidia not only deepens our understanding of microsporidia pathogenesis but also provides potential targets for therapeutic intervention against these emerging pathogens. Comparative studies with typical fungal pathogens further highlight the unique and sophisticated host-manipulating mechanisms evolved by microsporidia from the fungal kingdom.
Facing the multiple challenges brought about by global change and social development, this paper proposes the conceptual framework of “Holdiversity (和多样性)”, which defines human diversity, biological diversity, and environmental diversity as an interdependent, co-evolving, coupled system. This approach aims to systematically comprehend the synergistic mechanisms between humans and nature, facilitating the construction of trade-off strategies for sustainable development. Furthermore, this paper proposes that the watershed can serve as a fundamental operational unit for Holdiversity research. Its distinct natural boundaries and hierarchical structure enable it to effectively carry the spatial superposition and feedback coupling of multiple diversities. This concept aims to provide an integrated framework for interdisciplinary research and to offer a novel perspective on implementing the United Nations Sustainable Development Goals (SDGs).
Metallized biaxially oriented polypropylene (met-BOPP) is a flexible packaging material whose aluminium layer hinders mechanical recycling. This study presents a life cycle assessment (LCA) of a met-BOPP composite reinforced with cellulosic fibers, comparing its environmental performance to that of gypsum plasterboard, a conventional material widely used in drywall systems. The functional unit was defined as the production of 1 m2 of board. Primary data were obtained experimentally, and secondary data were sourced from the Ecoinvent 3.6 database, using OpenLCA 2.5 software and the ReCiPe 2016 Midpoint (H) impact assessment method. The results revealed substantially lower potential environmental impacts for the composite board compared to the gypsum plasterboard across several categories, with net environmental credits equivalent to 208% of the gypsum impact in Global Warming Potential, 460% in Marine Ecotoxicity, and 207% in Non-carcinogenic Human Toxicity. The environmental gains of the composite alternative result from the recycling of the post-consumer plastic waste used. A sensitivity analysis using a pure cut-off modelling, in which the met-BOPP waste enters the system burden-free and no valorization credits are granted, confirmed the environmental advantage of the composite in terms of GWP, showing a 90.8% reduction in GWP compared with gypsum plasterboard. These findings support met-BOPP composite panels as a promising low-carbon alternative for the construction sector, aligned with circular economy principles.
