Formalizing complexity in the life sciences: systems, emergence, and metafluxes

Wegner, Lars H.

doi:10.1007/s40626-023-00293-1

Cited by 4 publications

(1 citation statement)

References 52 publications

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“…The mechanisms represent the processes involved in the slow release of the inorganic selenium species and bio-corona components from trichogenic SeNPs and in the common/enhanced biological activity. The CESM model was used as a systemic approach to explain the emergent properties of biological systems, including plant ecology [240]. This systemic approach is intended to further develop trichogenic SeNPs as complex chemical systems that contain complex elements relevant to biological activities and agronomical functions with the biological systems in question.…”

Section: Future Research Directionsmentioning

confidence: 99%

The Clothes Matter—Exploiting Agronomical Functions of Trichogenic Selenium Nanoparticles Sharing Activities with Biological Systems Wherein (Were) Formed

Ciobanu,

Bînzari,

Dima

et al. 2024

Agronomy

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The formation of biogenic selenium nanoparticles (SeNPs) through microbial activities is a promising technique that can contribute to the development of reliable, non-toxic and environmentally friendly synthesis methods. Among these, under optimal conditions, myconanotechnology confers particular characteristics due to the generation of bioactive fungal metabolites with various bioactivities. The formed SeNPs are known to be stabilized by the biomolecules of the microorganism, forming a so-called bio-corona or capping structure. The composition of this bio-corona greatly impacts the SeNPs activity, but investigations have been limited to date. The SeNPs produced by Trichoderma sp. have potential applications in crops and environmental management, as both selenium and Trichoderma are known to benefit cultivated plants and phytoremediation. This review summarizes the biosynthesis of SeNPs by Trichoderma sp. and contextualizes the possible correlations between SeNPs and biomolecules produced by Trichoderma; it also provides a missing analysis that could help understand and optimize this process. Biosynthesis methods and probable mechanisms are briefly discussed as well as the role and applications of trichogenic SeNPs as plant protectants, plant biostimulants, and safe biofortifying agents. The knowledge gaps related to mechanisms of trichogenic SeNPs biosynthesis, the control of the desired characteristics for a specific agricultural function, and technology scale-up are discussed in connection with the needed future research directions.

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Section: Future Research Directionsmentioning

confidence: 99%