03189nam 2200445z- 450 991013680710332120210211(CKB)3710000000631076(oapen)https://directory.doabooks.org/handle/20.500.12854/53407(oapen)doab53407(EXLCZ)99371000000063107620202102d2015 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierMicrobial symbiosis of marine sessile hosts - Diversity and functionFrontiers Media SA20151 online resource (108 p.)Frontiers Research Topics2-88919-681-X Modern molecular -omics tools (metagenomics, metaproteomics etc.) have greatly contributed to the rapid advancement of our understanding of microbial diversity and function in the world's oceans. These tools are now increasingly applied to host-associated environments to describe the symbiotic microbiome and obtain a holistic view of marine host-microbial interactions. Whilst all eukaryotic hosts are likely to benefit from their microbial associates, marine sessile eukaryotes, including macroalgae, seagrasses and various invertebrates (sponges, acidians, corals, hydroids etc), rely in particular on the function of their microbiome. For example, marine sessile eukaryotes are under constant grazing, colonization and fouling pressure from the millions of micro- and macroorganisms in the surrounding seawater. Host-associated microorganisms have been shown to produce secondary metabolites as defense molecules against unwanted colonization or pathogens, thus having an important function in host health and survival. Similarly microbial symbionts of sessile eukaryotes are often essential players in local nutrient cycling thus benefiting both the host and the surrounding ecosystem. Various research fields have contributed to generating knowledge of host-associated systems, including microbiology, biotechnology, molecular biology, ecology, evolution and biotechnology. Through a focus on model marine sessile host systems we believe that new insight into the interactions between host and microbial symbionts will be obtained and important areas of future research will be identified. This research topic includes original research, review and opinion articles that bring together the knowledge from different aspects of biology and highlight advances in our understanding of the diversity and function of the microbiomes on marine sessile hosts.Microbiology (non-medical)bicsscmacroalgaemarine diseasesmarine microbiologyMicrobial DiversityMicrobial InteractionsoystersseaweedsSpongesSymbiosisMicrobiology (non-medical)Torsten Thomasauth1287807Suhelen EganauthBOOK9910136807103321Microbial symbiosis of marine sessile hosts - Diversity and function3020430UNINA04695nam 2201213z- 450 991055733680332120220111(CKB)5400000000042510(oapen)https://directory.doabooks.org/handle/20.500.12854/77060(oapen)doab77060(EXLCZ)99540000000004251020202201d2021 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierCarbon-Based Nanomaterials for (Bio)Sensors DevelopmentBasel, SwitzerlandMDPI - Multidisciplinary Digital Publishing Institute20211 online resource (234 p.)3-0365-2606-4 3-0365-2607-2 Carbon-based nanomaterials have been increasingly used in sensors and biosensors design due to their advantageous intrinsic properties, which include, but are not limited to, high electrical and thermal conductivity, chemical stability, optical properties, large specific surface, biocompatibility, and easy functionalization. The most commonly applied carbonaceous nanomaterials are carbon nanotubes (single- or multi-walled nanotubes) and graphene, but promising data have been also reported for (bio)sensors based on carbon quantum dots and nanocomposites, among others. The incorporation of carbon-based nanomaterials, independent of the detection scheme and developed platform type (optical, chemical, and biological, etc.), has a major beneficial effect on the (bio)sensor sensitivity, specificity, and overall performance. As a consequence, carbon-based nanomaterials have been promoting a revolution in the field of (bio)sensors with the development of increasingly sensitive devices. This Special Issue presents original research data and review articles that focus on (experimental or theoretical) advances, challenges, and outlooks concerning the preparation, characterization, and application of carbon-based nanomaterials for (bio)sensor development.Carbon-Based Nanomaterials for Technology: general issuesbicssc3D printingactive carbonaquatic faunabiomimetic sensorbiosensorbutanecarbon dioxidecarbon dotscarbon nanofiberscarbon nanomaterialscarbon nanotubescarbon-based nanomaterialscarbon-surfaceschemo- and biosensorCortaderia selloanadetectordipicolinic aciddopaminedrop-castelectrochemical sensorselectrospinningenvironmentfield effect transistorflexible electronicsfood safetygas sensorgauge factorGFETgraphenegraphene nanoribbonheavy metalhemoglobin determinationhumidityhybrid nanomaterialslead sensorlow-cost adsorbentsluminescencemetal organic frameworkMnO2 nanoflowersN-doped reduced graphene oxiden/anano carbon blacknanocompositenanoparticlesnitrogennon-covalentoxygenPDMSpercolation thresholdpolydimethylsiloxaneportable instrumentationpressure sensorspropanePrussian blueratiometric fluorescence nanoprobereal-timeresistorroom temperature phosphorescenceschizochytriumsensorsensors and biosensorsspectroscopic ellipsometrysurface-enhanced Raman scatteringTb3+ultrathin gold filmsuric acidvoltammetric sensorwaterwaterswearable electronicszirconia nanoparticlesπ-π stackingTechnology: general issuesMorais Simoneedt1277973Morais SimoneothBOOK9910557336803321Carbon-Based Nanomaterials for (Bio)Sensors Development3021095UNINA