Reed canary grass (Phalaris arundinacea L.) is a perennial fast-growing C 3 plant belongs to family Poaceae with an early season growth, a wide physiological tolerance and with large possibilities of utilization. Recently, the use for bioenergy has become very perspective mainly because its high yield (5-10 t dry matter ha/year) and very good properties for combustion. The mean calorific value is about 16-18 MJ/kg dry matter. It can be usually harvested twice a year at lower cultivation inputs and shows the ability to grow in wide range of soil conditions including on land, which is not appropriate for other agricultural purposes. It has also the potential for different industrial applications, for example for biogas, ethanol, pulp and paper production, or for the production of chemical raw materials, too. The cultivation area rapidly increases, mainly in North Europe, where it is cultivated on thousands of hectares. The cultivation for energy or other industrial purposes has also benefits to the environment because of low intensity on agricultural management, supporting biodiversity and soil preservation against erosion.
Some species of invertebrates especially bryozoans (Bryozoa syn. Ectoprocta) and marine sponges (Porifera) are very important sources of pharmacologically exploitable compounds. These substances are probably produced to protect themselves from fish predators and may be an advantage in competition. The real sources of compounds with these antipredatory effects are probably not marine invertebrates themselves, but microscopic symbionts or food which they feed on. Bryostatins from bryozoan species Bugula neritina are produced by a bacterial symbiont called Candidatus Endobugula sertula. They have significant anti-cancer effects, but also other therapeutic benefits. Compounds with the structure of bryostatins were also discovered in some other invertebrates. Sponges are a source of many compounds, e.g., ara-A (vidarabine), manzamine, lasonolides, spongistatins, peloruside and others with antimicrobial, anti-cancer, immunosuppressive and similar activities. Other important sources of compounds with medical effects are tunicates (Tunicata syn. Urochordata) and some snails (Mollusca). One drug was developed from tunicates – Yondelis against refractory soft-tissue sarcomas. Certain other drugs originate from snails: e.g., prialt, which acts against chronic pain in spinal cord injury.
Pectinatella magnifica (Leidy 1851) is an invasive freshwater colonial animal belonging to the phylum Bryozoa. It is native to the area east of the Mississippi River, from Ontario to Florida.
Abstract:The freshwater bryozoan species Pectinatella magnifica was found in 6 sandpits and in 19 mostly extensively managed ponds in the Protected Landscape Area and Biosphere Reserve Třeboňsko (Czech Republic) from its first record (in 2003) to 2012. Mean fresh biomass and abundance of P. magnifica colonies were 0.6 ± 1.5 kg m −2 and 0.7 ± 1.1 colony m −2 (± SD), respectively, in the shoreline zone during the growing season 2006-2011. The maximum biomass was mostly recorded during the first half of August in all basins. Colonization of further localities was recorded rather than increasing of P. magnifica biomass or abundance in 2012. There were no correlations between water temperature or water transparency and biomass/abundance of P. magnifica during the growing season. P. magnifica colonies preferred to grow on the branches or roots (especially of Salix sp.) to aquatic macrophytes and stones. Most of the water bodies, where this bryozoan species occurred, had lower concentration of total phosphorus in the water when compared with the typical fishponds in the Czech Republic. Inner space of colonies of P. magnifica provided suitable higher trophic level substrate when compared with the water of the sandpits/fishponds especially for green coccal algae. A massive algal colonization was indentified in decomposing colonies at the end of the growing season.
Hybrid sorrel is a perennial crop whose benefits include good wintering, early ripening, and relatively high biomass and energy yields. The average yields are usually in the range from 4 to 10 t ha−1 dry matter (DM) per year. Based on a long‐term study, a significant fertilization effect on hybrid sorrel yield was found. The crop establishment in spring is preceded by plowing in autumn. Hybrid sorrel can be harvested in the year following the establishment. As a perennial crop, hybrid sorrel provides ecosystem services to a greater extent than first‐generation annual crops. They are, for example, habitat functioning, air regulation, biodiversity conservation, anti‐erosion effect, and groundwater protection. After cultivation, it can leave up to 60 t ha−1 of slightly mineralizable organic matter in the soil. Hybrid sorrel's drawbacks include low resistance against weeds and sensitivity to drought damage. According to the available data, this hybrid sorrel is one of the most promising energy crops in the temperate zone. It is suitable for both combustion and biogas production. In biogas production, sorrel produces a total methane yield of about 2500 to 3500 mN3 ha−1, and as a biofuel for combustion it shows a relatively high DM calorific value, of about 18 MJ kg−1. Alongside its use for energy and fodder purposes, it can be cultivated to produce medicines and unique building materials. It can also be used for the phytoremediation of contaminated soils. © 2020 Society of Industrial Chemistry and John Wiley & Sons Ltd
Anaerobic digestion (AD) is a biotechnological process in which organic matter is microbially converted into biogas and digestate. Many parameters affect the underlying microbial processes, including depolymerization of organic compounds, acidogenesis, acetogenesis and methanogenesis, as part of the AD cycle. Optimal concentrations of different nutrients and micronutrients are a prerequisite for optimum microbial growth and metabolism in AD processes. The effluent digestate can be used as a substitute for chemical fertilizers, recycling nutrients to create more sustainable agricultural production systems. Trace elements (TEs) can be transferred to soils during application of digestate as fertilizer, being subjected to environmental influences. To evaluate TEs bioavailability and uptake by plants (which can be transferred to the food chain), TEs leaching processes (which can prevent loss of soils nutrients and run off in ground waters), and TEs effects on soil organisms (which can affect soil fertility and productivity), it is relevant to assess the fate and availability of TEs after land application of digestate. This book chapter provides an overview of different type of biogas plants and digestate post-treatment processes. Trace Elements in Anaerobic BiotechnologiesAssessing fate and bioavailability of trace elements
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