Suchergebnisse

Coastal countries have traditionally relied on the existing marine resources (e.g., fishing, food, transport, recreation, and tourism) as well as tried to support new economic endeavors (ocean energy, desalination for water supply, and seabed mining). Modern societies and lifestyle resulted in an increased demand for dietary diversity, better health and well-being, new biomedicines, natural cosmeceuticals, environmental conservation, and sustainable energy sources. These societal needs stimulated the interest of researchers on the diverse and underexplored marine environments as promising and sustainable sources of biomolecules and biomass, and they are addressed by the emerging field of marine (blue) biotechnology. Blue biotechnology provides opportunities for a wide range of initiatives of commercial interest for the pharmaceutical, biomedical, cosmetic, nutraceutical, food, feed, agricultural, and related industries. This article synthesizes the essence, opportunities, responsibilities, and challenges encountered in marine biotechnology and outlines the attainment and valorization of directly derived or bio-inspired products from marine organisms. First, the concept of bioeconomy is introduced. Then, the diversity of marine bioresources including an overview of the most prominent marine organisms and their potential for biotechnological uses are described. This is followed by introducing methodologies for exploration of these resources and the main use case scenarios in energy, food and feed, agronomy, bioremediation and climate change, cosmeceuticals, bio-inspired materials, healthcare, and well-being sectors. The key aspects in the fields of legislation and funding are provided, with the emphasis on the importance of communication and stakeholder engagement at all levels of biotechnology development. Finally, vital overarching concepts, such as the quadruple helix and Responsible Research and Innovation principle are highlighted as important to follow within the marine biotechnology field. The authors of this review are collaborating under the European Commission-funded Cooperation in Science and Technology (COST) Action Ocean4Biotech – European transdisciplinary networking platform for marine biotechnology and focus the study on the European state of affairs.

Coastal countries have traditionally relied on the existing marine resources (e.g., fishing, food, transport, recreation, and tourism) as well as tried to support new economic endeavors (ocean energy, desalination for water supply, and seabed mining). Modern societies and lifestyle resulted in an increased demand for dietary diversity, better health and well-being, new biomedicines, natural cosmeceuticals, environmental conservation, and sustainable energy sources. These societal needs stimulated the interest of researchers on the diverse and underexplored marine environments as promising and sustainable sources of biomolecules and biomass, and they are addressed by the emerging field of marine (blue) biotechnology. Blue biotechnology provides opportunities for a wide range of initiatives of commercial interest for the pharmaceutical, biomedical, cosmetic, nutraceutical, food, feed, agricultural, and related industries. This article synthesizes the essence, opportunities, responsibilities, and challenges encountered in marine biotechnology and outlines the attainment and valorization of directly derived or bio-inspired products from marine organisms. First, the concept of bioeconomy is introduced. Then, the diversity of marine bioresources including an overview of the most prominent marine organisms and their potential for biotechnological uses are described. This is followed by introducing methodologies for exploration of these resources and the main use case scenarios in energy, food and feed, agronomy, bioremediation and climate change, cosmeceuticals, bio-inspired materials, healthcare, and well-being sectors. The key aspects in the fields of legislation and funding are provided, with the emphasis on the importance of communication and stakeholder engagement at all levels of biotechnology development. Finally, vital overarching concepts, such as the quadruple helix and Responsible Research and Innovation principle are highlighted as important to follow within the marine biotechnology field. The authors of this review are collaborating under the European Commission-funded Cooperation in Science and Technology (COST) Action Ocean4Biotech – European transdisciplinary networking platform for marine biotechnology and focus the study on the European state of affairs. ; This publication is based upon work from COST Action CA18238 (Ocean4Biotech), supported by COST (European Cooperation in Science and Technology) program.AR, KK, and TR: the publication is part of a project that has received funding from the European Union Horizon 2020 Research and Innovation Programme under grant agreement no. 774499 – GoJelly project. AR and KK: this research was funded by the Slovenian Research Agency (research core funding P1-0245 and P1-0237). AR: this publication has been produced with financial assistance of the Interreg MED Programme, co-financed by the European Regional Development Fund (Project No. 7032, internal ref. 8MED20_4.1_SP_001) – B-Blue project. AB: acknowledges the support from the Research Council of Norway through the grant 267474 from the HAVBRUK2 program. MLC: acknowledges the Portuguese Foundation for Science and Technology (UIDB/04326/2020), the European Maritime and Fisheries Fund (MAR2020 OSTEOMAR/16-02-01-FMP-0057 and ALGASOLE/16.02.01-FMP-0058), the European Regional Development Fund (Atlantic Area BLUEHUMAN/EAPA/151/2016 and INTERREG V-A Spain-Portugal ALGARED+), and the European Commision (H2020-MSCA-ITN BIOMEDAQU/766347). MFC: wishes to acknowledge the funding from CEEC program supported by FCT/MCTES (CEECIND/02968/2017); ACTINODEEPSEA project (POCI-01-0145-FEDER-031045) co-financed by COMPETE 2020, Portugal 2020, ERDF and FCT; Strategic Funding UIDB/04423/2020 and UIDP/04423/2020 through national funds provided by FCT and ERDF. MC: financial support from the Programme of the Institute of Oceanology, PAS (grant no. II.3) and National Science Centre in Poland (project number NCN 2016/21/B/NZ9/02304). MCu: acknowledges the funding from the Ministerio de Ciencia e Innovación of Spain (SAF2009-0839 and RTA 2015-00010-C03-02) and INTERREG-MAC2/1.1b/279 (AHIDAGRO). AD-M: acknowledge financial support from INTERREG-MAC/1.1b/042 (BIOTRANSFER2) and Agustín de Betancourt Programme (Cabildo de Tenerife and Universidad de La Laguna). AD: work has been supported by the ERDF Activity 1.1.1.2 "Post-doctoral Research Aid" of the Specific Aid Objective 1.1.1, Operational Programme "Growth and Employment" (No. 1.1.1.2/VIAA/1/16/048). RJF: funding for this research was provided under the Marine Research Programme 2014–2020, through the Marine Institute of Ireland under grant PBA/MB/16/01 "A National Marine Biodiscovery Laboratory of Ireland (NMBLI)" and through the Food Institutional Research Measure, administered by the Department of Agriculture, Food, and the Marine, Ireland under grant issue 17/F/260 (MaraBioActive). SG: this work was supported by the Applied Molecular Biosciences Unit-UCIBIO which is financed by national funds from FCT/MCTES (UID/Multi/04378/2019). SG thanks financial support provided by FCT/MCTES through grant IF/00700/2014 and OceanTresaures project PTDC/QUIQUI/119116/2010. NID: wishes to acknowledge the funding from the Croatian Science Foundation Project CELLSTRESS (IP-2018-01-5840). MMa and TD: we wish to acknowledge funding from the General Secretariat for Research and Technology (GSRT) and the Hellenic Foundation for Research and Innovation (HFRI) under grant no. 239 (SPINAQUA project). AM-G: acknowledges the financial contribution from the project BYTHOS funded by the European Union's Interreg V-A Italia-Malta Programme under project code C1-1.1-9. HM-M: financial support from National Science Centre in Poland 2016/21/B/NZ9/02304 and 2017/25/B/NZ9/00202. MMe: this work has been supported by the French Government, through the UCAJEDI Investments in the Future project managed by the National Research Agency (ANR) with the reference number ANR-15-IDEX-01. MMe: thanks the Canceropôle Provence-Alpes-Côte d'Azur, and the Provence-Alpes-Côte d'Azur Region for the financial support provided to the MetaboCell project. DO: supported by the Doctorate Study program in Ecology and Environmental Sciences, Marine Research Institute, Klaipėda University, Lithuania. CR: we gratefully acknowledge the Research Council of Norway, the Møre and Romsdal County Council and Møreforsking AS for their financial contributions through the PROMAC (244244; www.promac.no), the Norwegian Seaweed Biorefinery Platform (294946; http://seaweedplatform.no/), and the Blå-Grønn (55031) projects. ER: this work benefited from financial support from the PACA Canceropôle, the National Cancer Institute, the PACA Regional Council and the French Government, managed by the National Research Agency as part of the Université Côte d'AzurJEDI Investissement d'Avenir project (ANR-15-IDEX-01). JS: work was supported by the Slovenian Research Agency (P4-0127 and J4-1771). IS: financial support from Ministry of Education, Youth and Sports of the Czech Republic (project CZ.02.1.01/0.0/0.0/17_048/0007323). XT: the tool "RRI Roadmap" was developed as part of the European Horizon 2020 project MARINA "Marine Knowledge Sharing Platform for Federating Responsible Research and Innovation Communities" under the European Union's Horizon 2020 Research and Innovation Programme under Grant Agreement No. 710566 (2016–2019). OT: his contribution is carried out with the support of the Marine Institute and is funded under the Marine Research Programme by the Irish Government (Grant-Aid Agreement No. PBA/MB/16/01). ; Peer reviewed

Coastal countries have traditionally relied on the existing marine resources (e.g., fishing, food, transport, recreation, and tourism) as well as tried to support new economic endeavors (ocean energy, desalination for water supply, and seabed mining). Modern societies and lifestyle resulted in an increased demand for dietary diversity, better health and well-being, new biomedicines, natural cosmeceuticals, environmental conservation, and sustainable energy sources. These societal needs stimulated the interest of researchers on the diverse and underexplored marine environments as promising and sustainable sources of biomolecules and biomass, and they are addressed by the emerging field of marine (blue) biotechnology. Blue biotechnology provides opportunities for a wide range of initiatives of commercial interest for the pharmaceutical, biomedical, cosmetic, nutraceutical, food, feed, agricultural, and related industries. This article synthesizes the essence, opportunities, responsibilities, and challenges encountered in marine biotechnology and outlines the attainment and valorization of directly derived or bio-inspired products from marine organisms. First, the concept of bioeconomy is introduced. Then, the diversity of marine bioresources including an overview of the most prominent marine organisms and their potential for biotechnological uses are described. This is followed by introducing methodologies for exploration of these resources and the main use case scenarios in energy, food and feed, agronomy, bioremediation and climate change, cosmeceuticals, bio-inspired materials, healthcare, and well-being sectors. The key aspects in the fields of legislation and funding are provided, with the emphasis on the importance of communication and stakeholder engagement at all levels of biotechnology development. Finally, vital overarching concepts, such as the quadruple helix and Responsible Research and Innovation principle are highlighted as important to follow within the marine biotechnology field. The authors of this review are collaborating under the European Commission-funded Cooperation in Science and Technology (COST) Action Ocean4Biotech – European transdisciplinary networking platform for marine biotechnology and focus the study on the European state of affairs.