DOCSLIB.ORG

Seaweed Potential As a Marine Vegetable and Other Opportunities

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Seaweed Potential As a Marine Vegetable and Other Opportunities Seaweed Potential as a marine vegetable and other opportunities by Barry Lee January 2008 RIRDC Publication No 08/009 RIRDC Project No CON-9A © 2008 Rural Industries Research and Development Corporation. All rights reserved. ISBN 1 74151 598 X ISSN 1440-6845 Seaweed: Potential as a marine vegetable and other opportunities Publication No. 08/009 Project No. CON-9A The information contained in this publication is intended for general use to assist public knowledge and discussion and to help improve the development of sustainable regions. You must not rely on any information contained in this publication without taking specialist advice relevant to your particular circumstances. While reasonable care has been taken in preparing this publication to ensure that information is true and correct, the Commonwealth of Australia gives no assurance as to the accuracy of any information in this publication. The Commonwealth of Australia, the Rural Industries Research and Development Corporation (RIRDC), the authors or contributors expressly disclaim, to the maximum extent permitted by law, all responsibility and liability to any person, arising directly or indirectly from any act or omission, or for any consequences of any such act or omission, made in reliance on the contents of this publication, whether or not caused by any negligence on the part of the Commonwealth of Australia, RIRDC, the authors or contributors. The Commonwealth of Australia does not necessarily endorse the views in this publication. This publication is copyright. Apart from any use as permitted under the Copyright Act 1968, all other rights are reserved. However, wide dissemination is encouraged. Requests and inquiries concerning reproduction and rights should be addressed to the RIRDC Publications Manager on phone 02 6271 4186 Researcher Contact Details Barry Lee Connectica International PO Box 294 Gymea Australia 2227 Phone: 0418 230393 Fax: 02 9545 2687 Email: [email protected] In submitting this report, the researcher has agreed to RIRDC publishing this material in its edited form. RIRDC Contact Details Rural Industries Research and Development Corporation Level 2, 15 National Circuit BARTON ACT 2600 PO Box 4776 KINGSTON ACT 2604 Phone: 02 6271 4100 Fax: 02 6272 4199 Email: [email protected]. Web: http://www.rirdc.gov.au Published in January 2008 Printed by Canprint ii Foreword Today in both Asian and western markets, the average consumer unknowingly consumes seaweed-derived products on an almost daily basis. These may range from processed foods, dairy products and cosmetics to garden fertilisers, pharmaceuticals and medicines. With such a breadth of industry applications, this project collates and consolidates information about the world seaweed industry based upon information from the International Seaweed Symposium, Japan (2007) and recent Australian industry research. The report is focussed primarily upon identifying the food research applications for seaweeds and seaweed products, especially those which may be used as marine vegetables. However, this report has also identified other research opportunities or seaweed applications which may provide additional broad benefits for rural Australia. The importance of this report is that it provides baseline statistical and research information for the international and Australian seaweed industry, and identifies the numerous market applications for seaweed products. It will be a useful basis for those contemplating investment or formulating policy and will help to inform RIRDC as it plans its research and development priorities into the future. This project was funded from RIRDC Core Funds which are provided by the Australian Government. This report, an addition to RIRDC’s diverse range of over 1700 research publications, forms part of our Asian Foods R&D program, which aims to support industry in its drive to develop new products and markets and to gain competitive advantage through productivity in, and achieving price premiums for, Australian production. Most of our publications are available for viewing, downloading or purchasing online through our website: downloads at www.rirdc.gov.au/fullreports/index.html purchases at www.rirdc.gov.au/eshop Peter O’Brien Managing Director Rural Industries Research and Development Corporation iii Acknowledgements Connectica International wishes to acknowledge the assistance and support of the following individuals and organisations with the compilation of this report: Mr Greg Jenkins Challenger TAFA, WA Mr Gavin Partridge Challenger TAFA, WA Mr Bruce Ginbey Challenger TAFA, WA Dr Craig Sanderson Consultant Dr Joe Herbertson Crucible Group (The) Assoc Professor Ravi Fotedar Curtin University Mr Vivek Kumar Curtin University Mr Robert Gott Dept of Primary Industries, Water and Environment Tasmania Mr Andrew Sharman Dept of Primary Industries, Water and Environment Tasmania Mr Paul Garrott Marinova Pty Ltd Dr Helen Fitton Marinova Pty Ltd Mr Derek Cropp Marinova Pty Ltd Professor John West Melbourne University Dr Leon Loftus Melbourne University Professor John Beardall Monash University Professor Michael Borowitzka Murdoch University Dr Geoff Allan NSW Department of Primary Industries Dr Pia Winberg Sustainable Seafood Pty Ltd Dr Gary Ellem University of Newcastle Abbreviations ABS Australian Bureau of Statistics AUSVEG Australian Vegetable and Potato Growers Federation A$ Australian Dollars CSIRO The Commonwealth Scientific and Industrial Research Organisation FAO Food and Agriculture Organisation HAL Horticulture Australia Limited IAAS Integrated Agri-Aquaculture Systems IMTA Integrated Multi-Trophic Aquaculture ISS International Seaweed Symposium (Japan 2007) $M $ Million NAC National Aquaculture Council NCEFF National Centre of Excellence for Functional Foods NHMRC National Health and Medical Research Council NSW New South Wales OFA Omega-3 Fatty Acids QLD Queensland RIRDC Rural Industries Research and Development Corporation SA South Australia SARDI South Australian Research and Development Institute US$ United States of America Dollars VIC Victoria WA Western Australia iv Contents Foreword ..............................................................................................................................................iii Acknowledgements.............................................................................................................................. iv Abbreviations....................................................................................................................................... iv List of Tables, Figures and Plates ...................................................................................................... vi Executive Summary ...........................................................................................................................vii What the report is about?..................................................................................................................vii Who is the report targeted at?...........................................................................................................vii Background ......................................................................................................................................vii Aims/Objectives ...............................................................................................................................vii Methods used...................................................................................................................................viii Results/Key findings .......................................................................................................................viii Implications.....................................................................................................................................viii Recommendations ............................................................................................................................xii 1. Introduction ...................................................................................................................................... 1 1.1 Background .................................................................................................................................. 1 1.2 What’s in a Name – Marine Vegetables? ..................................................................................... 1 1.3 The Consumer Today ................................................................................................................... 1 1.4 Objectives..................................................................................................................................... 2 1.5 Method.......................................................................................................................................... 2 2. Seaweeds and Consumers – An Overview...................................................................................... 3 2.1 What are Seaweeds?..................................................................................................................... 3 2.2 The Global Seaweed Industry ...................................................................................................... 3 2.3 The Australian Seaweed Industry................................................................................................. 4 2.4 Seaweeds and Australian Rural Research ...................................................................................
Load more

Recommended publications
  • Nutrient Bioextraction L
    soun nd d s sla tu i d g y n o NUTRIENT BIOEXTRACTION l WHAT IS NUTRIENT BIOEXTRACTION? HOW HAVE WE BEEN REDUCING Nutrient bioextraction (also called bioharvesting) is the NITROGEN IN LONG ISLAND SOUND? practice of farming and harvesting shellfish and seaweed for Since the 1990s, the Long Island Sound Study partners have the purpose of removing nitrogen and other nutrients from invested hundreds of millions of dollars to reduce the amount natural water bodies. of nitrogen discharged into the Sound and its watershed by upgrading wastewater treatment plants. National treatment WHY DO WE CARE ABOUT NITROGEN? standards do not require the breakdown and removal of nitrogen from sewage effluent. Other sources of nitrogen, Eutrophication has been identified by scientists as one of such as fertilizer and pet waste, have also been targeted by the most serious threats to coastal environments around the communities around the Sound. world. Reducing nutrient inputs is a top priority for many estuary programs in the United States, including Chesapeake Bay, Long Island Sound, and Great Bay. By reducing nutrients WHY DO WE NEED NUTRIENT BIOEXTRACTION? in coastal waters, states and federal agencies hope to reduce Efforts to control nutrient sources have reduced the amount widespread and recurring problems with algal blooms, loss of of nitrogen entering the Sound each year. However, changes seagrass, and hypoxia. in the Sound and its watershed, such as wetland loss and decreased populations of filter feeders, have diminished the capacity of the system to naturally process and treat nutrients. Nutrient bioextraction can complement source control programs, as do programs for wetland and riparian buffer restoration.
    [Show full text]
  • Kelp Cultivation Effectively Improves Water Quality and Regulates Phytoplankton Community in a Turbid, Highly Eutrophic Bay
    Science of the Total Environment 707 (2020) 135561 Contents lists available at ScienceDirect Science of the Total Environment journal homepage: www.elsevier.com/locate/scitotenv Kelp cultivation effectively improves water quality and regulates phytoplankton community in a turbid, highly eutrophic bay Zhibing Jiang a,b,d, Jingjing Liu a,ShangluLic,YueChena,PingDua,b,YuanliZhua,YiboLiaoa,d, Quanzhen Chen a, Lu Shou a, Xiaojun Yan e, Jiangning Zeng a,⁎, Jianfang Chen a,d a Key Laboratory of Marine Ecosystem and Biogeochemistry, State Oceanic Administration & Second Institute of Oceanography, Ministry of Natural Resources, Hangzhou, China b Function Laboratory for Marine Fisheries Science and Food Production Processes, Pilot National Laboratory for Marine Science and Technology (Qingdao), Qingdao, China c Marine Monitoring and Forecasting Center of Zhejiang Province, Hangzhou, China d State Key Laboratory of Satellite Ocean Environment Dynamics, Second Institute of Oceanography, Ministry of Natural Resources, Hangzhou, China e Key Laboratory of Applied Marine Biotechnology, Ministry of Education, Marine College of Ningbo University, Ningbo, China HIGHLIGHTS GRAPHICAL ABSTRACT • Kelp farming alleviated eutrophication and acidification. • Kelp farming greatly relieved light limi- tation and increased phytoplankton bio- mass. • Kelp farming appreciably enhanced phytoplankton diversity. • Kelp farming reduced the dominance of dinoflagellate Prorocentrum minimum. • Phytoplankton community differed sig- nificantly between the kelp farm and control area. article info abstract Article history: Coastal eutrophication and its associated harmful algal blooms have emerged as one of the most severe environ- Received 19 September 2019 mental problems worldwide. Seaweed cultivation has been widely encouraged to control eutrophication and Received in revised form 11 November 2019 algal blooms. Among them, cultivated kelp (Saccharina japonica) dominates primarily by production and area.
    [Show full text]
  • Nutrients and Bioactive Potentials of Edible Green and Red Seaweed in Korea K
    Sanjeewa et al. Fisheries and Aquatic Sciences (2018) 21:19 https://doi.org/10.1186/s41240-018-0095-y REVIEW Open Access Nutrients and bioactive potentials of edible green and red seaweed in Korea K. K. Asanka Sanjeewa, WonWoo Lee and You-Jin Jeon* Abstract Background: Traditionally, East-Asians (Korea, Japan, and China) utilize seaweeds as a food source and ingredient in traditional medicine. Korea is one of the biggest seaweed producer and consumer in the global trade. Especially, side dishes made from seaweeds are very popular in the traditional Korean cuisines. Seaweeds are popular as fresh vegetable salads and soup or eaten as snacks. Main body: Seaweeds are rich in essential nutrients, minerals, and vitamins as well as a promising source of novel bioactive compounds. The compounds (polysaccharides, polyphenols, and sterols) present in the edible Korean seaweeds possess important bioactive properties such as antioxidant, anti-inflammation, anticancer, anti-diabetic, and anticoagulant properties. Thus, the long-term consumption of seaweed has a potential to reduce the risk of cancer, diabetes, obesity, and inflammation-related complications. However, seaweed consumption is limited to the small population around the globe. Thus, it is important to increase the awareness of the health benefits of seaweeds consumption among the general population. Short conclusion: In the present study, we discussed some popular green and red edible Korean seaweeds and their health-promoting properties. This study might be useful to increase the public awareness of the consumption of seaweed as a food source. Keywords: Edible seaweed, Bioactive, Functional foods Background public awareness, demand for seaweeds and their commer- Seaweeds have been used as human food since ancient times.
    [Show full text]
  • Tofu Poke, Wakame, Corn Fit Potato Nori Soup
    TOFU POKE, WAKAME, CORN FIT Portion Size: ¾ cup Yield: 4 servings Tofu, extra firm 8 oz Corn, fresh, removed from cob 8 oz Canola Oil 1 tsp All Purpose Flour ¼ cup Corn Starch ¼ cup Salt ¾ tsp Black Pepper ½ tsp Sesame Oil 1 TBSP Wakame, Seaweed Salad ½ cup Ginger, fresh, minced 1 TBSP Soy Sauce, Low Sodium 1 TBSP Scallions, chopped 2 TBSP Jalapeno Peppers, minced 2 TBSP Sambal, Chili Paste 1 TBSP 1. Drain tofu and press it in a colander for 2 hours to rid of excess water. Cut tofu into 1/2" pieces. Nutrition Info (per serving): Cal: 240, 2. Toss corn with oil, roast at 350°F for 10-12 minutes or until tender. 3. In a bowl, whisk together flour, cornstarch, salt, and pepper. Toss cubed tofu Total Fat: 16g, Sat Fat: 2g, with dry ingredients and shake off excess. Sodium: 475 mg, Carbs: 14g, 4. Fry tofu in oil that is 350°F until golden brown. 5. Toast sesame oil in a pan until fragrant. Protein: 12g, Sugar: 3g, Fiber: 2g 6. In a large bowl, toss together roasted corn, fried tofu, toasted sesame oil, seaweed salad, ginger, soy sauce, scallion, jalapeno, and sambal. Chill. POTATO NORI SOUP FIT Portion Size: 1 cup Yield: 10 servings Water 10 cups Nori, finely chopped ¼ cup Yukon Gold Potatoes, diced 1 ½ cup Yellow Onion, chopped ½ cup Ginger, minced 2 tsp Garlic, minced 2 tsp Low Sodium Soy Sauce 1 TBSP Scallions, chopped 2 TBSP Sesame Oil 1 ½ tsp 1. Place water in large pot, add the nori and bring to a boil.
    [Show full text]
  • 10620150100042Co*
    CONSEJO NACIONAL DE INVESTIGACIONES CIENTIFICAS Y TECNICAS MINISTERIO DE CIENCIA, TECNOLOGIA E INNOVACION PRODUCTIVA Memoria 2014 CONVOCATORIA: Memoria 2014 SIGLA: CENPAT CENTRO NAC.PATAGONICO (I) DIRECTOR: GONZÁLEZ-JOSÉ, ROLANDO *10620150100042CO* 10620150100042CO 2014 MINISTERIO DE CIENCIA, TECNOLOGÍA E INNOVACIÓN PRODUCTIVA CONSEJO NACIONAL DE INVESTIGACIONES CIENTIFICAS Y TECNICAS MEMORIA UNIDADES EJECUTORAS 1. IDENTIFICACION DE LA UNIDAD EJECUTORA - VERIFICAR: Estos serán los datos donde se envien las comunicaciones formales 1.1 Datos Básicos (Instituto, Centro Cientro Científico Tecnológico o Programa o Laboratorio) Sigla Centro Nacional Patagónico CENPAT Domicilio Registrado / Rectificado Calle Bv. Almirante Brown 2915 Cód.Postal: U9120ACD Localidad: Puerto Madryn Provincia: Chubut Teléfonos: 54 02804 4883184 Fax: 54 0280 4883543 Correo Electrónico: [email protected] Web: www.cenpat-conicet.gob.ar Domicilio Rectificado Calle Cód.Postal: Localidad: Provincia: Teléfonos: Fax: Correo Electrónico: Web: DIRECTOR: Apellido/s Nombre/s Gonzalez-José Rolando Documento Inscripción AFIP DNI Nº 23.600.840 CUIL 20-23600840-2 Correo Electrónico: [email protected] Dans, Silvana Laura VICE-DIRECTOR (Apellido y Nombre): ç Gran Area de Conocimiento Código Otras Areas SI Cs. Agrarias, de la Ingeniería y de Materiales KA SI Cs. Biológicas y de la Salud KB SI Servicios SI Cs. Exactas y Naturales KE NO Centros Cientíco Tecnológico SI Cs. Sociales y Humanidades KS SI Tecnología KT 1.2 Dependencia Institucional Tipo de relación
    [Show full text]
  • FIC-Prop-65-Notice-Reporter.Pdf
    FIC Proposition 65 Food Notice Reporter (Current as of 9/25/2021) A B C D E F G H Date Attorney Alleged Notice General Manufacturer Product of Amended/ Additional Chemical(s) 60 day Notice Link was Case /Company Concern Withdrawn Notice Detected 1 Filed Number Sprouts VeggIe RotInI; Sprouts FruIt & GraIn https://oag.ca.gov/system/fIl Sprouts Farmers Cereal Bars; Sprouts 9/24/21 2021-02369 Lead es/prop65/notIces/2021- Market, Inc. SpInach FettucIne; 02369.pdf Sprouts StraIght Cut 2 Sweet Potato FrIes Sprouts Pasta & VeggIe https://oag.ca.gov/system/fIl Sprouts Farmers 9/24/21 2021-02370 Sauce; Sprouts VeggIe Lead es/prop65/notIces/2021- Market, Inc. 3 Power Bowl 02370.pdf Dawn Anderson, LLC; https://oag.ca.gov/system/fIl 9/24/21 2021-02371 Sprouts Farmers OhI Wholesome Bars Lead es/prop65/notIces/2021- 4 Market, Inc. 02371.pdf Brad's Raw ChIps, LLC; https://oag.ca.gov/system/fIl 9/24/21 2021-02372 Sprouts Farmers Brad's Raw ChIps Lead es/prop65/notIces/2021- 5 Market, Inc. 02372.pdf Plant Snacks, LLC; Plant Snacks Vegan https://oag.ca.gov/system/fIl 9/24/21 2021-02373 Sprouts Farmers Cheddar Cassava Root Lead es/prop65/notIces/2021- 6 Market, Inc. ChIps 02373.pdf Nature's Earthly https://oag.ca.gov/system/fIl ChoIce; Global JuIces Nature's Earthly ChoIce 9/24/21 2021-02374 Lead es/prop65/notIces/2021- and FruIts, LLC; Great Day Beet Powder 02374.pdf 7 Walmart, Inc. Freeland Foods, LLC; Go Raw OrganIc https://oag.ca.gov/system/fIl 9/24/21 2021-02375 Ralphs Grocery Sprouted Sea Salt Lead es/prop65/notIces/2021- 8 Company Sunflower Seeds 02375.pdf The CarrIngton Tea https://oag.ca.gov/system/fIl CarrIngton Farms Beet 9/24/21 2021-02376 Company, LLC; Lead es/prop65/notIces/2021- Root Powder 9 Walmart, Inc.
    [Show full text]
  • Vinegared Crab and Wakame Seaweed by Takuji Takahashi
    Vinegared Crab and Wakame Seaweed By Takuji Takahashi Ingredients 80g charcoal dried wakame from Naruto ‘Happo’ Vinegar (seasoned cooking vinegar) 4 rape blossoms 50g wakame from Iwate Sanriku 50ml rice vinegar 100ml umadashi broth 6 boiled crab legs 25g sugar Thin sliced pickled Shogo-in turnips 10g kombu seaweed 150ml dark soy sauce (copper pot specific) 1 large turnip (about 20 slices can be made per turnip) 300ml water 4 sprigs of red shiso flowers salt (2% of turnip weight) 25ml light soy sauce ginger to taste 200ml water 2 dried sardines broth for cooking the wakame 30g kombu seaweed 500ml dashi x 2 150ml rice vinegar Yoshino kuzu (arrowroot) powder, to taste 80ml mirin ‘All purpose’ dashi (to make in bulk) 60ml sake 1.2L dashi 80g sugar 80ml light soy sauce 2 red chili peppers (capsicum annuum) 80ml sake 80ml mirin Serves 4 1. Add 150ml of water and dark soy sauce to a copper pot and heat for 4-5 hours, releasing the mineral qualities of the copper. 2. Add the dashi ingredients in a stock pot. 3. Remove the thick skin of the turnip, and slice thinly with a mandolin slicer. Sprinkle salt on the sliced turnips. Once the salt has been absorbed, rinse with water and drain. 4. In a saucepan, bring the dashi broth base for the senmai zuke to a light simmer, then cool in ice water. 5. Divide the turnip slices from step 3 into one third lightly pickled slices and two thirds deeply pickled ones. The lighter pickles take about half a day, or a minimum of 20 to 30 minutes.
    [Show full text]
  • Happy Hour Umami Lingo
    umami lingo happy hour BOTTARGA Salted, dried fish roe Monday all day Tuesday-Saturday 3-6:30 p.m. Dine-in only BONITO Dried fish used to make stock DASHI Stock made from fish & seaweed drinks DRAFT BEER & BOMBS $1 OFF Typically a Chinese spice blend of cinnamon, FIVE SPICE cloves, fennel, star anise & Szechwan LONESTAR DRAFT 3 peppercorns SELECT WINE BY THE GLASS 4 Dry seasoning mixture of ingredients including SAUZA SILVER MARGARITA 5 FURIKAKE nori & sesame seeds FROZEN BLOOD ORANGE MARGARITA 6 Spicy paste used in Korean cooking, made FROZEN BANANA DAIQUIRI 6 GOCHUJANG from red chili peppers, fermented soy beans, rice & salt COCKTAILS 7 Island Mule, EXSW Margarita, Cooking technique that involves deep frying Tahitian Sangria, Piña Old Fashioned, KARAAGE meat coated with seasoned wheat flower or Magnum, P.I., Blue Hawaiian No. 4, potato starch mix Caribbean Cowboy, Eastern Sour KIZAMI NORI Shredded seaweed veggies+Cool CHARRED EDAMAME V Thick paste seasoning made from fermenting MISO salted 4 spicy 4.5 soy beans CHIPS & GUAC V 6 Tart, citrus-based sauce with a thin consistency EDAMAME HUMMUS V 6 PONZU & dark brown color THAI HIPPIE TOFU V 6 P&E SHRIMP GF 11 National alcoholic drink of Japan made from SAKE water & rice that has been polished to remove EGGS2 6 the husk YUMMY FRIES 10 Spicy, salty paste made from fermented fava TOBAN DJAN beans, soybeans, salt, rice & various spices warm Flavored chili pepper, which typically blends red BRISKET RANGOONS 7 TOGARASHI chili pepper, orange peel, black & white sesame seeds, ginger & nori SHISHITO PEPPER QUESO 5 An edible brown seaweed used typically in JFC POPCORN CHICKEN 10 WAKAME Kung Pao or Honey Sriracha the dried form sweets WHITE SHOYU A type of Japanese soy sauce HONG KONG WAFFLE 7 Salty & tart citrus fruit with a bumpy rind.
    [Show full text]
  • Analysis of Iodine Content in Seaweed by GC-ECD and Estimation of Iodine Intake
    journal of food and drug analysis 22 (2014) 189e196 Available online at www.sciencedirect.com ScienceDirect journal homepage: www.jfda-online.com Original Article Analysis of iodine content in seaweed by GC-ECD and estimation of iodine intake Tai Sheng Yeh*, Nu Hui Hung, Tzu Chun Lin Department of Food Science and Nutrition, Meiho University, Pingtung 91202, Taiwan, ROC article info abstract Article history: Edible seaweed products have been consumed in many Asian countries. Edible seaweeds Received 17 February 2013 accumulate iodine from seawater, and are therefore a good dietary source of iodine. An Received in revised form adequate consumption of seaweed can eliminate iodine deficiency disorders, but excessive 6 March 2013 iodine intake is not good for health. The recommended dietary reference intake of 0.15 mg/ Accepted 17 September 2013 d and 0.14 mg/d for iodine has been established in the United States and Taiwan, Available online 17 February 2014 respectively. In this study, 30 samples of seaweed were surveyed for iodine content. The samples included 10 nori (Porphyra), 10 wakame (Undaria), and 10 kombu (Laminaria) Keywords: products. The iodine in seaweed was derivatized with 3-pentanone and detected by gas GC-ECD chromatography-electron capture detector (GC-ECD). The method detection limit was Iodine 0.5 mg/kg. The iodine content surveyed for nori was 29.3e45.8 mg/kg, for wakame 93.9 Kombu e185.1 mg/kg, and for kombu 241e4921 mg/kg. Kombu has the highest average iodine Nori content 2523.5 mg/kg, followed by wakame (139.7 mg/kg) and nori (36.9 mg/kg).
    [Show full text]
  • Neoproterozoic Origin and Multiple Transitions to Macroscopic Growth in Green Seaweeds
    Neoproterozoic origin and multiple transitions to macroscopic growth in green seaweeds Andrea Del Cortonaa,b,c,d,1, Christopher J. Jacksone, François Bucchinib,c, Michiel Van Belb,c, Sofie D’hondta, f g h i,j,k e Pavel Skaloud , Charles F. Delwiche , Andrew H. Knoll , John A. Raven , Heroen Verbruggen , Klaas Vandepoeleb,c,d,1,2, Olivier De Clercka,1,2, and Frederik Leliaerta,l,1,2 aDepartment of Biology, Phycology Research Group, Ghent University, 9000 Ghent, Belgium; bDepartment of Plant Biotechnology and Bioinformatics, Ghent University, 9052 Zwijnaarde, Belgium; cVlaams Instituut voor Biotechnologie Center for Plant Systems Biology, 9052 Zwijnaarde, Belgium; dBioinformatics Institute Ghent, Ghent University, 9052 Zwijnaarde, Belgium; eSchool of Biosciences, University of Melbourne, Melbourne, VIC 3010, Australia; fDepartment of Botany, Faculty of Science, Charles University, CZ-12800 Prague 2, Czech Republic; gDepartment of Cell Biology and Molecular Genetics, University of Maryland, College Park, MD 20742; hDepartment of Organismic and Evolutionary Biology, Harvard University, Cambridge, MA 02138; iDivision of Plant Sciences, University of Dundee at the James Hutton Institute, Dundee DD2 5DA, United Kingdom; jSchool of Biological Sciences, University of Western Australia, WA 6009, Australia; kClimate Change Cluster, University of Technology, Ultimo, NSW 2006, Australia; and lMeise Botanic Garden, 1860 Meise, Belgium Edited by Pamela S. Soltis, University of Florida, Gainesville, FL, and approved December 13, 2019 (received for review June 11, 2019) The Neoproterozoic Era records the transition from a largely clear interpretation of how many times and when green seaweeds bacterial to a predominantly eukaryotic phototrophic world, creat- emerged from unicellular ancestors (8). ing the foundation for the complex benthic ecosystems that have There is general consensus that an early split in the evolution sustained Metazoa from the Ediacaran Period onward.
    [Show full text]
  • Edible Seaweed from Wikipedia, the Free Encyclopedia
    Edible seaweed From Wikipedia, the free encyclopedia Edible seaweed are algae that can be eaten and used in the preparation of food. They typically contain high amounts of fiber.[1] They may belong to one of several groups of multicellular algae: the red algae, green algae, and brown algae. Seaweeds are also harvested or cultivated for the extraction of alginate, agar and carrageenan, gelatinous substances collectively known as hydrocolloids or phycocolloids. Hydrocolloids have attained commercial significance, especially in food production as food A dish of pickled spicy seaweed additives.[2] The food industry exploits the gelling, water-retention, emulsifying and other physical properties of these hydrocolloids. Most edible seaweeds are marine algae whereas most freshwater algae are toxic. Some marine algae contain acids that irritate the digestion canal, while some others can have a laxative and electrolyte-balancing effect.[3] The dish often served in western Chinese restaurants as 'Crispy Seaweed' is not seaweed but cabbage that has been dried and then fried.[4] Contents 1 Distribution 2 Nutrition and uses 3 Common edible seaweeds 3.1 Red algae (Rhodophyta) 3.2 Green algae 3.3 Brown algae (Phaeophyceae) 3.3.1 Kelp (Laminariales) 3.3.2 Fucales 3.3.3 Ectocarpales 4 See also 5 References 6 External links Distribution Seaweeds are used extensively as food in coastal cuisines around the world. Seaweed has been a part of diets in China, Japan, and Korea since prehistoric times.[5] Seaweed is also consumed in many traditional European societies, in Iceland and western Norway, the Atlantic coast of France, northern and western Ireland, Wales and some coastal parts of South West England,[6] as well as Nova Scotia and Newfoundland.
    [Show full text]
  • The Valorisation of Sargassum from Beach Inundations
    Journal of Marine Science and Engineering Review Golden Tides: Problem or Golden Opportunity? The Valorisation of Sargassum from Beach Inundations John J. Milledge * and Patricia J. Harvey Algae Biotechnology Research Group, School of Science, University of Greenwich, Central Avenue, Chatham Maritime, Kent ME4 4TB, UK; [email protected] * Correspondence: [email protected]; Tel.: +44-0208-331-8871 Academic Editor: Magnus Wahlberg Received: 12 August 2016; Accepted: 7 September 2016; Published: 13 September 2016 Abstract: In recent years there have been massive inundations of pelagic Sargassum, known as golden tides, on the beaches of the Caribbean, Gulf of Mexico, and West Africa, causing considerable damage to the local economy and environment. Commercial exploration of this biomass for food, fuel, and pharmaceutical products could fund clean-up and offset the economic impact of these golden tides. This paper reviews the potential uses and obstacles for exploitation of pelagic Sargassum. Although Sargassum has considerable potential as a source of biochemicals, feed, food, fertiliser, and fuel, variable and undefined composition together with the possible presence of marine pollutants may make golden tides unsuitable for food, nutraceuticals, and pharmaceuticals and limit their use in feed and fertilisers. Discontinuous and unreliable supply of Sargassum also presents considerable challenges. Low-cost methods of preservation such as solar drying and ensiling may address the problem of discontinuity. The use of processes that can handle a variety of biological and waste feedstocks in addition to Sargassum is a solution to unreliable supply, and anaerobic digestion for the production of biogas is one such process.
    [Show full text]