Seaweed Explained

Seaweed, or macroalgae, refers to thousands of species of macroscopic, multicellular, marine algae. The term includes some types of Rhodophyta (red), Phaeophyta (brown) and Chlorophyta (green) macroalgae. Seaweed species such as kelps provide essential nursery habitat for fisheries and other marine species and thus protect food sources; other species, such as planktonic algae, play a vital role in capturing carbon and producing at least 50% of Earth's oxygen.[1]

Natural seaweed ecosystems are sometimes under threat from human activity. For example, mechanical dredging of kelp destroys the resource and dependent fisheries. Other forces also threaten some seaweed ecosystems; for example, a wasting disease in predators of purple urchins has led to an urchin population surge which has destroyed large kelp forest regions off the coast of California.[2]

Humans have a long history of cultivating seaweeds for their uses. In recent years, seaweed farming has become a global agricultural practice, providing food, source material for various chemical uses (such as carrageenan), cattle feeds and fertilizers. Due to their importance in marine ecologies and for absorbing carbon dioxide, recent attention has been on cultivating seaweeds as a potential climate change mitigation strategy for biosequestration of carbon dioxide, alongside other benefits like nutrient pollution reduction, increased habitat for coastal aquatic species, and reducing local ocean acidification.[3] The IPCC Special Report on the Ocean and Cryosphere in a Changing Climate recommends "further research attention" as a mitigation tactic.[4]

Taxonomy

"Seaweed" lacks a formal definition, but seaweed generally lives in the ocean and is visible to the naked eye. The term refers to both flowering plants submerged in the ocean, like eelgrass, as well as larger marine algae. Generally, it is one of several groups of multicellular algae; red, green and brown.[5] They lack one common multicellular ancestor, forming a polyphyletic group. In addition, blue-green algae (Cyanobacteria) are occasionally considered in seaweed literature.[6]

The number of seaweed species is still a topic of discussion among scientists, but it is most likely that there are several thousand species of seaweed.[7]

Genera

The following table lists a very few example genera of seaweed.

Genus Algae
Phylum
Remarks
Caulerpa Green Submerged.
Fucus Brown In intertidal zones on rocky shores.
Gracilaria Red Cultivated for food.
Laminaria Brown Also known as kelp
8–30 m under water and
cultivated for food.
Macrocystis Brown Giant kelp
forming floating canopies.
Monostroma Green
Porphyra Red Intertidal zones in temperate climate and
cultivated for food.
SargassumBrownPelagic especially in the Sargasso Sea.

Anatomy

Seaweed's appearance resembles non-woody terrestrial plants. Its anatomy includes:[8] [9]

The stipe and blade are collectively known as the frond.

Ecology

Two environmental requirements dominate seaweed ecology. These are seawater (or at least brackish water) and light sufficient to support photosynthesis. Another common requirement is an attachment point, and therefore seaweed most commonly inhabits the littoral zone (nearshore waters) and within that zone, on rocky shores more than on sand or shingle. In addition, there are few genera (e.g., Sargassum and Gracilaria) which do not live attached to the sea floor, but float freely.

Seaweed occupies various ecological niches. At the surface, they are only wetted by the tops of sea spray, while some species may attach to a substrate several meters deep. In some areas, littoral seaweed colonies can extend miles out to sea. The deepest living seaweed are some species of red algae. Others have adapted to live in tidal rock pools. In this habitat, seaweed must withstand rapidly changing temperature and salinity and occasional drying.[10]

Macroalgae and macroalgal detritus have also been shown to be an important food source for benthic organisms, because macroalgae shed old fronds.[11] These macroalgal fronds tend to be utilized by benthos in the intertidal zone close to the shore.[12] [13] Alternatively, pneumatocysts (gas filled "bubbles") can keep the macroalgae thallus afloat; fronds are transported by wind and currents from the coast into the deep ocean.[11] It has been shown that benthic organisms also at several 100 m tend to utilize these macroalgae remnants.[13]

As macroalgae takes up carbon dioxide and releases oxygen in the photosynthesis, macroalgae fronds can also contribute to carbon sequestration in the ocean, when the macroalgal fronds drift offshore into the deep ocean basins and sink to the sea floor without being remineralized by organisms.[11] The importance of this process for blue carbon storage is currently a topic of discussion among scientists.[14] [15] [16]

Biogeographic expansion

Nowadays a number of vectors—e.g., transport on ship hulls, exchanges among shellfish farmers, global warming, opening of trans-oceanic canals—all combine to enhance the transfer of exotic seaweeds to new environments. Since the piercing of the Suez Canal, the situation is particularly acute in the Mediterranean Sea, a 'marine biodiversity hotspot' that now registers over 120 newly introduced seaweed species -the largest number in the world.[17]

Production

As of 2019, 35,818,961 tonnes were produced, of which 97.38% were produced in Asian countries.[18]

Seaweed production! Country! tonns
per year,
cultured and wild
China20,351,442
Indonesia 9,962,900
South Korea1,821,475
Philippines 1,500,326
North Korea603,000
Chile 427,508
Japan412,300
Malaysia188,110
Norway 163,197
United Republic of Tanzania 106,069

Farming

Uses

Seaweed has a variety of uses, for which it is farmed[19] or foraged.[20]

Food

See main article: Edible seaweed. Seaweed is consumed across the world, particularly in East Asia, e.g., Japan, China, Korea, Taiwan and Southeast Asia, e.g. Brunei, Singapore, Thailand, Burma, Cambodia, Vietnam, Indonesia, the Philippines, and Malaysia,[21] as well as in South Africa, Belize, Peru, Chile, the Canadian Maritimes, Scandinavia, South West England,[22] Ireland, Wales, Hawaii and California, and Scotland.

Gim (김, Korea), nori (Japan) and zicai (China) are sheets of dried Porphyra used in soups, sushi or onigiri (rice balls). Gamet in the Philippines, from dried Pyropia, is also used as a flavoring ingredient for soups, salads and omelettes.[23] Chondrus crispus ('Irish moss' or carrageenan moss) is used in food additives, along with Kappaphycus and Gigartinoid seaweed. Porphyra is used in Wales to make laverbread (sometimes with oat flour). In northern Belize, seaweed is mixed with milk, nutmeg, cinnamon and vanilla to make "Spanish; Castilian: dulce" ("sweet").

Alginate, agar and carrageenan are gelatinous seaweed products collectively known as hydrocolloids or phycocolloids. Hydrocolloids are food additives.[24] The food industry exploits their gelling, water-retention, emulsifying and other physical properties. Agar is used in foods such as confectionery, meat and poultry products, desserts and beverages and moulded foods. Carrageenan is used in salad dressings and sauces, dietetic foods, and as a preservative in meat and fish, dairy items and baked goods.

Seaweeds are used as animal feeds. They have long been grazed by sheep, horses and cattle in Northern Europe, even though their nutritional benefits are questionable. Their protein content is low and their heavy metal content is high, especially for arsenic and iodine, which are respectively toxic and nutritious.[25] [26]

They are valued for fish production.[27] Adding seaweed to livestock feed can substantially reduce methane emissions from cattle,[28] but only from their feedlot emissions. As of 2021, feedlot emissions account for 11% of overall emissions from cattle. [29]

Medicine and herbs

See also: Fucoidan.

Alginates are used in wound dressings (see alginate dressing), and dental moulds. In microbiology, agar is used as a culture medium. Carrageenans, alginates and agaroses, with other macroalgal polysaccharides, have biomedicine applications. Delisea pulchra may interfere with bacterial colonization.[30] Sulfated saccharides from red and green algae inhibit some DNA and RNA-enveloped viruses.[31]

Seaweed extract is used in some diet pills.[32] Other seaweed pills exploit the same effect as gastric banding, expanding in the stomach to make the stomach feel more full.[33] [34]

Other uses

See also: Seaweed fertilizer and Seaweed fuel.

Other seaweed may be used as fertilizer, compost for landscaping, or to combat beach erosion through burial in beach dunes.[35]

Seaweed is under consideration as a potential source of bioethanol.[36] [37]

Alginates are used in industrial products such as paper coatings, adhesives, dyes, gels, explosives and in processes such as paper sizing, textile printing, hydro-mulching and drilling. Seaweed is an ingredient in toothpaste, cosmetics and paints. Seaweed is used for the production of bio yarn (a textile).[38]

Several of these resources can be obtained from seaweed through biorefining.

Seaweed collecting is the process of collecting, drying and pressing seaweed. It was a popular pastime in the Victorian era and remains a hobby today. In some emerging countries, seaweed is harvested daily to support communities.

Seaweed is sometimes used to build roofs on houses on Læsø in Denmark.[39]

Health risks

Rotting seaweed is a potent source of hydrogen sulfide, a highly toxic gas, and has been implicated in some incidents of apparent hydrogen sulfide poisoning.[40] It can cause vomiting and diarrhea.

The so-called "stinging seaweed" Microcoleus lyngbyaceus is a filamentous cyanobacteria which contains toxins including lyngbyatoxin-a and debromoaplysiatoxin. Direct skin contact can cause seaweed dermatitis characterized by painful, burning lesions that last for days.[41] [42]

Threats

Bacterial disease ice-ice infects Kappaphycus (red seaweed), turning its branches white. The disease caused heavy crop losses in the Philippines, Tanzania and Mozambique.[43]

Sea urchin barrens have replaced kelp forests in multiple areas. They are "almost immune to starvation". Lifespans can exceed 50 years. When stressed by hunger, their jaws and teeth enlarge, and they form "fronts" and hunt for food collectively.

See also

Further reading

External links

Notes and References

  1. Web site: How much oxygen comes from the ocean? . National Ocean Service . National Oceanic and Atmospheric Administration . 23 November 2021.
  2. Web site: California's crashing kelp forest. 2021-02-24. phys.org. en.
  3. Duarte. Carlos M.. Wu. Jiaping. Xiao. Xi. Bruhn. Annette. Krause-Jensen. Dorte. 2017. Can Seaweed Farming Play a Role in Climate Change Mitigation and Adaptation?. Frontiers in Marine Science. en. 4. 10.3389/fmars.2017.00100. 2296-7745. free.
  4. Book: Bindoff. N. L.. IPCC Special Report on the Ocean and Cryosphere in a Changing Climate. Cheung. W. W. L.. Kairo. J. G.. Arístegui. J.. Guinder. V. A.. Hallberg. R.. Hilmi. N. J. M.. Jiao. N.. Karim. Md S.. 2019. 447–587. Chapter 5: Changing Ocean, Marine Ecosystems, and Dependent Communities. . 4. https://www.ipcc.ch/site/assets/uploads/sites/3/2019/11/09_SROCC_Ch05_FINAL.pdf. L.. Williamson. P.. Tagliabue. A.. Suga. Purca Cuicapusa. Rinkevich. B.. S. R.. O'Donoghue. S.. Levin. T..
  5. Web site: 2019-06-15 . 5.4: Algae . 2024-02-10 . Biology LibreTexts . en.
  6. Lobban . Christopher S. . Harrison . Paul J. . Morphology, life histories, and morphogenesis . Seaweed Ecology and Physiology . 1994 . 1–68 . 10.1017/CBO9780511626210.002 . 9780521408974 .
  7. Book: Townsend . David W. . Oceanography and Marine Biology: An Introduction to Marine Science . March 2012 . Oxford University Press Inc . 9780878936021.
  8. Web site: seaweed menu. www.easterncapescubadiving.co.za. 2019-04-28. 2020-02-17. https://web.archive.org/web/20200217082733/https://www.easterncapescubadiving.co.za/index.php?page_name=more&list_id=158. dead.
  9. Web site: 2017-02-06 . The Science of Seaweeds . 2022-06-02 . American Scientist . en.
  10. Lewis, J. R. 1964. The Ecology of Rocky Shores. The English Universities Press Ltd.
  11. Krause-Jensen . Dorte . Duarte . Carlos . Substantial role of macroalgae in marine carbon sequestration . Nature Geoscience . 2016 . 9 . 10 . 737–742 . 10.1038/ngeo2790 . 2016NatGe...9..737K . .
  12. Dunton . K. H. . Schell . D. M. . Dependence of consumers on macroalgal (Laminaria solidungula) carbon in an arctic kelp community: δ13C evidence . Marine Biology . 1987 . 93 . 4 . 615–625 . 10.1007/BF00392799. 1987MarBi..93..615D . 84714929 .
  13. Renaud . Paul E. . Løkken . Therese S. . Jørgensen . Lis L. . Berge . Jørgen . Johnson . Beverly J. . Macroalgal detritus and food-web subsidies along an Arctic fjord depth-gradient . Front. Mar. Sci. . June 2015 . 2 . 10.3389/fmars.2015.00031 . 10417856 . free .
  14. Watanabe . Kenta . Yoshida . Goro . Hori . Masakazu . Umezawa . Yu . Moki . Hirotada . Kuwae . Tomohiro . Macroalgal metabolism and lateral carbon flows can create significant carbon sinks . Biogeosciences . May 2020 . 17 . 9 . 2425–2440 . 10.5194/bg-17-2425-2020 . 2020BGeo...17.2425W . September 21, 2020. free .
  15. Krause-Jensen . Dorte . Lavery . Paul . Serrano . Oscar . Marbà . Núria . Masque . Pere . Duarte . Carlos M. . Sequestration of macroalgal carbon: the elephant in the Blue Carbon room . The Royal Society Publishing . June 2018 . 14 . 6 . 10.1098/rsbl.2018.0236 . 29925564 . 6030603 .
  16. Ortega . Alejandra . Geraldi . Nathan R. . Alam . Intikhab . Kamau . Allan A. . Acinas . Silvia G . Logares . Ramiro . Gasol . Josep M . Massana . Ramon . Krause-Jensen . Dorte . Duarte . Carlos M . Important contribution of macroalgae to oceanic carbon sequestration . Nature Geoscience . 2019 . 12 . 9 . 748–754 . 10.1038/s41561-019-0421-8. 2019NatGe..12..748O . 10754/656768 . 199448971 . free .
  17. Book: Briand, Frederic . CIESM Atlas of Exotic Species in the Mediterranean. Volume 4. Macrophytes. . 2015 . CIESM, Paris, Monaco . 9789299000342 . 364 .
  18. https://www.fao.org/3/cb4579en/cb4579en.pdf Global seaweeds and microalgae production(FAO)
  19. News: Seaweed farmers get better prices if united. Sun.Star. 2008-06-19. 2008-07-16. https://web.archive.org/web/20080909013255/http://www.sunstar.com.ph/static/dav/2008/06/19/bus/seaweed.farmers.get.better.prices.if.united.jica.html. 2008-09-09. dead.
  20. News: Springtime's foraging treats. 2008-07-16. 2007-01-06. The Guardian. London.
  21. Mohammad. Salma. 4 Jan 2020. Application of seaweed (Kappaphycus alvarezii) in Malaysian food products. International Food Research Journal. 26. 1677–1687.
  22. Web site: Devon Family Friendly – Tasty Seaweed Recipe – Honest! . BBC . 2005-05-25 . 2012-06-28.
  23. News: Adriano . Leilanie G. . 'Gamet' sushi festival launched . 15 August 2021 . The Manila Times . 21 December 2005.
  24. Round F. E. 1962 The Biology of the Algae. Edward Arnold Ltd.
  25. 10.1016/j.anifeedsci.2015.09.018 . Seaweeds for livestock diets: A review . 2016 . Makkar . Harinder P.S. . Tran . Gilles . Heuzé . Valérie . Giger-Reverdin . Sylvie . Lessire . Michel . Lebas . François . Ankers . Philippe . Animal Feed Science and Technology . 212 . 1–17 .
  26. 10.1002/jsfa.6681 . Characterization of protein, lipid and mineral contents in common Norwegian seaweeds and evaluation of their potential as food and feed . 2014 . Mæhre . Hanne K. . Malde . Marian K. . Eilertsen . Karl-Erik . Elvevoll . Edel O. . Journal of the Science of Food and Agriculture . 94 . 15 . 3281–3290 . 24700148 . 2014JSFA...94.3281M .
  27. Heuzé V., Tran G., Giger-Reverdin S., Lessire M., Lebas F., 2017. Seaweeds (marine macroalgae). Feedipedia, a programme by INRA, CIRAD, AFZ and FAO. https://www.feedipedia.org/node/78 Last updated on May 29, 2017, 16:46
  28. Web site: Seaweed shown to reduce 99% methane from cattle . 9 April 2018 . irishtimes.com.
  29. Dutkiewicz . Jan . Want Carbon-Neutral Cows? Algae Isn't the Answer . en-US . Wired . 2023-12-30 . 1059-1028.
  30. Francesca Cappitelli . Claudia Sorlini . 2008 . Microorganisms attack synthetic polymers in items representing our cultural heritage . . 74 . 3 . 564–569 . 2227722 . 18065627 . 10.1128/AEM.01768-07. 2008ApEnM..74..564C .
  31. Kazłowski B. . Chiu Y. H. . Kazłowska K. . Pan C. L. . Wu C. J. . August 2012 . Prevention of Japanese encephalitis virus infections by low-degree-polymerisation sulfated saccharides from Gracilaria sp. and Monostroma nitidum . Food Chem. . 133 . 3 . 866–74 . 10.1016/j.foodchem.2012.01.106.
  32. Maeda. Hayato. Hosokawa. Masashi. Sashima. Tokutake. Funayama. Katsura. Miyashita. Kazuo. 2005-07-01. Fucoxanthin from edible seaweed, Undaria pinnatifida, shows antiobesity effect through UCP1 expression in white adipose tissues. Biochemical and Biophysical Research Communications. 332. 2. 392–397. 10.1016/j.bbrc.2005.05.002. 0006-291X. 15896707.
  33. Web site: New Seaweed Pill Works Like Gastric Banding . Fox News. 25 March 2015 .
  34. Web site: Appesat, the Seaweed Diet Pill that Expands in the Stomach . Elena Gorgan . 6 January 2009 . softpedia.
  35. News: Ihosvani . Rodriguez . Seaweed invading South Florida beaches in large numbers . https://archive.today/20130203181239/http://www.sun-sentinel.com/news/broward/fort-lauderdale/fl-lauderdale-beach-seaweed-20120410,0,3244366.story . dead . February 3, 2013 . . April 11, 2012 . 2012-04-11 .
  36. Web site: Seaweed Power: Ireland Taps New Energy Source. 2008-06-24. alotofyada.blogspot.co.uk. 9 April 2018.
  37. Macroalgae for biofuels production: Progress and perspectives. Renewable and Sustainable Energy Reviews. 47. 427–437. 10.1016/j.rser.2015.03.086. 2015. Chen. Huihui. Zhou. Dong. Luo. Gang. Zhang. Shicheng. Chen. Jianmin.
  38. Web site: The promise of Bioyarn from AlgiKnit. MaterialDriven.
  39. Web site: Seaweed Thatch. naturalhomes.org. 9 April 2018.
  40. Web site: Algues vertes: la famille du chauffeur décédé porte plainte contre X. https://web.archive.org/web/20140224213157/http://www.google.com/hostednews/afp/article/ALeqM5hmSXIrejkYYs-g9Y0L71SD9qNl7w?hl=fr. dead. Green algae: the family of the deceased driver files a complaint against X. AFP. . Saint-Brieuc. 2010-04-22. 2014-02-24. 2010-04-22. fr.
  41. Web site: Escharotic stomatitis caused by the "stinging seaweed" Microcoleus lyngbyaceus (formerly Lyngbya majuscula): case report and literature review. subscription.
  42. Lyngbya dermatitis (toxic seaweed dermatitis). International Journal of Dermatology. 51. 1. 59–62. 10.1111/j.1365-4632.2011.05042.x. 21790555. 2012. Werner. K. A.. Marquart. L.. Norton. S. A.. 22375739.
  43. Web site: Buck . Holly Jean . April 23, 2019 . The desperate race to cool the ocean before it's too late . 2019-04-28 . MIT Technology Review . en-US.