Digital library

  • Seaweed Aquaculture for Food Security, Income Generation and Environmental Health in Tropical Developing Countries

    To meet carbon emissions targets, more than 30 countries have committed to boosting production of renewable resources from biological materials and convert them into products such as food, animal feed and bioenergy. In a post-fossil-fuel world, an increasing proportion of chemicals, plastics, textiles, fuels and electricity will have to come from biomass, which takes up land. To maintain current consumption trends the world will also need to produce 50–70% more food by 2050, increasingly under drought conditions and on poor soils. Depending on bioenergy policies, biomass use is expected to continue to rise to 2030 and imports to Europe are expected to triple by 2020. Europe is forecast to import 80 million tons of solid biomass per year by 2020 (Bosch et al. 2015).

    Producing large volumes of seaweeds for human food, animal feed and biofuels could represent a transformational change in the global food security equation andin the way we view and use the oceans. In 2012, global production of seaweeds was approximately 3 million tons dry weight, and growing by 9% per annum. Increasing the growth of seaweed farming up to 14% per year would generate 500 million tons dry weight by 2050, adding about 10% to the world’s present supply of food, generating revenues and improving environmental quality (Table 1). Assuming a conservative average productivity from the best operating modern farms of about 1,000 dry metric tons per km2 (1 kg per m2), this entire harvest could be grown in a sea area of about 500,000 square kilometers, 0.03% of the oceans’ surface area, equivalent to 4.4 percent of the US exclusive economic zone.

    Author(s):

  • Seaweed Application to Hayward Kiwifruit (Actinidia Deliciosa) Orchard Trial

    We undertook this commercial orchard trial in order to investigate whether the use of seaweed soil & foliar treatments had any effect on leaf size or shape and does its use effect fruit weight, brix or dry matter to any measurable or economic amount. We found that leaf area was significantly increased by 6.4% (p=0.027) and that this was due to increase in leaf length but not the width, thus altering the leaf shape (p=<0.001). The change to leaf size and shape does not appear to be related to any increase in leaf nutrient content, but it appears to be hormonally activated. When the leaf analysis nutrient content data was subjected to compositional data analysis (CODA) with isometric log ratios, we found that the treated vines had enhanced photosynthetic efficiency. Treatment with seaweed did significantly increase fruit weight by 7.3% (p=0.010) giving a NZ$3,000 per hectare advantage through using seaweed treatments. 

    Author(s): Philip Barlow

  • Seaweed and their Importance

    Agar agar and algin serve as stabilizers, emulsifiers, thickeners, and gelling agents.

    Author(s): V. S. K. Chennubhotla, N. Kaliaperumal

  • Seaweed and Shellfish Solution

    Using Nature's Filters to help curb pollution and fish farm waste.

    Author(s): Renee Cho

  • Seaweed and seaweed-derived metabolites as prebiotics

    Seaweeds and their bioactive compounds, particularly polysaccharides and phenolics can be regarded as great dietary supplements with gut health benefits and prebiotics. These components are resistant to digestion by enzymes present in the human gastrointestinal tract, also selectively stimulate the growth of beneficial gut bacteria and the production of fermentation products such as short chain fatty acids. Commonly, the health benefits of seaweed components are assessed by including them in an in vitro anaerobic fermentation system containing human fecal inocula that mimics the environment of the human large bowel. Regarding to the complex interactions between dietary components, gastrointestinal physiological processes, and gut microbiota are difficult to model in vitro. Consequently it is important to follow up the promising in vitro results with in vivo animal or human testing. The aim of this chapter is to have a comprehensive review on the application of seaweeds and seaweed-derived metabolites as prebiotics, and understand the trends, gaps and future directions of both scientific and industrial developments. This work contributes to develop and expand new platform of seaweed utilization for higher-value products, particularly to functional food and nutraceutical industries in order to serve the social demand for health awareness and support economic development.

    Author(s): Wei Zhang, Peng Su, Reinu E. Abraham, Suvimol Charoensiddhi

  • Seaweed and Seaweed Bioactives for Mitigation of Enteric Methane: Challenges and Opportunities

    Seaweeds contain a myriad of nutrients and bioactives including proteins, carbohydrates and to a lesser extent lipids as well as small molecules including peptides, saponins, alkaloids and pigments. The bioactive bromoform found in the red seaweed Asparagopsis taxiformis has been identified as an agent that can reduce enteric CH4 production from livestock significantly. However, sustainable supply of this seaweed is a problem and there are some concerns over its sustainable production and potential negative environmental impacts on the ozone layer and the health impacts of bromoform. This review collates information on seaweeds and seaweed bioactives and the documented impact on CH4 emissions in vitro and in vivo as well as associated environmental, economic and health impacts.

    Author(s): Xiaohui Xing, Sinéad Waters , Pamela J. Walsh, Dirk von Soosten, Katerina Theodoridou, Mohammad Ramin, Ulrich Meyer, Vibeke Lind, Stuart F. Kirwan, Sophie J. Krizsan, David A. Kenny, Sharon Huws, Maria Hayes, Robert Gruninger, Fredrik Grondahl, Karen A. Beauchemin, Inga Marie Aasen, D. Wade Abbott

  • Seaweed and seagrass resources

    All macroscopic algae occurring in the marine habitat and coastal brackish waters are known as seaweeds. They from one of the important marine living resources and belong to four major classes namely Chlorophyceae (green algae), Phaeophyceae (brown algae), Rhodoyhyceae (red algae) and Cyanophyceae (blue-green algae). Seaweeds are the only source for the production of phytochemicals namely agar-agar, carrageenan and algin, which are extensively used in various industries such as food, confectionary, textiles, pharmaceuticals, dairy and paper industry mostly as gelling, stabilising and thickening agents. Seaweeds are also used as human food animal feed and manure in several countries.

    Author(s): Kaliaperumal, N, Kaladharan, P, Kalimuthu, S

  • Seaweed Adaptations to Herbivory

    Herbivory on seaweeds can be intense, with nearly 100% of production being consumed in some habitats (Carpente 1986). Seaweeds minimize damage from herbivore by any of three strategies (Lubchenco and Gaines 1981). They can escape in space or time so they do not co-occur with important herbivores or are not detected when they do co-occur. They can deter feeding by herbivores that encounter and recognize the plant. And they can minimize the decrease in fitness that results from herbivore attack. 

    Author(s): J. Emmett Duffy , Mark E. Hay

  • Seaweed 2.0 -Farming the Oceans for Fuels & Chemicals

    Stepping Stones to Commercialization : Food, feed, fuel

    Author(s):

  • Seaweed - A Global History

    Some might be put off by its texture, aroma, or murky origins, but the fact of the matter is seaweed is one of the oldest human foods on earth. And prepared the right way, it can be absolutely delicious. Long a staple in Asian cuisines, seaweed has emerged on the global market as one of our new superfoods, a natural product that is highly sustainable and extraordinarily nutritious. Illuminating seaweed’s many benefits through a fascinating history of its culinary past, Kaori O’Connor tells a unique story that stretches along coastlines the world over.
               
    O’Connor introduces readers to some of the 10,000 kinds of seaweed that grow on our planet, demonstrating how seaweed is both one of the world’s last great renewable resources and a culinary treasure ready for discovery. Many of us think of seaweed as a forage food for the poor, but various kinds were often highly prized in ancient times as a delicacy reserved for kings and princes. And they ought to be prized: there are seaweeds that are twice as nutritious as kale and taste just like bacon—superfood, indeed. Offering recipes that range from the traditional to the contemporary—taking us from Asia to Europe to the Americas—O’Connor shows that sushi is just the beginning of the possibilities for this unique plant.

    Author(s): Kaori O'Connor

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