Download 1 Introduction of Marine Algae Extracts - Wiley-VCH

Survey
yes no Was this document useful for you?
   Thank you for your participation!

* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project

Document related concepts

Freeganism wikipedia , lookup

Photosynthesis wikipedia , lookup

Human nutrition wikipedia , lookup

Food choice wikipedia , lookup

Plant nutrition wikipedia , lookup

Food politics wikipedia , lookup

Herbalism wikipedia , lookup

Food coloring wikipedia , lookup

Nutrition wikipedia , lookup

Transcript
1
1
Introduction of Marine Algae Extracts
Katarzyna Chojnacka and Se-Kwon Kim
1.1
Introduction
Recently, there is increased interest in naturally produced active compounds as
alternatives to synthetic substances. Although these compounds often show lower
activity, they are nontoxic and do not leave residues. It has already been reflected
by the projects of new law regulations in EU countries that have imposed legal
restrictions on the use of xenobiotics as plant protection products or preservatives. In the European Union there are plans of new directives that impose additional environmental taxes, primarily because of the residues of active substances
in the environment. This implies that there is a need to develop new and safe
products of biological origin, with properties similar to the synthetic, in particular
antimicrobial, antifungal, antioxidizing compounds, and colorants. These natural
compounds are found in algal extracts (Table 1.1).
Algal biomass have been used for centuries as food and medicine. The health
promoting effects of algae were discovered as early as 1500 BC [1]. However, the
biomass of algae gained interest as a source of chemicals and pharmaceuticals only
recently. Nowadays, the production regime requires the use of extracts rather than
the biomass itself, because of the formulation requirements (consistency, stability, color, flavor, etc.). Until now, algal products were available mainly as tablets,
capsules, or liquid extracts, and sometimes were incorporated into food products,
cosmetics, or products for plants [2]. In 2006, the market of microalgal biomass
produced 5000 mg dry biomass/year and generated a turnover of 1.25 × 109 USD
[2]. The global sector of macroalgae is worth 6 billion USD, with main contribution from hydrocolloids and crop protection products [3]. Recently, compounds
derived from algae (carotenoids, β-carotene astaxanthin, long-chain polyunsaturated fatty acids (PUFAs), docosahexaenoic acid) began to be produced on industrial scale [4]. Novel compounds isolated from algae possess a great further potential to be applied for their pharmacological and biological activity [4].
Seaweeds produce a vast spectrum of secondary metabolites because they
live in nonfriendly environment but are not damaged photodynamically as
they synthesize protective compounds and develop protecting mechanisms
Marine Algae Extracts: Processes, Products, and Applications, First Edition.
Edited by Se-Kwon Kim and Katarzyna Chojnacka.
© 2015 Wiley-VCH Verlag GmbH & Co. KGaA. Published 2015 by Wiley-VCH Verlag GmbH & Co. KGaA.
2
1 Introduction of Marine Algae Extracts
Table 1.1 Major compounds in algal extracts [2, 11, 19, 20].
Compound
Function
Application
Polysaccharides
Components of cell wall
(fucoidan, alginate,
laminarin)
Not found in terrestrial
plants
Phenol rings in polyphenols
act as electron traps to
scavenge radicals
Provide strength, flexibility,
maintain ionic equilibrium,
prevent from desiccation
Antimicrobial, antioxidant,
antiviral compounds that
protect the algae from abiotic
and biotic stress conditions, for
example, phlorotannins that
are formed from oligomeric
structures and phloroglucinol
Antioxidative, but difficult to
extract
Structural membrane lipids;
important in human and
livestock diet. Composed of
glycerol, sugars, bases
esterified with fatty acids
(saturated or unsaturated
(C12–C22))
Antioxidant, antiviral,
anti-inflammatory activity, UV
protection
—
Phenolics and
phlorotannins
Protein, peptides, and
essential amino acids
Lipids
The contents vary
Terpenoids and steroids
Carotenoids, xanthophyll,
fucoxanthin, astaxanthin
Vitamins
A, B1, B2, B6, B12, C, E,
nicotinate, biotin, folic acid,
pantothenic acid. Level
depends on the season
Se, Zn, Mn, Cu – structural
components of
antioxidative enzymes
Minerals
Polyunsaturated fatty acids
(PUFA) (ω-3 and
ω-6) – higher level than in
terrestrial plants
—
[5]. Environmental stress to which algae are exposed include rapid fluctuations of light intensity, temperature, osmotic stress, desiccation that lead to
the formation of free radicals and oxidizing agents that lead to photodynamic
damage [6].
1.2
Algal Biomass as a Useful Resource
Algae are the oldest photosynthetic organisms dating back to 3.8 billion years
(prokaryotic cyanophytes) [7]. The number of species is estimated as 280 000 [7].
Algal biomass is being used as the raw material for different branches of industry
1.2
Algal Biomass as a Useful Resource
and the global production is prevalently increasing [7]. Algae are photosynthetic
organisms that convert light energy from the Sun into chemical energy stored in
the form of chemical compounds in the process of photosynthesis [1]. A characteristic of algae is that they possess a simple reproductive structure [8]. The biomass
of algae contains various compounds with diversified structures and functions
that are synthesized in the response to stress conditions, for example, heat/cold,
desiccation, salinity, osmotic stress, anaerobiosis, nitrogen deficiency, photooxidation, as protection from physiological stressors [1]. Algae are a diversified group
of organisms and are divided into microalgae and macroalgae. The first group
includes prokaryotic cyanobacteria and eukaryotic microalgae [9]. Algae are very
diversified organisms when considering size (from unicellular microalgae to multicellular macroalgae) [10]. The basis for the classification of algae is pigmentation:
green (Chlorophyceae), red (Rhodophyceae), and brown (Phaeophyceae) [11]. The
difference concerns not only pigmentation, but also the type of storage material
and the composition of cell wall polysaccharides [12]. Algae are simpler than terrestrial plants [12]. Algae could be considered as natural factories that produce
bioactive compounds [13]. The composition of green algae: 10% protein, 35% carbohydrate, and 50% ash (Ca, Fe, P, Cl) [12].
Algae were in use since prehistory as the components of diet and as medicine
[14]. Although the importance of algal industry is permanently increasing, there
are some contradictions between Asian (Far East) and European ways of utilization of this resource [14]. In Europe, the biomass of seaweeds was treated as a sort
of waste from seas and oceans [14]. Certainly, algal biomass is still an underutilized
biological resource.
Algal biotechnology is divided into two branches: microalgal and macroalgal,
with its unique specificity [15]. Microscopic algae are called microalgae; however,
this term is not related to taxonomy. Among microalgae, cyanobacteria are
distinguished, which are prokaryotic [15]. Macroalgal biotechnology includes the
production of (phycocolloids agar-agar, alginates, carrageenan) from Rhodophyta
and Phaeophyta, and the global value is 6 × 109 per year [15]. At present, the main
directions in macroalgal biotechnology are biofuels, agricultural biostimulants
for crop plants, probiotics for aquaculture, soil bioremediation, wastewater
treatment, and biomedical applications of extracted compounds (polyphenols,
polysaccharides) [3]. Microalgal biotechnology refers to the production of
different products: phycocyanin, carotenoids (β-carotene, astaxanthin), fatty
acids and lipids, polysaccharides, immune modulators that find an application
in health food, cosmetics, feed and food supplements, pharmaceuticals, and
fuel production [15]. Microalgal groups of the major importance are cyanobacteria (Spirulina sp.), Chlorophyta (Chlorella sp., Dunaliella sp.), Rhodophyta
(Porphyridium sp.), Bacillariophyta (Odontella sp., Phaeodactylum sp.) [15].
While macroalgae are harvested from natural habitats, microalgae are cultivated in artificial systems [15]. The products of microalgal biotechnology are
coloring substances (astaxanthin, phycocyanin, phycoerythrin), antioxidants
(β-carotene, tocopherol, antioxidant CO2 extract), and arachidonic acid (ARA),
docosahexaenoic acid (DHA), and PUFA extracts [15].
3
4
1 Introduction of Marine Algae Extracts
1.3
Biologically Active Compounds Extracted from Algae
Because algae are coastal primary producers and have impressive possibilities to
survive in extreme environmental conditions, in particular to trigger oxidative
stress, they produce a variety of useful compounds [16]. Algae live in extreme
conditions: fluctuating salinity, temperature, nutrients, and UV–vis irradiation
[10]. Long periods of desiccation cause overproduction of reactive oxygen species,
which is neutralized by physiological and biological mechanisms: the production
of secondary metabolites [16]. Therefore, compounds isolated from the biomass
of seaweeds possess biological activity. The biomass of algae contains many valuable components: minerals, vitamins (A, B, C, E), PUFAs (ω-3), amino acids, proteins, polysaccharides, lipids, and dietary fiber [17]. Many of these bioactive constituents can be extracted to obtain antioxidative, anti-inflammatory, antimicrobial, anticancer, antihypertensive products [11, 17]. Particularly useful are secondary metabolites with antiviral, antimalarial, anticancer properties [1]. Products derived from algae also contain polysaccharides, polyphenolic compounds,
and terpenes [11]. Seaweeds and their extracts are added to food as antioxidants,
antimicrobials, dietary fiber, and dietary iodine [6].
In various studies, strong antioxidative properties of compounds isolated from
seaweeds were confirmed [18]. Antioxidative activity produces phlorotannins
(polyphenolic compounds – 1–10% d.m. of brown seaweeds), alkaloids, terpenes,
ascorbic acid, tocopherols, and carotenoids [18]. Antioxidants transform radicals
into nonradicals by donating electrons and hydrogen, chelation of transition
metals, and dissolving peroxidation compounds [6]. The role of antioxidants is
to prevent lipid oxidation, inhibiting the formation of products as a result of
oxidation, and consequently prolonging the shelf life of products [6]. Algae are a
rich source of natural antioxidants and antimicrobial compounds [6].
The research on the composition of algal extracts concerns mainly antioxidants
as an alternative to synthetic, because according to recent research these compounds if used as food additives are potential promoters of carcinogenesis [1]. The
extracts modulate the oxidative stress and diseases related to radical scavenging
effect: sesquiterpenoids and flavonoids (green alga Ulva lactuca), phlorotannins
(brown alga Eisenia bicyclis, Ecklonia cava, E. kurome), phycobiliprotein, and phycocyanin (blue-green alga Spirulina platensis), which protect from DNA damage
by H2 O2 [17].
• Anti-HIV – cyanovirin – protein from Nostoc ellipsosporum [1]
• Photoprotective compounds – repair DNA damage – mycosporine-like amino
acids, scytonemin enzymes (shock proteins) – superoxide dismutase, catalase,
and peroxidase [1].
Microalgae contain carotenoids, PUFAs, phycobilins, sterols, polyhydroxyalkonates, and polysaccharides [9]. They can be considered as cosmeceuticals,
nutraceuticals, and functional foods [9]. For instance, Spirulina contains lipids
1.4
The Application of Products Derived from Algal Biomass
(6–13; 50% in the form of fatty acids), phycocyanin (20–28%), and carbohydrates
(15–20%; mainly as polysaccharides) [21].
Algal cells contain phytochelatins – proteins synthesized in response to exposure to toxic metal ions [22]. However, the attempt to extract and use these proteins is not found in the available literature [22].
1.4
The Application of Products Derived from Algal Biomass
The global wild stocks of seaweeds yield 8 million mg of biomass [18]. In 2004,
the contribution in the market was as follows: sea vegetables (88%), phycocolloids (11%), phycosupplements (1%), and the minor contribution of soil additives,
agrochemicals, and animal feeds (totally, 6000 million USD) [14]. Algal extracts
create a new market sector, because they can be used in a variety of products,
for example, antioxidant capsules containing Spirulina extract, Chlorella extract
in health drinks, oral capsules containing carotenoid extracts from Dunaliella
[15]. Other examples of algal extracts-based products are pet functional food,
biofertilizers (which increase water-binding capacity and serve as the source of
minerals and substances promoting germination, growth of leaves and stems and
flowering).
Of particular interest are antioxidants present in algae and their extracts, as
the use of synthetic antioxidants has been restricted because of toxicity and
health risks [23]. It is important to replace these synthetic compounds with
natural antioxidants [23]. Antioxidative compounds from marine sources include
various functional compounds, for example, tocopherols [19]. Lipid-soluble algal
extracts can be used as protective functional ingredients [19]. Antioxidative
properties of natural compounds from algae can prolong the shelf life of foods
and cosmetics through delayed oxidation [11]. Natural anti-oxidants may also
be useful in treating aging, UV-exposure, and diseases associated with oxidation
[11]. Extracts from algae are used in cosmetics, for example, from Spirulina and
Chlorella [2].
Polysaccharides isolated from algae are other important components of foods
and cosmetics and in nutraceutical and pharmaceutical preparations and are produced mainly from seaweeds [21]. Polysaccharides (carrageenans, alginates) are
used in food industry as edible packaging materials [6].
The main source of industrially exploited polysaccharides (alginate, agar, carrageenan) originates from the biomass of algae [12]. Algal biomass contains significantly higher levels of polysaccharides than terrestrial plants [12]. Algal polysaccharides differ from those in terrestrial plants: sulfate groups, additional sugar
residues, high content of ionic groups, high solubility in water, and unique rheological properties [12].
Polysaccharide production includes the following steps: selection of raw material, stabilization and grinding of biomass, extraction and purification, precipitation, and drying [12].
5
6
1 Introduction of Marine Algae Extracts
1.4.1
Agriculture – For Plants
In modern agriculture, higher production should accompany lower environmental impact and higher sustainability [24]. These criteria fulfill biostimulants that
improve efficiency of regular fertilization (increase the efficiency of nutrients
uptake), enhance yield and the quality of crops, improve tolerance to environmental stress, and possess antioxidant properties [24]. Biostimulants are natural
substances that promote growth, uptake of nutrients, and tolerance to abiotic
stress and different climatic conditions [25]. Seaweed extracts can be used as
foliar sprays for vegetables, grains, and flowers [24]. Plant growth regulators are
defined as bioactive compounds. It is desired that they perform well and are
degraded into products that are not harmful to the environment [26].
European Biostimulant Industry Council (EBIC) was established to help introduce agriculture biostimulants to the market and support regulatory EU authorities to describe biostimulants as innovative class of products, the production of
which uses minimal synthetic processing. Biostimulants are approved in organic
crops, with an important group of products derived from macroalgae [27].
Seaweeds have been used in the cultivation of plants since antiquity [28].
Seaweeds were composted since antiquity and used as soil amendments. The
first industrial applications of seaweeds in agriculture were in 1944, as the new
source of fiber [14]. At present, the extracts are applied directly to shoots foliarly
or to soil [3]. The examples of algal extracts currently available on the market are
Kelpak, Actiwave, and AlgaGreen [3]. Seaweed concentrates (e.g., Kelpak) are
applied at low rates and have growth promoting effect following the presence
of plant growth regulators (e.g., cytokinins and auxins, polyamines, putrescine,
spermine) rather than nutrients [29]. These active substances increase the growth
of nutrient-stressed plants [29].
In 1949, the product Maxicrop was developed [14]. Using liquid seaweed
is advantageous, because plants respond immediately and positively (dilution
1 : 500); also, the ions of micronutrients (Cu, Co, Mn, Fe) are soluble at high
pH and are chelated by partly hydrolyzed sulfated polysaccharides; soil crumb
structure is improved (with alginate and fucoidan), microorganisms, root system,
and plant growth are stimulated [14].
Extracts from seaweeds are useful in the cultivation of plants because they
improve a wide range of physiological responses: increase crop yield, improve
growth, improve plants’ resistance to frost, serve as biofungicide and bioinsecticide, increase nutrients’ uptake from soil because they contain plant growth
regulators [30]. The extracts are used in low doses (high dilutions), because the
active substances are efficient even in small quantities [30].
The compounds found in algal extracts that are important for plant growth are
cytokinins, auxins, abscisic acid, vitamins, amino acids, and nutrients [24]. The
outcome is the result of the synergistic effect of many compounds present in algal
extracts [24]: phytohormones, betaines (organic osmolytes), polymers, nutrients,
and alginic acid (soil conditioning agent that supports soil structure) [25, 28].
1.4
The Application of Products Derived from Algal Biomass
There are various reports of laboratory, pot, and field studies that aimed to
test the plant growth stimulating properties of algal extracts. El-Baky et al. [31]
investigated the effect of treatments with microalgae extracts (Spirulina maxima
and Chlorella ellipsoida) on antioxidative properties in grains of wheat. The content of carotenoid, tocopherol, phenolic, and protein in grain was investigated.
Antioxidant activity of ethanolic extracts showed the significant increase of radical scavenging activity in response to microalgal extracts treatment [31].
1.4.2
Functional Food
Functional food is defined as food that positively affects one or more physiological functions to increase the well-being and reduce the risk of suffering for diseases [8]. Recently, a new market for functional food has evolved, the food called
“food for the not-so-healthy” [13]. Functional food is produced by the addition of
active components. Functional food contains functional ingredients: micronutrients ω-3 fatty acids, linoleic acids, phytosterols, soluble fiber (inulin – prebiotics),
probiotics, carotenoids, polyphenols, vitamins that present healthy effect on the
organism [13]. New, biologically active natural ingredients (antioxidant, antiviral,
antihypertensive) extracted from the biomass of algae are becoming important
research objects in the area of food science and technology [10].
Algal extracts are the components of functional food, because they are considered as natural, biologically active components. The latter, beside nutrition, should
have the beneficial influence on functions of the body by improving health or preventing from diseases [32]. Extracts from Spirulina can be added to functional
foods because of antioxidant, antimicrobial, anti-inflammatory, antiviral, and antitumoral properties of the compounds (phycocyanins, carotenoids, phenolic acids,
and ω-3 and six PUFAs) [32].
Algae are used as dietary supplements that are classified into three groups: (i)
Spirulina platensis, (ii) Aph. flos-aquae, and (iii) Chlorella pyrenoidosa [33]. The
biomass of these microalgae is obtained either from lakes or by cultivation in artificial ponds [33]. Algae can be cultivated, in which the growth rate is high and in
some cases there is a possibility of controlling the production of active compounds
by adjusting cultivation conditions [10].
The potential use of brown seaweed extracts to inhibit the growth of microorganisms responsible for food spoilage and pathogenic microorganisms was also
investigated [5]. The addition of 6% of the extract substantially reduced the growth
of nondesired microflora [5].
1.4.3
Cosmetics
Microalgae, the biomass of which is to be used as the raw material for isolation of
beneficial compounds, are cultivated in artificial systems that provide the biomass
that is free of impurities [7]. Algal extracts are useful in the skin care market as
7
8
1 Introduction of Marine Algae Extracts
well because they support regeneration of tissues and reduce wrinkles, in particular, the extracts from Spirulina (which repair signs of aging, prevent stria formation) and Chlorella (stimulate collagen synthesis) [2]. The properties of microalgal
extracts include reduction of intracellular oxidative stress and synthesis of
collagen [7].
Extracts from the following microalgae are produced commercially for cosmetic
industry [7]:
• Nannochloropsis oculata – vitamin B12, vitamin C, and antioxidants
• Dunaliella salina – pigment industry (carotenes), amino acids, and polyphenols
• Chlorella vulgaris – proteins, and inorganics substances.
1.4.4
Pharmaceuticals
Algal extracts can replace commercial antibiotics in disease treatments [34].
Biologically active metabolites isolated from marine algae have the potential to be
used as pharmaceuticals because they inhibit the growth of bacteria, viruses, and
fungi [34]. The chemicals are macrolides, cyclic peptides, proteins, polyketides,
sesquiterpenes, terpenes, and fatty acids [34]. Cavallo et al. [34] investigated the
effect of lipid extracts from six algae and their antibacterial activity against fish
pathogens and found that they can be used as antibacterial, health promoting
feed for aquaculture.
Extracts from Spirulina are active against viruses (herpes, influenza,
cytomegalovirus) and inhibit carcinogenesis [35]. Spirulina is the source of
vitamin A that is highly absorbable [36].
Hot water extract from Spirulina supports human immune system by the
improvement of immune markers in blood (higher level of gamma interferon and
interleukin-12p40 and toll-like receptors) and acts directly on myeloid lineages
and natural killer-cells (NK cells) [35]. Immulina is a polysaccharide found in
the extract from Spirulina that activates monocytes. Water extracts also showed
antiviral activity [35].
1.4.5
Fuels
Seaweed extracts can be the resource to produce liquid fuels (ethanol), because of
high carbohydrates (laminaran, mannitol) content [37]. Seaweeds can be bioconverted to methane [37].
1.4.6
Antifouling Compounds
Extracts from marine algae (e.g., Enteromorpha prolifera) contain compounds
that have antifouling properties toward, for example, mussels (Mytilus edulis) and
1.5
Extraction Technology
larval settlement: tannins (Sargassum natans), bromophenol (Rhodomela larix),
diterpenes (Dictyota menstrualis), and halogenated furanones (Delisea pulchra).
These compounds have the potential in the prevention from fouling of ship hulls
and aquaculture nets instead of organotin or paints based on toxic metals [38].
1.5
Extraction Technology
Seaweed industry was established in 1950s [3]. The production concerned mainly
low-cost fertilizers and food [3]. For the first time liquefaction of seaweeds was
undertaken in 1857 by compressing [28]. The goal was to obtain the formulation
that is transportable over long distances [28]. Algal extracts were obtained and
patented in 1952 by alkaline extraction [3]. Another process was milling in low
temperature [28].
Although natural extracts possess a great applicable potential, the problem with
natural products is variable composition of extracts because of fluctuations in the
raw material (season, location), different extraction techniques [12]. Extraction
methods vary and the following can be distinguished: ethanol, methanol, enzymatic [17], composting, supercritical CO2 extraction with cosolvents.
In the elaboration of a new extraction technology, it is necessary to select the
target bioactive compound, select the species of alga for extraction containing
the compound of interest, select the operation conditions to find a compromise
between the yield and purity, and consider if large enough resources of the algae
are available.
It is essential to develop appropriate, quick, cost-efficient, and environmentally
friendly methods of extraction that aim to isolate biologically active compounds
of interest [10] without loss of their activity. It is essential to develop extraction
procedures that involve the use of specific solvents and processes [8].
The production of algal extracts consists of several unit operations [7]:
• Upstream processing – preparation for cultivation
• Cultivation – in photobioreactors
• Downstream processing – cell harvesting, rehydration and hot water extraction, centrifugation, and ultrafiltration
• Formulation, preservation, and conditioning.
Traditional extraction techniques (soxhlet) solid–liquid extraction (SLE),
liquid–liquid extraction (LLE) consume large quantities of solvents and require
high extraction times [8]. These procedures present low yield of extraction and
low selectivity toward bioactive compounds [8]. Because of the lack of automation, reproducibility is low [8]. Recently developed techniques supercritical
fluid extraction (SFE), pressurized liquid extraction (PLE), accelerated solvent
extraction (ASE), pressurized hot water extraction (PHWE), ultrasound-assisted
extraction (UAE), microwave-assisted extraction (MAE) have further reduced
these limitations [8]:
9
10
1 Introduction of Marine Algae Extracts
• Solvent extraction – large quantities of toxic organic solvents are used, long time
of extraction, laborious, low selectivity, low extraction yields, and not mild conditions (temperature, light, oxygen) [32].
• Pressure liquid extraction – less solvent, shorter time of extraction, automated,
no oxygen, and no light [32].
• Supercritical fluid extraction – technique used to isolate active components
from natural materials [32].
SFE uses solvents at temperatures and pressures above their critical point and is
used to extract compounds from biomasses [8]. In this technique, the consumption of toxic organic solvents is reduced and the main solvent used is CO2 [8].
The disadvantage is low polarity of CO2 and resulting necessity of the use of polar
modifiers or cosolvents [8]. Advantages are high diffusivity, easiness in the control
of temperature and pressure (possibility of modification of solvent strength), and
obtaining solvent-free extracts [8].
Extraction of biologically active compounds from algal biomass is not selective.
The extract is a mixture of different compounds [11]. The factors that influence
the composition and thus the activity of algal extracts depend on species, environmental conditions, season of the year, age, geographical location, and processing
technologies [11]. For instance, ethanol was found to be more efficient in the
extraction of polyphenols than water [23]. Seaweed extracts contain PUFAs (in
particular ω-3 long chain PUFA) that have several health promoting effects and
have the potential to be useful in treatment or reducing symptoms of: cardiovascular disease, depression, rheumatoid arthritis, and cancer [19].
Chaiklahan et al. [21] optimized the extraction of polysaccharides from
Spirulina sp. It was found that the mostly significant operation conditions were
temperature and solid to liquid ratio and time. The extract contains rhamnose
and phenolic content [21].
Seaweed concentrates are used as supplementary soil conditioners that promote
plant growth and improve crop yield [29]. An example product is Kelpak from
Ecklonia maxima [29]. These products are used in very low doses and contain,
for example, cytokinins and auxins that are plant growth regulators [29]. Seaweed
extracts are particularly useful if applied on plants that are nutrient-stressed [29].
®
1.6
Conclusions
Algae are a useful raw material for biobased economy, because their cells contain
a vast array of useful compounds with high biological activity. Biomass of algae
is certainly an underestimated resource. In the process of extraction it is possible
to draw the valuable compounds closed in the algal cells. However, this should be
carried out in such a way that the structure and thus the properties of the compounds are not destroyed and that the solvent used does not limit their use as safe
components of products for plants, animals, and human.
References
There are many ways to implement the extraction process and this is thoroughly
discussed in this book. In addition to developing extraction technology, it is very
important to assess the utilitarian values of the extracts, which can be documented
in application studies of extracts in real systems.
Preparation of algal extracts represents a new approach in the preparation of
natural products with a standardized composition, as compared with the biomass
itself and certainly will be a future for algal industry.
References
1. Shanab, S.M.M., Mostafa, S.S.M.,
2.
3.
4.
5.
6.
7.
8.
Shalaby, E.A., and Mahmoud, G.I. (2012)
Aqueous extracts of microalgae exhibit
antioxidant and anticancer activities.
Asian Pac. J. Trop. Biomed., 2, 608–615.
Spolaore, P., Joannis-Cassan, C., Duran,
E., and Isambert, A. (2006) Commercial applications of microalgae. J. Biosci.
Bioeng., 101, 87–96.
Sharma, H.S., Shekhar, S., Lyons, G.,
McRoberts, C., McCall, D., Carmichael,
E., Andrews, F., and McCormack, R.
(2012) Brown seaweed species from
Strangford Lough: compositional analyses of seaweed species and biostimulant
formulations by rapid instrumental methods. J. Appl. Phycol., 24,
1141–1157.
Borowitzka, M. (2011) Pharmaceuticals From Algae, Biotechnology, vol. 7,
Encyclopedia of Life Support System.
Gupta, S., Cox, S., Rajauria, G., Jaiswal,
A.K., and Abu-Ghannam, N. (2012)
Growth inhibition of common food
spoilage and pathogenic microorganisms in the presence of brown seaweed
extracts. Food Bioprocess Technol., 5,
1907–1916.
Gupta, S. and Abu-Ghannam, N. (2011)
Recent developments in the application of seaweeds or seaweed extracts
as a means for enhancing the safety
and quality attributes of foods. Innovative Food Sci. Emerging Technol., 12,
600–609.
Stolz, P. and Obermayer, B. (2005) Manufacturing microalgae for skin care. Cosmet. Toilet., 120, 99–106.
Ilbanez, E., Herrero, M., Mendiola,
J.A., and Castro-Puyana, M. (2012) in
Marine Bioactive Compounds: Sources,
9.
10.
11.
12.
13.
14.
15.
16.
17.
Characterization and Applications
(ed M. Hayes), Springer, pp. 55–98.
Borowitzka, M.A. (2013) High-value
products from microalgae—their development and commercialization. J. Appl.
Phycol., 25, 743–756.
Plaza, M., Cifuentes, A., and Ibanez, E.
(2008) In the search of new functional
food ingredients from algae. Trends Food
Sci. Technol., 19, 31–39.
Balboa, E.M., Conde, E., Moure, A.,
Falqué, E., and Domínguez, H. (2013)
In vitro antioxidant properties of crude
extracts and compounds from brown
algae. Food Chem., 138, 1764–1785.
Alves, A., Sousa, R.A., and Reis, R.L.
(2013) A practical perspective on ulvan
extracted from green algae. J. Appl.
Phycol., 25, 407–424.
Herrero, M., Mendiola, J.A., Plaza, M.,
and Ibanez, E. (2013) in Advanced Biofuels and Bioproducts (ed. J.W. Lee),
Springer, pp. 833–872.
Craigie, J.S. (2011) Seaweed extract
stimuli in plant science and agriculture.
J. Appl. Phycol., 23, 371–393.
Pulz, O. and Gross, W. (2004) Valuable products from biotechnology of
microalgae Mini-Review. Appl. Microbiol. Biotechnol., 65, 635–648.
Contreras-Porcia, L., Callejas, S.,
Thomas, D., Sordet, C., Pohnert,
G., Contreras, A., Lafuente, A.,
Flores-Molina, M.R., and Correa, J.A.
(2012) Seaweeds early development:
detrimental effects of desiccation and
attenuation by algal extracts. Planta,
235, 337–348.
Lee, J.C., Hou, M.-F., Huang, H.-W.,
Chang, F.-R., Yeh, C.-C., Tang, J.-Y.,
and Chang, H.-W. (2013) Marine algal
natural products with antioxidative,
11
12
1 Introduction of Marine Algae Extracts
18.
19.
20.
21.
22.
23.
24.
25.
anti-inflammatory, and anti-cancer
properties. Cancer Cell Int., 13, 55–62.
O’Sullivan, A.M., O’Callaghan, Y.C.,
O’Grady, M.N., Queguineur, B.,
Hanniffy, D., Troy, D.J., Kerry, J.P.,
and O’Brien, N.M. (2011) In vitro and
cellular antioxidant activities of seaweed extracts prepared from five brown
seaweeds harvested in spring from the
west coast of Ireland. Food Chem., 126,
1064–1070.
Kindleysides, S., Quek, S.-Y., and Miller,
M.R. (2012) Inhibition of fish oil oxidation and the radical scavenging activity
of New Zealand seaweed extracts. Food
Chem., 133, 1624–1631.
Onofrejova, L., Vasickova, J., Klejdus, B.,
Stratil, P., Misurcova, L., Kracmar, S.,
Kopecky, J., and Vacek, J. (2010) Bioactive phenols in algae: the application
of pressurized-liquid and solid-phase
extraction techniques. J. Pharm. Biomed.
Anal., 51, 464–470.
Chaiklahan, R., Chirasuwan, N.,
Triratana, P., Loha, V., Tia, S., and
Bunnaga, B. (2013) Polysaccharide
extraction from Spirulina sp. and its
antioxidant capacity. Int. J. Biol. Macromol., 58, 73–78.
Volland, S., Schaumlöffel, D., Dobritzsch,
D., Krauss, G.-J., and Lütz-Meindl, U.
(2013) Identification of phytochelatins
in the cadmium-stressed conjugating
green alga Micrasterias denticulata.
Chemosphere, 91, 448–454.
Farvin, K.H.S. and Jacobsen, C. (2013)
Phenolic compounds and antioxidant
activities of selected species of seaweeds
from Danish coast. Food Chem., 138,
1670–1681.
Rathore, S.S., Chaudhary, D.R., Boricha,
G.N., Ghosh, A., Bhatt, B.P., Zodape,
S.T., and Patolia, J.S. (2009) Effect of
seaweed extract on the growth, yield
and nutrient uptake of soybean (Glycine
max) under rainfed conditions. S. Afr. J.
Bot., 75, 351–355.
Spinelli, F., Fiori, G., Noferini, M.,
Sprocatti, M., and Costa, G. (2010) A
novel type of seaweed extract as a natural alternative to the use of iron chelates
in strawberry production. Sci. Hortic.,
125, 263–269.
26. Cutler, H.G. and Cutler, S.J. (2007) in
27.
28.
29.
Encyclopedia of Chemical Technology,
vol. 13 (ed. K. Othmer), John Wiley &
Sons, Inc., pp. 1–36.
Sharma, H.S.S., Fleming, C., Selby, C.,
Rao, J.R., and Martin, T. (2014) Plant
biostimulants: a review on the processing of macroalgae and use of extracts
for crop management to reduce abiotic
and biotic stresses. J. Appl. Phycol., 26,
465–490.
Jannin, L., Arkoun, M., Etienne, P.,
Laîne, P., Goux, D., Garnica, M., Fuentes,
M., San Francisco, S., Baigorri, R.,
Cruz, F., Houdusse, F., Garcia-Mina,
J.-M., Yvin, J.-C., and Ourry, A. (2013)
Brassica napus growth is promoted
by Ascophyllum nodosum (L.) Le Jol.
Seaweed extract: microarray analysis
and physiological characterization of N,
C, and S metabolisms. J. Plant Growth
Regul., 32, 31–52.
Papenfus, H.B., Kulkarni, M.G., Stirk,
W.A., Finnie, J.F., and Van Staden, J.
(2013) Effect of a commercial seaweed
extract (Kelpak ) and polyamines on
nutrient-deprived (N, P and K) okra
seedlings. Sci. Hortic., 151, 142–146.
Stirk, W.A. and Van Staden, J. (1997)
Comparison of cytokinin- and auxinlike activity in some commercially used
seaweed extracts. J. Appl. Phycol., 8,
503–508.
El-Baky, H.H.A., El-Baza, F.K., and
El Baroty, G.S. (2010) Enhancing antioxidant availability in wheat grains from
plants grown under seawater stress in
response to microalgae extract treatments. J. Sci. Food Agric., 90, 299–303.
doi: 10.1002/jsfa.3815
Santoyo, S., Herrero, M., Senorans, F.J.,
Cifuentes, A., Ibanez, E., and Jaime, L.
(2006) Functional characterization of
pressurized liquid extracts of Spirulina
platensis. Eur. Food Res. Technol., 224,
75–81.
Heussner, A.H., Mazija, L., Fastner, J.,
and Dietrich, D.R. (2012) Toxin content
and cytotoxicity of algal dietary supplements. Toxicol. Appl. Pharmacol., 265,
263–271.
Cavallo, R.A., Acquaviva, M.I., Stabili,
L., Cecere, E., Petrocelli, A., and
®
30.
31.
32.
33.
34.
References
Narracci, M. (2013) Antibacterial activity of marine macroalgae against fish
pathogenic Vibrio species. Cent. Eur. J.
Biol., 8, 646–653.
35. Capelli, B. and Cysewski, G.R. (2010)
Potential health benefits of Spirulina
microalgae. A review of the existing
literature. Nutra Foods, 9, 19–26.
36. Annapurna, V.V., Deosthale, Y.G., and
Bamji, M.S. (1991) Spirulina as a source
of vitamin A. Plant Foods Hum. Nutr.,
41, 125–134.
37. Horn, S.J., Aasen, I.M., and Ostgaard, K.
(2000) Ethanol production from seaweed
extract. J. Ind. Microbiol. Biotechnol., 25,
249–254.
38. Cho, J.Y., Kwon, E.-H., Choi, J.S., Hong,
S.Y., Shin, H.W., and Hong, Y.K. (2001)
Antifouling activity of seaweed extracts
on the green alga Enteromorpha prolifera and the mussel Mytilus edulis.
J. Appl. Phycol., 13, 117–125.
13