Biodiesel Production From Algae to Overcome the Energy Crisis


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HAYATI Journal of Biosciences 24 (2017) 163e167
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HAYATI Journal of Biosciences
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hayati-journal-of-biosciences
Review Article
Biodiesel Production From Algae to Overcome the Energy Crisis

Suliman Khan,1 Rabeea Siddique,2 Wasim Sajjad,3 Ghulam Nabi,1 Khizar Mian Hayat,4

Pengfei Duan,5 Lunguang Yao5*

1 The Key Laboratory of Aquatic Biodiversity and Conservation of Chinese Academy of Sciences, Institute of Hydrobiology, Chinese Academy of Sciences, Wuhan,
Hubei 430072, China.
2 Department of Biomedical Engineering, Huazhong University of Science and Technology, Wuhan 430074, PR China.
3 Key Laboratory of Petroleum Resources, Gansu Province/Key Laboratory of Petroleum Resources Research, Institute of Geology and Geophysics, Chinese Academy
of Sciences, Lanzhou 730000, PR China.
4 MOE Key Laboratory of Cell Activities and Stress Adaptations, School of Life Sciences, Lanzhou University, Lanzhou 730000, PR China.
5 Collaborative Innovation Center of Water Security for Water Source Region of Mid-line of South-to-North Diversion Project, College of Agricultural Engineering,
Nanyang Normal University, Henan, China.
a r t i c l e i n f o

Article history:
Received 14 January 2017
Received in revised form
9 October 2017
Accepted 30 October 2017
Available online 22 November 2017

KEYWORDS:
algae,
biofuel,
fossil fuel,
gene
* Corresponding author.
Peer review under responsibility of Institut Perta

https://doi.org/10.1016/j.hjb.2017.10.003
1978-3019/Copyright © 2017 Institut Pertanian Bogo
creativecommons.org/licenses/by-nc-nd/4.0/).
a b s t r a c t

The use of energy sources has reached at the level that whole world is relying on it. Being the major
source of energy, fuels are considered the most important. The fear of diminishing the available sources
thirst towards biofuel production has increased during last decades. Considering the food problems,
algae gain the most attention to be used as biofuel producers. The use of crop and food-producing plants
will never be a best fit into the priorities for biofuel production as they will disturb the food needs.
Different types of algae having the different production abilities. Normally algae have 20%e80% oil
contents that could be converted into different types of fuels such as kerosene oil and biodiesel. The
diesel production from algae is economical and easy. Different species such as tribonema, ulothrix and
euglena have good potential for biodiesel production. Gene technology can be used to enhance the
production of oil and biodiesel contents and stability of algae. By increasing the genetic expressions, we
can find the ways to achieve the required biofuel amounts easily and continuously to overcome the fuels
deficiency. The present review article focusses on the role of algae as a possible substitute for fossil fuel as
an ideal biofuel reactant.
Copyright © 2017 Institut Pertanian Bogor. Production and hosting by Elsevier B.V. This is an open access

article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/).
1. Introduction

Energy crisis is among the biggest problems, leading the world
to be unsafe and non-peaceful. The demand is increasing day by
day. The available resources are rapidly decreasing and indication is,
soon will be vanished. In such situations, more attention is needed
to be given towards renewable energy sources. Fossil fuels are used
on a large scale in the world, but unsustainable because they in-
crease CO2 level and accumulate greenhouse gases which make the
environment unhealthy. To keep the environment clean and
maintain sustainability, renewable and environmentally friendly
fuels are needed to be produced (Schenk, 2008). Biofuels are
defined as the liquid fuels produced from the biomass of different
agricultural and forest products and biodegradable portion of
nian Bogor.

r. Production and hosting by Els
industrial waste (Dufey, 2006). Biodiesel is extracted from vege-
table oils (Shay, 1993), biobutanol (Dürre, 1997), Jatropha curcas
(Becker and Makkar, 2008) and algae (Roessler et al., 1994;
Sawayama et al., 1995; Dunahay et al., 1996; Sheehan et al., 1998).
Brazil, the United States and the European Union are the world's
largest biodiesel producers (Balat 2007). Biofuel production has
been estimated to be 35 billion litres (O European Commission,
2006).

The algae are now becoming the main source of
biofuel production in the world. They are considered as the safer,
non-competitive and rapidly growing organisms among those
could be used for biodiesel production. They have the abilities to
grow without much care on waste nutrients (Roberts, 2013), and
are considered the better source of biodiesel production as other
sources can cause food problems as they are mainly including those
plants which are used for food (Patil et al., 2008). Moreover,
evier B.V. This is an open access article under the CC BY-NC-ND license (http://

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S. Khan, et al164
biodiesel contents of crops are less sustainable and less in quantity
as compared with algae (Charles et al., 2007). Algae have around
80% energy content to that contained by petroleum (Chisti, 2007,
2013). Algal cells have 30% lipid content (Lam and Lee, 2012),
which is higher than other sources including soybeans and palm
oils (Lam and Lee, 2011; Kligerman and Bouwer, 2015). Microalgae
have 30%e40% lipid contents by dry weight and this value raises to
85%. Botryococcus braunii is a microalga which is having 30%e40%
hydrocarbon content which can be extracted easily (Mirza et al.,
2008). Algae can efficiently remove the toxic components from
water, so playing a role in waste water treatment. Their remediating
role in waste water treatment and rich sources of biodiesel make
them suitable sources to be grown on large scale (Pittman et al.,
2011; Kligerman and Bouwer, 2015).

Micro as well as macro algae can be cultivated on large scale in
short period. Micro algae are photosynthetic and heterotrophic
having the potential to be grown as energy crops. They have the
ability to produce certain economically important compounds
including fats and oils (Rawat et al. 2011; Pittman et al. 2011). Algal
biofuel does not have harmful chemicals, so environment can be
kept clean after the combustion.

Pakistan state oil has currently started work on biodiesel pro-
duction and successfully cultivated J. curcas plant to produce bio-
diesel. Drying needs energy in the case of crops and food-producing
plants; but in the case of algae, it is economical to dry them with
sun light. Thermo chemical drying process is also easy in algae in
comparison with other plants (Banerjee et al. 2002; Tsukahara and
Sawayama, 2005). Biomass is treated with anaerobic microorgan-
isms to produce biogas which is having high content of methane, so
it can be used as an alternate source of energy (Mes et al. 2003).
Algae cells have the bio fuel contents inside the cells, and the cell
wall retains these components intact, so the cell wall must be
broken; and in most cases, anaerobic digestion is preferred, which
is the most prominent method of extracting these components
Figure 1. This figure illustrates the general process of biodiesel production from algae on sm
algal species for the oil contents. Dotted arrow indicates the addition to specific steps whi
from the cells (Reith, 2004). The algae with high biofuel contents
and easily cultivatable are preferred. The objective of this review
article was to critically describe various aspects of algae as an ideal
target for biofuel productions.

2. The Processes for Biofuel Production Using Algae

Algae have oil contents with different compositions depending
on the specie types. Some species were identified that they have
good fatty acid values. In the same way, some algae have more
components of fatty acids by their dry masses. Micro algae can
grow in different conditions even in availability of fewer nutrients.
They are best to be chosen for cultivation. The collection of sample
needs care so that the whole biofuel contents could be obtained
through careful handling of the instruments. The growth is also
affected by different environmental factors which are not specif-
ically known for every region, so the process needs careful atten-
tion accordingly (Richmond, 2004).

The simple method of fatty acids extraction and separation of
biodiesel is the blending method on small or experimental scale.
This process consists of several steps which have been shown in
Figure 1.

It is also necessary to know about the cultivation unit of the algal
cultivation, whether it is good to choose the closed system or open
system. The process either batch or continuous is confirmed
depending on the conditions and facilities, including pH, temper-
ature, type of algal specie and the amount of algal biomass
(Kaewpintong, 2004; Chojnacka and Marquez-Rocha, 2004;
Chojnacka et al. 2005). Harvesting techniques are finalized based
on the location and conditions (Grima et al. 2003). Most favourable
harvesting techniques suggested are based on settling pond or
sedimentation tank. Density and moisture adjustment is required
during the whole process of biodiesel production. The drying
technique mostly used is spray drying, drum drying was also
all scale and for experimental purpose. This method could be used to compare different
ch have been highlighted with bold letters and full lined arrows.



Biodiesel to Overcome the Energy Crisis 165
suggested. The disruption process through mechanical handlings is
considered the most favourable. The other requirements are the use
of solvents such as hexane and ethanol are required for active
process. Ultrasound and microwave-based extraction methods can
also be of benefit if other sources are not available (Richmond,
2004).

3. Cultivation Systems

Two main cultivation systems are open system and closed sys-
tem. The open system is normally a pond system, where the algae
can grow naturally or their growth can be enhanced with human
interactions. According to Kaewpintong (2004), closed system is
preferred as the process is easy and energy saving along with least
chances of the interference by environmental factors. Also, the
factors and nutrients can be controlled easily in the closed system;
but in some cases, the open system gains priority. In a study
regarding algae production, Ugwu (2008) concluded that algae
could be grown either in open culture systems or closed systems,
but on larger scale production open system is preferred. Open
system does not require the huge amount of energy and man po-
wer, and also economical. Open system cultivation also helps in the
treatment of waste water sources, and the production process
continues without disruptions. Open ponds are easy to construct
and operate. However, major limitations in open ponds include
poor light utilization by the cells, evaporative losses, diffusion of
CO2 to the atmosphere and requirement of large areas of land. The
closed system has some advantages over open system. In closed
systems (photo bioreactors), higher biomass products are obtained,
and contamination can easily be prevented. Because of these ad-
vantages, the closed system also obtains attention.

Besides these major systems, the other cultivation systems or
methods include water stabilization pond, advanced integrated
waste water pond system and algal high-rate ponds. Cost-effec-
tiveness, larger production, commercial scale growth, minimization
of sludge accumulation, low energy demands, well suited for
tropical and subtropical countries and removal of Biological Oxygen
Demand (BOD) are some of the advantages these systems have, but
they also have some serious disadvantages, including light pene-
tration limitation, windy weather disruptions, hard to take care and
the chances of destroying are higher (Kligerman and Bouwer, 2015).

4. Comparative Analysis of Algal Growth and Their Oil
Contents Production

Mitsuo et al. (1989) worked on spirulina, which is a blue-green
alga. They developed the cultivation method of this alga in the
closed system. They were developing this method to sue this algal
specie for space. This development was beneficial to keep the
conditions for growing of algae homogenous. This was a good step
to obtain the products of algae. The system was made in such a way
the carbon dioxide and oxygen control was made beneficial.
Moreover, by the separation of algae and biomass, product isolation
was made easy. Leghari (2002) carried out the ecological study of
algal flora of the Jhelum River in Azad Kashmir during the period of
January to June 1998. This included the research on 134 species,
belonging to 68 genera from seven groups of algae. The basic idea of
the study was to assess the population of this algal flora as they play
an important role in a balanced ecological system. Water pollution
has increased the population of the flora to dangerously high levels,
inducing oxygen-depletion in water, which unbalances the
ecosystem as is hazardous for aquatic life. Scarcity of such plants
may also be dangerous as they are the primary producers and their
scarcity may unbalance the aquatic food chain. Thus, for a balanced
ecosystem, a balanced population of the algal flora is necessary.
Leghari (2004) carried out the comparative ecological study of algal
genera and useful aquatic weeds of various localities. Twenty-nine
genera of algae belonging to five classes, 47 aquatic weeds
belonging to 21 families of five groups and 35 physicochemical
parameters were recorded. Lakes are rich in primary productivity
and fish production. The study revealed to search the algal flora and
aquatic weeds, water analysis to observe physicochemical proper-
ties, comparative study to explore species either rare or common to
observe and are beneficial or toxic in use.

Ali (2007) reviewed the limnological studies, keeping in view
their strong impact on wetland’s biodiversity. The results revealed
that among total 103 species of planktons, 51 were found in Uchalli,
47 in Khabbaki and 39 in Jahalar Lake, and 31% species were
phytoplankton, whereas 69% were zooplankton. Chisti (2008)
revealed that because of the higher photosynthetic efficiency of
algae, higher biomass productivities, a faster growth rate than
higher plants (which was also important in the screening step),
highest CO2 fixation and O2 production, growing in liquid medium
which can be handled easily, algae can be grown in variable cli-
mates and non-arable land including marginal areas unsuitable for
agricultural purposes (e.g. desert and seashore lands), in non-
potable water or even as a waste treatment purpose, use far less
water than traditional crops and do not displace food crop cultures;
their production is not seasonal and can be harvested daily.
Fernandez et al. (2008) studied viability of marine algae as a source
of renewable energy to laboratory scale. They evaluated the
anaerobic digestion of Macrocystis pyrifera, Durvillaea antarctica
and their blend 1:1 (w/w) in a two-phase system and observed
methane in biogas yield of algae blend, but a lower biogas yield was
obtained. They concluded that methane could be produced in a
two-phase digestion system using either algae species or their
blend. Mirza et al. (2008) discussed that attention had been given to
the use of municipal and industrial wastes for power generation.
The government had been financing many projects related to
biomass energy development in the country, but still lot more ef-
forts were being needed for harnessing full potential and taking
maximum benefit out of this important renewable energy resource.

Gouveia (2009) investigated the screening of microalgae
(Chlorella vulgaris, Spirulina maxima, Nannochloropsis sp., Neochloris
oleoabundans, Scenedesmus obliquus and Dunaliella tertiolecta),
which was performed to choose the best one(s), in terms of
quantity and quality as oil source for biofuel production. N. oleoa-
bundans (fresh water microalga) and Nannochloropsis sp. (marine
microalga) proved to be suitable as raw materials for biofuel
production because of their high oil content (29.0% and 28.7%,
respectively). Both microalgae, when grown under nitrogen
shortage, showed a great increase (»50%) in oil quantity. If the
purpose is to produce biodiesel only from one species, S. obliquus
presents the most adequate fatty acid profile, namely in terms of
linolenic and other polyunsaturated fatty acids. However, the
microalgae N. oleoabundans, Nannochloropsis sp. and D. tertiolecta
can also be used if associated with other micro algal oils and
vegetable oils. Sharif et al. (2008) studied the common species
Oedogonium and Spirogyra to compare the amount of biodiesel
production. Algal oil and biodiesel (ester) production was higher in
Oedogonium than Spirogyra sp. However, biomass (after oil extrac-
tion) was higher in Spirogyra than Oedogonium sp. Sediments
(glycerin, water and pigments) were also higher in Spirogyra than
Oedogonium sp. There was no difference of pH between Spirogyra
and Oedogonium specie. These results indicate that biodiesel can be
produced from both species and Oedogonium is better source than
Spirogyra specie.

Park et al. (2011) reported that algae could use growth nutrients
such as nitrogen and phosphorous from a variety of wastewater
sources (agricultural run-off, concentrated animal feed



S. Khan, et al166
operations and industrial and municipal wastewater), thus
providing a sustainable bioremediation of these waste water for
economic benefits).

Prem et al. (2009) reviewed that worldwide, many nations
impose blending of their transport fuels with biofuels, approxi-
mating 10% globally by 2020, to contribute to energy security while
reducing emission of greenhouse gases. Pienkos and Darzins (2009)
concluded that the comparison of one unique aspect of algae with
other advanced feedstock was the spectrum of species available for
amenability for biofuel production. Various species may be selected
to optimize the production of different biofuels. Algae offer a
diverse spectrum of valuable products and pollution solutions such
as food, nutritional compounds, animal feed, energy sources
(including jet fuel, aviation gas, biodiesel, gasoline and bioethanol),
organic fertilizers, biodegradable plastics, recombinant proteins,
pigments, medicines, pharmaceuticals and vaccines. A number of
microorganisms belonging to the genera of algae, yeast,
bacteria and fungi have ability to accumulate neutral lipids under
specific cultivation conditions. The microbial lipids contained high
fractions of polyunsaturated fatty acids and had the potential to
serve as a source of significant quantities of transportation fuels
(Liam and Owende, 2010). Subhadra and Edwards (2010) studied
that algal biomass provided viable third generation feedstock for
liquid transportation fuel that does not compete with food crops for
cropland. However, fossil energy inputs and intensive water usage
diminishes the positive aspects of algal energy production. An in-
tegrated renewable energy park approach was proposed for
aligning renewable energy industries in resource-specific regions
in the United States for synergistic electricity and liquid biofuel
production from algal biomass with net zero carbon emissions.

5. Role of Gene Technologies in Biodiesel Production

Genomics can play a key role in solving the world energy crisis.
Through genomics, scientists can develop a better approach of
how to harness various renewable sources of energy, such
as cyanobacteria, microalgae and lignocellulosic biomass. One day
on a global scale, the development of sustainable biofuel through
genetic engineering of an enzyme will replace fossil fuels
(Davidson, 2008). Cellulose biomass has the capability to meet the
demand for liquid fuel, but for high-scale deployment of biomass-
to-biofuel technologies, process inefficiencies and land-use
requirements are the main obstacles. Thus, the genomics knowl-
edge of microorganisms can break down the biomass, and po-
tential energy crops will be vital for improving the prospects of
important cellulosic biofuel production (Rubin, 2008). The
genomic information of bioenergy crops will also accelerate the
domestication of these plants, and even will improve their growth
on poor agricultural lands to avoid competition with other food
crops (Rubin, 2008). Further genetic underpinning, such as cell
wall chemistry, stem thickness, branching habit, competition for
light and growth rates, will maximize biomass yield per unit land
area (Tuskan et al. 2006; Rubin, 2008). Currently, intensive global
researches, for increasing and modifying the accumulation of
energy rich compounds, such as polysaccharides, hydrocarbons,
alcohols, lipids and other energy rich chemical compounds in
photosynthetic organisms, bacteria and yeast via genetic engi-
neering have been carried out with good results. Although many
advances through genetic engineering in photosynthetic micro-
organisms have been achieved, because of their capability to
secrete or store energy-rich hydrocarbons, superior growth rates,
diverse metabolic abilities and high photosynthetic conversion
efficiencies (Radakovits et al., 2010). Still, further studies are
needed to extend these advances to industrially relevant
microorganisms.
6. Conclusion

Although much work has been performed, identification of
suitable specie having good characteristics not only production
wise but also growth wise is needed. The growth of algae needs
suitable environment, and work on its cultivation and harvesting is
needed to be developed that a large amount could be grown.
Technical experience and technological development are also
required. More advancement in genetically engineering species
growth is needed to produce required amounts of biodiesel in short
time and less energy utilization.

Conflict of Interest Statement

The authors declare that there is no conflict of interest regarding
the publication of this paper.

Acknowledgement

The authors are thankful to CAS-TWAS president's fellowship
program and State Key Laboratory of Freshwater Ecology and
Biotechnology (Grant No. Y119011F01) for financial support.

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	Biodiesel Production From Algae to Overcome the Energy Crisis
	1. Introduction
	2. The Processes for Biofuel Production Using Algae
	3. Cultivation Systems
	4. Comparative Analysis of Algal Growth and Their Oil Contents Production
	5. Role of Gene Technologies in Biodiesel Production
	6. Conclusion
	Conflict of Interest Statement
	Acknowledgement
	References