2(1)40-45


 

CONTACT : AGUSRAHMAN EKAPUTRA ABAS      Albusrahman@gmail.com 
� International Journal of Applied Biology 40 

Abstract 
The biosynthesis of gold nanoparticles by using algae Spirogyra 
peipingensis was conducted. This research aimed to determine 
biosynthesis of gold nanoparticles by using algae Spirogyra peipingensis 
with different concentration and incubation time. The synthesis of gold 

nanoparticles using HauCl4 solution with variations of concentration 5 

ppm, 10 ppm, 15 ppm and 20 ppm respectively in 1 liter of aquabidest. 

Algae Spirogyra peipingensis was grown in HauCl4 medium with the 
addition of 0.2 gr Sulfahri-01 nutrient. Then each 5 gram Spirogyra algae 

incubated in HAuCl4 medium with the addition of Sulfahri-01 0.2 gram 

nutrients. 4 hours long incubation under exposure to sunlight. 

Nanoparticle size determination is done by looking at the color that 

appears in the solution. From the results of the research, it is known that 

Spirogyra peipingensis algae is able to synthesize gold nanoparticles 

characterized by the color change in algae biomass from green to purple 

color after being treated and forming gold nanoparticles with size 40-60 

NM. The best-used HAuCl4 consent is 5 ppm with the smallest particle 

size. 

 

ISSN : 2580-2410 

eISSN : 2580-2119 

 

 
 

The Potential of Algae Spyrogyra peipingensis to Produce 
Nanogold in Batch Culture Medium 
 

Agusrahman Ekaputra Abas1, Chitriani Armidha2, Arbaina Syahdinnur1 

 
1 Department of Biology, Faculty of Mathematics and Natural Sciences, Hasanuddin 

University, Makassar, Indonesia 
2 Department of Chemistry, Faculty of Mathematics and Natural Sciences, Hasanuddin 

University, Makassar, Indonesia 

 

 

 
 
  
  
 
 
 
 
 
 
 
 
 
Introduction 

The development of nanotechnology applications has driven the industrial 

revolution globally. It has been reported that more than 400 companies worldwide have 

undertaken nanotechnology research and development activities. As a relatively new 

discipline, globally nanotechnology research and applications are growing very rapidly 

(Hoerudin & Irawan, 2015). Nanoparticles are a scope of nanotechnology. It is called a 

nanoparticle when the particle size is in the range of 1-100 NM. With unique properties and 

sizes, nanoparticles have great potential as a material that is superior in the future. The 

nanoparticle material can be organic material such as 2.5 NM DNA, 50 NM protein, 100 NM 

Virus type (Pantidos & Horsfall, 2014), or inorganic materials such as semi-conductor 

       OPEN ACCESS              International Journal of Applied Biology 

Keyword 
Intracelullar, Spirogyra 
peipingensis, 
HAuCl4, 
Biosynthesis. 
 

Article History 
Received 8 June 2018 

Accepted 14 July 2018 

 

International Journal of Applied Biology is licensed under a 
Creative Commons Attribution 4.0 International License, which 
permits unrestricted use, distribution, and reproduction in any 
medium, provided the original work is properly cited.  

 

International Journal of Applied Biology, p-ISSN : 2580-2410 e-ISSN : 2580-2119. 
Journal homepage : http://journal.unhas.ac.id/index.php/ijoab



International Journal of Applied Biology, 2(1), 2018 

 41 

nanoparticles (titanium oxide and zinc oxide), and precious metal nanoparticles (silver and 

gold) (Shaileyee & C Mandal, 2014). 

According to Rohiman et al (2014), in the world of nanotechnology, research on gold 
nanoparticles has attracted the attention of many world researchers because of its 

superiority in its various applications. Gold nanoparticles (AuNPs) are gold ions that are 

reduced to non-charged gold and nano-sized (Maruani, 2013). AuNPs have prominent 

advantages compared to gold particles, which have optical and electronic properties with 

low toxicity (Rohiman, et al, 2014) In addition, AuNPs can be used as a water purifier (Qian, 
et al, 2013), carriers of cancer-killing drugs (Alhalili, et al, 2017), chemical and biological 
sensors (Qin, et al, 2018), catalysts (Amdouni, et al, 2018), biohydrogen production and 
various biomedical applications (Zhang & Shen, 2007). The production of AuNPs can be 

carried out by various chemical methods, but the production of eco-friendly nanoparticles 

are being intensively developed (Sovawi, et al., 2016) through biosynthetic pathways using 
biological agents such as yeast, fungi, bacteria, plants, plant extracts and algae (Thakkar, 

2010). 

Algae are thallophyta organisms that have been known to have a lot of potential. 

One of the most easily found algae in Indonesia is Spirogyra peipingensis algae. This algae 

has the potential to reduce both organic and inorganic compounds. Based on the Bahri 

(2017) study, Spirogyra pepingensis algae can significantly reduce toxicity, absorbing heavy 
metals (Gupta & Rastogi, 2008), and reducing textile waste (Özer, et al., 2006) that have 
mechanisms such as activated carbon. The use of algae as a gold metal bioreductor has 

previously been done by Roychordhury (2016). Algae used derived from the group of 

prokaryotic algae (Cyanobacteria) namely Anabaena sphaerica and eukaryotic green algae 
namely Chlorococcum infusionum. The alignment of cell components in algae such as 
carotenoids, polysaccharides, proteins and pigments in chloroplasts / thylakoids has a major 

role as reducing agents in the biosynthesis of nanoparticle metals (Roychordhury, et al., 
2016). carotenoids, polysaccharides, proteins and chloroplast pigments are also found in 

Spirogyra algae (Tipnee, 2015). Therefore, Spirogyra peipingensis algae is believed to have 
the potential to reduce gold particles to nano-sized gold particles. 

 

Materials and Methods 
Algae Preparation   

Alga Spirogyra peipingensis obtained from the rice field area around the city of 
Makassar. then the algae is cleaned and identifiable under a light microscope before being 

cultured on growth medium sulfahri-01 (3000 lux, 12:12) which later becomes algae stock 

during the research phase. 

 

Preparation of HAuCl4 Solution 
0.1 grams of gold metal dissolved into 20 ml aquaregia (3HCl: 1HNO3). heat over hot 

plate until completely dissolved. then dilute it into a 500 ml measuring flask to make a 

parent solution of 200 ppm. The HAuCl 4 gold mains solution was diluted with aquabides 

with variations in dilution concentration of 5 ppm / L, 10 ppm / L, 15 ppm / L, 20 ppm / L in 

1000 ml aquarium. 

 

 

 

  



International Journal of Applied Biology, 2(1), 2018 

 42 

Incubation of algae Spirogyra peipingensis into gold medium 
5 gr of Spirogyra peipingensis biomass were incubated on HAuCl4 gold medium and 0.2 gr of 

additional surlfahri-01 nutrient media under exposure to 4 hours of sunlight. The top of the 

aquarium is covered with a cling wrap that is sufficiently ventilated for air circulation. 

 
Determines the size of gold nanoparticles 

After Spirogyra peipingensis algae incubation for 4 hours, the yellowish amorphous 
media solution was changed. The color variations formed can be used to determine the 

particle size of the synthesized product. This refers to the color guide of the solution to 

determine the size of the gold nanoparticles published by Noutarianni (2013). 
 

Results and discussion  
Algae Preparation 

Fresh algae biomass Spirogyra peipingensis taken in the rice fields Sudiang, 

Makassar, Indonesia. then cleaned and identified under a magnification light microscope 

100 times above Sedgwick Rafter Counting Chamber (SRC). Determination of Spirogyra 
peipingensis algae type was based on the publication (Zarina, et al, 2007) with unbranched 
filamentous morphology, with vegetative cell width 104-157 μm and length 156-200 μm and 
5-7 pyrenoid. After identification, then Alga Spirogyra peipingensis in culture in 0.2 gr / L 

medium sulfahri-01 with water height 20 cm at 3000 lux lighting lamp with a duration of 

12:12. The composition of the media has been tested based on Sulfahri, et al, (2016). From 

several variations of water height (10,20,30 cm), 20 cm is the most ideal water level with 

the highest level of productivity. 

 

Algae Incubation 
5 gr Biomass Algae Spirogyra peipingensis was incubated in a medium composed of 

0.2 gr/L sulfahri-01 in several concentrations of HAuCl4 with a series of 5 ppm, 10 ppm, 15 

ppm and 20 ppm. Each solution was placed in a 20 cm glass tank with a capacity of 1000 ml 

and placed under 4 hours of sun exposure. The sulfahri-01 medium is the most superior 

medium among several types of mediums compared to having high nitrogen content which 

may play an important role (Sulfahri, et al, 2016) 
After incubation for 4 hours, a change of color occurs in Spirogyra peipingnsis 

biomass. The algae biomass, which was initially light green, became dark purple and was 

confirmed to have died from exposure to the metal mixture in its incubation medium 

(Fig.2a,2b). This change indicates that algae Spirogyra peipingensis can positively synthesize. 
This is in accordance with the results obtained by parial, et al (2012) who trace the types of 
Phormidium valderianum algae, P. tenue, Microcoleus chthonoplastes, Rhizoclonium 
fontinale and Ulva intestinalis. These five algae can positively synthesize intracellular gold 
nanoparticles. According to parial, et al, (2012) the five algae potentially as "Bionano-
factories" and this is evident from the visual transformation of the algal thalli from green to 

deep purple.  

 



International Journal of Applied Biology, 2(1), 2018 

 43 

 
Fig. 2a. Before Incubation   Fig. 2b. After Incubation 
 

The ability of algae as a reducing agent to synthesize gold nanoparticles is much in 

play by the variety of cellular components such as carotenoids, polysaccharides, proteins 

and complete pigments in chloroplasts / tilakoid (Royconduri, et al, 2016). The reduction of 

the metal ions occurs upon the surface of the algal cell as well as on the cytoplasmic 

membrane, leading to the formation of gold nanoparticles (Senapati, et al, 2012). The exact 

process of intracellular formation of gold nanoparticles by alga biomass is not yet fully 

understood (Parial, et al, 2012). 

 

Determines the size of gold nanoparticles 

Fig. 3a.  variations colour of media solutions      3b. GNPs sizing guide 
 

In this way (Fig. 3a), it is possible to deduce the size of the Au NPs produced, ranging 

from 40-60 nm. This refers to the GNPs sizing guide based on the color of the solution 

(Fig.3b) from Queensland University of Technology (Notarriani, 2014). From this research, it 

can be seen that the bigger HAuCl4 concentration, then the size of GNPs in the file will be 

greater because the particle size generated in the concentration series 5,10,15,20 ppm 

respectively contribute the change of color dry awaiting young to blue, which describes the 

existence the addition of the diameter of the nanoparticles, therefore, the 5 ppm 

concentration is considered the best as an incubation medium in producing gold 

nanoparticles. 

According to Parial (2012), All applications of gold (or other) nanoparticles thus 

demand a well-defined size and accurate measurement of these parameters is 

correspondingly important. The optical property of surface plasmon resonance is directly 



International Journal of Applied Biology, 2(1), 2018 

 44 

dependent on the size of the gold nanoparticle: ~20nm particles show an orange-red colour 

but the colour gradually shifts to blue when particle size increases to ~100 nm. Plasmon 

resonance also changes with aspect ratio. 

 
Conclusions 

From the study, it can be concluded that Spirogyra peipingensis algae can synthesize 

gold nanoparticles. Incubation of HAuCl4 medium 5 ppm 0.2 g/L Sulfahri-01 best produces 

gold nanoparticles. From the color of the solution obtained, can also be concluded the 

smaller the concentration of HAuCl4 the smaller the size of the particles produced. The 

intracellular gold nanoparticles biosynthesis has great potential to develop to industrial 

scale because it is easier, cheaper, and environmentally friendly. 

 
Acknowledgment  

The authors gratefully acknowledge financial support from the Ministry of Research, 

Technology and Higher Education of Indonesia with project PKM (Program Kreativitas 

mahasiswa). 

 
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