APPLICATION OF DIGITAL CELLULAR RADIO FOR MOBILE LOCATION ESTIMATION


IIUM Engineering Journal, Vol. 19, No. 1, 2018 Jebun et al. 

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PRODUCTION AND STABILITY OF MYCO-

FLOCCULANTS FROM LENTINUS SQUARROSULUS 

RWF5 AND SIMPLICILLIUM OBCLAVATUM RWF6 

FOR REDUCTION OF WATER TURBIDITY 

NESSA  JEBUN, MD. ZAHANGIR ALAM*, ABDULLAH AL-MAMUN   

AND RAHA AHMAD RAUS 

Bioenvironmental Engineering Research Centre (BERC),  

Department of Biotechnology Engineering, Faculty of Engineering,  

International Islamic University Malaysia,  

Jalan Gombak, 53100 Kuala Lumpur, Malaysia. 

*
Corresponding author: zahangir@iium.edu.my 

(Received: 8th May 2018; Accepted: 21st Nov 2017; Published on-line: 1st June 2018)  

https://doi.org/10.31436/iiumej.v19i1.843 

ABSTRACT: The production and stability of two novel myco-flocculants produced by 

river water fungus (RWF) were investigated. Screening tests were conducted to find 

suitable nutrients, pH, nutrient concentration, inoculum dose, and stability for two myco-

flocculants L. squarrosulus (RWF5) and S. obclavatum (RWF6). The strains showed good 

flocculating activity in reducing turbidity of kaolin suspension while malt extract was used 

as nutrient source. Supernatants of RWF5 and RWF6 were able to reduce turbidity from 

900±10 NTU to 46 NTU (95%) and 195 NTU (78%), respectively. In order to enhance the 

production, optimization of cultivation conditions were studied using a one-factor-at-a-

time (OFAT) method. L. squarrosulus (RWF5) reduced 96% of turbidity at optimum 

conditions, comprising of 0.1% (w/v) malt extract, 3% (v/v) inoculum dose, and initial pH 

7.0 for 6 days. The results of the compatible mixed culture showed good flocculation 

activity at 88% compared to a single culture of S. obclavatum at 78%. On the other hand, 

L. squarrosulus showed better turbidity reduction in the single culture rather than the 

mixed culture. The stability of L. squarrosulus and S. obclavatum supernatants showed 

excellent turbidity reduction over a wide pH range of 4-8 with the maximal flocculation 

rate of 96% and 90%, respectively, at pH 7.0. They also exhibited high turbidity removal 

ability in a temperature range of 4 oC – 55 oC for 24h with a maximum turbidity removal 

rate of 96% (RW5) and 87% (RW6) at 25 oC. Time stability of the L. squarrosulus 

supernatant showed good turbidity removal potential at above 90% at room temperature 

(28± 2 oC) and 85% at low temperature (4 oC) for 12 days. The high flocculating rate of 

the myco-flocculants and their good stability under wide range of temperature indicated 

their potentiality as biodegradable flocculants for water and wastewater treatment industry.  

ABSTRAK: Keberhasilan dan kestabilan dua myco-gumpalan baharu oleh kulat air sungai 

(RWF) telah dikaji. Ujian penapisan telah dijalankan untuk mencari nutrien sesuai, pH, 

kepekatan nutrien, dos inokulum dan kestabilan dua myco-gumpalan L. squarrosulus 

(RWF5) dan S. obclavatum (RWF6). Rantaian menunjukkan aktiviti gumpalan yang baik 

dalam mengurangkan kekeruhan air sungai dengan penggantungan koalin di mana ekstrak 

malt telah digunakan sebagai sumber nutrien. Larutan supernatan RWF5 dan RWF6, 

masing-masing mampu mengurangkan kekeruhan dari 900±10 NTU kepada 46 NTU 

(95%) dan 195 NTU (78%). Bagi meningkatkan pengeluaran, keadaan optimum bagi 

menggalakkan hasil telah diselidiki menggunakan kaedah Satu Faktor pada Tiap Masa 

(OFAT). Pada takat optimum, L. squarrosulus (RWF5) mengurangkan 96% kekeruhan, 



IIUM Engineering Journal, Vol. 19, No. 1, 2018 Jebun et al. 

 49 

ianya terdiri daripada ekstrak malt 0.1% (w/v), dos inokulum 3% (v/v) dan pH awal 7.0 

selama 6 hari. Keputusan kultur campuran yang sesuai menunjukkan aktiviti 

penggumpalan yang baik pada 88% berbanding kultur sendirian S. obclavatum pada 78%. 

Pada waktu sama, L. squarrosulus menunjukkan pengurangan kekeruhan yang lebih baik 

dalam kultur sendirian berbanding kultur campuran. Kestabilan larutan supernatan L. 

squarrosulus dan S. obclavatum menunjukkan pengurangan kekeruhan yang sangat baik 

pada pH yang luas iaitu 4-8 dengan kadar maksimum kekeruhan pada 96% dan 90%, pada 

pH 7.0 masing-masing. Keduanya menunjukkan kebolehan penyingkiran kekeruhan yang 

tinggi pada skala suhu 4 oC – 55 oC selama 24 jam dengan kadar nyah kekeruhan 

maksimum pada 96% (RW5) dan 87% (RW6) pada suhu 25 oC. Kestabilan masa larutan 

supernatan L. Squarrosulus menunjukkan potensi penyingkiran kekeruhan terbaik atas 

90% pada suhu bilik (28± 2 oC) dan 85% pada suhu rendah (4 oC) selama 12 hari. Kadar 

gumpalan yang tinggi oleh myro-gumpalan dan kestabilan yang baik pada julat suhu yang 

luas menunjukkan potensinya sebagai agen biodegradasi gumpalan kepada air dan industri 

rawatan loji air. 

KEYWORDS: flocculation; jar test; Lentinus squarrosulu; mixed culture; Simplicillium 

obclavatu; stability; turbidity   

1. INTRODUCTION  

Chemical flocculants are widely used in wastewater and drinking water treatment, food 

and fermentation industries, as well as in downstream processing due to their high 

flocculating efficiency and cost-effectiveness. [1, 2] Generally, flocculating agents that have 

the most usage in water treatment are the synthetic ones such as aluminium sulphate, ferric 

chloride, lime, and synthetic polymers. [3, 4] Aluminium salts are the most widely used 

coagulant in water and wastewater treatment because of their proven performance and cost 

effectiveness. However, chemical coagulants cannot be easily degraded in nature and may 

result in various health and environmental problems. [5] Compared with chemical 

flocculants, bioflocculants have more advantages, such as being environmentally friendly 

due to their biodegradability, largely nontoxic with no secondary pollution, and harmless to 

both humans and animals. [6] Therefore, bioflocculants have recently gained global 

attention in research because they hold immense potential in replacing chemical flocculants. 

For example, Li et al. [7] reported that B. licheniformis produced ZS-7 bioflocculant is 

expected to be a potential replacement for conventional synthetic flocculants such as PAC 

(polyaluminum chloride) and PAM (polyacrylamide) for the treatment of low temperature 

and room temperature (25 oC) drinking water. Similarly, Gong et al. [8] reported Serratia 

ficaria produced bioflocculant SF-1 showed 91.8 – 93.7% turbidity removal from 

wastewater, which is better than that of PAC and PAM. Aspergillus flavus produced IH-7 

bioflocculant showed better flocculation performance than PAC and IH-7 was significantly 

used to flocculate different types of suspended solids such as activated carbons, kaolin clays, 

soil solids, and yeast cells [9]. Moreover, bioflocculants are widely used for the recovery of 

suspended solids (SS) from wastewater treatment [10-12]. 

Bioflocculants are secondary metabolites produced during the growth of 

microorganisms such as bacteria, yeast and fungi that are composed of polysaccharides, 

proteins, lipids, glycoproteins, and glycolipids [13-15]. The composition and properties of 

coagulants depend on the type of flocculant-producing microorganisms (BPMs), 

composition of the media, and many conditions. The differences in the composition and 

properties of polysaccharides and proteins lead to differences in the charge of coagulant 

[16]. Culture conditions screening is a powerful approach to increase the production of extra 

polymeric substances from microorganism cultivation [17]. Although most flocculants can 



IIUM Engineering Journal, Vol. 19, No. 1, 2018 Jebun et al. 

 50 

be used to flocculate kaolin suspension, they show different flocculating ability for other 

particles or colloids in aqueous solutions. Jebun et al. [18, 19] reported some filamentous 

fungi isolated from river water samples showed good entrapment potentiality to reduce 

turbidity from river water. Deng et al. [20] reported Aspergillus parasiticus produced a 

coagulant with high flocculating activity for kaolin suspension and water-soluble dyes. Pu 

et al. [21] reported that the compound coagulant produced by two strains of Rhizopus sp. 

was successfully used to reduce turbidity from potato starch wastewater. The same 

observation was made by Luvuyo et al. [22] for turbidity removal from kaolin clay by 

bioflocculant produced by a mixed culture of Methylobacterium sp. and Actinobacterium 

sp. 

In the present study, we examine the suitable culture conditions for the production of 

myco-flocculants by two novel L. squarrosulus RWF5 and S. obclavatum RWF6 for 

reducing turbidity from synthetic turbid water. The screening tests were conducted to find 

suitable nutrients, pH, nutrients concentration and inoculum size of these two potential fungi 

to enhance flocculation performance. In addition, stability of the single and compatible 

mixed culture supernatants (myco-flocculants) was investigated for chemical and 

environmental conditions to reduce turbidity by jar test. 

2.  MATERIALS AND METHODS  

2.1  Microorganisms and Growth Conditions  

L. squarrosulus RWF5 and S. obclavatum RWF6 were isolated from river water 

samples collected from the River Pusu on the IIUM campus for coagulant production.  L. 

squarrosulus RWF5 and S. obclavatum RWF6 cultures were maintained on potato dextrose 

agar (PDA) (Oxoid, UK) and initial pH was adjusted to 5.8±0.2. Distilled water was used 

to prepare medium solutions and sterilized at 121 oC for 20 minutes. The culture plates were 

incubated at 32±2 oC for 10 days. Subculture was conducted twice in a month and sub 

culture plates were stored at 25 oC in an incubator for further use. 

2.2  Myco-coagulants Production  

2.2.1 Screening of Nutrients 

The screening medium consisted of 5 g/l starch, sucrose, yeast extract, and malt extract 

and each of the medium was mixed with 1 liter of distilled water. The medium was then 

sterilized by autoclaving it at 121 °C for 15 minutes and then inoculated with 2% (v/v) 

fungal mycelial inoculum (340 mg/l). The liquid culture was then incubated in a rotary 

shaker with agitation at 150 rpm at 30± 2oC for 8 days. Initial pH of the broth was adjusted 

at 7.0 ± 0.1 using 1 M NaOH or 2 M HCl. Supernatants were taken at different time intervals 

to determine the flocculation activity. The effect of cultivation time for myco-flocculants 

production was investigated for 8 days.  

2.2.2 Factors Affecting the Flocculating Rate 

To study the effect of malt extract concentration of 0-1% (g/l), initial pH values of 5, 

6, 7, and 8, and inoculum doses of 1-4% on the flocculating rate were investigated. In this 

experiment, OFAT analysis was followed for three factors such as media concentration, pH, 

and inoculum dose.   

2.2.3 Single and Mixed Culture  

The production medium consisting of 5 g/l malt extract was autoclaved at 121 °C for 

15 minutes. The sterilized medium was inoculated with 2% (v/v) fungal inoculum for single 



IIUM Engineering Journal, Vol. 19, No. 1, 2018 Jebun et al. 

 51 

and mixed culture (mycelium concentration of 340 mg/l). Ten day old culture plates were 

used to prepare fungal inoculum and the culture was incubated in a rotary shaker with 150 

rpm at 30± 2 oC for 6 days. Initial pH of the culture was adjusted at 7.0±0.1 using 1 M NaOH 

or 2 M HCl. The cultures were harvested after 6 days of treatment and centrifuged to 

separate the biomass from supernatant (103 rpm for 10 mins at 25 oC). The supernatants 

were used as myco-flocculants and stored at room temperature at 28±2 oC for further use.  

2.3  Myco-flocculant Stability 

2.3.1 pH Stability of Supernatants 

The pH of myco-flocculants from single and mixed cultures was adjusted to 4, 5, 6, 7, 

and 8 with 1 M NaOH and 2 M HCl. A Jar test was conducted to observe flocculation 

activity in different pH. Initial turbidity and pH of kaolin suspension were recorded at 

900±10 NTU and 7.0±0.1, respectively and the mixture was stirred at 120 rpm for 40 

minutes and allowed to settle for 30 minutes. 

2.3.2 Temperature Stability      

 Myco-flocculants were treated at different temperatures of 4, 25, 35, 45 and 55 oC for 

24 hours.  Both supernatants were applied in kaolin suspension to reduce turbidity with the 

same conditions as referred to section 2.3.1. 

2.3.3 Time Stability of L. squarrosulus Produced Myco-flocculant 

The myco-flocculant produced by L. squarrosulus RWF5 was tested for flocculation 

activity capability. The myco-flocculant was kept in room temperature (28±2 oC) and low 

temperature (4 oC) for 20 days. Jar tests were conducted to observe flocculation activity in 

terms of reducing turbidity from kaolin suspension. 

2.3.3 Flocculation Activity  

Kaolin suspension was prepared using 0.7 g kaolin clay in 1 liter of tap water (turbidity 

900±10 NTU). Each Jar contained 500 ml kaolin suspension was added with 1% supernatant 

(v/v). The jar apparatus was then operated at a speed of 120 rpm with 40 minutes mixing 

time and allowed to settle for 30 minutes [19]. Next, the top layer of water in each Jar was 

collected with a micro pipette and turbidity was measured with a portable turbidimeter 

2100Q HACH, USA to measure residual turbidity. In the control experiment, 1% (v/v) of 

supernatant was replaced with 1% (v/v) of nutrient broth. The flocculating activity was 

calculated according to the following equation [23].  

Flocculating activity (%)  = [
𝐴−𝐵

𝐴
]  × 100%    (1) 

where, A is the initial turbidity value and B is the residual turbidity after flocculation. 

3.    RESULTS AND DISCUSSION 

3.1   Myco-flocculant Production 

3.1.1 Screening of Potential Nutrient  

Figure 1 (a) shows the flocculating activity of two coagulants for 6 days in media 

containing starch, sucrose, yeast extract, and malt extract. Starch, sucrose, and yeast extract 

were not favourable for L. squarrosulus and S. obclavatum growth, while the production of 

coagulants was relatively low when carbon and nitrogen sources were used 

 separately.  



IIUM Engineering Journal, Vol. 19, No. 1, 2018 Jebun et al. 

 52 

 

Fig. 1: The effects of nutrient and cultivation time on myco-flocculant production. 

a)  Screening of potential nutrient, b) Culture time with malt extract. 

The highest myco-flocculant production from L. squarrosulus and S. obclavatum were 

obtained in malt extract media. Malt extract was used as co-substrate to enhance the 

separation and filtration process of treated sludge by fungal growth formation [24]. 

Aljuboori et al. [25], reported that the highest coagulant production by Aspergillus niger 

was observed when the C/N ratio increased up to 20/1 with a flocculating rate of 79% 

respectively, but that further increase in the C/N ratio slightly decreased the production. 

Figure 1 (b) shows the cultivation time with flocculation activity in terms of turbidity 

removal rate of myco-coagulants. The culture during the early stationary phase showed the 

highest (95% and 82% at 6 days) flocculating rate of L. squarrosulus and S. obclavatum, 

respectively. Results showed the flocculating rate decreased slowly after 6 days, suggesting 

these strains may be secreting deflocculation enzymes. A similar result was reported in the 

cultivation of A. parasiticus [20] and B. licheniformis [26]. Consequently, a period of 6 days 

was chosen as the culture time for the subsequent experiments. 

3.1.2 Effect of Media Concentration, Initial pH, and Inoculum Size 

Figure 2 shows the effect of malt extract concentration on the flocculating rate of two 

myco-coagulants. L. squarrosulus and S. obclavatum increased myco-flocculants at 0.1% 

(w/v) and 0.25% concentration, respectively. The flocculating activity of two fungal strains 

was poor without malt extract concentration in the culture (0%). Small growth was found 

from the two fungal strains without nutrients (malt extract), suggesting that the strains may 

not able to secrete any metabolites due to lack of growth. 

20

40

60

80

100

Starch  Yeast extract  Sucrose  Malt extract

T
u
rb

id
it

y
 r

e
m

o
v
a
l 

(%
)

Nutrients

L. squrrosulus S. obclavatum

30

40

50

60

70

80

90

100

2 4 6 7 8

T
u
rb

id
it

y
 R

e
m

o
v
a
l 

(%
)

Cultivation Time (Day)

L. squarrosulus S. obclavatum Control

(a) 

(b) 



IIUM Engineering Journal, Vol. 19, No. 1, 2018 Jebun et al. 

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Fig. 2: Effect of media concentration of the flocculation activity on myco-flocculants. 

Figure 3 shows the effect of the initial pH of the culture medium on bio-coagulant 

production. The flocculating activity increased when pH was varied from 5 to 7 with the 

maximum flocculating activity of 95%. The removal rate (77%) decreased at an alkaline pH 

(8) for both of the cultures. Salehizadeh et al. [1] investigated that the initial pH of the 

production medium influences the electric charge of the cell and oxidation-reduction 

potential, which in turn affects the nutrient absorption and enzymatic reaction. 

 

Fig. 3: Effect of the initial pH of the culture medium on the flocculating  

activity of myco-flocculants. 

The flocculating rates obtained from the culture inoculated with 1 to 4% (v/v) inoculum size 

of two fungal strains are shown in Fig. 4. The use of 2 to 3% of L. squarrosulus inoculum 

dose in production medium recorded the highest flocculating rate of 96%. S. obclavatum 

was gradually decreased when inoculum dose was increased due to excessive overlapping 

of cells, resulting in inhibition of coagulant production. Aljuboori et al. [13] reported an 

optimal coagulant production by Aspergillus flavus at 2% (v/v) inoculum size, whereas a 

higher inoculum size of 10% (v/v) was most suitable for coagulant production by Rhizopus 

sp. [21] 

 

30

40

50

60

70

80

90

100

0 1 2.5 5 7.5 10

T
u
rb

id
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e
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o
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a
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(%
)

Media concentration (g/l)

L. squarrosulus S. obclavatum

50

60

70

80

90

100

5 6 7 8

T
u

rb
id

it
y

 r
e

m
o

va
l 

(%
)

pH

L. squarrosulus S. obclavatum



IIUM Engineering Journal, Vol. 19, No. 1, 2018 Jebun et al. 

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Fig. 4: Effect of inoculum dose of culture medium on myco-flocculants production.  

3.1.3 Compatible Mixed Culture 

Figure 5(A) shows ten day old single and mixed culture plates of L. squarrosulus and 

S. obclavatum. Figure 5(B) shows the turbidity removal (%) of single and mixed cultures. 

The flocculation rate was higher at 88% of mixed culture compared to the single culture of 

S. obclavatum (78%). The mixed culture showed significant growth of L. squarrosulus in 

the PDA plate, which indicated that the compatible mixed culture of L/S may have produced 

more substances to enhance flocculation to reduce turbidity compared to single S. 

obclavatum culture. Alam et al. [12] reported the fungal mixed culture of Aspergillus 

niger and Penicillium corylophilum was enhanced the separation process of wastewater 

sludge. Two strains of Rhizopus sp. produced a compound coagulant that was used to reduce 

turbidity of 91.1% from potato starch wastewater [21]. 

 

 

 

 

 

 

 

 

 

Fig. 5: Compatible mixed culture (A) L. squarrosulus (A-a), S. obclavatum (A-b), L. 

squarrosulus and S. obclavatum (L/S) front side of plate (A-c), L/S reverse side of plate 

(B) Turbidity removal by single and compatible mixed culture. 

40

50

60

70

80

90

100

1 2 3 4

T
u
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id
it

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 r

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o
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a
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(%
)

Inoculum dosage %(v/v)

L. squarrosulus S. obclavatum

40

50

60

70

80

90

100

L. squarrosulus S. obclavatum Mixed culture Control

T
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id
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a
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(%
)

LS LS 

L S 

a b 

c 
d 

(A) 

(B) 



IIUM Engineering Journal, Vol. 19, No. 1, 2018 Jebun et al. 

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3.1.4 Myco-coagulants Stability by Jar Test  

Figure 6(a) shows that L. squarrosulus was stable at a wide range, from pH 4.0 to 8.0 

and more than 90% flocculation was achieved within this range. At pH 7.0, the turbidity 

removal rate was higher for both myco-coagulants and the flocculation rate decreased 

slowly as the pH increased further. The mixed culture also showed good stability at pH 7.0. 

Thus, these myco-coagulants are suitable to be applied at acidic and neutral conditions. This 

may be due to the fact that myco-flocculants show different electric charges at different pH 

levels and affect the flocculation ability of the bio-flocculant for kaolin particles [27].  

 

 

 

Fig. 6: Myco-flocculant stability: a) The pH stability of L. squarrosulus, S. obclavatum 

and mixed culture; b) Temperature stability of  L. squarrosulus, S. obclavatum and mixed 

culture; c) Time Stability of myco-flocculant (L. squarrosulus). 

70

75

80

85

90

95

100

4 5 6 7 8

T
u

rb
id

it
y

 r
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m
o

va
l 

(%
)

pH

L. squarrosulus S. obclavatum Mixed culture

a

75

80

85

90

95

100

4 25 35 45 55

T
u

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id

it
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(%
)

Temperature (oC)

L. squarrosulus S. obclavatum Mixed culture

b

50

60

70

80

90

100

0 2 4 6 8 10 12 14 16 18 20 22

T
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(%
)

Time (Day)

28±2 C 4 C

c



IIUM Engineering Journal, Vol. 19, No. 1, 2018 Jebun et al. 

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The effect of temperature on the flocculating activity of myco-flocculants was 

investigated (Fig. 6-b). The results showed that both myco-flocculants are fairly 

temperature-tolerant and had good flocculation activity at a wide range of temperatures. The 

flocculation ratio varied from 92% to 96% (L. squarrosulus) and 84% to 90% (S. 

obclavatum) in the temperature range of 4 oC to 55 oC, and only begins to decrease slightly 

with further temperature increase from 45 oC to 55 oC. The mixed myco-flocculant showed 

good stability at 4oC, then gradually decreased in temperature range to 45 oC -55 oC. The 

highest turbidity removal rate of 96% was observed at 25 oC and 35 oC for the L. 

squarrosulus myco-coagulant. These myco- flocculants were more stable at moderate 

temperatures (range 25 oC and 35 oC). Similar findings were observed by Aljuboori et al. 

[9], on the bioflocculant produced by Aspergillus flavus with a residual flocculating activity 

of about 93% at temperature range from 5 to 45 °C, thus indicating a thermostable 

bioflocculant. The result was similar to reported for the bioflocculant produced by 

Aspergillus parasiticus and it had moderate heat-stability [20]. 
Figure 6(c) shows the effect of time stability on turbidity removal rate of L. 

squarrosulus produced myco-flocculant. The highest turbidity removal % was recorded at 

room temperature (28±2 oC) till 12 days then it showed decreased flocculation activity of 

the myco-flocculant. This may be due to the fact that the metabolites of the myco-coagulant 

are deactivated gradually after two weeks of storage. However, turbidity removal rate was 

85% at low temperature (4 oC) stored coagulant with 12 days. After two weeks, the 

flocculation activity was decreased gradually and it reached at about 50% at 20 days. This 

may have occurred due to the deactivation of metabolites. 

4.   CONCLUSIONS 

This study shows that L. squarrosulus and S. obclavatum produced myco-flocculants 

that were effective in the removal of turbidity of a kaolin suspension. The optimal conditions 

of L. squarrosulus myco-flocculant production were malt extract concentration 0.1% (g/l), 

initial pH 7.0 and inoculum dose 3% (v/v) for 6 day cultivation time which the flocculating 

activity reached above 95%. The two myco-flocculants’ stability indicates that they can 

work at different pH ranges between 4-8 and can be stored at room temperature (25 oC). 

Finally, both novel myco-coagulants are expected to be potential replacements of chemical 

coagulants and widely applied in water treatment and other industries.  

ACKNOWLEDGMENT 

The authors would like to express their thanks to Ministry of Higher Education (MOHE) for 

granting a Fundamental Research Grant Scheme (FRGS), project No. FRGS-14-109-0350 

for the financial support. Thanks also to Research Management Centre (RMC), International 

Islamic University Malaysia for financial management and monitoring the progress of the 

project. 

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