APPLICATION OF DIGITAL CELLULAR RADIO FOR MOBILE LOCATION ESTIMATION


IIUM Engineering Journal, Vol. 24, No. 2, 2023 Khatib et al. 
https://doi.org/10.31436/iiumej.v24i2.2590 

BIODEGRADATION OF FATS, OIL AND GREASE USING 

MICROORGANISMS ISOLATED FROM PALM OIL  

MILL EFFLUENT 

MA'AN FAHMI RASHID AL KHATIB*, FADI ALQEDRA AND MD. ZAHANGIR ALAM 

Biotechnology Engineering Research Center (BERC),  

Department of Chemical Engineering and Sustainability, Kulliyyah of Engineering, 

International Islamic University Malaysia, Kuala Lumpur, Malaysia 

*
Corresponding author: maan@iium.edu.my 

(Received: 30 August 2022; Accepted: 19 January 2023; Published on-line: 4 July 2023) 

ABSTRACT:  The biodegradation of fat, oil, and grease (FOG) is important in water 

pollution control and wastewater management. In this study, the viability of FOG-

degrading microorganisms on palm oil biodegradation was assessed. Seven strains capable 

of degrading FOG were isolated from palm oil mill effluent (POME). The potential 

bacterial strains were selected based on Tween-80-degrading ability. Micrococcus lylae 

strain DSM 20315 showed the highest growth compared to the other strains. Hence, it was 

selected for FOG degradation test. The biodegradability was performed as a function of 

pH (6, 7, 8), initial oil concentration (1, 3, 5% v/v), and inoculum concentration (2, 6, 10% 

v/v). Optimization of these parameters of palm oil degradation was studied using 2-level 

factorial design. The maximum oil degradation was 68%, obtained at pH 6, initial oil 

concentration 1 % v/v, and bacterial inoculum concentration of 10 % v/v. The lowest oil 

degradation obtained was 22%. The initial oil concentration followed by bacterial 

inoculum concentration enhanced the removal efficiency of FOG, but the pH level did not 

significantly promote the degradation rate. As a result, the optimum process conditions for 

maximizing oil degradation were at pH 6, initial oil concentration 1 %v/v, and bacterial 

inoculum concentration of 10 %v/v.  

ABSTRAK:  Biodegradasi lemak, minyak, dan gris (FOG) adalah penting dalam kawalan 

pencemaran air dan rawatan air buangan. Kajian ini adalah berkenaan kebolehhidupan 

organisma pengurai-FOG dalam biodegradasi minyak kelapa sawit. Tujuh strain 

berkeupayaan mendegradasi FOG diasingkan daripada cairan buangan minyak kelapa 

sawit (POME). Strain bakteria yang berpotensi telah dipilih berdasarkan keupayaan 

degradasi-Geladak-80. Strain Mikrokokus lilae DSM 20315 menunjukkan pertumbuhan 

tertinggi berbanding strain lain. Oleh itu, ia dipilih bagi ujian degradasi FOG. Keupayaan 

biodegradasi telah dihasilkan berdasarkan fungsi pH (6, 7, 8) ketumpatan  awal minyak (1, 

3, 5% v/v) dan ketumpatan inokulum (2, 6, 10% v/v). Parameter optimum degradasi minyak 

kelapa sawit dikaji menggunakan reka bentuk faktorial 2-tahap. Nilai maksimum 

degradasi minyak adalah sebanyak 68%, terhasil pada pH 6, berketumpatan awal 1% v/v, 

dan ketumpatan inokulum bakteria 10% v/v. Degradasi minyak terendah pula adalah 

sebanyak 22%. Ketumpatan awal minyak diikuti ketumpatan bakteria inokulum 

meningkatkan kecekapan penyingkiran  FOG, tetapi level pH tidak ketara dalam 

membantu kadar degradasi. Sebagai kesimpulan, keadaan optimum bagi degradasi minyak 

maksimum adalah pada pH 6, ketumpatan awal minyak 1% v/v dan ketumpatan bakteria 

inokulum sebanyak 10% v/v.   

KEYWORDS: FOG; degradation; POME; oil; optimization; wastewater 

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1. INTRODUCTION 

Wastewater with high fat, oil, and grease (FOG) concentrations is attracting more 

attention because of population growth and industrialization. FOG accumulation in sewer 

systems has a negative impact on both health and the environment, thus effective strategies 

for controlling FOG deposition are critical. Triglycerides, or triglycerides linked to glycerol 

molecules, are the building blocks of fat, oil, and grease. The physical properties of fat, oil, 

and grease vary depending on the type of fatty acids that comprise the triglycerides and their 

physical state. 

FOG is produced by the dairy industry, slaughterhouses, food processing plants, and 

other industries that process fatty substances, in addition to private residences [1]. When 

wastewater carrying fat, oil, and grease flow in sewer pipes, FOG will deposit in the pipes 

by forming layers of lipid-rich materials [2]. Sewer blockage causes over 25,000 flooding 

events in the United Kingdom each year. FOG is thought to account for more than half of 

all sanitary sewer overflows (SSOs) [3]. The American Environmental Agency (EPA) 

estimates that between 10,350 and 36,000 sanitary sewer spills occur in the United States 

each year, with FOG accounting for approximately 47% of the total. Furthermore, Indah 

Water Konsortium (IWK), the wastewater municipality in Malaysia, reported that up to 45% 

of SSOs may be caused by FOG [4]. Due to their prevalence in sewer systems (such as 

pipelines, pump stations, wet wells, etc.) and subsequent wastewater treatment facilities, 

FOG deposits have an impact on health and the environment. They often result in sanitary 

sewer overflows (SSOs) by reducing sewer diameter or totally blocking the pipelines. The 

ensuing sewage discharge increases water contamination and pathogen exposure. FOG can 

also attract vermin such as rats, and sloughed deposits can clog pumping stations and sewage 

treatment plants [5]. To implement effective control measures, it is necessary to have a 

complete understanding of the properties and impacts of FOG. 

Approaches to controlling FOG can be categorized as physical, chemical, or biological.  

Long chain fatty acids are introduced to wastewater during the chemical hydrolysis of FOG, 

which may limit microbial activity and disrupt the wide variety of microorganisms present 

[6], resulting in a decline in wastewater treatment efficacy and recurrent production of 

intolerable odors. 

Physical methods use FOG's reduced density in comparison to water. Grease traps (also 

known as grease interceptors) are one of the most frequently used physical-based FOG 

removal devices used prior to entering wastewater systems. When FOG-containing 

wastewater enters a grease trap, lower density FOG floats to the surface, allowing virtually 

FOG-free water to exit the grease trap and enter the sewer system. The FOG that has floated 

to the surface will be manually removed. Tilted plates (TP) are a modified grease trap. TP 

are parallel gravity separators that offer a large surface area while taking up less than 10% 

of the volume of a typical grease trap [7]. During dissolved air foliation, micro-bubbles bind 

to FOG particles, allowing them to float to the water's surface and be swiftly removed. To 

clear the accumulating FOG layers, physical approaches require human intervention. The 

increased demand for human resources raises the expense of FOG cleaning and the 

maintenance of related facilities, which already cost millions of dollars per year. 

Furthermore, these techniques are ineffective at reducing FOG, which can eventually limit 

the oxygen transfer rate, compromising biological treatment [8]. Additionally, it was shown 

that microbial activity in grease traps generated large amounts of long-chain fatty acids, 

which, when released into sewer systems, aid in the production of FOG deposits [9]. 

Biological FOG treatment is gaining traction due to its ability to treat FOG at the source 

and prevent it from entering sewer systems. FOG is biologically treated by bacteria capable 

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of secreting enzymes that speed up the hydrolysis process or by direct use of enzymes such 

as lipases and commercial additives. Isolating such bacterial strains and determining the 

optimal parameters and overall process. Teixeira et al. isolated bacteria from activated 

sludge and wastewater effluent to biodegrade triolein and oleic acid [10]. Aeromonas sp. 

and Staphylococcus cohnii were shown to be the best degraders. However, in a 7-day 

assessment of FOG content, the elimination of oleic acid and/or triolein was 37.9% and 

19.1%, respectively. Phong et al. identified bacteria from wastewater collected from 

restaurants and canteens containing vegetable oil [11]. Because of its strong lipid 

degradation ability, Acinetobacteria soli strain AL3 was selected as a potential for FOG 

biodegradation. Similarly, strains belonging to the genera Acinetobacter, Bacillus, and 

Pseudomonas demonstrated the ability to efficiently degrade FOG [12]. The FOG removal 

efficiency of Pseudomonas sp. strain D2D3 were 94.5% and 94.4% for olive oil and animal 

fat, respectively, whereas sunflower oil had the lowest percentage at 62% [2]. It is beneficial 

to isolate the bacteria from a medium that is rich in FOG and where the microorganisms 

have had time to acclimate to ensure a high degree of biodegradation. 

Raw palm oil mill effluent (POME) contains high concentrations of organic substances, 

including oil and grease, which lead to elevated levels of COD and BOD. POME treatment 

in open oxidation ponds will eventually reduce these amounts significantly [13]. This 

suggests that POME would accommodate and sustain bacteria capable of metabolizing palm 

oil during the natural decomposition process in the ponds. Many studies have demonstrated 

the potential of isolating lipolytic bacteria from POME [14]. Some strains, however, were 

unable to use palm oil directly as a carbon source. As a result, the isolation and screening 

procedures were modified to select bacterial strains capable of using palm oil as a carbon 

source. POME is a preferred source for isolating lipid-degrading bacteria due to its nature 

and potential. 

The objective of this study is to isolate bacteria from palm oil mill effluent and 

screen them for lipolytic activity on Tween 20. The high-performing bacteria will then be 

used to biodegrade cooking palm oil, which is a popular oil with a fatty acid composition 

similar to that of FOG. The selected bacteria's growth conditions will then be optimized. 

2. MATERIALS AND METHODS 

2.1  Screening and Isolation of Lipolytic Bacteria  

POME that was serially diluted from 101 to 107 was used to isolate bacterial strains. A 

sample of each dilution was plated on LB agar and incubated overnight at 37 °C [15]. To 

obtain the pure strains, the colonies that formed on the agar plates were sub-cultured on new 

agar plates. More than 20 pure strains were obtained. The lipase activity was seen using 

Kanmani et al.'s agar plate assay [16]. Tween 20 (Sigma-Aldrich) was utilized as a substrate 

since it is suitable for the simple and rapid detection of microbial lipolytic activity on an 

agar plate. The pure colonies were streaked on Tween 20 agar plates. Lipase producers have 

a zone of white-like precipitate surrounding the lipase-active colony. The first 7 strains that 

appeared on agar were selected for further screening.  

2.2  Characterization of the Isolated Strains 

Individual bacteria isolates were identified beforehand using classical tests such as cell 

shape, Gram staining, and colony morphology on solid nutrient media. First BASE 

Laboratories Sdn. Bhd., Malaysia, performed the genetic identification of isolates by 

determining the nucleotide sequence of the 16S rRNA gene. 

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2.3  Growth Profile of the Isolated Strains 

The lipolytic strains were added to a 250 mL Erlenmeyer flask containing 1 mL of palm 

oil as a carbon source and 100 mL of minimal salt medium (MSM) media. The author of 

[15] describes how to make an inoculum in LB broth medium. The inoculum was added to 

100 mL of MSM containing 2.5 g/L NaCl, 4.74 g/L K2HPO4, 0.56 g/L KH2PO4, 0.5 g/L 

MgSO4.7H2O, 0.1 g/L CaCl.6H2O, and 0.5 g/L NH4NO3 in dH2O. The media (100 mL) 

were poured into a 250 mL Erlenmeyer flask and autoclaved for 15 minutes at 121 °C. All 

samples were inoculated with a starter culture (1% v/v) produced in LB medium 

(OD600=1.0) [15]. Before inoculation, the starter culture was centrifuged (13,000 rpm, 10 

minutes, 4°C) and rinsed a couple of times in a physiological salt solution to avoid the 

transfer of LB organic compounds into fresh media. Bacteria were omitted from the control 

samples. All the samples underwent a two-week incubation period in a rotary shaker (150 

rpm, 25 °C). On a UV-Visible spectrophotometer every 6 hours, the growth was measured 

at absorbance of 600 nm [17]. 

2.4  Optimization of FOG-Degradation    

Biodegradation of palm oil was performed to determine the highest concentration of 

palm oil that could be degraded using bacterial strains in 250 mL Erlenmeyer flasks that 

were stoppered with cotton wool to promote oxic conditions. Each flask held 100 mL of 

MSM, supplemented with a predetermined oil concentration, inoculum concertation, and 

pH level. 1N NaOH or HCl were used to adjust the pH. Before inoculation, samples were 

autoclaved. The experiment lasted two weeks at 37 °C and 150 rpm. Experiments with 

bacterial samples and controls were carried out in duplicate.  

Using Design Expert 6.0.8 software, biodegradation optimization runs were designed 

applying 2-Level Factorial Design (2LFD) with one replicate and three center points. The 

optimized parameters were the pH of the MSM medium (A), the concentration of oil (B), 

and the inoculum concentration (C). These variables were assessed at 3 different levels: pH 

(6, 7, 8), oil concentration (1, 3, 5% v/v), and inoculum concentration (2, 6 and 10% v/v). 

The software developed a matrix containing 11 experiments. Under predetermined 

conditions, oil degradation was carried out as designed. Following the incubation period, 

the oil was degraded using gravimetric methods. The software was used to enter and analyze 

these data. ANOVA (standard analysis of variance) and a contour plot were produced. 

The partition gravimetric technique was implemented to estimate the medium's residual 

oil content [18] The residual oil content was strained numerous times with 5 mL of hexane 

such that there was no oil layer in the aqueous phase and the solvent phase was clear. In a 

water bath at 70°C, the mixed solvent extract was completely evaporated, and the amount 

of residual oil was calculated to determine the percent decrease [3]. 

3. RESULTS AND DISCUSSION 

3.1  Growth Profile of the Isolated Strains 

To construct an efficient oil-containing wastewater treatment system, oil-degrading 

microorganisms were isolated from POME. A sample of palm oil mill effluent was serially 

diluted and screened. In the initial screening, twenty POME isolates were obtained. The oil-

degrading ability of the selected strains was then tested using Tween 20 agar medium. Seven 

strains that displayed the highest precipitate formation around the colonies in Tween 20 agar 

plates were selected for subsequent FOG biodegradation experiments. The growth profiles 

of the seven strains were screened using optical density, and the strain with the highest cell 

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growth rate was investigated for oil degradation optimization. Figure 1 depicts the growth 

curve for the selected seven. Strain X3 demonstrated the highest growth, hence it was 

selected for further investigation. 

3.2  Characterization of Isolated Bacteria 

Based on gram staining of the isolated strains, Table 1 indicates that two strains belong 

to gram negative category, while the other five strains belong to gram positive bacteria. 

Table 2 shows the phenotypical characteristics of the seven isolates when grown on LB agar. 

  

Fig. 1: The growth curve for the seven selected strains. 

Table 1: Identification of the isolated strains 

Sample Gram staining Identification of the strains 

(X1, X2,X3) Gram positive Micrococcus lylae strain DSM 20315 

X4 Gram positive Corynebacterium aurimucosum strain H2456 

X5 Gram negative Lysinibacillus boronitolerans strain 10a 

X6 Gram positive Staphylococcus hominis subsp. 

novobiosepticus strain GTC 1228 

X7 Gram negative Bacillus drentensis strain LMG 21831 

     Table 2: Phenotypical characteristics of the seven isolates when grown on LB agar 

Isolate (X1, X2, X3) X4 X5 X6 X7 

Form of colony Irregular Circular Circular Circular Circular 

Elevation Convex Convex Flat Flat Flat 

Margin Entire Entire Entire Entire Entire 

Pigmentation Yellow White Red White Red 

Texture Rough Smooth Smooth Smooth Smooth 

Optical properties Opaque Opaque Opaque Opaque Opaque 

Appearance Dull Shiny Shiny Shiny Shiny 

Strain X3, which showed the highest degradation capability, was identified using 

morphological tests and 16S RNA sequence analysis (Fig. 2). Strain X3 was gram-positive 

bacteria capable of producing lipase. The 16S ribosomal RNA (16S rRNA) gene was 

sequenced and the generated sequences were analyzed using BLAST to reveal that X3 

belongs to the genus Micrococcus. The 16S rRNA (500bp) sequence analysis of strain X3 

revealed a significant similarity (more than 99%) to that of the genus Micrococcus. Based 

on these traits and its 16S rRNA sequence, strain X3 was identified as Micrococcus lylae 

strain DSM 20315. 

X
1 

X
2 

X
3 

X
4 

X
5 

X
6 

X
7 

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Fig. 2: Phylogenetic tree of X3 strain. 

In the present study, Micrococcus lylae strain DSM 20315 was shown to have lipolytic 

activity. To the knowledge of the researchers, this study was the first time Micrococcus lylae 

strain DSM 20315 was used as a potential lipid-degrading strain. This supports the 

hypothesis that POME is a potential source for oil-degrading bacteria [5]. 

Table 3: Two LFD Experimental design setup and response 

Run no. A 

pH 

B 

Oil conc. 

% (v/v) 

C 

Inoculum conc. 

% (v/v) 

Response 

Oil biodegradation 

% 

Std 

Exp’l Pred. 

1 7.0 3.0 6.0 35.3 44.9 6.79 

2 8.0 5.0 10.0 25.4 22.8 1.84 

3 8.0 1.0 2.0 58 55.4 1.84 

4 6.0 5.0 2.0 38.6 36.0 1.84 

5 7.0 3.0 6.0 33 44.9 8.41 

6 8.0 1.0 10.0 53 55.6 1.84 

7 7.0 3.0 6.0 37 44.9 5.59 

8 6.0 1.0 10.0 68 65.4 1.84 

9 6.0 5.0 10.0 29.2 31.8 1.84 

10 8.0 5.0 2.0 37 39.6 1.84 

11 6.0 1.0 2.0 50 52.6 1.84 

3.3   Statistical Optimization of FOG-Degradation  

The highest biodegradation achieved following the experimental design setup (Table 3) 

was 68% at pH 6, 1% (v/v) oil concentration, and 10% (v/v) inoculum concentration (run 

no. 8). Lipid-degrading bacteria such as Bacillus thermoleovorans IHI-91 was found to be 

able to degrade palmitic acid, steric acid, lanoline, olive oil, sunflower seed oil, soya oil, 

and fish oil as sole carbon source [19]. [2] isolated and identified Pseudomonas sp. strain 

D2D3 that is capable of degrading fat, oil, and grease. They also found that the degradation 

rate ranged from (62.0% -94.5%) based on the substrate. [20] investigated the lipolytic 

activity of Raoultella planticola bacterial strain and found its efficiency to degrade a mixture 

of lipids substances with maximum degradation level of 91.9% for oleic acid.  

ANOVA for the 2LFD model (Table 4) revealed an F-value of 11.84, indicating that 

the model is significant and that there is only a 3.4% likelihood that such a big F-value could 

occur due to noise. Model terms are significant when "Prob > F" is less than 0.05. In this 

case, B (oil concentration) and BC are significant model terms. Values larger than 0.10 

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suggest that the model terms are not significant. Generally, large magnitudes of t and F, as 

well as smaller p-values, indicate that the associated coefficient terms are significant. R2 

indicates how much of the observed response's variability may be attributed to the 

experimental factors and their interactions. R2 is a measure of how well a model can predict 

a response, and the closer it is to 1, the stronger the correlation between experimental and 

predicted values are. A ratio larger than 4 is preferred when measuring the signal to noise 

ratio with adequate precision. With a ratio of 10.975, it is clear that there are sufficient 

signals and models to help one move about the design space. Lack of fit > 0.05 is 

insignificant, and because the lack of fit test reflects how well the model fits the 

experimental data, this model could be used to make predictions. 

 The final equation terms of coded factors are: 

Oil biodegradation = +44.9 -1.55 * A -12.35 * B – 1.00 * C +0.2 * A * B – 3.15 * A * 

C -4.25 * B * C  (1) 

The equation can be used to make predictions about the outcomes, for given amounts 

of each of the factors. It can also be used to ascertain the relative influence of factors by 

comparing the factor coefficient. 

Table 4: ANOVA of oil biodegradation 

source Sum of 

squares 

Df Mean 

square 

F-value p-value 

Prob >F 

 

Model 1471.6 6 245.2667 11.839 0.034 significant 

A-pH 19.22 1 19.22 0.928 0.407  

B-Oil conc. 1220.18 1 1220.18 58.896 0.005  

C-Inoculum conc. 8 1 8 0.386 0.578  

AB 0.32 1 0.32 0.015 0.909  

AC 79.38 1 79.38 3.832 0.145  

BC 144.5 1 144.5 6.975 0.078  

Pure Error 8.0726 2 4.0363    

Lack of Fit 54.08 1 54.08 13.398 0.067 not significant 

 

Figure 3 shows the predicted versus actual plot values. The data points are evenly 

distributed across the 45° line, indicating agreement between the actual data and that 

produced by the model. 

 

Fig. 3: Predicted versus actual plot of oil biodegradation percentage. 

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Fig. 4: 3D response surface showing the effects of (a) pH and oil concentration (b) pH and 

inoculum concentration and (c) oil concentration and inoculum concentration on oil degradation. 

The 3D response surface plots are a graphical approach to expressing the regression 

equation. They illustrate how the variables interact and are used to identify the optimal value 

of each factor for a suitable response. The plots for the interactions between pH and oil 

concentration (A-B), pH and inoculum concentration (A-C), and oil concentration and 

inoculum concentration (A-C) are shown in Fig. 4 a, b, and c, respectively (B-C). 

Figure 4a shows a decrease in oil biodegradation with an increase in oil concentration 

while pH did not show any effect. Figure 4b depicts the interaction between pH and 

inoculum concentration. Increased pH resulted in a slight increase in oil biodegradation, 

whereas increased inoculum concentration resulted in an increase in oil biodegradation at 

lower pH. In Fig. 4c, the interaction between oil concentration and inoculum concentration 

shows that oil degradation is highest when the oil concentration is lowest, and the inoculum 

concentration is highest. This is consistent with what is stated by [21]. Increased bacterial 

enzyme accessibility to substrate will result in improvement of the hydrolysis reaction rate. 

(a) 

(b) 

(c) 

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This study revealed that while microbial concentration does not have significant effect as a 

single factor (Table 4) its interaction with oil concentration has a significant effect on the 

amount of degraded oil. Microbial concentration is important as it provides more bacterial 

cells and thus more enzyme secretion to degrade the oil and therefore increase the rate of 

degradation [22]. 

By applying the 2-Level Factorial Design of Oil degradation, a maximum oil 

degradation was obtained at a pH of 6, oil conc. 1% (v/v), and 10% (v/v) of bacterial 

inoculum. 

4. CONCLUSIONS 

Seven microorganisms isolated from POME were studied for the degradation of FOG. 

Micrococcus lylae strain DSM 20315 was identified as the largest growing microorganism 

through morphological tests and 16S rRNA sequence analysis. This strain was used to 

optimize the degradation process. The optimum condition that achieved the highest 

biodegradation was at pH 6, oil concentration 1% (v/v), and 10 % (v/v). The results revealed 

that microorganisms isolated from POME are capable of biodegrading FOG, which could 

be attributed to the two wastes' similar properties. 

ACKNOWLEDGMENT 

This study was partially funded by the International Foundation for Science (IFS), 

Stockholm, Sweden and thankful to the Department of Chemical Engineering and 

Sustainability at International Islamic University Malaysia. 

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