Nepal Journal of Biotechnology. D e c .  2 0 1 5  Vol. 3, No. 1:6-9    ISSN 2091-1130 (Print) / ISSN 2467-9319 (online) 

 
ORIGINAL RESEARCH ARTICLE 

©NJB, Biotechnology Society of Nepal   6        Nepjol.info/index.php/njb 

Detection and Quantitation of Aflatoxin f or the Diagnosis of 

Aspergillus flavus  
Geeta Rajbhandari Shrestha1* and Amin Udhin Mridha2  

1Amrit Campus, Tribhuvan University, Kathmandu, Nepal. 
2University of Chittagong, Chittagong, Bangladesh 

Abstract 
Aflatoxins are the potent mycotoxins produced by Aspergillus flavus, which is hepatotoxic causing 
hepatocellular carcinoma. A. flavus produces sufficient amount of Aflatoxin B1 under favourable 
environments.   Inhalation of spores and use of Aflatoxin B1, contaminated food by Aspergillus spp., 
could transfuse the toxins in the blood streams. The presence of these toxins in body fluid can be 
detected by immunological assays and which provides an effective technique for the diagnosis of the 
disease caused by A. flavus. Aflatoxins producing strain of A.  flavus were screened in Aflatoxin 
Producing Medium. Production of Aflatoxin B1 by A. flavus was studied in different parameters such 
as incubation periods, temperatures, pH variations, sucrose concentration in Yeast Extract Sucrose 
medium and different natural media such as par-boiled rice, corn and groundnuts. The detection of 
toxins was done by TLC using silica gel (Merk) coated plates and confirmative test was done by 
Association of Official Analytical Chemists (AOAC) method. Presence and quantization was done by 
Enzyme Linked Immunosorbent Assay (ELISA) technique. Highest amount of Aflatoxin B1 was 
reported 68.56 ng/ml by ELISA in synthetic medium (Yeast Extract Sucrose) with 2% sucrose, pH 5.5, 
on 14th days of incubation, at 28±10C (p-value 0.05). Similarly, highest amount was recorded in 
groundnuts (121.20ng/g) by ELISA and (500ng/kg) by TLC methods.  ELISA is one of the most 
efficient methods used for detection and diagnosis of human diseases cause due to exposure of 
Aflatoxin B1 and A. flavus.  

Key words: Aflatoxin, Aspergillus flavus, ELISA, AOAC, TLC 

*Correspondence Author:  

Email: ga.gi.cha@hotmail.com 

 

Introduction   
Mycotoxins are secondary metabolites produce by 

different fungi under certain environmental 

conditions.   Mycotoxins cause acute kidney failure 

(ochratoxin), damage of central nervous system 

(tremogenic mycotoxin) and damage the upper 

respiratory tract. Aflatoxins are the most potent and 

naturally occurring mycotoxins produce by 

Aspergillus flavus and A. parasiticus. Many factors 

affect the growth of fungi and contamination 

aflatoxins on foods and feeds. Different factors 

affecting Aflatoxins contamination include the 

climate of the region, the genotype of the crop 

planted, soil type, minimum and maximum daily 

temperatures, and daily net evaporation. 

Contamination of toxins can occur at any time of 

growth of plant, pre and post harvesting periods and 

storage conditions [1]. 

 It was found that high doses (>6000mg) exposure of 

aflatoxins may cause acute toxicity with lethal effect 

and prolonged exposure to small doses is 

carcinogenic [2]. Mainly Aflatoxin B1 (AftB1) is the 

potent carcinogenic toxins to some animals and 

humans [3], which is one of the leading cause of 

cancer deaths worldwide [4]. When animals are 

exposed to through the contaminated feeds, the toxin 

is converted into aflatoxinM1 and contaminate in their 

milk. It is one of the sources of contamination 

aflatoxins of dairy products [5]. The exposure of 

aflatoxins causes many diseases such as 

hepatocellular carcinoma (HCC), impaired growth, 

immune suppression etc. Exposure of aflatoxins and 

the risks of toxic doses are more prevalent in the poor 

nations worldwide in both urban–rural areas, 

however more strongly in the rural populations [6].  

These diseases are more common in most of the 

developing countries. It was estimated that 550,000–

600,000 new HCC cases worldwide each year, of 

which about 25,200–155,000 were due to aflatoxins 

exposure. Most of the people from developing 

countries such as sub-Saharan Africa, Southeast Asia, 

and China including Nepal are suffering from HCC. 

Their prevalence accounted largely due to aflatoxins 

contamination in food [7]. It is essential to control 

contamination of food and feeds for minimization of 

outbreak due to aflatoxins. The presence of AftB1 

biomarker reflects the formation of the reactive 

metabolite and the level of DNA damage in the 

livers. Enzyme Linked Immunosorbent Assay 

(ELISA) is one of the diagnostic test, depends upon 



Nepal Journal of Biotechnology. D e c .  2 0 1 5  Vol. 3, No. 1:6-9                Shrestha and Mridha 

  

 

 

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protein content, is used to determine aflatoxins 

qualitatively and quantitatively in the samples [8]. 

ELISA and a monoclonal antibody against AFB1, 

AFB1 bound to albumin can be used to detect 

aflatoxins in urine and blood samples. The presence 

of aflatoxins residues adducts, and metabolites are 

assayed directly in tissues, fluids and excreta [9] and 

analyzed. The method is easy and inexpensive that 

developed with the necessary reliability, accuracy, 

and sensitivity to bring immunoassay technology. 

Materials and Methods 
Aspergillus flavus was isolated from the atmosphere of 

Kathmandu by gravity plate method. Lyophilized 

Aflatoxins producing strains of A. flavus was obtained 

from United States Department of Agriculture and 

used as the reference to compare the Aflatoxin B1 

production with that isolated from air. Aflatoxins 

standard was purchased from Sigma Co. The 

different strains of A. flavus producing aflatoxins 

were screened on Aflatoxin Producing Medium 

(APM) as described by Donald et al. (1981) [10]. 

Extraction of Aflatoxin B1 was carried out as the 

method described by Abarca et al, (1988) and Chu 

(1987) [11, 12]. Detection of Aflatoxin B1 was done by 

Thin Layer Chromatography (TLC) as the method 

described by using pre-coated silica gel plates 

(Merck) [13]. The confirmation test was done by 

Association of Official Analytical Chemists (AOAC) 

method [14]. Quantization of AftB1 in different 

samples were carried out by ELISA in various 

parameters such as incubation periods (7th, 9th, 11th, 

13th, and 15th, days), pH variations (4.5, 5.5 and 6.5), 

temperatures (240, 280 and 320C), and concentrations 

of sucrose (1.5%, 2% and 2.5%) in Yeast Extract 

Sucrose medium (YES) and different media like; 

Synthetic Low Salt medium (SLS), Coconut medium 

(CM),  natural media such as par-boiled rice, corn 

and groundnut described by Davis et al.1966 [15]. For 

the study of production of Aflatoxin B1, three replicas 

were maintained in each parameter. The 

experimental results from this study were analyzed 

by SPSS 16.0 [10, 12]. 

Results  
The highest amounts of AftB1 (68.56 ng/ml) was 

recorded in YES medium with 5.5 pH, 2% sucrose 

and  after 14 days of incubation at 28 ±1°C (Figure 

1A). The various temperatures have significant effect 

on the production of AftB1 (Figure 2B). However, 

sucrose concentrations different and pH have no 

significant the effect, since p-values are more than 

0.050 (Figure 2A and Figure 2B).  

 
Figure 1: Effect of A. Incubation periods B. Temperature on 

production of Aflatoxin B1 

 
Figure 2: Effect of A. Sucrose concentration and B. pH in YES 

medium on the production of Aflatoxin B1 

Spearman's rho test showed that there is no 

significant linear relation between two variables- 

incubation period (time in days) and production of 

AftB1 (ng/mL) as the p-value is more than 5% level of 

significance (Table 1).  

Table 1: Analysis of Aflatoxin B1 produced by A.flavus; 

TLC and ELISA method in various incubation periods. 

Note: ++ denotes for intensity of fluorescence 

Kruskal-Wallis test showed that there is no 

significant effect of a particular medium on the 

production of AftB1 (the p-value of 0.998 is more than 

5% level of significance). Moreover, each of six 

medium has equal effect on it. However, the highest 

No. Incubation periods* 

Aflatoxin B1 

TLC ELISA ng/ml 

1 7 + 2.6 

2 9 ++ 6.46 

3 11 +++ 24.76 

4 13 +++ 68.56 

5 15 +++ 58.8 



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level (121.20ng/g) of alfatoxin B1 was obtained in 

natural medium; groundnuts.  

 
 Note: YES = Yeast extract medium, SLS= Synthetic low salt 
medium, CM= Coconut medium 

Figure 3: Effect of different media on the production of 

Aflatoxin B1.in different incubation periods at 28 ±1°C. 

Discussion  
Aflatoxins produced by food borne Aspergillus flavus 

and A. parasiticus cause several human diseases such 

as Hepatocellular carcinoma (HCC), or liver cancer. 

Contamination of Aflatoxins can occur at any stage of 

food production from pre-harvest to storage [16]. Its 

contamination is determined by the most commonly 

used method; thin layer chromatography (TLC).   The 

thin layer chromatography method was used for 

screening and quantification. Aflatoxins production is 

low during early stages of growth that increases with 

the decline of growth and the maximum production 

was recorded after the stationary phase of growth, 

which soon decline in its production (Table 1 and 

Figure 1). Similarly, West et al. (1973) reported that 

the aflatoxin level falls after reaching a maximum, 

which might be due to non-specific chemical 

mechanism for degradation of the toxin [17]. Smith 

and Moss (1985) also reported that very low 

aflatoxins was produced during the phase of 

vigorous growth in a laboratory and when some 

nutritional factor runs out and limits growth toxins 

biosynthesis occurs rapidly [18]. Factors that affect 

aflatoxins contamination include the climate of the 

region, the genotype of the crop planted, soil type, 

minimum and maximum daily temperatures, and 

daily net evaporation. Wilson and Payne (1994) and 

Fandohan et al. (2005) reported that many factors 

affect the growth of Aspergillus fungi and the level of 

aflatoxins production in food [16, 19]. It is essential to 

reduce Aflatoxins contamination of food by 

providing unsuitable condition to produce toxins. 

AftB1 production is also promoted by stress or 

damage to the crop due to drought prior to harvest, 

insect activity, poor timing of harvest, heavy rains at 

harvest and post-harvest, and inadequate drying of 

the crop before storage [20]. Humidity, temperature, 

and aeration during drying and storage are also 

important factors for aflatoxins contamination.   

The most effective method of detection and 

quantification of aflatoxins contamination in foods 

and feeds is ELISA by which a very low amount of it 

can be detected [12]. In this study the highest 

amounts of AftB1 (68.56 ng/mL) was recorded in YES 

medium with 5.5 pH, 2% sucrose and  after 14 days of 

incubation at 28 ±1°C. The study on the effect of 

different parameters on Aflatoxin B1 production 

showed that temperature has significant effect (P= 

0.050). However, different pH and sucrose 

concentrations have no significant effect, since P= > 

0.050. This method can be employed for the detection 

and quantification of aflatoxins exposure of human 

and causes of hepatocellular carcinoma due to 

Aspergillus flavus from Urine, blood samples. 

Groopman et al (1994) showed that aflatoxin 

metabolites in urine reflect recent exposure (i.e. 2-3 

days) whereas the measurement of aflatoxins 

albumin adducts in blood reflects exposure over a 

longer period (i.e. 2-3 months) [21]. Qian et al (1994) 

studies showed correlation of aflatoxins intakes to 

biomarker levels and to disease [22].   

Conclusions 
The spores of A. flavus under the favourable 

environmental conditions produce sufficient amount 

of AftB1 that effect on human health. AftB1 had been 

detected and quantified by TLC and ELISA. Aflatoxin 

B1 could use as a marker for the diagnosis of various 

diseases caused by Aspergillus species, especially A. 

flavus. More research is needed to determine 

aflatoxins levels in biological specimens that are 

associated with adverse health effects.  

Acknowledgement 
We are highly obliged to UNESCO for providing 

fellowship to execute the work in China and very 

much thankful to Prof. Dr. Zhang Yizeng, the Head 

of the Department of Molecular Biology, Sichuwan 

University, Prof. Dr. Guangian Wang, Dept. of 

Sanitary Technology, School of Public Health, West 

China University of Medical Science, Chengdu, 

China. We are grateful to Dr. Peterson SW, 

Microbiologist, United States Department of 

Agriculture, Midwest Area, and National Center for 

Agriculture Utilization Research for providing 

lyophilized aflatoxins producing strains of A. flavus.  

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