Evaluation of fungi and mycotoxins of smoked fish with special reference to some Aspergillus species.

Document Type : Original researches

Abstract

           
A total of 100 samples of smoked herring fish, 50 samples of whole fish, and 50 fillets were collected from different shops in Menofea Governorate. The samples were examined mycologically for counting, isolation, and identification of mould. The mean averages of total mould count were 3.5 x105 ± 1.14 x 103cfu/g and 3.8 x104 ± 0.62 x102 cfu/g for whole fish and fillets respectively. The predominant isolated strain is Aspergillus species particularly A. flavus, A. niger, A. fumigatus and A. ochraceus with a total percentage of 74%. The concentration values of Aflatoxins B1, B2, and Ochratoxin A ranged between 0.096 ppb -7.938 ppb, 0.075 ppb - 3.509 ppb, and 0.062 ppb – 1.219 ppb respectively. All samples are free from Aflatoxins G1 or G2. This study draws attention to the preparation and production of smoked herring fish to avoid possible health hazards from the Mycotoxins.

Keywords

Main Subjects

Full Text

Evaluation of fungi and mycotoxins of smoked fish with special reference to some Aspergillus species.

*Flourage M. Rady, **Elsayed M. Abd- Elaaty and Eman M. Younis***

 

*Department of Mycology, **Department of Food Hygiene, Animal Health Research Institute, Shebin El koom Branch, Agriculture Research Center  (ARC), Egypt.

***Department of Biochemistry, Animal Health Research Institute, Agriculture

Research Center  (ARC), Egypt.

ABSTRACT

A total of 100 samples of smoked herring fish, 50 samples of whole fish, and 50 fillets were collected from different shops in Menofea Governorate. The samples were examined mycologically for counting, isolation, and identification of mould. The mean averages of total mould count were 3.5 x105 ± 1.14 x 103cfu/g and 3.8 x104 ± 0.62 x102 cfu/g for whole fish and fillets respectively. The predominant isolated strain is Aspergillus species particularly A. flavus, A. niger, A. fumigatus and A. ochraceus with a total percentage of 74%. The concentration values of Aflatoxins B1, B2, and Ochratoxin A ranged between 0.096 ppb -7.938 ppb, 0.075 ppb - 3.509 ppb, and 0.062 ppb – 1.219 ppb respectively. All samples are free from Aflatoxins G1 or G2. This study draws attention to the preparation and production of smoked herring fish to avoid possible health hazards from the Mycotoxins.

 

INTRODUCTION:

Fish is a major source of protein, particularly in Egypt. It is also an important source of vitamins, iodine and unsaturated fatty acids (Abolagba and Melle 2008). Fish is more susceptible to contamination, so it must go through some sort of processing or preservation. Otherwise, it will become unfit for ingestion by humans, and even after being treated, the fish may continue to be spoiled, especially if traditional procedures were applied (Oparaku   and Mgbenka 2012, Shewan 2000). The technique of preserving food like fish involves several processes that prevent the growth of microorganisms such as the addition of growth-inhibiting substances or customized storage conditions by freezing or drying (Akise et al. 2013). For thousands of years, smoking has been applied to prepare and preserve food (Krasemann, 2004). Bad hygiene, insufficient cleaning, or preservation in open trays allow the fungal invasion, production of toxins, and spoilage of the product (Hassan et al. 2009 and Fredrick et al. 2016). During storage, the growth of fungi such as Aspergillus, Rhizopus and Penicillium species was enhanced (Ayolabi and Fagade 2010). According to (Ayeloja et al. 2018), Aspergillus flavus, Fusarium oxysporum, Ceotrichium albidium, Rhizopus species, Penicillium species, and Trichoderma species were isolated from Nigerian smoked fish. Also, (Daramola et al. 2023) examined smoked fish samples mycologically revealed seven types of fungi namely, Aspergillus flavus, Aspergillus niger, Aspergillus fumigatus, Rhizopus species, Alternaria, Candida species, Mucor species.

 

In seafood, some fungal species are capable of producing mycotoxins as aflatoxins (AFs), Fusarium mycotoxins, and ochratoxins (OTs) (Nourbakhsh and Tajbakhsh 2021and Shamimuzzaman et al. 2022). Mycotoxins are stable based on their chemical structures, and it is difficult to remove them from the food chain (Huang et al. 2011). The International Agency for Research on Cancer (IARC) has designated aflatoxins as a class 1 human carcinogen because they are the most potent metabolite and because they are also extremely hepatotoxic, mutagenic, and genotoxic (IARC. 2012). To ensure food safety, it is necessary to evaluate and quantify the metabolites in staple and vital food products given the harmful effects of aflatoxins on the human body, and also need to educate both the traders and the consumers on the risks involved in the consumption of such contaminated products.

 

MATERIAL AND METHODS:

  1. Collection of samples:

 Samples of smoked herring fish (n = 50), and smoked herring fillets (n = 50) were purchased from markets in the Menoufia governorate.

 

  1. Preparation of the samples (AOAC, 2000):

The muscle of the smoked fish was thoroughly mixed and ground to obtain a uniform mass. The analysis was carried out as soon as possible or chilling the sample in the refrigerator to avoid decomposition.

 

 

  1. Isolation of mould:

       Ten grams (10g) of each sample was aseptically weighed into a sterile bottle containing 90 ml of sterile peptone water. The mixture was shaken vigorously using vortex mixer, and 5-fold serial dilutions were prepared (Samson et al. 2010). One milliliter of each dilution was dispensed in duplicate in sterile Petri dishes. Molten Saboraud dextrose agar to wincorporated and phenicol (0.5g/l) had been incorporated was added to the Petri dishes, which were gently rotated, the plates were allowed to solidify and were incubated at 25C° for 3-7 days.

The cultures were examined for growth at regular intervals and all observed colonies were subculture to obtain pure colonies, which were subsequently isolated and identified using morphological characteristics (Alkenz et al. 2015), macroscopy and microscopy (Ellis et al. 2007and Samson et al. 2010).

 

  1. Aflatoxins and Ochratoxin A1 determination:

4.1. Apparatus and Equipment:

High-performance liquid chromatography (HPLC) used for aflatoxin determination was an Agilent 1100 HPLC system, Agilen Technologies, Waldbronn, Germany, equipped with quaternary pump model G 1311A, UV detector (Model G 1314A) set at 254nm wavelength. Also, auto sampler (model G1329A VP-ODS) and Shim pack (150× 4.6 mm) column (Shimadzu, Kyoto, Japan) were used. The Chemstation Software program was used to integrate and record the data. Liquid nitrogen and ultra-high purity (99%) argon gas were adopted. The present study used Easi-Extract Aflatoxin immunoaffinity columns.

 

4.2. Standard Aflatoxins B1 (AFB1), B2 (AFB2), G1 (AFG1), G2 (AFG2) and Ochratoxin A (OCA) solutions:

 The stock standard solutions of AFB1, AFB2, AFG1, AFG2, and OCA were prepared by dissolving the solid standard in benzene: acetonitrile (98:2, v/v). According to AOAC (2000), the precise concentration was measured by using a Shimadzu UV-1601 PC spectrophotometer, Shimadzu Scientific Instruments, Japan. The stock solution was prepared by using an intermediate standard solution in benzene: acetonitrile (98: 2, v/v) at a concentration of 9.855 ng ml. This solution was used to elaborate a calibration curve in the concentration range of 0.1 –9.8 ng/ml. All the solutions were stored at -18°C in amber vials.

 

4.3. Quantitative determination of aflatoxins (European Council 2006):

4.3.1. Sample extraction: 

 In a blender, 50 g of the prepared homogenized sample was mixed with 100 ml of acetone and 100 ml of water for 10 min, 10 g of diatomaceous earth was added and carefully mixed for 5 min then filtered by using Whatman No. 1 filter paper. To prepare the mixture, 0.01 ml of the filtrate was added to a 500 ml wide mouth glass stoppered Erlenmeyer volumetric flask. Then, 50 ml of 5% NaCl and 50 ml of hexane were added to the flask. The flask was gently shaken for five minutes at a speed of 2400 rpm on a mechanical shaker (IKA, GmbH, Germany). The hexane layer was discarded. After adding 50 ml of 5% NaCl and 150 ml of chloroform (3x50 ml) to the aqueous layer shake gently for 5 min each time. The chloroform layer was collected from the three extractions, dried over anhydrous sodium sulphate, and evaporated using a rotary evaporator. The residues were re-dissolved in 1 ml chloroform.

 

4.3.2. Clean-up procedure: 

 After adding 2 ml of 0.5% aqueous acetic acid to condition the column, the C18 column was loaded with 1 ml of the filtered extract and 4 ml of 0.5% acetic acid. Next, 0.5 ml of 20% Tetrahydrofuran (THF) in 0.5% aqueous acetic acid was used to wash the column. 2 ml of hexane was then added to the column tube, which was subsequently dried under nitrogen. After being cleaned with 3 ml of 25% THF in hexane, the column tube was dried for 1 minute in nitrogen. The retained aflatoxins were dried over a stream of nitrogen after being eluted with 2x2 mL from 1% THF in methylene chloride. The dried aflatoxins were reconstituted in 0.5 ml of toluene before the injection in HPLC.

 

4.3.3. HPLC determination: 

Each aflatoxin was determined with HPLC at wave length 365 and 440 nm for excitation and emission, respectively. The mobile phase was composed of toluene, ethyl acetate, formic acid, and methanol (90:5:2.5:2.5, v/v) which was pumped with constant flow at 1.0 ml min. 20 ul of the reconstituted sample were injected in the HPLC at 24°C to get the optimum resolution of aflatoxins. Several blanks (methanol only) and aflatoxin standard solutions were injected. The assessment of the given samples was done in triplicates and the sample was regarded as positive for aflatoxin, if its retention time and peak corresponded to that of the standard. Calculations to get the level of each aflatoxin in the examined samples were carried out automatically by Agilent Chem Station Software System.

 

4.4. Quantitative determination of ochratoxin A (Toscani et al. 2007):

4.4.1. Sample extraction: 

An aliquot of 10 g of the prepared sample and 100 ml of (chloroform: 85% orthophosphoric acid 100: 4, v/v) solution were mixed and homogenized in a blender for 2 min. After thoroughly filtering through Whatman No. 3 filter paper, sixty ml of the filtrate was transferred into a separating funnel and extracted twice with 5 ml of (buffer 0.2 M Tris-Hydrochloric acid: Acetonitrile 90:10, v/v). The upper aqueous layer was carefully gathered and well mixed.

 

4.4.2. Clean-up procedure: 

Accurately, 50 ml of the aliquot was passed through the Agilent ZORBAX C18 (3 μm, 2.1x250 mm) column for cleanup. The column was washed by water and dried by air. Ochratoxin A was eluted with 2 ml methanol with a vacuum manifold. The methanol was dried under gentile nitrogen stream and the residue was re-dissolved in the mobile phase (water: acetonitrile: glacial acetic acid 49.5: 49.5: 1.0) before the injection in HPLC.

 

4.4.3. HPLC determination: 

Ochratoxin A was assessed at wavelength 380 and 440 nm excitation and emission, respectively. The mobile phase was composed of water: acetonitrile: and glacial acetic acid 49.5: 49.5: 1.0, which was pumped with constant flow at 1 ml/ min. Typically, the same techniques and steps used for the determination of aflatoxins were applied to estimate ochratoxin A automatically by Agilent Chem Station Software System.

 

 

  1. Statistical analysis

The analysis of data for mould count in smoked herring fish and smoked herring fillet using student's t- test are significantly different at a confidence interval of 95% (p ≤ 0.05) and the result is expressed as mean ± SD.

 

References

Abdel-maksoud SA, El-Kuttan AA , Mohamed MEM. 2010. Mycological studies on smoked fish marketed in Dumyat with special reference to public health importance.10th Science Veterinary Medicine Conference (10-13 February 2010) Luxor.
Abdoullahi HO, Guira F, Abdelsalam T, Nikiéma FKE, Bazié BSR, Abakar IL, Savadogo A. 2019. Screening of mycotoxins producer fungal and aflatoxins level in dried and smoked fish (Clarias Sp.) and (Oreochromis Sp.) from LAKE FITRI – CHAD. Journal of Food Technology Research. 6 (1): 49-56.
Abolagba OJ, Melle OO. 2008. Chemical composition and keeping qualities of a scaly fish tilapia (oreochromisniloticus) smoked with two energy sources. African Journal of Genetic Agriculture, (4):113-117.
Adebayo-Tayo BC, Onilude AA, Patrick UG. 2008. Mycofloral of smoke-dried fishes sold in Uyo, Eastern Nigeria. World Journal of Agricultural Science, 4 (3): 346- 350.
Adesokan IA, Onifade DA, Bolarinwa OO, Awotoye JA. 2016. Investigation of fungal and aflatoxin contamination of smoked dried fish samples collected in Ibadan, Southwest Nigeria. Nigerian Journal of Microbiology, 30(1): 3263-3265.
Akinyemi AA, Adejola AQ, Qbasas O, Ezeri GNO. 2011. Aflatoxin in smoked dried fish sold in Abeokuta, Ogun State, South west Nigeria. Proceeding of the Environmental Management conference, Federal University of Agriculture, Abeokuta, Nigeria
Akise OG, Abolagba OJ, Eyong MM. 2013. Mycoflora of three fish species smoke-dried using rubber wood (Hevea brassillensis) in Nigeria. Greener Journal of Agricultural Science, 3 (5): 396-402.
Aliyu MA, Wartu JR, Hussaini MA. 2018. Fungal contamination of smoked-dried fish in Minna Nigeria. Bayero Journal of Medical Laboratory Science, 3(1): 199 – 206.
Al Jabir M, Barcaru A, Latiff A, Jaganjac M, Ramadan G, Horvatovich P. 2019. Dietary exposure of the Qatari population to food mycotoxins and reflections on the regulation limits. Toxicology Reports, (6):975–82.
Alkenz S, Sassi AA, Abugnah YS, Alryani MB. 2015. Isolation and identification of fungi associated with some Libyan foods. Africa Journal of Food Science. 9(7): 406-410.
Association of Official Analytical Chemists "AOAC".2000. Official Methods of the AOAC International Analysis.  13th Ed., Horwitz. W; (Editor), Academic Press, Washington D.C, USA.
Ayeloja A, George F, Jimoh W, Shittu M, Abdulsalami S. 2018. Microbial load on smoked fish commonly traded in Ibadan, +Oyo State, Nigeria. Journal of Applied Science of Environmental Management, 22(4): 493–497.
Ayolabi CI, Fagade EO. 2010. Mycological evaluation of smoked fish (Ethhmalosa fimbriata) from retail outlets in Ago-Iwoye, Ogunstate, Nigeria 3 (2): 64 -68.
Chinedu AAWilliams SARaphael AO. 2019. Fungal Contaminants of Smoke-Dried Fish Sold in Open Markets in Makurdi, Benue State, North-Central Nigeria. Food and Nutrition Sciences, 10(3):290-297.
Daramola JA, Kester CT, Adonkie DA. 2023. Antifungal potential of black Mangrove leave extracts on isolates of smoked bonga fish sampled from Oju-Ore and Iyana markets in Ota, Ogun State, Nigeria, Journal of Applied Science of Environmental Management, 27 (4) 703-708. 
Ellis D, Davis S, Alexiou H, Handke R, Bartley R. 2007. Description of medical Fungi. Mycology Unit, Women’s and Children’s Hospital, North Adelaide, USA.
Commission Regulation No. 401/2006 of 23 February 2006 laying down the methods of sampling and analysis for the official control of the levels of mycotoxins in foodstuffs. Official Journal of the European Union, L70: 12–34.
Fagbohun ED, Lawal OU. 2015. Aflatoxins investigation and mycobiota of selected marketed smoked-dried fish samples in Ado-Ekiti, Nigeria and their environmental health implications. Br. Microbiol. Research Journal, 7(3): 126-132.
Fatima OW, Olusola A, Oluwapelumi AO, Chibundu NE, Adeyinka OA, Grace OT. 2021. Incidence of mycotoxins in mouldy smoked dried fish and meat (kundi) marketed in Southwestern Nigeria. Fungal Territory, 4 (2): 9-11.
Fredrick SJ, Immaculate J, Patterson EJK. 2016. Aflatoxin investigation on dried fish of Tuticorin, South East Coast of India. Journal of Foodborne and Zoonotic Diseases 3(4): 49–62.
Hassan AA. 2003. Detection of some mycotoxins and mycotoxins producing fungi in both macro and micro- environmental of diseased animals. 7th Science Congress Egyptian Society for Cattle Diseases. Assiut, Egypt.: 112–119
Hassan AA, Wael MT, Abd El-Aziz AE, Howayda ME. 2009. The hepatoprotective effect of dimethyl 4,4- dimethoxy 5,6,5,6- dimethylenedioxy biphenyl- dicarbxylate (D.D.B.) against liver injury induced by aflatoxin B1 in rates, Egypt. Journal of Applied Science, 24 (9): 86-100.
Hassan EM Farag,  Azza A. El-TabiyHeba M. Hassan. 2011. Assessment of ochratoxin A and aflatoxin B1 levels in smoked fish with special reference to the moisture and sodium chloride content. Research Journal of Microbiology.6(12):813-825.
Huang Y, Han D, Zhu X, Yang Y, Jin J, Chen Y, Xie S. 2011. Response and recovery of gibel carp from subchronic oral administration of aflatoxin B1. Aquaculture 2011, (319):89–97.
Ibrahim-Hemmat M, Rasha A El Sabagh, Abou El-Roos-Nahla A, Abd El kareem-mohebat. 2017. Mycotic quality of locally manufactured smoked herring fish. Benha Veterinary Medical Journal, 32 (1), 113- 120.
Indra SS,  Elasto N. 2020.Prevalence of Aflatoxins in Smoked-Dried and Fresh Fish in Zambia. Journal of Environmental Protection.11 (1):13-21.
International Agency for Research on Cancer (IARC). 2012. Some traditional herbal medicines, some mycotoxins, naphthalene and styrene. IARC Monogr Eval Carcinog Risks Hum, 82: 171. PMID:12687954.
Isaac FFS, Ibourahema C, Athanase KK, Clément KK, Ibrahim K. 2023. Isolation and identification of fungal strains from fresh and smoked fish from the Sassandra River in Côte d’Ivoire. Biotechnology Journal International, 27(3): 1-7.
Job MO, Agina SE, Dapiya HS. 2016. Occurrence of Aflatoxigenic Fungi in Smoke-dried Fish Sold in Jos Metropolis. British Microbiology Research Journal, (11): 1-7.
John W, Buba B, Ayisa TT, Oke O, Ihum T, Ishaya M. 2020. Mycological examination of smoke-dried fish sold in Bida major markets. European Journal of Biology.5(1):28-40.
Junaid SA, Olarubofin F, Olabode AO. 2010. Mycotic contamination of stockfish sold in Jos, Nigeria. Journal of Yeast and Fungal Research, (1):136-141.
Khalifa EMI, Mazyad GI. 2009. Hygienic criteria of smoked herring fish marketed in KAFR EL- SHEIKH city. Kafrelsheikh, Veterinary Medical Journal,3rd Congress. 10-12 May 2009: 488-508.
Krasemann S. 2004. A History of smoke preservation < http :// www. 3men.com/history.htm.
Mounir MSB, Abd Al-Azeem MW, Hashim ESY. 2011. Mycological Aspect of Smoked Fish at Retail Outlet at the Delta Province of Egypt. Journal of Applied Environmental Biological Science, 1(1):26-31.
Nourbakhsh F, Tajbakhsh E. 2021. Neurotoxicity mechanism of Ochratoxin A. Qual. Assur. Saf. Crops Foods, 13(2):34–45.
Olayemi FF, Raji AO, Adedayo MR. 2012. Microbiological quality of catfish (Clarias gariepinus) smoked with Nigerian Stored Products Research Institute (NSPRI) developedsmokingkiln. International Research Journal of Microbiology.3(13):426-430.
Oparaku NF, Mgbenka BO. 2012. Effects of electric oven and solar dryer on a proximat and water activity of Clarias gariepinus Fish. European Journal of Scientific Research, 81 (1):139-144.
Saad MS, Hassan MA, Hassanien FS, Awud AA. 2020. Mycotoxin residues in some fish products. Benha Veterinary Medical Journal 39 (2020): 175-179.
Samson R, Houbraken J, Thrane U, Frisvad JC, Andersen B. 2010. Food and Indoor Fungi. CBS-KNAW Fungal Biodiversity Centre, Utrecht, The Netherlands.
Shamimuzzaman M, Roy RK, Majumder TR, Barman, NC, Lina NN, Hasan MT, Dash BK. 2022. Microbial profile of some ready-to-cook frozen food items sold in Dhaka city, Bangladesh. Food Sci. Hum. Wellness, 11, (2):289–296.
Shewan JM. 2000. The Microbiology of sea water fish. In fish as food. Ed by B. Borgstrom, I New York Academic Press.:487.
Toscani T, Moseriti A, Dossena A, Dallasta C, Semoncini N, Virgili R. 2007. Determination of ochratoxin A in dry-cured meat products. Journal Chromatography (855): 242-248.
 

Files

Share

How to cite

Statistics