Submit Manuscript

International Journal of Pharmacology

Year: 2019 | Volume: 15 | Issue: 2 | Page No.: 177-188
Facebook Twitter Digg Reddit Linkedin StumbleUpon E-mail

ABSTRACT

Background and Objective: Aflatoxin B1 (AFB1), a pre-carcinogenic and toxic compound which contaminates foodstuffs and edible tissues, is associated with oxidative stress and hepatotoxicity. This investigation aimed to assess the counteractive role of ethanol (EWP), petroleum ether (PWP) and n-hexane (HWP) white pepper extracts for oxidative stress and hepatotoxicity induced by AFB1 in a rat model. Materials and Methods: Concentrated white pepper extracts (WPEs) estimated for total phenolic, total flavonoids, anti-oxidant and anti-fungal activities. Otherwise, the fatty acids composition of white pepper was analyzed. Forty-eight male albino rats were divided into 8 groups, negative and positive AFB1 groups and the other 6 groups were treated to evaluate the WPEs biological effects either in the AFB1 presence or absence. Results: The results elucidated that WPEs suppressed both the raising of aminotransferases enzymes (alanine and aspartate) and alkaline phosphatase and the reduction of total protein. The WPEs combat the negative impact of AFB1 on kidney functions and alleviated AFB1 mediated oxidative stress either in plasma or liver. Also, it relieved the AFB1 mediated lipid disturbance and hemoglobin reduction and exhibited antioxidant and antifungal activities. Conclusion: It was concluded that the extracts gave a counteractive role for oxidative stress which support the hepatotoxicity induced by AFB1 presence.
PDF Abstract XML References Citation
Received: October 25, 2018;   Accepted: November 28, 2018;   Published: February 22, 2019
Copyright: © 2019. This is an open access article distributed under the terms of the creative commons attribution License, which permits unrestricted use, distribution and reproduction in any medium, provided the original author and source are credited.

INTRODUCTION

Aflatoxins, the secondary metabolites of fungi produced by Aspergillus flavus and A. parasiticus, are considered dangerous and toxic compounds (especially AFB1) which contaminate foodstuffs1. Since cereals and food grains included in most human diets are susceptible for the aflatoxins contamination2,3. Aflatoxins are not only carcinogenic and teratogenic substances4, but also it associated with several health problems such as growth retardation, hematologic disorders, hepato and nephrotoxicity and immunosuppression5-8. The metabolism of AFB1 in the liver results in reactive oxygen species (ROS) production including superoxide anion, hydroxyl radical and hydrogen peroxide (H2O2) by cytochrome P450. The soluble cell compounds and membranes can be attacked by these reactive oxygen species which results in the impairment of cell functions and cytolysis9.

Various phytochemicals compounds are reported to detoxifying aflatoxins10. White pepper (Piper nigrum family Piperaceae) is the sun-dried stony seeds of ripen pepper fruits, it was reported as rich in several phytochemicals compounds11. It is utilized as a common spice in food preparation. Otherwise, it was included in several traditional medicine recipes particularly in China and Southeast Asia countries12. Several health benefits for white pepper are demonstrated among its anti-oxidant, anti-inflammation, anti-atherogenic as well as anti-platelet aggregation activities13,14. Piperine, as a phytochemical component, reported inhibiting aflatoxin production by toxigenic fungi15. Also a modern study reported the piperine genetic impact on aflatoxigenic fungi strains which leads to suppress aflatoxin production16. According to extraction type, piperine reported higher in the non-polar extraction17. Despite the microbial load and mycotoxin contamination on pepper fruits (black or white) were dealt with it in previous studies, while aflatoxin reduction by different WPEs types, also the oxidative stress of toxigenic fungi-producing strains in the presence of WPEs has not been evaluated.

The current research was designed to innovate a novel utilization of WPEs against the hazard biological effects occurred by AFB1 and to evaluate the counteractive role of WPEs against the oxidative stress and hepatotoxicity induced by AFB1 in biological systems. Otherwise, the changes in biochemical parameters and tissue enzymes system conjugated to utilize WPEs were also estimated to validate the safety application of WPEs in food products.

MATERIALS AND METHODS

The current study was carried out in the National Research Centre, Cairo, Egypt from January-June, 2018.

Materials
Plant materials: White pepper was purchased from the local market, sun-dried then ground using an electric grinder and directly extracted.

Animals: Male albino rats of 125.27±7.52 g as (Mean±SD) were obtained from the animal house of the National Research Centre, Cairo, Egypt. Animals were kept individually in stainless steel cages at room temperature. Water and food had been given ad-libitum.

Diets: Balanced diet was prepared to contain 10% protein supplemented from casein, 10% corn oil, 10% sucrose, 60.5% maize starch, 5% fiber, 3.5% salt mixture and 1% vitamin mixture provided by the AIN-93 formulation18. The oil soluble vitamins had given weekly to rats separately from the diet.

METHODS


Extracts preparation: The EWP, PWP and HWP extracts were prepared using ethanol, petroleum ether 40/60 and n-hexane, respectively. The solvent was added to extract the fine powder (4:1 w/v). The mixture was stirred using an overhead ultrasonic probe (30°C/45 min), filtered through Whatman No. 4 filter paper for separating the extract. The filtrate was concentrated to 25% (v/v) at 40°C using a rotary evaporator system. Nitrogen gas was utilized to complete solvent removing then stored at -20°C until further analysis and applications.

Determination of total phenolic and total flavonoid contents of WPEs: Total phenolic contents (TPC) and total flavonoid contents (TFC) were determined according to Singleton et al.19 and Chang et al.20, respectively. The TPC was expressed as mg Gallic acid equivalents (GAE) per g extract while the TFC were expressed as mg quercetin equivalent (QE) per g extract.

DPPH radical scavenging activities of WPEs: The free radical scavenging activity was measured by spectrophotometer using the DPPH method as described by Teke et al.21.

ABTS cation decolonization assay of WPEs: The ability to scavenge free ABTS radicals was applied based on the protocol declared by Re et al.22. Results were expressed as μmol trolox equivalents (TE)/g sample.

Ferric reducing ability (FRAP) assay of WPEs: The FRAP assay was performed according to Hwang and Thi23. The results were expressed as μmol trolox equivalent (TE)/g sample.

Fatty acid composition evaluation: Fatty acid methyl esters of HWP extract were prepared according to AOAC24 to be subjected to GLC analysis of fatty acids. Identification of the fatty acid methyl ester was carried out by direct comparison of retention times of each of the separated compounds with authentic standards and the results were reported as weight percentages after integration and calculation using Chem. Station (Agilent Technologies).

White pepper extracts effect on fungal growth: Yeast extract sucrose (YES) was utilized to evaluate fungal growth inhibition25. The inhibition was represented as a loss in dry weight of fungal growth in the presence of extracts against the control.

Agar diffusion test: Disk diffusion was evaluated according to the method described by Badr et al.25. The inhibition effect was determined as a ratio of the calculated as the equation follows:

Image for - Counteractive Role of White Pepper Extracts for Oxidative Stress and Hepatotoxicity Induced by Aflatoxin B1 in Rats


Where:
Ac = Fungal diameter growth in control plate
At = Fungal diameter growth in treatment plate

Wells diffusion test: Well diffusion was evaluated according to the method described by Badr et al.25. Each well in a plate media was loaded by 250 μL of WPEs, one plate used for one fungus and one extract type, the plates were incubated at 25°C/5 days. The inhibition zone was determined as a ratio of decreasing in fungal growth compared to the control.

Determination of minimal fungicidal concentration of white pepper: The inhibition was used to determine the anti-fungal activity of the extracts against fungi as previously described by Shehata et al.26. The concentration required to give 50% inhibition of growth IC50 was calculated from the regression equation. Nystatin was used as a positive control.

Preparation of standards for aflatoxin: The dry-film standard of aflatoxin was applied to prepare a calculated concentration as ng mL1 using a volume of methanol: acetonitrile (9:1).

Preparation of dosage form: White pepper extracts were dispersed separately in phosphate buffer saline (pH = 7.2) to be given orally to rats.

Design of the animal study: Forty-eight rats were used in the present study. After one week of acclimation, rats were divided into 8 groups (n = 6) as follows:

Group 1 (G1) : Normal healthy group (Normal control)
Group 2 (G2) : Rats were treated orally with AFB1
Group 3 (G3) : Rats were treated orally with AFB1 and ethanol extract of white pepper (AFB1+EWP)
Group 4 (G4) : Rats were treated orally with ethanol extract of white pepper (EWP)
Group 5 (G5) : Rats were treated orally with AFB1 and petroleum ether extract of white pepper (AFB1+PWP)
Group 6 (G6) : Rats were treated orally with petroleum ether extract of white pepper (PWP)
Group 7 (G7) : Rats were treated orally with AFB1 and n-hexane extract of white pepper (AFB1+HWP)
Group 8 (G8) : Rats were treated orally with n-hexane extract of white pepper (HWP)

The daily oral dose of aflatoxin B1 adjusted at 850 ng kg1 b.wt./day. Moreover, the daily oral dose of each extract of white pepper was 250 mg kg1 b.wt./day. All rats were fed on a balanced diet all over the study period (4 weeks). During the experiment, body weight and food intake recorded weekly. However, the total food intake, body weight gain and food efficiency ratio calculated at the end of the experiment. Blood samples were collected from all rats after an overnight fast. A portion of the whole blood was analyzed for hemoglobin (Hb) concentration27. The remaining blood was centrifuged and the plasma was analyzed for plasma levels of total proteinusing the method of Rheinhold28, the activities of aspartate transaminase (AST) and alanine transaminase (ALT) according to Reitman and Frankel29 and alkaline phosphatase (ALP) according to Bessey et al.30. The levels of creatinine, urea, blood urea nitrogen (BUN), albumin and uric acid were determined depending on Larsen31, Fawcett and Scott32, Christian et al.33, Doumas et al.34 and Watts35 in succession as indicators of kidneys function. Total cholesterol, high-density lipoprotein cholesterol (HDL-C), low-density lipoprotein cholesterol (LDL-C) and triglycerides were determined according to Watson36, Burstein et al.37, Schriewer et al.38 and Megraw et al.39 in succession. Cholesterol/HDL-C ratio and VLDL-C were calculated. Plasma total anti-oxidant capacity was determined according to Koracevic et al.40. Plasma and liver malondialdehyde (MDA) was determined according to Ohkawa et al.41. Liver catalase, glutathione-s-transferase (GST) and superoxide dismutase (SOD) activities were determined according to Beers and Sizer42, Habig et al.43 and Nishikimi et al.44 in succession. Rats were dissected and liver, kidney were immediately separated from each rat and weighed. This study has been carried out according to the Ethics Committee, National Research Centre, Cairo, Egypt and followed the recommendations of the National Institutes of Health Guide for Care and Use of Laboratory Animals (Publication No. 85-23, revised 1985).

Statistical analysis: The results were expressed as the Mean±SE. Results of animal experiments were analyzed statistically using the one-way analysis of variance ANOVA followed by Duncan’s test. In all cases; p<0.05 was used as the criterion of statistical significance.

RESULTS

The represented data in Table 1 declared that the petroleum ether extract of white pepper seeds recorded the highest values of anti-oxidant activities (AA) for the three applied assays (DPPH, ABTS and FRAP). Whereas, n-hexane extract of white pepper showed the lowest values of anti-oxidant activities. The TPC of WPEs was also ordered ascendingly as HWP<EWP<PWP. Moreover, the highest value of total flavonoid content was recorded by petroleum ether extract.

The fatty acid composition of white pepper (n-hexane extract) was illustrated in Table 2. As shown white pepper n-hexane extract recorded high content of oleic acid (13.22%) and linoleic acid (8.26%). The major saturated fatty acid was luric acid (17.69%). Erucic acid was not detected in the white pepper n-hexane extract.

Evaluation of minimal fungicidal concentration of white pepper extracts: The results presented in Table 3 showed the minimal fungicidal concentration values of white pepper extracts compared to Nystatin as a standard anti-fungal material. It was obvious that petroleum ether extract of white pepper recorded the best results of minimal fungicidal concentration against the four toxigenic fungi strains.

Table 1:Total anti-oxidant, total phenolic and total flavonoid of white pepper extracts
Image for - Counteractive Role of White Pepper Extracts for Oxidative Stress and Hepatotoxicity Induced by Aflatoxin B1 in Rats
TPC: Total phenolic content, TFC: Total flavonoid content

Table 2:Fatty acid composition of white pepper n-hexane extract
Image for - Counteractive Role of White Pepper Extracts for Oxidative Stress and Hepatotoxicity Induced by Aflatoxin B1 in Rats
ND: Not detected

Anti-fungal inhibition of white pepper extracts: The data in Table 4 presented the inhibition percentage of each extract against the control. The highest inhibition (%) recorded by the PWP extract, it was ranged from 39.2-48.6% of the control. The highest inhibition (%) of toxigenic fungi showed for F. oxysporum ITEM 12591 growth (using well diffusion assay), while the lowest inhibition (%) recorded for Aspergillus parasiticus ITEM 11 (on desk diffusion assay). However, the differentiation between the agar desk diffusion and agar well diffusion was not so far which may indicate honesty for the WPEs anti-fungal effect against the toxigenic fungi.

As shown in Table 4, the highest reduction of mycelial growth was accomplished by PWP. The highest reduction value recorded for F. oxysporium ITEM 12591, while the lowest reduction value was recorded for A. pairasticus ITEM 11.

Effect on body weight gain or total food intake: Results (Table 5) revealed that the administration of aflatoxin B1 to rats lead to reduction in the body weight gain compared to the normal rats. Also orally treated rats with aflatoxin B1 recorded the lowest value of food intake(16.25 g/day) and total food intake (455 g).

Table 3:Minimal fungicidal concentration of white pepper extracts
Image for - Counteractive Role of White Pepper Extracts for Oxidative Stress and Hepatotoxicity Induced by Aflatoxin B1 in Rats

Table 4:Fungal inhibition effect of white pepper extracts on solid and liquid media growth
Image for - Counteractive Role of White Pepper Extracts for Oxidative Stress and Hepatotoxicity Induced by Aflatoxin B1 in Rats

Table 5:Nutritional parameters of different experimental groups (Mean±SE)
Image for - Counteractive Role of White Pepper Extracts for Oxidative Stress and Hepatotoxicity Induced by Aflatoxin B1 in Rats
In each column, same letters means non-significant difference; different letter means the significance among the tested groups at 0.05 probability

Table 6:Liver and kidney weight of different experimental groups (Mean±SE)
Image for - Counteractive Role of White Pepper Extracts for Oxidative Stress and Hepatotoxicity Induced by Aflatoxin B1 in Rats
In each column, same letters means non-significant difference, different letter means the significance among the tested groups at 0.05 probability

On the other hand, orally treated rats with ethanol, petroleum ether or n-hexane extracts of white pepper along with aflatoxin B1 showed improvement in the nutritional parameters either body weight gain or total food intake.

Effect on liver and kidney weight: With regard to liver and kidney weight of the studied groups, results (Table 6) declared that the liver weight of orally treated rats with aflatoxin B1 significantly increased in comparison to the normal control rats. Rats administrated with of ethanol, petroleum ether, or n-hexane extracts of white pepper along with aflatoxin B1 recorded liver weight lower than rats treated with aflatoxin B1 only. It was obvious that the liver weight didn’t affected by the administration of WPEs only without the aflatoxicosis induction. There weren’t significant differences in kidney weight of the studied groups.

Table 7:Liver functions of different experimental groups (Mean±SE)
Image for - Counteractive Role of White Pepper Extracts for Oxidative Stress and Hepatotoxicity Induced by Aflatoxin B1 in Rats
In each column, same letters means non-significant difference, different letter means the significance among the tested groups at 0.05 probability

Table 8:Kidney functions of different experimental groups (Mean±SE)
Image for - Counteractive Role of White Pepper Extracts for Oxidative Stress and Hepatotoxicity Induced by Aflatoxin B1 in Rats
In each column, same letters means non-significant difference; different letter means the significance among the tested groups at 0.05 probability

Effect on liver functions: As illustrated in Table 7, the impact of aflatoxin B1 on the liver functions was evident. Since the activities of ALT, AST and alkaline phosphatase significantly elevated in orally treated rats with aflatoxin B1 (69.70,99.27and 89.42U L1 in succession) compared to the normal control rats. The total protein value significantly decreased in orally treated rats with aflatoxin B1 (3.06 g dL1). The extracts of white pepper suppressed either the raising in ALT, AST and alkaline phosphatase activities or the reduction in total protein. The petroleum ether extract of white pepper exhibit the most promising effect followed by white pepper n-hexane extract. The rats given ethanol, petroleum ether or n-hexane extracts of white pepper only without the aflatoxicosis induction didn’t show significant differences neither in ALT, AST and alkaline phosphatase activities nor in total protein values in comparison to normal control rats.

Effect on kidney functions: Kidney functions were not immune to the negative effect of aflatoxin B1. Since as noticeable in Table 8, orally treated rats with aflatoxin B1 exhibited the highest values of urea, uric acid and creatinine (33.09, 2.45 and 1.13 mg dL1 in succession) while the albumin value decreased significantly in these rats in comparison to the normal control rats. The extracts of white pepper combat the negative effect of aflatoxin B1 on kidney functions. The most promising effect on kidney functions was achieved by the petroleum ether extract of white pepper.

Hemoglobin concentration and oxidative stress impacts: It was manifested from Fig. 1a that the lowest value of hemoglobin concentration was recorded by the group given aflatoxin B1 only (10.82 g dL1). The extracts of white pepper suppressed the reduction of hemoglobin concentration value induced by aflatoxin B1.

Figure 1b and c declared that the intake of aflatoxin B1 caused oxidative stress which was clearly demonstrated throughout the elevation of plasma malondialdehyde value as well as the reduction of plasma total antioxidant capacity value for the group given aflatoxin B1 only in compared to the other groups. On the other hand, the extracts of white pepper reduced the oxidative effect of aflatoxin B1 when they administrated together.

As shown in Fig. 2a-c, no significant differences in the oxidative stress markers (malondialdehyde, catalase, SOD and GST) in liver tissues were observed between the normal control group and the groups treated with each extract of white pepper only. On the other hand, the oxidative stress markers in liver tissues affected by the intake of aflatoxin B1. While the extracts of white pepper alleviated the raising of liver malondialdehyde and the reduction of liver catalase, SOD as well as GST activities. The petroleum ether extract of white pepper exhibited the most promising effect.

Image for - Counteractive Role of White Pepper Extracts for Oxidative Stress and Hepatotoxicity Induced by Aflatoxin B1 in Rats
Fig. 1(a-c): (a) Hemoglobin, (b) Plasma malondialdehyde and (c) Total anti-oxidant capacity of different experimental groups
  Same letters means non-significant difference, different letter means the significance among the tested groups at 0.05 probability

Table 9:Lipid profile of different experimental groups (Mean±SE)
Image for - Counteractive Role of White Pepper Extracts for Oxidative Stress and Hepatotoxicity Induced by Aflatoxin B1 in Rats
In each column, same letters means non-significant difference, different letter means the significance among the tested groups at 0.05 probability

Plasma lipid profile: The plasma lipid profile also was affected by the intake of aflatoxin B1. Results (Table 9) revealed that the highest values of plasma total cholesterol, triglycerides, LDL-Ch and VLDL-Ch as well as T- Ch/ HDL-Ch ratio were recorded by the group given aflatoxin B1 only whereas, this group showed the lowest value of HDL-Ch. Significantly the extracts of white pepper improved the lipid profile when they administrated along with aflatoxin B1.

Image for - Counteractive Role of White Pepper Extracts for Oxidative Stress and Hepatotoxicity Induced by Aflatoxin B1 in Rats
Fig. 2(a-d):Oxidative stress markers in liver, (a) Malondialdehyde, (b) Catalase, (c) SOD and (d) GST of different experimental groups
  Same letters means non-significant difference; different letter means the significance among the tested groups at 0.05 probability

DISCUSSION

Taking into consideration the contamination of food stuffs and edible tissues with mycotoxin, especially aflatoxin B1 which exhibit several hazards on the health, there is a need to natural products to suppress the negative effects and hazards of aflatoxin B1. Anti-oxidant and anti-fungal activities of ethanol and petroleum ether extracts as well as n-hexane extract of white pepper were evaluated also the protective effect of these items against hepatotoxicity induced by aflatoxin B1 in rats was studied. Logically, the suppression of fungal growth results in prevention of mycotoxin production. The anti-fungal activities of ethanol and petroleum ether extracts as well as n-hexane extract of white pepper, may be attributed to its anti-oxidant activities and contents of phenolic compounds. Since, El Khoury et al.45 reported that; there was a relation between the total phenolic and anti-oxidant activity of plant extracts and fungal growth degradation. The results reported by Grintzalis et al.46 referred to an inhibition effect of anti-oxidant on mycotoxin production more than its effect on the sclerotial of fungi. Mahoney et al.47 reported that phenolic compounds could inhibit aflatoxin production and fungal growth of A. flavus. Moreover, the synthetic anti-oxidant like butylated hydroxyanisole (BHA) also showed a similar impact48. It was reported in a previous studies that the materials with a higher minimal inhibitory concentration and minimal fungicidal concentration values represented more potent role in fungal growth inhibition25,49. This effect may refer to the change of oxidative stress in the fungal growth media which cause a reduction not only in fungal growth amount, but also in the mycotoxin secreted by the fungi in the media50. In addition to anti-oxidant activities and phenolic compounds of ethanol and petroleum ether extracts of white pepper, the antifungal activities of these items may be attributed to the alkaloid compound known as piperine (1-peperoyl piperidine) which possesses anti-fungal and antioxidant effects as mentioned by Gurinderdeep17. Although Kanaki et al.51 disclosed that petroleum ether one of the solvents utilized for piperine extraction also ethanol one of the solvents utilized for piperine extraction52 but Raman and Gaikar53 found that the highest extraction efficiency of piperine (94% with a purity of 85%) was achieved using petroleum ether as a non-polar solvent while the lowest extraction efficiency of piperine (75-80% with a purity of 72%) was achieved using polar solvent such as ethanol. This finding may interpret the superiority of the effect of white pepper petroleum ether extract as anti-fungal and anti-oxidant agent. In the same pattern, results of the current study demonstrated that the white pepper petroleum ether extract showed the superiority as a hepatic protective agent against aflatoxin B1 in rats. This superiority may be due to its higher content of piperine which possesses hepatoprotective activity15. Aflatoxin B1 mediated weight gain reduction is related to the anorexia54. Choi et al.55 reported that the hepatic damage caused by aflatoxin B1 is associated with the generation of reactive oxygen species and aflatoxin B1- 8,9-epoxide. ALT, AST as well as ALP are considered biomarkers which indicate to the hepatic injury shown to be increased in hepatotoxicity induced by aflatoxin56-59 B1. The elevation of these biomarkers may be due to the disruption of plasma membrane by reactive oxygen species produced during the metabolism of aflatoxin60 AFB1, Galvano et al.61 also mentioned that; the metabolic processing of aflatoxin B1 by cytochrome P450 in the liver results in reactive oxygen species. These reactive oxygen species are associated with aflatoxin B1 mediated oxidative stress which clearly observed in the results of the present study via the elevation of plasma and liver MDA, reduction of plasma TAC and decreasing of liver catalase, SOD as well as GST of rats given aflatoxin B1 alone. White pepper extracts potentially reversed the oxidative stress (either in plasma or in the liver) with an elevation of elevation of liver functions due to its antioxidant activities. In addition to that, the beneficial effect of white pepper extracts may be attributed not only to piperine which has an important role in free radical damage and can reduce the expressions of MDA and SOD activity62,63 but also to other bioactive compounds such as flavonoids which exhibit protective effect of cells against aflatoxin64 AFB1 and can improve the detoxification of aflatoxin B1 possibly by enhancing the activities of ROS detoxifying enzymes, thus the redox imbalance caused by aflatoxin B1 and the cellular macromolecules oxidation and fragmentation can be prevented65,66. The results of the current study indicated that rats treated with aflatoxin B1 alone showed elevation of total cholesterol, triglycerides and low density lipoprotein levels as well as the reduction of high density lipoprotein. Abdel-Wahhab et al.67,68 reported that a disturbance in the lipid metabolism causes by the toxic action of aflatoxin B1 on liver functions. So, the improvement of lipid profile which accomplished by white pepper extracts may be due to its beneficial effect on liver functions. In addition to the presence of hypolipidemic bioactive compounds such as phenolic compounds and flavonoids in these extracts. Aflatoxin B1 mediated hemoglobin reduction is related to not only the anemia caused by aflatoxin54 B1 but also to the red blood cells haemolysis by elevated lipid peroxides69. Thus, white pepper extracts potentially reversed the hemoglobin reduction due to its antioxidant activities.

CONCLUSION

The results of the current investigation indicated to the potency of white pepper extracts as an anti-oxidant and anti-fungal agent. The most promising effect was accomplished by the petroleum ether extract of white pepper, either for its bioactive components contents or its anti-fungal potency. The counteractive role of white pepper extracts for oxidative stress and hepatotoxicity induced by aflatoxin B1 in rats was demonstrated. These results directing to recommend implementing WPEs in safe foodstuffs production, mycotoxin health hazard avoidance in food products, besides the possibility to extend food shelf-life.

SIGNIFICANCE STATEMENT

This study confirmed that the white pepper extracts can act as anti-oxidant and antifungal agents. The counteractive role of white pepper extracts for oxidative stress and hepatotoxicity induced by aflatoxin B1 in rats was demonstrated. The results of the current study directing to recommend implementing WPEs in safe foodstuffs production, mycotoxin health hazard avoidance in food products, besides the possibility to extend food shelf-life.

REFERENCES

  1. Bennett, J.W. and M. Klich, 2003. Mycotoxins. Clin. Microbiol. Rev., 16: 497-516.
    CrossRefDirect Link
  2. Caloni, F. and C. Cortinovis, 2011. Toxicological effects of aflatoxins in horses. Vet. J., 188: 270-273.
    CrossRefDirect Link
  3. Reza, S.S.M., A. Masoud, T. Ali, G. Faranak and N. Mahboob, 2012. Determination of aflatoxins in nuts of Tabriz confectionaries by ELISA and HPLC methods. Adv. Pharmaceut. Bull., 2: 123-126.
    CrossRefDirect Link
  4. Wangikar, P.B., P. Dwivedi, N. Sinha, A.K. Sharma and A.G. Telang, 2005. Teratogenic effects in rabbits of simultaneous exposure to ochratoxin A and aflatoxin B1 with special reference to microscopic effects. Toxicololgy, 215: 37-47.
    CrossRefDirect Link
  5. Bintvihok, A., 2002. New insights to controlling mycotoxin danger in ducks. Feed Technol., 6: 28-29.
    Direct Link
  6. Gong, Y.Y., K. Cardwell, A. Hounsa, S. Egal, P.C. Turner, A.J. Hall and C.P. Wild, 2002. Dietary Aflatoxin exposure and impaired growth in young children from Benin and Togo: Cross sectional study. Br. Med. J., 325: 20-21.
    CrossRefPubMed
  7. Guindon, K.A., L.L. Bedard and T.E. Massey, 2007. Elevation of 8-hydroxydeoxyguanosine in DNA from isolated mouse lung cells following In vivo treatment with aflatoxin B1. Toxicol. Sci., 98: 57-62.
    CrossRefDirect Link
  8. Fapohunda, S.O., C.N. Ezekiel, O.A. Alabi, A. Omole and S.O. Chioma, 2008. Aflatoxin-mediated sperm and blood cell abnormalities in mice fed with contaminated corn. Mycobiology, 36: 255-259.
    CrossRefPubMedDirect Link
  9. Lee, J.K., E.H. Choi, K.G. Lee and H.S. Chun, 2005. Alleviation of aflatoxin B1-induced oxidative stress in HepG2 cells by volatile extract from Allii Fistulosi Bulbus. Life Sci., 77: 2896-2910.
    CrossRefDirect Link
  10. Brinda, R., S. Vijayanandraj, D. Uma, D. Malathi, V. Paranidharan and R. Velazhahan, 2013. Role of Adhatoda vasica (L.) nees leaf extract in the prevention of aflatoxin‐induced toxicity in Wistar rats. J. Sci. Food Agric., 93: 2743-2748.
    CrossRefDirect Link
  11. Ganesh, P., R.S. Kumar and P. Saranraj, 2014. Phytochemical analysis and antibacterial activity of pepper (Piper nigrum L.) against some human pathogens. Central Eur. J. Exp. Biol., 3: 36-41.
    Direct Link
  12. Wang, B., Y. Zhang, J. Huang, L. Dong, T. Li and X. Fu, 2017. Anti-inflammatory activity and chemical composition of dichloromethane extract from Piper nigrum and P. longum on permanent focal cerebral ischemia injury in rats. Rev. Brasil. Farmacogn., 27: 369-374.
    CrossRefDirect Link
  13. Kim, H.G., E.H. Han, W.S. Jang, J.H. Choi and T. Khanal et al., 2012. Piperine inhibits PMA-induced cyclooxygenase-2 expression through downregulating NF-κB, C/EBP and AP-1 signaling pathways in murine macrophages. Food Chem. Toxicol., 50: 2342-2348.
    CrossRefDirect Link
  14. Son, D.J., S.Y. Kim, S.S. Han, C.W. Kim and S. Kumar et al., 2012. Piperlongumine inhibits atherosclerotic plaque formation and vascular smooth muscle cell proliferation by suppressing PDGF receptor signaling. Biochem. Biophys. Res. Commun., 427: 349-354.
    CrossRefDirect Link
  15. Matsuda, H., K. Ninomiya, T. Morikawa, D. Yasuda, I. Yamaguchi and M. Yoshikawa, 2008. Protective effects of amide constituents from the fruit of Piper chaba on D-galactosamine/TNF-alpha-induced cell death in mouse hepatocytes. Bioorg. Med. Chem. Lett., 18: 2038-2042.
    CrossRefPubMedDirect Link
  16. Caceres, I., R. El Khoury, S. Bailly, I.P. Oswald, O. Puel and J.D. Bailly, 2017. Piperine inhibits aflatoxin B1 production in Aspergillus flavus by modulating fungal oxidative stress response. Fungal Genet. Biol., 107: 77-85.
    CrossRefDirect Link
  17. Gurinderdeep, S., 2017. Piperine: A remarkable marker with intense biological activity. Int. J. Pharmacogn. Chinese. Med., Vol. 1.
    Direct Link
  18. Reeves, P.G., F.H. Nielsen and G.C. Fahey Jr., 1993. AIN-93 purified diets for laboratory rodents: Final report of the American Institute of Nutrition ad hoc writing committee on the reformulation of the AIN-76A rodent diet. J. Nutr., 123: 1939-1951.
    CrossRefPubMedDirect Link
  19. Singleton, V.L., R. Orthofer and R.M. Lamuela-Raventos, 1999. Analysis of Total Phenols and other Oxidation Substrates and Antioxidants by Means of Folin-Ciocalteu Reagent. In: Methods in Enzymology, Burslem, G.L. (Ed.), Academic Press, Cambridge, Massachusetts, ISBN: 9780121822002, pp: 152-178.
    CrossRefDirect Link
  20. Chang, C.C., M.H. Yang, H.M. Wen and J.C. Chern, 2002. Estimation of total flavonoid content in propolis by two complementary colometric methods. J. Food Drug Anal., Vol. 10.
    CrossRefDirect Link
  21. Teke, G.N., P.K. Lunga, H.K. Wabo, J.R. Kuiate and G. Vilarem et al., 2011. Antimicrobial and antioxidant properties of methanol extract, fractions and compounds from the stem bark of Entada abyssinica Stend ex A. Satabie. BMC Complem. Altern. Med., Vol. 11.
    CrossRef
  22. Re, R., N. Pellegrini, A. Proteggente, A. Pannala, M. Yang and C. Rice-Evans, 1999. Antioxidant activity applying an improved ABTS radical cation decolorization assay. Free Radical Biol. Med., 26: 1231-1237.
    CrossRefDirect Link
  23. Hwang, E.S. and N.D. Thi, 2014. Effects of extraction and processing methods on antioxidant compound contents and radical scavenging activities of laver (Porphyra tenera). Prev. Nutr. Food Sci., 19: 40-48.
    CrossRefDirect Link
  24. AOAC., 2000. Official Methods of Analysis. 16th Edn., Association of Official Analytical Chemists, Washington, DC., USA.
  25. Badr, A.N., M.G. Shehata and A.G. Abdel-Razek, 2017. Antioxidant activities and potential impacts to reduce aflatoxins utilizing jojoba and jatropha oils and extracts. Int. J. Pharmacol., 13: 1103-1114.
    CrossRefDirect Link
  26. Shehata, M.G., A.N. Badr, A.G. Abdel-Razek, M.M. Hassanein and H.A. Amra, 2017. Oil-bioactive films as an antifungal application to save post-harvest food crops. Annu. Res. Rev. Biol., 16: 1-16.
    Direct Link
  27. Drabkin, D.L., 1949. The standardization of hemoglobin measurement. Am. J. Med. Sci., 217: 710-710.
    PubMed
  28. Rheinhold, J.G., 1953. Total Protein, Albumin and Globulin. In: Standard Methods of Clinical Chemistry, Seligron, D. (Ed.). Vol. 1, Academic Press, New York, pp: 88.
  29. Reitman, S. and S. Frankel, 1957. Calorimetric methods for aspartate and alanine transaminase. Am. J. Clin. Path., 28: 55-60.
  30. Bessey, O.A., O.H. Lowry and M.J. Brock, 1946. A method for the rapid determination of alkaline phosphates with five cubic millimeters of serum. J. Biol. Chem., 164: 321-329.
    PubMedDirect Link
  31. Larsen, 1972. Creatinine assay by a reaction-kinetic principle. Clin. Chim. Acta, 41: 209-217.
    CrossRefPubMedDirect Link
  32. Fawcett, J.K. and J.E. Scott, 1960. A rapid and precise method for the determination of urea. J. Clin. Pathol., 13: 156-159.
    CrossRefPubMedDirect Link
  33. Christian, G.D., E.C. Knoblock and W.C. Purdy, 1965. A coulometric determination of urea nitrogen in blood and urine. Clin. Chem., 11: 700-707.
    Direct Link
  34. Doumas, B.T., W.A. Watson and H.G. Biggs, 1971. Albumin standards and the measurement of serum albumin with bromcresol green. Clin. Chim. Acta, 31: 87-96.
    CrossRefPubMedDirect Link
  35. Watts, R.W.E., 1974. Determination of uric acid in blood and in urine. Ann. Clin. Biochem., 11: 103-111.
    CrossRefDirect Link
  36. Watson, D., 1960. A simple method for the determination of serum cholesterol. Clin. Chim. Acta, 5: 637-643.
    CrossRefDirect Link
  37. Burstein, M., H.R. Scholnick and R. Morfin, 1970. Rapid method for the isolation of lipoproteins from human serum by precipitation with polyanions. J. Lipid Res., 11: 583-595.
    PubMedDirect Link
  38. Schriewer, H., U. Kohnert and G. Assmann, 1984. Determination of LDL cholesterol and LDL apolipoprotein B following precipitation of VLDL in blood serum with phosphotungstic acid/MgCl2. J. Clin. Chem. Clin. Biochem., 22: 35-40.
    CrossRefDirect Link
  39. Megraw, R.E., D.E. Dunn and H.G. Biggs, 1979. Manual and continuous-flow colorimetry of triacylglycerols by a fully enzymic method. Clin. Chem., 25: 273-278.
    Direct Link
  40. Koracevic, D., G. Koracevic, V. Djordjevic, S. Andrejevic and V. Cosic, 2001. Method for the measurement of antioxidant activity in human fluids. J. Clin. Pathol., 54: 356-361.
    CrossRefPubMedDirect Link
  41. Ohkawa, H., N. Ohishi and K. Yagi, 1979. Assay for lipid peroxides in animal tissues by thiobarbituric acid reaction. Anal. Biochem., 95: 351-358.
    CrossRefPubMedDirect Link
  42. Beers, Jr. R.F. and I.W. Sizer, 1952. A spectrophotometric method for measuring the breakdown of hydrogen peroxide by catalase. J. Biol. Chem., 195: 133-140.
    CrossRefPubMedDirect Link
  43. Habig, W.H., M.J. Pabst and W.B. Jakoby, 1974. Glutathione S-transferases: The first enzymatic step in mercapturic acid formation. J. Biol. Chem., 249: 7130-7139.
    CrossRefPubMedDirect Link
  44. Nishikimi, M., N.A. Rao and K. Yagi, 1972. The occurrence of superoxide anion in the reaction of reduced phenazine methosulfate and molecular oxygen. Biochem. Biophys. Res. Commun., 46: 849-854.
    CrossRefPubMedDirect Link
  45. El Khoury, R., A. Atoui, F. Mathieu, H. Kawtharani, A. EL Khoury, R.G. Maroun and A. EL Khoury, 2017. Antifungal and antiochratoxigenic activities of essential oils and total phenolic extracts: A comparative study. Antioxidants, Vol. 6.
    CrossRefDirect Link
  46. Grintzalis, K., S.I. Vernardis, M.I. Klapa and C.D. Georgiou, 2014. The role of oxidative stress in sclerotial differentiation and aflatoxin B1 biosynthesis in Aspergillus flavus. Applied Environ. Microbiol., 80: 5561-5571.
    PubMedDirect Link
  47. Mahoney, N., R. Molyneux, J. Kim, B. Campbell, A. Waiss and A. Hagerman, 2010. Aflatoxigenesis induced in Aspergillus flavus by oxidative stress and reduction by phenolic antioxidants from tree nuts. World Mycotoxin J., 3: 49-57.
    CrossRefDirect Link
  48. Nesci, A., M. Rodriguez and M. Etcheverry, 2003. Control of Aspergillus growth and aflatoxin production using antioxidants at different conditions of water activity and pH. J. Applied Microbiol., 95: 279-287.
    CrossRefDirect Link
  49. Abdel-Razek, A.G., A.N. Badr and G.S. Mohamed, 2017. Characterization of olive oil By-products: antioxidant activity, its ability to reduce aflatoxigenic fungi hazard and its aflatoxins. Annu. Res. Rev. Biol., 14: 1-14.
    CrossRefDirect Link
  50. Fountain, J.C., P. Bajaj, S.N. Nayak, L. Yang and M.K. Pandey et al., 2016. Responses of Aspergillus flavus to oxidative stress are related to fungal development regulator, antioxidant enzyme and secondary metabolite biosynthetic gene expression. Front. Microbiol., Vol. 7.
    CrossRefDirect Link
  51. Kanaki, N., M. Dave, H. Padh and M. Rajani, 2008. A rapid method for isolation of piperine from the fruits of Piper nigrum Linn. J. Natural Med., 62: 281-283.
    CrossRefDirect Link
  52. Meghwal, M. and T.K. Goswami, 2013. Piper nigrum and piperine: An update. Phytother. Res., 27: 1121-1130.
    CrossRefDirect Link
  53. Raman, G. and V.G. Gaikar, 2002. Microwave-assisted extraction of Piperine from Piper nigrum. Ind. Eng. Chem.Res., 41: 2521-2528.
    CrossRefDirect Link
  54. Trebak, F., A. Alaoui, D. Alexandre, S. El Ouezzani, Y. Anouar, N. Chartrel and R. Magoul, 2015. Impact of aflatoxin B1 on hypothalamic neuropeptides regulating feeding behavior. Neurotoxicology, 49: 165-173.
    CrossRefDirect Link
  55. Choi, K.C., W.T. Chung, J.K. Kwon, Y.S. Jang, J.Y. Yu, S.M. Park and J.C. Lee, 2011. Chemoprevention of a flavonoid fraction from Rhus verniciflua stokes on aflatoxin B1‐induced hepatic damage in mice. J. Applied Toxicol., 31: 150-156.
    CrossRefDirect Link
  56. Ajiboye, T.O., 2011. In vivo antioxidant potentials of Piliostigma thonningii (Schum) leaves: Studies on hepatic marker enzyme, antioxidant system, drug detoxifying enzyme and lipid peroxidation. Hum. Exp. Toxicol., 30: 55-62.
    CrossRefDirect Link
  57. Oloyede, H.O.B., T.O. Ajiboye, Y.O. Komolafe and A.K. Salau, 2013. Polyphenolic extract of Blighia sapida arilli prevents N-nitrosodiethylamine-mediated oxidative onslaught on microsomal protein, lipid and DNA. Food Biosci., 1: 48-56.
    CrossRefDirect Link
  58. Adeleye, A.O., T.O. Ajiboye, G.A. Iliasu, F.A. Abdussalam, A. Balogun, O.B. Ojewuyi and M.T. Yakubu, 2014. Phenolic extract of Dialium guineense pulp enhances reactive oxygen species detoxification in aflatoxin B1 hepatocarcinogenesis. J. Med. Food, 17: 875-885.
    CrossRefDirect Link
  59. Ajiboye, T.O., 2015. Standardized extract of Vitex doniana Sweet stalls protein oxidation, lipid peroxidation and DNA fragmention in acetaminophen-induced hepatotoxicity. J. Ethnopharmacol., 164: 273-282.
    CrossRefDirect Link
  60. Shen, H.M., C.Y. Shi, Y. Shen and C.N. Ong, 1996. Detection of elevated reactive oxygen species level in cultured rat hepatocytes treated with aflatoxin B1. Free. Radic. Biol. Med., 21: 139-146.
    Direct Link
  61. Galvano, F., A. Piva, A. Ritieni and G. Galvano, 2001. Dietary strategies to counteract the effects of mycotoxins: A review. J. Food Prot., 64: 120-131.
    Direct Link
  62. Eigenmann, D.E., C. Durig, E.A. Jahne, M. Smiesko and M. Culot et al., 2016. In vitro blood-brain barrier permeability predictions for GABA A receptor modulating piperine analogs. Eur. J. Pharm. Biopharm., 103: 118-126.
    CrossRefDirect Link
  63. Wang, H., J. Liu, G. Gao, X. Wu, X. Wang and H. Yang, 2016. Protection effect of piperine and piperlonguminine from Piper longum L. alkaloids against rotenone-induced neuronal injury. Brain Res., 1639: 214-227.
    CrossRefDirect Link
  64. Nones, J., J. Nones and A.G. Trentin, 2013. Flavonoid hesperidin protects neural crest cells from death caused by aflatoxin B1. Cell Biol. Int., 37: 181-186.
    CrossRefDirect Link
  65. Ajiboye, T.O., H.O. Raji, H.F. Muritala, O.B. Ojewuyi and M.T. Yakubu, 2013. Anthocyanin extract of Lannea microcarpa fruits stall oxidative rout associated with aflatoxin B1 hepatocarcinogenesis. Food Biosci., 4: 58-67.
    CrossRefDirect Link
  66. Ajiboye, T.O., A.O. Adeleye, A.K. Salau, O.B. Ojewuyi, N.S. Adigun, S. Sabiu and T.O. Sunmonu, 2014. Phenolic extract of Parkia biglobosa fruit pulp stalls aflatoxin B1-mediated oxidative rout in the liver of male rats. Rev. Brasil. Farmacogn., 24: 668-676.
    CrossRefDirect Link
  67. Abdel-Wahhab, M.A., H.H. Ahmed and M.M. Hagazi, 2006. Prevention of aflatoxin B1-initiated hepatotoxicity in rat by marine algae extracts. J. Applied Toxicol., 26: 229-238.
    CrossRefDirect Link
  68. Abdel-Wahhab, M.A., N.S. Hassan, A.A. El-Kady, Y.A. Khadrawy and A.A. El-Nekeety et al., 2010. Red ginseng extract protects against aflatoxin B1 and fumonisins-induced hepatic pre-cancerous lesions in rats. Food Chem. Toxicol., 48: 733-742.
    CrossRefDirect Link
  69. Arun, G.S. and K.G. Ramesh, 2002. Improvement of insulin sensitivity by perindopril in spontaneously hypertensive and streptozotocin-diabetic rats. Indian J. Pharmacol., 34: 156-164.
    Direct Link

Leave a Comment

Your email address will not be published. Required fields are marked *