• Application Note

Determination of Aflatoxins Utilizing XBridge HPLC Columns

Determination of Aflatoxins Utilizing XBridge HPLC Columns

  • John Martin
  • Waters Corporation
Black mold fungi Aspergillus


This application note evaluates XBridge C18 columns for their ability to accurately separate aflatoxins which provides excellent resolution and quantification at a picogram level.


Aflatoxins are toxic metabolites produced by certain fungi in food and feeds and have been associated with various health risks in livestock, domestic animals and humans worldwide. Potentially harmful effects include aflatoxicosis and carcinogenic effects which have been seen in laboratory animals. Because of their acute toxicological effects in humans, aflatoxins have been studied to a greater degree than most other mycotoxins.

Aflatoxins are produced primarily by strains of Aspergillus flavus and of Aspergilus parasiticus, plus related species of Aspergillus nomius and Aspergillus niger. There are four major aflatoxins, B1, B2, G1 and G2 that are significant as direct contaminants of foods and feeds. There are also two additional aflatoxin metabolites, M1 and M2, which have been isolated and determined to be harmful (Table 1 and Table 2).

Aflatoxin sources Table 1. Aflatoxin sources
Aflatoxin molecular structures Table 2. Aflatoxin molecular structures

These toxins have similar structures and form a unique group of highly oxygenated, naturally occurring heterocyclic compounds (Figure 1). Aflatoxins B2 and G2 have been identified as dihydroxy derivatives of B1 and G1 respectively.


Aflatoxin molecular structures Figure 1. Aflatoxin molecular structures.

Crops which are frequently affected by aflatoxins include cereals (wheat, maize, sorghum, rice), oil seeds (peanuts, sunflower, cotton, soybean), spices (chili peppers, black pepper, red pepper, turmeric, ginger) and tree nuts (almond, pistachio, brazil nut, coconut, walnut).  Virtually all sources of commercial peanut butter contain minute quantities of aflatoxin but at levels far below the US Food and Drug Administration’s recommended limit.

Humans are exposed to aflatoxins when consuming foods contaminated with products of fungal growth.  Even though heavily contaminated food is not permitted to enter the food supply in developed countries, concern still exists regarding the possible adverse effects resulting from long-term exposure to low levels of aflatoxins in the foods.  Aflatoxins are considered unavoidable contaminants in food and feed, even where good manufacturing practices are in place.  The FDA, as well as other regulatory bodies around the word, has established specific guidelines on acceptable levels of aflatoxins in human food and animal feed as seen in Table 3.

Action Levels for Aflatoxins United States (FDA) Action Levels (B1, B2, G2, G2, M1)

Action Levels for Aflatoxins  United States

EU Action Levels

EU Action Levels

Japan Action Levels

 Aflatoxin regulatory action limits Table 3. Aflatoxin regulatory action limits.

In addition to the health ramifications, there is also an economic impact attributable to aflatoxin growth linked directly to crop and livestock losses as well as indirectly to the cost of governmental programs designed to reduce risks to animal and human health. The Food and Agriculture Organization (FAO) estimates that 25% of the world’s food crops are affected by mycotoxins, of which the most widespread are the aflatoxins. Losses attributable to aflatoxin contaminated feeds include death and the lesser effects of immune system suppression, reduced growth rates and losses in feed efficiency. Other adverse economic effects of aflatoxin include lower yields for food and fiber crops. Because of these dramatic effects, most countries have taken action to mitigate mycotoxins in general and aflatoxins specifically (Table 4).

Standarized Testing Methods for Aflatoxins

AOAC Official Methods for Mycotoxins AOAC Official Methods for Mycotoxins

CEN (European Committee for Standardization) Methods for Mycotoxins

CEN Methods for Mycotoxins Table. 4. Standardized methods for aflatoxins.

Numerous analytical methods based on high-performance liquid chromatography (HPLC) have been developed for detecting and quantifying aflatoxins. This report describes two improved analytical methodologies for the identification of aflatoxins using XBridge  C18 HPLC columns.


Example One

By far, the most commonly used laboratory methods for aflatoxins utilize High Performance Liquid Chromatography (HPLC) with fluorescence detection.  In this example, a standard aflatoxin mixture was used to evaluate the ability of the XBridge C18 HPLC column to separate these compounds.


Sample Preparation

A commercial mixture of aflatoxins B1, B2, G1 and G2.  A final solution was appropriately prepared to create the final concentrations:

B1: 250 pg/ml

B2: 25 pg/ml

G1: 250 pg/ml

G2: 25 pg/ml

HPLC conditions


Utilizing an excitation wavelength of 365 nm and an emission wavelength of 455 nm, all of the standard aflatoxins were separated and identified using the XBridge C18 Column (Figure 2).

Chromatogram of aflatoxin standard mixture Figure 2. Chromatogram of aflatoxin standard mixture.  Chromatogram provided courtesy of the University of Iowa.

Example Two

Humans are exposed to aflatoxins in a wide variety of food stuffs. In this example, a sample of commercially available red pepper was obtained and analyzed for mycotoxins, using the XBridge C18 HPLC column.

Sample Preparation

A commercial aflatoxin standard was obtained. Working standard solutions were prepared daily.

An extraction of the sample was performed utilizing the following: 50 g of sample was added to 5 g NaCl, extracted with 300 mL methanol:water (80:20, v/v) in a mixer. Filtered extract was diluted with 60 mL PBS and 65 mL of diluted filtrate was applied to an immunoaffinity column conditioned with PBS. The column was washed with 10 mL water and air applied until dry. Aflatoxins were then eluted by applying 1.20 mL of methanol to the column. The eluate was diluted with 1.50 mL water.

HPLC conditions


Utilizing the described chromatographic conditions, a standard test mixture and an extract of red pepper were analyzed.  The XBridge C18 column provided excellent separation of the analytes of interest (Figure 3 and Figure 4). Toxins in the extract were identified based upon a comparison to the standard chromatogram.

 Chromatogram of prepared aflatoxin standard mixture Figure 3. Chromatogram of prepared aflatoxin standard mixture:  G2, 0.2 ng/mL; G1, 0.4 ng/mL; B2, 0.2 ng/ml; B1, 0.4 ng/mL.  Chromatogram provided courtesy of Istanbul University.
Chromatogram of aflatoxins in red pepper extract Figure 4. Chromatogram of aflatoxins in red pepper extract. Chromatogram provided courtesy of Istanbul University.


The ability of aflatoxins to cause cancer and related diseases in humans and impart broad economic impact worldwide has made them a primarily mycotoxins of concern and widely analyzed. In these studies XBridge C18 columns were evaluated for their ability to accurately separate aflatoxins. Providing excellent resolution and quantification at a picogram level, these columns are shown to be well studied for trace level analysis of these analytes.

WA60195, April 2008

Back To Top Back To Top