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Tech Resources - Application Notes

Histamine Analysis in Wine Samples Using the Microplate Format


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Authors: Paul Held Ph.D, Senior Scientist, Wendy Goodrich, Applications Engineer, Applications Department, BioTek Instruments




Bioactive amines are low molecular weight organic bases, formed by biological processes in all living organisms. One such bioactive amine is histamine. Wine, particularly red wine, is a beverage that contains significant amounts of histamine. Although there are many agents in red wine known to cause headaches (e.g. ethanol), histamine has been identified as the primary cause for intense headaches and migraines that some people experience after consuming red wine. Histamine is a bioactive amine that can be produced in vivo or ingested from dietary sources. Endogenous production of histamine is the result of enzymatic decarboxylation of the amino acid histidine, which is catalyzed by the enzyme L-histidine decarboxylase (Figure 1). Once formed the compound is either stored or rapidly inactivated by the action of histamine-N-methyltransferase and diamine oxidase enzymes. Most tissue histamine is found in the metachromatic granules of mast cells of basophilic leukocytes. Other tissues containing histamine include the brain, where it acts as a neurotransmitter and the enterochromaffin cell of the stomach. In the course of type I allergy histamine is released from mast cells and basophils as a result of antigen binding to IgE on the surface of the cells, resulting in typical allergic reactions. In the case of ingestion of histamine, many of the same symptoms can appear without a true IgE allergic reaction taking place. This phenomenon is referred to as “food intolerance”, with the term “food allergy” being used for true immunological reaction.



 Figure 1. Formation of histamine by the enzymatic decarboxylation of the amino acid histidine.


Rash, diarrhea, nausea and vomiting, headache and asthma clinically characterize food intolerances caused by elevated histamine levels. The extent of the reaction is directly related to the amount of histamine ingested and can be exacerbated by a lack of diamine oxidase. In addition to food intolerances, toxic reactions caused by very high histamine also exist. These toxic levels of histamine are usually the result of bacterial degradation of protein-rich food. This is particularly true with many fish species. Histamine content of many ichthyic species is the result of the degradation by bacteria on the fish skin. Post-mortem, these bacteria transform free histidine to histamine. High levels of histamine are therefore considered to be an early sign of decomposition.

There are a number of different analytical techniques for determining the levels of histamine in wine samples, mainly based on gas chromatography, liquid chromatography, HPLC and capillary electrophoresis. These methods often require several preparative steps to transform histamine into a detectable moiety. In addition these methods are often time and reagent consuming, resulting in considerable expense in terms of instrumentation and reagents and precluding the measurement of large numbers of samples. The ELISA procedure described has the advantage of being easily performed on many samples using an ELx50™ Microplate Strip Washer (BioTek Instruments, Winooski, VT) and an ELx800™ Absorbance Microplate Reader (BioTek Instruments, Winooski, VT).

The basis of the test is the antigen-antibody reaction. The wells are coated with specific antibodies against N-acyl-histamine. After sample preparation, histamine in samples and standards is derivatized into N-acylhistamine. Acylated histamine standards and samples in solution along with enzyme labeled N-acylhistamine (enzyme conjugate) are added respectively. Free and enzyme-labeled histamine compete for the antibody binding sites. Any unbound enzyme conjugate is then removed by a washing step. Enzyme substrate (urea peroxide) and chromogen (tetramethylbenzidine) are added to the wells and incubated. Bound enzyme conjugate converts the colorless chromogen into a blue product. Addition of the stop reagent (sulfuric acid) causes a color change from blue to yellow. Measurement of color development is performed photometrically at 450 nm (optional reference wavelength ³ 600 nm). The resulting absorbance values are inversely proportional to the histamine concentration of the sample. (See Figure 2.)


Figure 2. Competitive Enzyme Immunoassay. Free N-acyl-histamine and enzyme conjugated N-acyl-histamine compete for specific antibody binding sites. Because color development id directly related to the amount of captured conjugate while binding of free and conjugated N-acyl-histamine directly compete for binding, color development is indirectly proportional to histamine concentration of the sample.




RIDASCREEN® Histamine (catalog #1604) kits were purchased from R-Biopharm (Darmstadt, Germany). Each kit contained all of the necessary components, including an uncoated acylation plate, standards, reagents and a coated assay plate, to perform 48 determinations. The test procedure was performed according to the kit instructions. Briefly, samples and standards were first acylated by reacting 100 µl of sample or control with 25 µl of acylation reagent and 200 µl of acylation buffer supplied in the test kit. The reaction was allowed to incubate at room temperature for 15 minutes, after which the sample or standard was ready to assay. Using the antibody-coated plate supplied with the kit, 25 µl aliquots of samples and standards were pipetted into wells of the microplate. Each well also received 100 µl of Anti-histamine capture antibody and the mixture was allowed to incubate for 40 minutes at room temperature. After incubation, the microplate was washed using an ELx50™ Microplate Strip Washer (BioTek Instruments, Winooski, VT) 3 times with 250 µl of wash buffer. After washing, 100 µl of conjugate was added and allowed to incubate for 20 minutes at room temperature. The plate was again washed with 3 cycles of 250 µl of wash buffer using the ELx50 washer followed by the addition of 100 µl of substrate/chromogen mixture. Color was allowed to develop for 15 minutes at room temperature in the dark. The reaction was stopped by the addition of 100 µl of acid stop solution and the absorbance of each well at 450 nm (630 nm reference) was determined using an ELx800™ Absorbance Microplate Reader (BioTek Instruments, Winooski, VT). For all samples and standards, the ratio of the sample or standard to the mean of the zero standard (B/Bo) was calculated. The B/Bo calculation for the standards was then used to generate a standard curve.


Experiment 1

The first experiment was setup with three different sets of kit standards in duplicates. In addition to the standards provided by the kit, 6 replicates of the Negative Control, and 6 replicates of the Positive Control provided by the kit were also tested. Intra assay repeatability experiments involved multiple runs of standard curves using different kits. In each case standard curves were generated using a 4-parameter logistical fit to describe the data. For comparison, multiple experiments repeated the testing of the kit standards, as well as a number of white wine and white zinfandel samples were run in duplicate.




These data demonstrate that the R-Biopharm kit in conjunction with the ELx800™ Absorbance Microplate Reader and an ELx50™ Microplate Strip Washer can be used to quantitate histamine in wine samples. As with any competitive ELISA reaction, increasing analyte concentration results in a decrease in absorbance (Figure 3). Repeated standard curves with different samples resulted in curves very similar in shape and parameters.


Figure 3. Typical standard curves. Three different standard curves were overlayed using Gen5™ Data Analysis Software and plotted on the same set of axis. Each data point represents the mean of duplicate determinations for the specific standard curve.


When individual samples at various known concentrations of histamine are compared, very good inter-assay repeatability is observed. Samples at 15, 5, and 1.5 ppb span most of the dynamic range of the standard curve. For each concentration, individual samples returned very similar calculated concentrations when measured on the same microplate (Figure 4). While similar samples, when measured at different times (intra-assay repeatability) showed an increase in variability, there was still very good agreement between different samples (Figure 5).

When two different wines were assayed for histamine, very close agreement between separate samples was observed. The CVs for the absorbance values at 450 nm for either sample was less than 5% (Table 2). The low levels of histamine in these wine samples result in absorbance values that are located in portions of the standard curve that are relatively unchanging. This manifests in rather large changes in calculated concentrations with relatively small deviations in absorbance, leading to the higher CVs observed for sample concentrations. 


 Figure 4. Inter-assay Repeatability. Multiple replicates of samples at three different concentrations were assayed individually on the same microplate. The absorbance values for each sample were then used to interpolate a standard curve. The resultant calculated concentrations were exported to Microsoft Excel via Gen5’s Power Export function and plotted.


The ELISA test kit is very specific towards acylated histamine. As demonstrated in Table 1, the antibody used only demonstrates a small amount of cross reactivity towards the closely related compounds N-methyl-histamine when assayed. Other compounds tested were found to be below the detection limits.


Table 1. Assay Specificity for R-Biopharm ELISA **

Assay Specificity

Compound Specificity
N-acyl-histamine 100%
N-methyl-histamine 0.01%
5-hydroxy-indole-acetic acid Below detection limits
Imidazole acetic acid Below detection limits
L-histadine Below detection limits
N-methyl imidazole acetic acid Below detection limits
Serotonin Below detection limits
** As reported in the kit insert



Figure 5. Intra-assay Repeatability. Individual samples were run in duplicate on three different assay plates. The individual results were exported using Gen5’s Power Export to Microsoft® Excel® and plotted. Note that each color denotes the three different experimental plates.


 Table 2. Wine Sample Measurements


Raw 450 B/B0% Mean CV (%) Conc. X Dilution Mean CV (%)
SPL1 1.318 61.57     2.372 1186.0    
  1.387 64.80     2.107 1053.7    
  1.296 60.55     2.462 1230.8    
  1.307 61.06     2.417 1208.3    
  1.190 55.59     2.936 1468.0    
  1.284 59.99 60.16 4.13 2.512 1255.9 1251.9 8.99
  1.343 62.74     2.273 1136.7    
  1.250 58.40     2.658 1329.2    
  1.215 56.76     2.817 1408.6    
  1.273 59.47     2.558 1279.2    
  1.283 59.94     2.516 1258.0    
  1.307 61.06     2.417 1208.3    
SPL2 1.732 80.92     1.055 527.5    
  1.778 83.07     0.938 469.2    
  1.754 81.94     0.999 499.4    
  1.622 75.78     1.352 676.1    
  1.734 81.01     1.05 524.9    
  1.818 84.93 79.28 4.76 0.84 420.0 576.7 18.60
  1.794 83.81     0.899 449.3    
  1.647 76.95     1.282 641.1    
  1.582 73.91     1.468 733.9    
  1.660 77.55     1.246 623.2    
  1.600 74.75     1.415 707.6    
  1.642 76.71     1.296 648.0    




These data demonstrate that histamine can be quantitatively determined from wine samples using ELISA. Many of the other methods of determining histamine levels require extensive sample preparation, expensive equipment, and a great deal of technical expertise to perform. The ELISA method requires minimal sample preparation and a minimal amount of equipment, yet can be used for a large number of samples. In addition, ELISA can be used with a large number of different analytes without changing the basic procedure or instrumentation. Furthermore, BioTek’s ELx800™ Absorbance Microplate Reader and ELx50™ Microplate Strip Washer are ideal cost effective tools to perform these types of assays.

Histamine is considered to be an allergen and a causative agent for headaches. While on average histamine in wine is 5.7 ppm and 3.4 ppm for red and white wine respectively, an extremely low histamine content is a desirable characteristic. The detection limit of the test kit is considered to be the lowest standard containing histamine (i.e. 0.5 ppb). Because wine samples are diluted 1:500, the lowest detectable limit in wine samples therefore would be 250 ppb. This is well below the typical ranges in wine, which are usually in the low ppm range. This large margin of sensitivity means that this assay can be used to monitor the formation of histamine by decarboxylation of histadine by lactic acid bacteria during fermentation.

The study of bioactive amines is of interest for a number of reasons. There is a certain amount of “risk” from the ingestion of exogenous histamine, particularly at high levels. Prevention of exposure to high levels in wine products is certainly of importance from a liability standpoint. In addition, there is a possible relationship between high amine content and the quality of the grape used, as well as the hygienic or sanitary conditions prevalent during the wine making process [1]. It has been reported as early as 1978, that routine checking of biogenic amine content of wine was a means to detect defective production procedures [2]. In addition, bioactive amine content of wines may be regulated in the future, such as those implemented for fish. Some countries have established limits for histamine in wines. Switzerland recommends 10 mg/L as a maximal level, Germany recommends 2 mg/L, while Belgium and France recommend 5 mg/L and 8 mg/ml respectively. [3].




[1] Vidal-Carou, M.C. et. Al. (1990) Histamine and tyramine in ish wines: their formation during the wine making process. Am. J. Enol. Vitic. 41:160-167.

[2] Battaglia, R. and Frolich, D. (1978) HPLC Determination of Histamine in Wine. J. High Resolut. Chromatogr.

[3] Souza, S.C., Theodoro, K.H., Souza, E.R., daMotta, S., Beatriz, M., Gloria, A., (2005) Bioactive Amines in Brazillian Wines: Types, Levels, and Correlation with Physico-chemical Parameters. Brazilian Archives of Biology and Technology Vol. 48.

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