An alarming global trend highlights the serious harm that can result from ingesting illegally brewed alcohol. Home-distilled spirits prepared with industrial solvents (i.e., wood alcohol) and presented as alcoholic beverages often contain methanol. This ingredient causes blindness and can lead to death when ingested. This has led to fatal consequences on multiple continents [1–3].
The breaking point for the Czech Republic came in September 2012. The sale of hard liquor was temporarily banned after 20 people died from the consumption of spirits with dangerous levels of methanol [2]. After an exhaustive study using different screening tools, the Czech Republic turned to Raman spectroscopy as the method of choice for identification and quantification of methanol in contaminated spirits.
This Application Note discusses the reasons why Raman spectroscopy is the ideal choice for this application and shows a real-world example of Raman analysis of methanol-laced rum.
Raman spectroscopy is a fast and easy analytical tool for quantifying the amount of methanol contamination present in alcoholic beverages. It is an ideal method for the discrimination of very similar molecules like ethanol (CH3CH2OH) and methanol (CH3OH), as shown in Figure 1.
Raman spectroscopy is superior to comparative technologies such as infrared spectroscopy (e.g., FTIR) because of its:
- ability to measure through optically transparent containers
- insensitivity to interference from water
These two key properties enable accurate detection of methanol down to approximately 1% by volume in the field with no need to open the bottles being tested.
An in-house study measured commercially available coconut rum that was spiked with methanol in concentrations between 0.33% and 5.36%. The i-Raman® Plus, a sensitive high resolution laboratory system with a fiber-optic probe, was used to collect Raman spectra of the mixtures, shown in Figure 2. Table 1 lists the relevant equipment and instrument settings used for this application study.
The peak at around 1000 cm-1 visibly increases with increasing concentration of methanol, becoming significant at approximately 1%.
Table 1. Experimental parameters.
| Equipment | Acquisition settings | |
|---|---|---|
| i-Raman Plus 785S | Laser Power | 100 |
| Vial holder (NR-LVH) | Int. time | 20s |
| Vision Software | Average | 1 |
This data was analyzed with Vision software, and a partial least squares (PLS) regression model was developed on normalized data. The two-factor model developed over the range from 920–1580 cm-1 gave the calibration curve shown in Figure 3, which has a root mean square error of cross-validation (RMSECV) of 0.1069 (Table 2). The R2 value of 0.9977 shown in Table 2 means that the Raman method used here can be used to confidently quantify the amount of methanol in a mixed alcohol sample.
Table 2. Regression parameters used for the development of the PLS model to determine methanol in rum with the i-Raman Plus 785S.
| Parameter | Value |
|---|---|
| Spectral processing | Standard Normal Variate Savitzky-Golay derivative |
| R2 | 0.9977 |
| RMSEC | 0.0976 |
| RMSECV | 0.1069 |
These results verify that Raman can be used for rapid, quantitative screening of dangerous adulterants in alcoholic beverages that pose a public safety risk. This technique can be expanded to investigate adulteration in other media such as food, petroleum, and pharmaceutical drugs [4].
- Lachenmeier, D. W.; Schoeberl, K.; Kanteres, F.; Is Contaminated Unrecorded Alcohol a Health Problem in the European Union? A Review of Existing and Methodological Outline for Future Studies. Addiction 2011, 106 (s1), 20–30. https://doi.org/10.1111/j.1360-0443.2010.03322.x.
- Spritzer, D.; Bilefsky, D. Czechs See Peril in a Bootleg Bottle. The New York Times. USA September 17, 2012.
- Collins, B. Methanol Poisoning: The Dangers of Distilling Spirits at Home. ABC. Australia June 13, 2013.
- Gryniewicz-Ruzicka, C. M.; Arzhantsev, S.; Pelster, L. N.; et al. Multivariate Calibration and Instrument Standardization for the Rapid Detection of Diethylene Glycol in Glycerin by Raman Spectroscopy. Appl Spectrosc 2011, 65 (3), 334–341. https://doi.org/10.1366/10-05976.
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