By Dr. Maria G. Corradini, Arrell Chair in Food Quality, Department of Food Science; Dr. Robert Hanner, Department of Integrative Biology; Maleeka Singh, PhD candidate, Department of Food Science; Sujani Rathnayake, research assistant, Hanner Lab

This article is republished from The Conversation Canada under a Creative Commons licence. Read the original article.


a headshot of Dr. Maria Corradini
Dr. Maria Corradini

Maple syrup, Canada’s “liquid gold,” is among the 10 most adulterated foods globally.

Maple syrup’s desirability has made it a target for delinquent activities, including food fraud and theft. In 2011 and 2012, almost 3,000 tonnes of maple syrup were stolen from the Strategic Reserve in Québec.

The Great Maple Syrup Heist reflects the food’s status as a highly valuable commodity and the target of delinquent activities.

In addition to the threat posed to maple syrup by thieves and smugglers, unreliable production yields due to climate events have required establishing production quotas to stabilize pricing and supply. As a consequence, there have been reports of prohibition-style smuggling and sugar syrups labelled as maple syrup permeating the market. These actions cheat consumers and introduce food safety risks into the supply chain.

Consumers pay more for a lower value product. In addition, the introduction of other sugars or sugar syrups may pose risks to individuals with sugar sensitivities, as maple syrup has a lower glycemic index than white sugar or corn syrups.

Fingerprinting maple syrup glow

Dr. Robert Hanner stands outside the Centre for Biodiversity Genomics
Dr. Robert Hanner

As such, there is a need for the development of more accurate and rapid testing tools to monitor maple syrup fraud.

Our research team at the University of Guelph has been developing methods to detect maple syrup fraud. We use fluorescence fingerprinting, which analyzes how certain molecules in maple syrup glow when exposed to UV and visible light, to see if there is any potential maple syrup adulteration.

In UV light, maple syrup naturally glows. Fluorescence fingerprinting maps the intensity of the light emitted by these specific fluorescent (glowing) compounds, and can provide a unique 3D rendering of a sample’s composition while also reporting on its quality, safety and identity. Using key features found in the fluorescence fingerprints, we explored ways to better detect maple syrup adulteration even when the levels are as low as one per cent.

Our study examines the adulteration of dark and amber maple syrups with common maple syrup adulterants, at percentages ranging from one to 50 per cent.

Distinct fluorescence fingerprints were found for each tested syrup and mixture, revealing features that can be used to distinguish pure from adulterated samples.

Machine learning and identification

an aerial photo of a cup with glowing liquid
Maple syrup glows under UV light. (M. Singh), Author provided

The fluorescence fingerprints obtained when the samples were exposed to UV and visible light show several features (or peaks) that gradually changed in samples tampered with adulterants. We were able to correctly detect adulteration in 70 to 100 per cent of samples, depending on how the features were quantified and analyzed, by creating a fluorescence index or by using machine learning techniques.

To fully validate this approach, we will need to use larger datasets that will help us control for other factors — like the environments maple trees grow in — that may affect the content of the syrups.

Other common fingerprinting techniques, such as DNA barcoding that examines short DNA fragments, can detect adulteration in other foods, like fish or sausages. These methods don’t work well for maple syrup because the extensive processing required to transform sap into syrup potentially degrades the DNA.

PhD student Maleeka Singh

In contrast, fluorescence fingerprints rely on a food’s chemical composition, so identifying the presence of adulterants can happen even in highly processed samples.

Most foods naturally contain intrinsic fluorescent compounds, which means they glow under UV and visible light — the amount of and type of glow represent distinguishing characteristics.

Since using fluorescent fingerprinting only requires the use of light, it is a non-invasive, efficient and affordable strategy for checking whether maple syrup contains any other sugar syrups. It is also fast, providing information about a sample within minutes.

This approach can be applied at different points in the supply chain as part of quality assurance and control. This would ensure that consumers receive safe, high-quality foods, and that they are not cheated financially. Confirming the quality of maple syrup would also protect the brand reputation of Canadian products.

Maia Zhang, research assistant at the University of Guelph, co-authored this article.


The Conversation Canada is always seeking new academic contributors. University of Guelph researchers wishing to write articles should contact the U of G News Service.