Honeybees can detect lung cancer: MSU researchers reveal groundbreaking findings

Lung cancer remains one of the leading causes of cancer-related deaths worldwide, with early detection being crucial for improving survival rates. Traditional diagnostic tools, while effective, can often be invasive, expensive, or limited in sensitivity at very early stages.

In a surprising and innovative breakthrough, researchers at Michigan State University (MSU) have discovered that honeybees can detect biomarkers in human breath linked to lung cancer. Even more remarkably, the insects can differentiate between different types of lung cancer cells using only their powerful sense of smell. This pioneering research, published in the journal Biosensors and Bioelectronics, could pave the way for non-invasive, rapid, and highly sensitive cancer diagnostics inspired by nature.

Honeybees’ super sense of smell: Detecting cancer in human breath

Honeybees are well known for their extraordinary sense of smell, which they use to detect flowers, pheromones, and even chemical changes in their hive. According to Debajit Saha, assistant professor at MSU’s College of Engineering and Institute for Quantitative Health Science and Engineering, bees share similarities with dogs in their ability to sense odours at incredibly low concentrations. By harnessing this natural ability, scientists wanted to test whether honeybees could distinguish between healthy human breath and breath containing chemical markers of lung cancer.

How scientists used synthetic human breath to test honeybees’ cancer detection

To carry out the experiments, Elyssa Cox, a former MSU lab manager, and Michael Parnas, a doctoral candidate, created a synthetic mixture that mimicked the breath of lung cancer patients. This mixture contained specific compounds such as trichloroethylene and 2-methylheptane, which are known to be present in the breath of individuals with lung cancer.Another mixture was created to represent healthy breath. Around 20 honeybees were then exposed to these synthetic breath samples.

Understanding honeybees' way of detecting cancer biomarkers

To study the bees’ neural responses, Cox designed a custom 3D-printed harness to hold live honeybees in place while tiny electrodes were attached to their brains. When the odours were passed over the bees’ antennae, the electrodes recorded neural firing patterns.The results were striking. Honeybees showed measurable changes in brain activity when exposed to cancer-associated compounds. Even more impressively, they could detect chemicals at concentrations as low as parts per billion, demonstrating an extraordinary level of sensitivity.

Distinguishing between lung cancer types

The research went a step further by testing whether honeybees could also differentiate between different lung cancer cell lines. With the help of Christopher Contag, director of MSU’s Institute for Quantitative Health Science and Engineering, lung cancer cell cultures were grown in airtight containers.Using the bee-brain sensor system, researchers successfully distinguished between small cell lung cancer, non-small cell lung cancer, and healthy cells.

This is a significant breakthrough because different lung cancer types require different treatment strategies, and early differentiation could lead to faster, more accurate interventions.

Implications for future cancer detection

The implications of this discovery are profound. According to Saha and his team, this work could lead to the development of non-invasive breath-based diagnostic tools. In the future, patients may simply need to breathe into a device containing a bee-brain-inspired sensor, which would then wirelessly transmit results to doctors in real time.Such technology could:

Why scientists chose honeybees over dogs for this research

While dogs have long been used in research for smell-based detection of diseases, honeybees provide a unique advantage. They are smaller, easier to study under controlled laboratory conditions, and their neural activity can be recorded directly with electrode-based sensors. This makes them a powerful biological model for advancing smell-based diagnostic technologies.Disclaimer: This article is for informational purposes only and does not constitute medical advice. Always consult a qualified healthcare professional before making any changes to your health routine or treatment.Also read | Health problems linked to poor posture: Back pain, digestion, breathing and more