Sensor to detect cyanide in water & human cells developed by IIT-G reseachers

Guwahati, May 27: A team of researchers at the Indian Institute of Technology (IIT) Guwahati, led by Prof G Krishnamoorthy from the Department of Chemistry, has developed a highly responsive fluorescent sensor that can detect cyanide in water and human cells using only a UV light source.

The developed sensor changes colour and emits bright fluorescence in the presence of cyanide, contributing to both environmental safety and forensic investigations.

Cyanide is a highly toxic compound widely used in industrial processes, such as manufacturing of synthetic fibres, metal cleaning, plastics, electroplating, and gold mining. Improper disposal of cyanide often leads to its release into the environment, contaminating soil and water sources.

Consumption of this contaminated water can disrupt oxygen supply in the human body. Even a small amount can cause severe health effects or death.

Fluorescent chemosensors are chemicals that light up under light when they interact with specific chemicals. These sensors are popular due to their ease of use, low cost, high sensitivity, and potential for use in biological systems.

“While many existing sensors work by dimming their light, known as a ‘turn-off’ response when detecting substances, a ‘turn-on’ response, where the signal brightens instead, is often more effective because it avoids false negatives and improves detection clarity,” Prof Krishnamoorthy said.

The IIT Guwahati team has developed a ‘turn-on’ chemosensor based on a compound called 2-(4?-diethylamino-2?-hydroxyphenyl)-1H-imidazo-[4,5-b]pyridine, which gives a weak blue fluorescence under UV light.

In the presence of cyanide, this fluorescence turns on and shifts to a brighter cyan colour due to a chemical change in the molecule.

This reaction is highly specific to cyanide, especially in a carefully selected solvent system that includes water.

“The detection limit achieved in aqueous samples is as low as 0.2 micrometre (?M), which is much less than the World Health Organization permissible limit of 1.9 ?M in drinking water,” Prof Krishnamoorthy said.

The research team conducted a combination of lab experiments and advanced computational calculations, called DFT calculations, to confirm the sensing mechanism of the developed technology.

“What sets this sensor apart is its versatility. The sensor works not only in lab solutions but also in river and tap water samples, with an accuracy of 75 per cent to 93 per cent. It can be embedded into paper strips for portable testing and is effective in live cell imaging. In fact, the sensor was used to detect cyanide inside biological cells, showing promise for applications in environmental and forensic investigations,” Prof Krishnamoorthy said.

The researchers also demonstrated that this molecular sensor can function like a basic logic gate, a key element in digital electronics.

“This means it may have future use in developing smart, sensor-based electronic devices that can detect harmful chemicals like cyanide in real time,” Prof Krishnamoorthy said.

The study, published in Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, was conducted in collaboration with Prof Bithiah Grace Jaganathan of the Department of Bioscience and Bioengineering of IIT Guwahati.

Mongoli Brahma was the research scholar involved in the development of this sensor along with other research scholars, Arup Das Kanungo, Minati Das, and Sam P Mathew.

-By Staff Reporter