Researchers from the Indian Institute of Technology Guwahati have reportedly developed a perovskite-based approach to detecting harmful metals like mercury in living cells and the environment.
The team relied on perovskites' unique interaction with light, which enables them to serve as fluorescent probes inside living cells. However, their quick degradation in water has previously limited their applications. To address this, the researchers encapsulated the perovskite nanocrystals in silica and polymer coatings, significantly enhancing their stability and luminescent intensity in water. This modification ensures the nanocrystals maintain their functionality over extended periods, making them highly effective for practical use.
The enhanced nanocrystals emit a bright green light under specific wavelengths, enabling precise detection of mercury ions, which are hazardous even in minute concentrations.
Mercury exposure, whether through contaminated food, water, inhalation, or skin contact, poses severe health risks, including nervous system damage, organ dysfunction, and cognitive impairments. The team’s nanocrystals demonstrated remarkable sensitivity, detecting mercury levels as low as a few nanomolar concentrations.
Moreover, when tested on live mammalian cells, the nanocrystals were found to be non-toxic, preserving cell function while effectively monitoring mercury ions.
Prof. Saikat Bhaumik, Assistant Professor, Department of Physics, IIT Guwahati, said, “One of the standout features of these perovskite nanocrystals is their narrow emission linewidth, which is desirable for improving the sensitivity due to the high signal-to-noise ratio for metallic detection.”
Bhaumik said, “Traditional imaging methods often struggle with light scattering, making it difficult to capture clear images from deeper cell layers. The ability of the perovskite nanocrystals to undergo multiphoton absorption overcomes this limitation, allowing for sharper and more detailed imaging. These properties make them ideal for advanced fluorescence imaging in medical and biological research.”
The potential applications of this research extend beyond mercury detection. These nanocrystals could play a pivotal role in identifying other toxic metals in biological systems and could also be adapted for drug delivery, enabling real-time monitoring of treatment efficacy.
