| Feb 28, 2025 |
First nanosensor to distinguish Fe(II) and Fe(III) in plants enables real-time tracking, improving crop health, nutrient use, and applications in health and environment.
(Nanowerk News) Researchers from the Disruptive & Sustainable Technologies for Agricultural Precision (DiSTAP) interdisciplinary research group (IRG) of Singapore-MIT Alliance for Research and Technology (SMART), MIT’s research enterprise in Singapore, in collaboration with Temasek Life Sciences Laboratory (TLL) and Massachusetts Institute of Technology (MIT), have developed a groundbreaking near-infrared (NIR) fluorescent nanosensor capable of simultaneously detecting and differentiating between iron forms – Fe(II) and Fe(III) – in living plants.
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Iron is crucial for plant health, supporting photosynthesis, respiration, and enzyme function. It primarily exists in two forms: Fe(II), which is readily available for plants to absorb and use, and Fe(III), which must first be converted into Fe(II) before plants can utilise it effectively. Traditional methods only measure total iron, missing the distinction between these forms – a key factor in plant nutrition. Distinguishing between Fe(II) and Fe(III) provides insights into iron uptake efficiency, helps diagnose deficiencies or toxicities, and enables precise fertilisation strategies in agriculture, reducing waste and environmental impact while improving crop productivity.
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This first-of-its-kind nanosensor by SMART researchers enables real-time, non-destructive monitoring of iron uptake, transport, and changes between its different forms, such as Fe(II) and Fe(III) – providing precise and detailed observations of iron dynamics. Its high spatial resolution allows precise localisation of iron in plant tissues or subcellular compartments, enabling the measuring of even minute changes in iron levels within plants – these minute changes can inform how a plant handles stress and uses nutrients.
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| DiSTAP researchers develop sensors for rapid iron detection and monitoring in plants, enabling precision agriculture and sustainable crop management. (Image: SMART DiSTAP)
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Traditional detection methods are destructive or limited to a single form of iron. This new technology enables the diagnosis of deficiencies and optimisation of fertilisation strategies. By identifying insufficient or excessive iron intake, adjustments can be made to enhance plant health, reduce waste, and support more sustainable agriculture. While the nanosensor was tested on spinach and bok choy, it is species-agnostic, allowing it to be applied across a diverse range of plant species without genetic modification. This capability enhances our understanding of iron dynamics in various ecological settings, providing comprehensive insights into plant health and nutrient management. As a result, it serves as a valuable tool for both fundamental plant research and agricultural applications, supporting precision nutrient management, reducing fertiliser waste, and improving crop health.
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“Iron is essential for plant growth and development, but monitoring its levels in plants has been a challenge. This breakthrough sensor is the first of its kind to detect both Fe(II) and Fe(III) in living plants with real-time, high-resolution imaging. With this technology, we can ensure plants receive the right amount of iron, improving crop health and agricultural sustainability,” said Dr Duc Thinh Khong, DiSTAP research scientist and co-lead author of the paper.
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“In enabling non-destructive real-time tracking of iron speciation in plants, this sensor opens new avenues for understanding plant iron metabolism and the implications of different iron variations for plants. Such knowledge will help guide the development of tailored management approaches to improve crop yield and more cost-effective soil fertilisation strategies,” said Dr Grace Tan, TLL Research Scientist and co-lead author of the paper.
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The research, recently published in Nano Letters (“Nanosensor for Fe(II) and Fe(III) Allowing Spatiotemporal Sensing in Planta“), builds upon SMART DiSTAP’s established expertise in plant nanobionics, leveraging the Corona Phase Molecular Recognition (CoPhMoRe) platform pioneered by the Strano Lab at SMART DiSTAP and MIT. The new nanosensor features single-walled carbon nanotubes (SWNTs) wrapped in a negatively charged fluorescent polymer, forming a helical corona phase structure that interacts differently with Fe(II) and Fe(III). Upon introduction into plant tissues and interaction with iron, the sensor emits distinct NIR fluorescence signals based on the iron type, enabling real-time tracking of iron movement and chemical changes.
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The CoPhMoRe technique was used to develop highly selective fluorescent responses, allowing precise detection of iron oxidation states. The NIR fluorescence of SWNTs offers superior sensitivity, selectivity, and tissue transparency while minimising interference, making it more effective than conventional fluorescent sensors. This capability allows researchers to track iron movement and chemical changes in real-time using NIR imaging.
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“This sensor provides a powerful tool to study plant metabolism, nutrient transport, and stress responses. It supports optimised fertiliser use, reduces costs and environmental impact, and contributes to more nutritious crops, better food security, and sustainable farming practices,” said Professor Daisuke Urano, TLL Senior Principal Investigator, DiSTAP Principal Investigator, NUS Adjunct Assistant Professor, and co-corresponding author of the paper.
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“This set of sensors gives us access to an important type of signalling in plants, and a critical nutrient necessary for plants to make chlorophyll. This new tool will not just help farmers to detect nutrient deficiency but also give access to certain messages within the plant. It expands our ability to understand the plant response to its growth environment,” said Professor Michael Strano, DiSTAP Co-Lead Principal Investigator, Carbon P. Dubbs Professor of Chemical Engineering at MIT, and co-corresponding author of the paper.
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Beyond agriculture, this nanosensor holds promise for environmental monitoring, food safety, and health sciences, particularly in studying iron metabolism, iron deficiency, and iron-related diseases in humans and animals. Future research will focus on leveraging this nanosensor to advance fundamental plant studies on iron homeostasis, nutrient signaling, and redox dynamics. Efforts are also underway to integrate the nanosensor into automated nutrient management systems for hydroponic and soil-based farming and expand its functionality to detect other essential micronutrients. These advancements aim to enhance sustainability, precision, and efficiency in agriculture.
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