Sucrose is a vital energy source in plants. It also drives growth and serves as an important signaling molecule during stress and development. Sucrose is a key product of photosynthesis and the primary form of sugar used for long-distance transport in plants. As such, its movement through plant tissues reveals much about its internal state. Yet, despite its importance, tracking sucrose in real time within living plants remains a persistent challenge.
One major challenge is the limited availability of in vivo sensors capable of capturing subtle physiological events, such as the movement of sucrose through plant tissues. Current techniques rely on destructive sampling or short-lived measurements. But sugars such as sucrose are dynamic—they shift depending on the time of day, light exposure, and plant developmental stage. So, the big question is whether these fluctuations can be measured continuously, in real time, especially to test emerging hypotheses about how plants absorb water and solutes through unexpected pathways like leaf stomata.
Now, researchers from Waseda University, led by Professor Takeo Miyake, and collaborating institutions have developed a flexible, needle-type enzymatic biosensor that can be inserted into plant tissues and report sucrose concentrations in real time. Miyake’s team at Waseda University included Shiqi Wu, Wakutaka Nakagawa, Dr. Saman Azhari, and Dr. Gábor Méhes. Professor Tomonori Kawano from the University of Kitakyushu and Yuta Nishina from Okayama University were also part of the team. Their findings were published in the journal Biosensors and Bioelectronics and made available online on June 8, 2025.
The biosensor integrates a multi-enzyme anode—glucose oxidase, invertase, and mutarotase—capable of catalyzing sucrose down to glucose and detecting its presence electrochemically. The cathode was bilirubin oxidase-based and worked with a unique agarose gel interface. The novel sensor achieved a high sensitivity, a detection limit of 100 µM, a detection range up to 60 mM, a response time of 90 seconds, and stable operation for over 72 hours. The device could be smoothly inserted into stems and fruits of plants with minimal damage.
“We designed the sensor specifically to capture sucrose uptake through stomata, which is a largely unexplored pathway,” says corresponding author Miyake. “The performance metrics were important, but what excites us most is the new biology it helped uncover.”
Using the sensor, the team observed a daily rhythm in sucrose transport within the stems of strawberry guava (Psidium cattleianum). Sucrose levels peaked during nighttime, consistent with the redistribution of photosynthetically generated sugars—a pattern that matches known growth cycles in many plants.
Further interesting findings came from experiments with the Japanese cedar (Cryptomeria japonica). Here, the researchers immersed cedar leaves in a sucrose solution and alternated between light and dark conditions. The biosensor, embedded in the plant’s stem, detected rising sucrose concentrations only during light exposure, when stomata are known to open. This suggested that sucrose could enter through the leaves and be transported internally, demonstrating stomatal-mediated sucrose uptake in a higher plant for the first time.
To confirm that water—and the dissolved sucrose—was indeed entering through stomata, the researchers used water labeled with the stable isotope oxygen-18. Analysis showed higher isotope levels in illuminated leaves, further supporting the hypothesis. They also observed a time lag of around 45 minutes between light exposure and sucrose increase in the stem, matching known transport speeds in plant phloem.
“This is the first time we’ve been able to directly track soluble sugar uptake through stomata in real-time,” said Miyake. “It challenges long-standing assumptions about how plants acquire water and nutrients.”
The authors note that the current version of the sensor is designed for short-term lab experiments, but future iterations may include wireless transmission and reduced invasiveness, making it suitable for long-term monitoring in the field. They also point out that the presence of secondary metabolites in plant sap did not interfere significantly with the sensor’s accuracy, due to the selective enzyme design.
In the future, the researchers want to apply the sensor for monitoring sugar dynamics in roots, seeds, and reproductive organs of plants. This could help create new strategies in crop yield optimization, stress detection, and growth modeling. As Miyake puts it, “If we can measure what the plant is doing in real-time, we can start to think about growing crops more intelligently.”
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Reference
Authors: Shiqi Wu1, Wakutaka Nakagawa1, Yuki Mori2, Saman Azhari1, Gábor Méhes1, Yuta Nishina3,4, Tomonori Kawano2, Takeo Miyake1*
DOI: 10.1016/j.bios.2025.117674
Affiliations:
1Graduate School of Information, Production and Systems, Waseda University, Kitakyushu, Japan
2Faculty and Graduate School of Environmental Engineering, The University of Kitakyushu, Kitakyushu, Japan
3Research Institute for Interdisciplinary Science, Okayama University, Okayama, Japan
4Institute for Aqua Regeneration, Shinshu University, Matsumoto, Japan
About Waseda University
Located in the heart of Tokyo, Waseda University is a leading private research university that has long been dedicated to academic excellence, innovative research, and civic engagement at both the local and global levels since 1882. The University has produced many changemakers in its history, including eight prime ministers and many leaders in business, science and technology, literature, sports, and film. Waseda has strong collaborations with overseas research institutions and is committed to advancing cutting-edge research and developing leaders who can contribute to the resolution of complex, global social issues. The University has set a target of achieving a zero-carbon campus by 2032, in line with the Sustainable Development Goals (SDGs) adopted by the United Nations in 2015.
To learn more about Waseda University, visit https://www.waseda.jp/top/en
About Professor Takeo Miyake
Professor Takeo Miyake is a bioelectronics researcher at Waseda University’s Graduate School of Information, Production and Systems. An alumnus of Waseda, he earned his B.S., M.S., and Ph.D. in electrical and nanoengineering fields. He has held academic positions in Japan and the U.S., including at Tohoku University, University of Washington, and the University of California, Santa Cruz. His research focuses on biocompatible electronics, biofuel cells, and interfaces between electronics and living systems. He has published over 70 papers and received multiple honors, including Japan’s Young Scientists’ Prize.
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