In a major advance applying insights from quantum physics to the inner workings of biology, a team of WashU researchers has successfully implanted quantum sensors in living cells to measure shifts in magnetism and temperature. The measurements could offer new insights into the efficiency of cellular metabolism in health and disease.

“We were able to accurately measure quantum-level properties within our nanodiamond sensors in living cells,” said Shakil Kashem, a graduate student in physics in Arts & Sciences at Washington University in St. Louis and co-lead author of a preprint posted to bioRxiv. The other lead author is Stella Varnum, a recent WashU immunology Ph.D. graduate.

The measurements focused on mitochondria, the energy-producing organelles within cells. “This approach could help us better understand mitochondrial function in health and in diseases linked to mitochondrial dysfunction, such as heart failure, Type 2 diabetes and metabolic diseases.”

Kashem presented the research March 16 at the 2026 annual meeting of the American Physical Society, held in Denver.

Co-senior authors of the paper include Kashem’s adviser, Chong Zu, an assistant professor of physics; Shankar Mukherji, also an assistant professor of physics; and Jonathan Brestoff, an associate professor of pathology and immunology at WashU Medicine. Other key contributors include physics graduate student Changyu Yao and David Piston, the Edward J. Mallinckrodt, Jr. Professor, head of cell biology and physiology at WashU Medicine and co-director of the Center for Quantum Leaps.

To achieve the unprecedented measurements, the team harnessed the quantum powers of nanodiamonds. Each diamond was blasted with nitrogen ions that knocked carbon atoms from the crystal lattice. The resulting vacancies trap electrons that are extremely sensitive to their surroundings, including changes in temperature and fluctuations in magnetic fields.

To insert the diamonds into living mouse cells, the team enlisted help from biology. “We used macrophages, immune system cells that eat bacteria,” said Mukherji, who specializes in cellular functions. “When we mixed nanodiamonds with macrophages in a test tube, the macrophages quickly consumed them, placing the sensors inside the cells.”

The researchers then used a special microscope to track how the electrons within the diamond responded to their new environment. As predicted, the quantum biosensors detected subtle shifts in magnetism and temperature driven by mitochondria—the cell’s energy powerhouses. “The really exciting thing is that we could measure both magnetism and temperature in the same sample,” Mukherji said.

Several chemical reactions inside mitochondria can influence temperature and magnetism. For example, the organelles create and transport iron-containing compounds, a process that produces extremely small magnetic fluctuations. “We’re measuring the magnetic noise that reflects metabolism inside the cell,” Kashem said.

Scientists have long tried to measure these signals inside cells, but many techniques can disrupt cellular function.

In his lab, Brestoff had tried unsuccessfully to measure temperature changes inside cells using near-infrared cameras. In a casual conversation with a mutual colleague at a St. Louis playground, Zu heard about that project and its many frustrations.

“I reached out to Jonathan (Brestoff) to tell him about our nanodiamonds, and the collaboration was born,” Zu said. “We’ve been trying to introduce these sensors to a range of experts outside of physics. We’re looking for people who can embrace this quantum leap.”

The study goes beyond a simple proof of concept, Kashem said. It revealed previously unknown nuances in mitochondrial metabolism that could point researchers toward new lines of inquiry.

“Our findings suggest that the movement of iron-containing molecules seems to play an important role in metabolism,” he said. “We want to create a new technique for measuring mitochondrial health, which could lead to novel therapies.”

Future progress with biosensors will depend on collaboration across multiple disciplines—the kind that made this study possible.

“It takes physicists to build and optimize the sensing platform, engineers to design the microscope, and biologists to interpret the results,” Kashem said. “Fortunately, we have all of that expertise here at WashU.”

In back-to-back studies published in Nature, researchers from Purdue University and Columbia University report a naturally evolved gene-editing system that can activate genes, offering an advantage over existing CRISPR gene-editing systems that merely find and cut DNA. The research includes two complementary studies, one examining the biological function of the system and the other revealing the molecular mechanism that enables it.

The team’s research on a variant of the CRISPR—Clustered Regularly Interspaced Short Palindromic Repeats—system broadens understanding of CRISPR’s natural diversity and provides a foundation for new gene-regulation technologies. Because this CRISPR variant activates genes without cutting DNA, it could be adapted for precise gene control applications, including research tools and potential therapeutic strategies that turn on genes without permanently altering the genome.

One study shows that this CRISPR system, using a strand of RNA as a guide, finds specific sections of DNA, known as genes, and attracts the cell’s own gene expression machinery to the location to activate the gene. The second study explains how the molecular complex performs this task, revealing how its structure allows it to recruit RNA polymerase—the enzyme responsible for transcribing DNA into RNA—to initiate gene expression.

Chang, with contributions from postdoctoral researcher Renjian Xiao and Ph.D. student Dan Xie, used a combination of cryo-electron microscopy and biochemical experiments to uncover the structural and mechanistic basis of this RNA-guided gene activation system.

Using cryo-electron microscopy, the researchers visualized the multiprotein complex at near-atomic resolution, revealing how the RNA guide directs the complex to a specific DNA sequence and positions it to engage the cell’s transcription machinery. Biochemical experiments further demonstrated how this interaction triggers gene activation.

“In traditional CRISPR, RNA guides the complex to a DNA target to cut it. Here, the RNA still directs the complex to the target, but instead of cutting the DNA, it recruits the cell’s transcription machinery to activate gene expression,” said Chang. “It’s like switching from molecular scissors to a GPS-guided activation switch.”

The studies also show that this system can activate transcription even at genomic locations that lack a kind of genetic signpost known as a promoter sequence, which is normally required to start gene expression. The findings highlight an unexpected diversification of CRISPR systems in nature, demonstrating that some have evolved to control gene activity rather than cut DNA.

“Our goal is to understand the fundamental mechanisms of RNA-guided molecular machines,” Chang said. “By defining how these systems work at a molecular level, we can lay the groundwork for safer and more versatile genome engineering technologies.”

Soil salinity is a critical concern in agriculture when excessive soluble salts restrict a plant’s water uptake, according to the U.S. Department of Agriculture, hindering crop growth and reducing yields on roughly 30% of U.S. irrigated land. Caused by irrigation, poor drainage or saltwater intrusion, soil salinity impacts soil structure, reduces fertility and causes economic losses. To help growers identify and mitigate salt stress, in a proof-of-concept study, a team led by Penn State researchers built a low-cost sensor system that detects signals released by plants in trouble.

Low-cost ‘electronic nose’ for crops

The sensor works by detecting specific gases, called volatile organic compounds, emitted by plants. The researchers reported that not only do salt-stressed plants give off different gas patterns than unstressed plants, but that their low-cost sensor system can detect the difference. They reported their findings in IEEE Sensors Journal.

“The low-cost sensor system we developed detects volatile organic compounds released by plants when stressed—think of it like an electronic nose for crops that ‘smells’ gases put off by plants in distress and can warn farmers of salt stress early, before visible damage occurs,” said co-author Francesco Di Gioia, Penn State associate professor of vegetable crop science. “Salinity stress is a major issue in many regions and coastal areas around the world, and most vegetable crops are highly susceptible to the accumulation of salts like sodium chloride, which hinder nutrient uptake and decrease productivity.”

Study first author Ali Ahmad, a researcher and doctoral student at the Polytechnic University of Valencia in Spain, conducted this research in Di Gioia’s lab in the College of Agricultural Sciences as a visiting scholar at Penn State. He selected arugula—a cruciferous leafy green commonly used raw in salads—to use in the experiment. It was grown in a hydroponic greenhouse managed by the Department of Plant Science.

“We used a hydroponic system for the experiment to be able to control the level of salinity and exclude other factors, to be sure that what we were detecting on the plants’ volatile profile was determined by the difference in salinity levels,” Ahmad said.

Inside the greenhouse stress experiment

The researchers induced salt stress by adding two different amounts of sodium chloride to the nutrient solutions feeding the plants, creating a moderately stressed group and a strongly stressed group. A third set of plants—a control group—was not exposed to salt. Plants were placed under dome enclosures that captured gases they released, measured by low-cost gas sensors at the top of the domes. These sensors measured changes in air chemistry caused by volatile organic compounds released by the plants for eight days.

“We studied metal-oxide semiconductor sensors because they are small and easy to deploy, widely available online and very cheap—some under $1,” Ahmad said, explaining the sensors detect even minuscule gas changes because they initiate different electrical signals in the semiconductor layer of the sensor. “That means farmers could potentially deploy many sensors across a field. But before they could become a major tool in precision agriculture, technical improvements are needed in sensor hardware and networks.”

AI reads gas patterns from plants

The researchers reported that the sensors detected different gas patterns depending on salt stress level, with three distinct patterns emitted from the healthy plants, the moderately stressed plants and the highly stressed plants, respectively. The researchers then trained machine learning models—a type of artificial intelligence (AI)—to recognize the gas patterns given off by salt-stressed plants.

To confirm the sensor system’s accuracy, the researchers measured the plants’ physical traits, such as growth, leaf condition and physiological responses, determining that the sensor network achieved up to 99.15% accuracy in identifying plant stress levels. Salt-stressed plants, eventually, exhibited visible signs of distress.

Wider promise for smart farming tools

In related work published in Advanced Sensor Research, the research team also evaluated the potential future use of low-cost metal-oxide semiconductor gas sensors for precision agriculture. In precision agriculture, which seeks to grow more crops while using fewer resources such as water, chemicals and energy, sensors could be used to detect plant problems like disease or other non-salt stress early.

That study by Di Gioia, Ahmad and colleagues suggests the same inexpensive gas sensors used in the more recent salt stress study could detect volatile organic compounds given off by healthy, sick and stressed plants dealing with drought, disease and pests. The ability to detect these different patterns of volatile organic compound emissions, combined with AI, could revolutionize farming—but only if current technical and practical limitations are overcome, according to Di Gioia.

“Very inexpensive gas sensors combined with artificial intelligence point to a promising future for smart farming,” said Di Gioia. “But right now, the technology isn’t fully reliable and there are significant challenges involved in setting up affordable networks, so more research and better data are needed. But if these problems are solved, this approach could become a major tool in precision agriculture.”