News Release

Painless real-time proteomics may one day speed up cancer surgery

Peer-Reviewed Publication

American Society for Biochemistry and Molecular Biology

SpiderMass Device for Painless Mass Spectrometry of Living Tissue

image: Researchers at the University of Lille developed a device that enables ionization and MS analysis of proteins, lipids and metabolites from the outermost few microns of skin or other tissues. The device, called the SpiderMass, works by selectively exciting water in the tissue with a pulsed laser. The ions are aspirated and transferred to a mass spectrometer for analysis. Ionization leaves a white trail of dehydrated skin, but the traces disappear within a few minutes. Volunteers reported just a slight tingling sensation. view more 

Credit: Isabelle Fournier

Isabelle Fournier and her team are out to change surgical oncology.

"Better surgery is associated with better prognosis and higher survival," said Fournier, a professor at the University of Lille and co-director of a proteomics center of INSERM, the French national institute of health. Her laboratory has worked for several years on a device they call the SpiderMass that will enable surgeons to look for markers of cancer in a living patient's tissue, during an operation. In an article in Molecular & Cellular Proteomics, the team reports on an important step toward finding protein biomarkers during surgery.

Surgery to remove a primary tumor involves a wait. After the tumor and some healthy surrounding tissue are removed, the surgical team pauses while a pathologist checks the tissue margins under a microscope. Although this process is important for preventing recurrence of the cancer, it can add up to 45 risky minutes under anesthesia.

With the new device, Fournier said, "We think that it is possible to open the way to in vivo real-time proteomics," which could help surgeons find stray cancer cells faster, perhaps even as they make incisions.

Fournier's device uses mass spectrometry, which measures the mass of molecules from complex mixtures. But turning an in vivo tissue sample into gas phase ions for measurements can be a challenge. Until now, no one knew how to extract ions from living tissues without doing harm.

So Fournier's team got creative. Riffing on MALDI, an ionization strategy that uses a carrier molecule mixed with the analyte of interest, they decided to use the water that makes up a majority of human tissue as a carrier to produce a water-assisted laser desorption/ionization, or WALDI. If they could excite the water in a tiny area, it should vaporize, taking ionized organic molecules with it.

"It was an idea at the beginning, and many people thought that it would not work," Fourier said. "Finally, we have it working beautifully."

The team built a pulsed laser excitation device tuned to heat water precisely by causing vibration in the oxygen-hydrogen bond. In a 2016 paper, they described using this laser to ionize the outermost layer of tissue, penetrating less than one-twentieth of a millimeter. The human volunteers reported a slight tingling sensation. But the ions that appeared were mostly small molecules and lipids, which are more apt than proteins to adopt a negative charge. The team hoped to measure proteins as well.

In this new paper, Fournier and colleagues report that they have cracked the protein puzzle. By using a more sensitive mass spectrometer and looking for positively instead of negatively charged ions, they found peaks representing purified proteins they had introduced into a cow liver sample. Now that they know the proteins are detectable, the next step will be finding ways to amplify the protein signal over more abundant lipids and metabolites.

In the meantime, the device is already in use for four-legged patients. Fournier's lab has worked with the veterinary biotech company Oncovet Clinical Research to run a pilot trial, comparing biopsies from pet dogs with sarcoma to healthy tissues. The team developed a lipidomics- and metabolomics-based classification system to robustly identify healthy, necrotic and cancerous tissues. Soon, they will introduce a prototype into a veterinary operating room. If it is successful there, Fournier said, she hopes to reach human clinics, improving tumor removal surgery to give patients better health outcomes.

See a video about the Spidermass here.

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About Molecular & Cellular Proteomics

Molecular & Cellular Proteomics (MCP) showcases research into proteomes, large-scale sets of proteins from different organisms or biological contexts. The journal publishes work that describes the structural and functional properties of proteins and their expression, particularly with respect to developmental time courses. Emphasis is placed on determining how the presence or absence of proteins affect biological responses, and how the interaction of proteins with their cellular partners influences their functions. For more information about MCP, visit http://www.mcponline.org.

About the American Society for Biochemistry and Molecular Biology

The ASBMB is a nonprofit scientific and educational organization with more than 11,000 members worldwide. Most members teach and conduct research at colleges and universities. Others conduct research in government laboratories, at nonprofit research institutions and in industry. The Society publishes three journals: the Journal of Biological Chemistry, the Journal of Lipid Research, and Molecular and Cellular Proteomics. For more information about ASBMB, visit http://www.asbmb.org.


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