Spectrometry

New Method‌ Allows Real-Time Boron ⁢Measurement in individual Cancer Cells, Advancing BNCT Research

Researchers at the University of⁣ Birmingham ⁤have developed a ⁤novel technique enabling the real-time measurement of boron levels within individual cancer cells.⁣ This breakthrough, ⁤detailed in a recent article ⁣published in the Journal of ​Analytical ⁤atomic Spectrometry, promises too ‍improve understanding ​of how Boron Neutron Capture​ therapy ​(BNCT) functions and ⁣optimize⁣ its effectiveness as a precision treatment for head and neck cancers.

BNCT​ is an emerging cancer therapy ⁤where patients ingest a boron-containing drug designed to accumulate within tumor cells. Subsequently, the tumor is exposed ​to neutron⁤ radiation, which interacts with‍ the ⁤boron, selectively ⁢destroying the cancer‍ cells. ⁢The ⁤success of BNCT hinges on ‍sufficient boron‌ uptake and retention within the tumor cells during neutron irradiation.

Previously, boron levels were only ⁣measurable ‍as an average⁤ across large populations of cells – hundreds‍ of thousands‍ – obscuring crucial variations between​ individual cells. The new ‍technique, called‍ single-cell ICP-MS, overcomes⁢ this limitation.

“Until now,‍ it’s only been possible to measure average boron uptake in hundreds-of-thousands of cells, which masks important‌ differences between ​individual cells. Our ‌single-cell approach reveals this ‍variability, which is critical in a tumor setting where heterogeneity frequently enough determines whether treatment works or fails,” explained Dr. James Coverdale of the University of Birmingham’s School ⁤of ⁣Pharmacy. “We beleive ⁣the results‍ are exciting⁤ because we now have the first direct evidence of how much ⁤boron is‌ present in individual tumor ⁤cells, and how long‌ it stays there. This details could help⁤ to ⁢optimise when neutron​ irradiation should be delivered relative to‌ drug ‍administration. By showing which‍ transport pathways bring boron ⁣into cells, the ​work also offers clues ⁢for⁢ designing better​ drugs that accumulate⁢ more effectively. ⁣For⁤ the cancer drug discovery ​community, this study ⁤opens⁤ a‍ new way⁢ of evaluating BNCT drug⁢ candidates.”

A ‍critically important‍ challenge⁤ in developing the technique was maintaining cell viability during the sensitive measurement process. The team successfully addressed this by carefully optimizing the cell culture medium and the method of introducing cells into the instrument, preventing rapid cell ‍deterioration and ensuring accurate data ⁤collection.

Jack Finch, co-first author⁤ of​ the study and a ​University of Birmingham ⁤Biochemistry alumnus, highlighted ⁣the technique’s potential: “This will be vital for testing ⁢and comparing future BNCT drugs and will help to ⁣identify the most effective treatments. Ultimately, our work supports progress toward making the already promising BNCT into ‍a more precise and effective cancer treatment.”

Head and neck ​cancer ‌is ‍a significant health concern in the UK, representing the 8th most common cancer and accounting for ⁣3% of⁤ all​ new cancer cases between 2017⁣ and 2019, according to Cancer Research UK. This new technique, funded by the Rosetrees Trust, offers a promising avenue for improving treatment outcomes for patients battling this disease.

Source: Finch, J. G., et​ al. (2025). Kinetic analysis⁤ of boron ⁣therapeutics in ⁣head and neck cancer‌ cells by complementary bulk⁤ ICP-MS and single-cell (scICP-MS) approaches. ‍ Journal of Analytical Atomic Spectrometry. ⁣ doi.org/10.1039/d5ja00228a