Créditos de las imagenes: Dani Machlis/BGU.
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A team of researchers from Ben-Gurion University of the Negev (BGU) has developed a groundbreaking bio-sensing technology that predicts the response of cancer patients to anti-PD1, an immune checkpoint inhibitor (ICI) therapy, with significantly greater accuracy than current methods.
The study’s results were published late last week in the prestigious journal Science Advances.
The study was led by Bar Kaufman, a talented MD-Ph.D. student, and Master’s student Orli Abramov, under the guidance of Prof. Moshe Elkabets and Prof. Angel Porgador from the Faculty of Health Sciences at BGU, along with collaborators from Soroka Medical Center and Barzilai Hospital.
This bio-sensing technology, called the Immuno-checkpoint Artificial Reporter with overexpression of PD1 (IcAR-PD1), measures the binding functionality of PD1 ligands, PDL1 and PDL2, to their receptor PD1. The researchers found that assessing the functionality of PD1 ligands was an effective predictor to identify who will positively respond to anti-PD1 and will benefit from this treatment. The anti-PD1 is the leading immunotherapy (ICI) treatment in cancer patients, thus such achievement can impact the quality of life of thousands of cancer patients worldwide every day.
The IcAR technology is a groundbreaking development that enables the measurement of the functionality, in principle, of any immuno-modulator targets in medical oncology. What that means is that doctors can now use the IcAR-PD1 technology to predict which patients will respond best to anti-PD1 therapies and tailor treatments accordingly, while sparing non-responders from ineffective treatment. In the future, this bioassay technology may help predict responses to other ICI therapies and could be used to tailor personalized ICI treatment protocols.
The major advances of the IcAR technology are the accuracy and sensitivity along with its logistical simplicity. The technology enables the screening of substantial amounts of cancer samples without requiring fresh biopsies or biological material, making it accessible for medical care in Israel and abroad. By solving the logistical bottleneck, the researchers make the diagnostic tool easier for doctors to identify potential responders.