Assay Uses Novel Method for Early Detection of Ovarian Cancer
By LabMedica International staff writers Posted on 05 Jul 2022 |
High-grade serious ovarian cancer (HGSOC) is the most aggressive of all ovarian cancers and accounts for up to 70% of all ovarian cancer cases. Nearly 50% of ovarian cancer is detected at stage III or stage IV with poor survival outcomes. Current surveillance methods, including CA125, a current standard of care for ovarian cancer diagnosis, and ultrasound, are not effective enough at detecting early-stage disease. Emerging methods for early cancer detection rely primarily on tumor DNA circulating in blood (ctDNA), which is scarce in early-stage cancers, costly to measure, and not reliably obtained from tumors that are not well vascularized. Now, an assay that uses a novel method of analyzing biomarkers based on individual extracellular vesicles (EVs) has substantially outperformed CA125 when distinguishing patients with early-stage HGSOC from women with benign conditions in a new study.
Mercy BioAnalytics, Inc.’s (Natick, MA, USA) novel Mercy Halo technology enables simultaneous detection of multiple cancer-related biomarkers co-localized on the surface of individual tumor-derived extracellular vesicles, which are abundant in circulation and can be readily measured. The Mercy Halo OC assay is designed to detect stage I/II ovarian cancer and to distinguish cancer from benign conditions.
The study found that the Mercy Halo OC assay displayed separation of HGSOC from benign adnexal masses and healthy controls that was superior to CA125. When run against a variety of off-target cancers and inflammatory conditions, it discriminated them from ovarian cancer in most instances When run in paired serum and plasma samples, the Mercy Halo OC assay had highly correlated signals with virtually no bias, indicating that it can be validated further in established blood biorepositories, which offers the potential to accelerate clinical study and development.
“These preliminary data suggest this approach may detect all stages of ovarian cancer with high sensitivity at a very high specificity and works equally well in both plasma and serum. Mercy’s assay shows promise in improving on CA125 by distinguishing stage I/II cancer from benign ovarian tumors and could have clinical utility for both early detection and surgical referral recommendation for benign and malignant ovarian tumors,” said Christine D. Berg, M.D., retired Chief, Early Detection Research Group, National Institutes of Health.
“Too many women today suffer, and ultimately lose their lives, as a result of the late detection of ovarian cancer. We are encouraged by the data of our most recent study comparing the Mercy Halo Ovarian Cancer assay to CA125 in detecting early-stage ovarian cancer and distinguishing it from benign disease,” said Paul Blavin, Chief Executive Officer of Mercy BioAnalytics. “Our unique approach, focused on co-localization to interrogate single extracellular vesicles, has important advantages over current early cancer detection methods, and our work thus far has fueled our passion for relieving suffering and saving lives through the early detection of cancer. We look forward to expanding our studies of the Mercy Halo Ovarian Cancer assay to include average risk, asymptomatic women who might benefit from an improved ovarian cancer screening paradigm.”
Related Links:
Mercy BioAnalytics, Inc.
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