Bedford Metals Corp. announced the successful completion and assessment of its VNIR (Visible Near Field Infrared) and SWIR (Shortwave Infrared) satellite investigation at the Ubiquity Lake Uranium Project, just south of the Athabasca Basin, Saskatchewan. The statistical analysis, conducted by Dr. Neil Pendock, PhD in Applied Mathematics, identified several key indicators for uranium mineralization.

The investigation revealed anomalous helium emissions and methane, the latter of which is interpreted as altered clays, particularly illite. At Ubiquity Lake, the principal target zone (TZ1) is a 3.6km northwest-trending fault, striking at an angle roughly 90 degrees to the Cable Shear fault. The satellite survey identified a large but well-defined methane gas anomaly that correlated strongly with the footprint of TZ1.

Methane gas is a marker for illite, which forms through hydrothermal alteration ? the primary mechanism responsible for uranium deposition in the Athabasca Basin region. Additionally, the survey revealed multiple highly anomalous helium blooms over TZ1 and other prospective areas, with the greatest intensities near radioactive boulder fields.

These boulder fields have been identified and confirmed through multiple prospecting surveys. Like radon gas, helium is a first-order decay product of uranium, and its presence strongly correlates with uranium deposits. Bedford remains committed to conducting all exploration activities to the highest environmental standards.

The Company is dedicated to minimizing its environmental footprint and ensuring that all operations are sustainable and responsible. Additionally, Bedford values its relationships with local communities and indigenous groups and is committed to working collaboratively to ensure that its activities benefit these stakeholders. Dr. Peter Born, P.Geo., is the designated qualified person as defined by National Instrument 43-101 and the president of the Company and is responsible for and has approved the technical information contained in this release.