BMR Research

The Body MRI group research links basic science with clinical MRI and industrial product development in an effort to provide improved techniques for patient care.  Our main focus areas are breast MRI, abdominal MRI, musculoskeletal MRI, MRI near metal, and the development of novel acquisition and reconstruction techniques for MRI.


Research Focus Areas

  • Breast MRI

    Breast cancer is the second leading cause of cancer deaths among American women after lung cancer according to the Center for Disease Control. Currently the most common breast cancer screening method is X-ray mammography; however, several studies have shown that MRI has much higher sensitivity for detecting cancer, especially in high-risk women.

  • MRI Near Metal

    The presence of metal can be a serious problem in MRI, because (1) Magnetic metals can experience a force in the scanner, (2) Long wires (such as in pacemakers) can result in induced currents and heating from the RF magnetic field and (3) Metals cause the static (B0) magnetic field to be inhomogeneous, causing severe image degradation.

  • Abdominal MRI

    There are many clinical indications for abdominal MRI, ranging from cancer to vascular abnormalities to emergency assessment. Abdominal MRI requires rapid imaging combined with other methods such as breath-holding, cardiac-triggered or respiratory-triggered imaging, and fat suppression in order to reliably show tissues of interest.

  • Musculoskeletal MRI

    Osteoarthritis (OA) is a major cause of disability - 75% of people over 60 will suffer from OA. In OA, articular cartilage degenerates, leaving no cushion for the joint to articulate, resulting in pain. Acute injuries such as ACL and meniscal tears increase the risk of OA. MRI offers excellent soft tissue contrast, and is the most accurate non-invasive way to image cartilage, menisci, ligaments and tendons.

  • Acquisition/Reconstruction

    In addition to numerous specific application areas, our group spends considerable time developing new MRI techniques that can be applied broadly. These include RF pulse design, MRI pulse sequences, reconstruction algorithms and image analysis tools, as well as "packages" that combine some of these elements.

Brian Hargreaves PhD

Associate Professor of Radiology, and (by courtesy) Electrical Engineering and Bioengineering

Contact Information

Lucas Center for Imaging 
1201 Welch Rd, Stanford, CA 94305-5488

Directions: Lucas Ctr. or Porter Dr. Locations