Special Glasses Help Surgeons Visualize Cancer
By MedImaging International staff writers Posted on 27 Feb 2014 |
Image: Breast surgeon Julie Margenthaler, MD, visualizing cancer cells (Photo courtesy of WUSTL - Washington University in St. Louis).
High-tech glasses may help surgeons distinguish cancer cells from healthy cells by making them glow blue when viewed through the eyewear.
Developed by researchers at Washington University (St. Louis, MO, USA), the technology, called optical projection of acquired luminescence (OPAL), incorporates custom video technology, a head-mounted display, and a targeted molecular contrast agent that attaches to cancer cells, making them glow blue when irradiated with a special light. The resulting fluorescence intensity maps are projected onto the imaged surface and viewed through the glasses, rather than via wall-mounted display monitors.
To demonstrate the proof-of-principle for OPAL applications in oncologic surgery, lymphatic transport of indocyanine green was visualized in live mice for real-time identification of sentinel lymph nodes. Subsequently, peritoneal tumors in a murine model of breast cancer metastasis were identified using OPAL following systemic administration of a tumor-selective fluorescent molecular probe. The researchers noted that tumors as small as one mm in diameter could be detected. The study was published in the December 2013 issue of the Journal of Biomedical Optics.
“These initial results clearly show that OPAL can enhance adoption and ease-of-use of fluorescence imaging in oncologic procedures relative to existing state-of-the-art intraoperative imaging systems,” said lead author professor of radiology and biomedical engineering Samuel Achilefu, PhD. “This technology has great potential for patients and health-care professionals. Our goal is to make sure no cancer is left behind.”
“We’re in the early stages of this technology, and more development and testing will be done, but we’re certainly encouraged by the potential benefits to patients,” said associate professor of surgery Julie Margenthaler, MD, who performed the first in-human operation using the system at the WUSTL Barnes-Jewish Hospital (St. Louis, MO, USA) on February 10, 2014. “Imagine what it would mean if these glasses eliminated the need for follow-up surgery and the associated pain, inconvenience, and anxiety.”
Related Links:
Washington University
Barnes-Jewish Hospital
Developed by researchers at Washington University (St. Louis, MO, USA), the technology, called optical projection of acquired luminescence (OPAL), incorporates custom video technology, a head-mounted display, and a targeted molecular contrast agent that attaches to cancer cells, making them glow blue when irradiated with a special light. The resulting fluorescence intensity maps are projected onto the imaged surface and viewed through the glasses, rather than via wall-mounted display monitors.
To demonstrate the proof-of-principle for OPAL applications in oncologic surgery, lymphatic transport of indocyanine green was visualized in live mice for real-time identification of sentinel lymph nodes. Subsequently, peritoneal tumors in a murine model of breast cancer metastasis were identified using OPAL following systemic administration of a tumor-selective fluorescent molecular probe. The researchers noted that tumors as small as one mm in diameter could be detected. The study was published in the December 2013 issue of the Journal of Biomedical Optics.
“These initial results clearly show that OPAL can enhance adoption and ease-of-use of fluorescence imaging in oncologic procedures relative to existing state-of-the-art intraoperative imaging systems,” said lead author professor of radiology and biomedical engineering Samuel Achilefu, PhD. “This technology has great potential for patients and health-care professionals. Our goal is to make sure no cancer is left behind.”
“We’re in the early stages of this technology, and more development and testing will be done, but we’re certainly encouraged by the potential benefits to patients,” said associate professor of surgery Julie Margenthaler, MD, who performed the first in-human operation using the system at the WUSTL Barnes-Jewish Hospital (St. Louis, MO, USA) on February 10, 2014. “Imagine what it would mean if these glasses eliminated the need for follow-up surgery and the associated pain, inconvenience, and anxiety.”
Related Links:
Washington University
Barnes-Jewish Hospital
Latest General/Advanced Imaging News
- Radiation Therapy Computed Tomography Solution Boosts Imaging Accuracy
- PET Scans Reveal Hidden Inflammation in Multiple Sclerosis Patients
- Artificial Intelligence Evaluates Cardiovascular Risk from CT Scans
- New AI Method Captures Uncertainty in Medical Images
- CT Coronary Angiography Reduces Need for Invasive Tests to Diagnose Coronary Artery Disease
- Novel Blood Test Could Reduce Need for PET Imaging of Patients with Alzheimer’s
- CT-Based Deep Learning Algorithm Accurately Differentiates Benign From Malignant Vertebral Fractures
- Minimally Invasive Procedure Could Help Patients Avoid Thyroid Surgery
- Self-Driving Mobile C-Arm Reduces Imaging Time during Surgery
- AR Application Turns Medical Scans Into Holograms for Assistance in Surgical Planning
- Imaging Technology Provides Ground-Breaking New Approach for Diagnosing and Treating Bowel Cancer
- CT Coronary Calcium Scoring Predicts Heart Attacks and Strokes
- AI Model Detects 90% of Lymphatic Cancer Cases from PET and CT Images
- Breakthrough Technology Revolutionizes Breast Imaging
- State-Of-The-Art System Enhances Accuracy of Image-Guided Diagnostic and Interventional Procedures
- Catheter-Based Device with New Cardiovascular Imaging Approach Offers Unprecedented View of Dangerous Plaques