Combining optical coherence tomography (OCT) with another advanced imaging technology may more accurately identify coronary artery plaques that are most likely to rupture and cause a heart attack. In a report being published online in JACC Cardiovascular Imaging, investigators from the Wellman Center for Photomedicine at Massachusetts General Hospital (MGH) describe the first use in patients of a catheter-based device utilizing both OCT and near-infrared autofluorescence (NIRAF) imaging.
“OCT provides images of tissue microstructure but not of its chemical and molecular composition,” says Gary Tearney, MD, PhD, of the Wellman Center and the MGH Pathology Department, co-senior author of the paper. “Since both of those characteristics are needed to fully understand coronary artery disease, the combination of OCT with NIRAF could provide a more powerful tool for investigating coronary pathology.”
The detailed images provided by OCT are created by bouncing near-infrared light off the internal surfaces of blood vessels and can identify plaques that have the appearance of rupture-prone “vulnerable” plaques with the potential to cause a heart attack or sudden cardiac death. Fluorescence imaging techniques like NIRAF illuminate an artery with a specific wavelength of light to excite certain molecules, which respond by emitting different wavelengths. Since only certain molecules respond, the resulting signal provides information on the molecular composition of analyzed tissue.
Tearney’s team has been investigating whether the additional data provided by NIRAF could identify rupture-prone sites within arterial plaques – particularly fibroatheromas, advanced lesions consisting of a core of dead cells covered by an often-thin fibrous cap, which are particularly prone to rupture. In a previous study using coronary artery segments from cadavers, the investigators showed that the NIRAF signal was elevated in fibroatheromas and highest in those with thin fibrous caps. The current study is the first to investigate the use of NIRAF in living patients.
The study enrolled 12 patients receiving cardiac catheterization at the MGH between July 2014 and January 2015. In addition to the clinical procedures conducted to diagnose and/or treat the patients’ cardiac disease, Farouc Jaffer, MD, PhD, director of MGH Coronary Intervention and co-senior author of the paper, used the novel device developed by the Wellman/MGH team that acquires both OCT and NIRAF data to construct images of coronary arterial segments. The investigational procedure was identical to that used for conventional OCT imaging.
“Performing OCT-NIRAF imaging is just like conducting standalone coronary OCT imaging, and we are now able to obtain near-infrared fluorescence biological plaque information seamlessly integrated with OCT anatomical images, with no additional time required,” Jaffer says. “The clinical success of OCT-NIRAF should further pave the way forward for targeted near-infrared fluorescence molecular imaging using injectable molecular- or cellular-specific agents.”
The primary results of the study were confirmation that the procedure was as safe and as feasible to perform as conventional OCT. The OCT-NIRAF images revealed that the NIRAF signal was elevated in areas in which OCT results suggested the presence of a fibroatheroma, and even higher in lesions with thin caps or at sites of plaque rupture and clot formation. Several aspects of the NIRAF signal were different from the patterns produced by other coronary vascular imaging modalities, and more investigation is needed to determine the molecular underpinnings and clinical significance of NIRAF signal results. NIRAF was also elevated in sites showing evidence of inflammation, another potential biomarker of plaques likely to rupture.
“Overall we believe that the combined OCT-NIRAF examination provides information on molecules within arterial plaques and other features associated with a higher risk of an acute coronary event,” says Tearney, a professor of Pathology at Harvard Medical School and the Mike and Sue Hazard Family MGH Research Scholar. “But right now this is a hypothesis, and our findings need to be borne out in larger studies, which we plan to have underway later this year.”
Co-senior author Jaffer is a member of both the MGH Cardiovascular Research Center and the Wellman Center and an associate professor of Medicine at Harvard Medical School. Giovanni J. Ughi, PhD, of the Wellman Center is lead author of the JACC Cardiovascular Imaging paper. Additional coauthors are Hao Wang, PhD, Edouard Gerbaud, MD, Joseph Gardecki, PhD, Ali Fard, PhD, Ehsan Hamidi, PhD, Paulino Vacas-Jacques, PhD, and Mireille Rosenberg, PhD, all of the Wellman Center. Support for the study includes National Institutes of Health grants R01HL093717 and R01HL122388, American Heart Association grant 13GRNT1760040 and support from Canon USA. Patent applications covering the combined OCT-NIRAF have been filed.
Massachusetts General Hospital, founded in 1811, is the original and largest teaching hospital of Harvard Medical School. The MGH conducts the largest hospital-based research program in the United States, with an annual research budget of more than $800 million and major research centers in AIDS, cardiovascular research, cancer, computational and integrative biology, cutaneous biology, human genetics, medical imaging, neurodegenerative disorders, regenerative medicine, reproductive biology, systems biology, transplantation biology and photomedicine. In July 2015, MGH returned into the number one spot on the 2015-16 U.S. News & World Report list of "America's Best Hospitals."
Julie Cunningham, firstname.lastname@example.org, 617 724-6433