Researchers from Tokyo Medical and Dental University (TMDU) demonstrate a thorough and non-invasive imaging technique to identify areas of the eye affected by diabetic retinopathy, a progressive eye disease associated with diabetes
Tokyo, Japan—Just as bright light can illuminate the depths of a darkened room, researchers in Japan have found that blue light can be used to probe the depths of the eye and uncover areas affected by diabetic retinopathy (DR), a leading cause of blindness.
In a new study published in Asia-Pacific Journal of Ophthalmology, researchers from Tokyo Medical and Dental University (TMDU) have revealed that blue images obtained by multicolor widefield scanning laser ophthalmoscopy (SLO) may be used to identify areas of DR-induced damage in a more extensive portion of the eye compared with previous methods.
Current eye imaging methods include fluorescein angiogram, which involves the injection of dye into the eye. SLO is a non-invasive approach that does not require dye, and multicolor widefield SLO represents an advancement of this technique in which red, blue, and green lasers are used to simultaneously capture images of a wide portion of the eye. Previous research has shown that blue images captured by conventional SLO may reveal hyporeflective areas in the eye indicative of damage associated with DR. Researchers at TMDU sought to further evaluate this finding using widefield SLO.
In this retrospective study, the researchers compared blue widefield SLO images and fluorescein angiogram images taken in people with diabetes. The morphology of the retina was also evaluated in some individuals with DR.
“We found that the hyporeflective areas in the blue widefield SLO images appeared to correspond with areas of ischemia in the fluorescein angiogram images of patients with DR,” explains Kyoko Ohno-Matsui, senior author. “We were pleased to find that the rate of concordance was high.”
Further evaluation of patient images showed that ischemic areas (i.e., areas of reduced blood flow) appeared to correspond with parts of the retina that were thin and partially disorganized.
“It’s possible that the blue wavelength of light can pass more easily through these thinned areas of the retina, which presents as hyporeflective areas in the SLO images,” says Horie.
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