Peter A. Calabresi, professor of neurology at the Johns Hopkins University School of Medicine, and his colleagues used optical coherence tomography (OCT) to scan nerves deep in the back of the eye, applying special software they co-developed that is capable of assessing previously immeasurable layers of the light-sensitive retinal tissue. The scan uses no harmful radiation and is one-tenth the cost of an MRI. The software will soon be widely available commercially.
"The eye is the window into the brain and by measuring how healthy the eye is, we can determine how healthy the rest of the brain is," says Calabresi. "Eye scans are not that expensive, are really safe, and are widely used in ophthalmology, and now that we have evidence of their predictive value in MS, we think they are ready for prime time. We should be using this new quantitative tool to learn more about disease progression, including nerve damage and brain atrophy."
Calabresi and his team report measuring thickness or swelling of the inner nuclear layer of the retina in 164 patients with MS and 60 healthy controls, following changes in these tissues over four years. At the same time, they also used brain MRI to measure inflammation spots directly, and performed clinical tests to determine disability levels. The more inflammation and swelling the researchers found in the retinas of the MS patients, the more inflammation showed up in their brain MRIs. The correlation, they said, affirmed the value of the retinal scans as a stand-alone surrogate to assess brain damage. Having such information so easily available could allow physicians to accurately tell how far the disease has progressed, and to better advice patients about how they should proceed with their care.
In a second study, Calabresi and colleagues looked at eye and brain scans of 84 MS patients and 24 healthy controls. They focused on two other deep retinal layers, the ganglion cell layer + inner plexiform layer (GCL+IPL), and the peripapillary retinal nerve fiber layer (pRFNL). Greater cell wasting in those areas was strongly correlated with more atrophy in the gray matter of the brain, signifying more nerve damage from MS.
Calabresi says this finding is particularly important because neurodegeneration is so difficult to accurately gauge. In a young person with MS, the brain may be atrophying but may cause no symptoms because the brain is able to compensate for what is being lost. Ultimately, though, the loss of brain cells becomes apparent and is irreversible. Calabresi says that if he saw the kind of thickness on an eye scan indicating severe atrophy, he would consider a patient's prognosis less encouraging than someone with a healthy retina, and this information may guide physicians to treat more aggressively.
Calabresi says his findings could also shift how researchers approach MS, long believed to be caused by an immune system that wrongly attacks the fatty protein called myelin that insulates nerves and helps them send electrical signals that control movement, speech and other functions. The usefulness of the scans raises the possibility that there could be something else going on, as there is no myelin deep in the retina of the eye. If the immune system is going after something else along with myelin, it could help researchers find new medications to target the incapacitating symptoms of MS, such as blurred vision, numbness and weakness.
"It is really important to know what the immune system is attacking," he says. "The treatments we have right now are only moderately effective, so maybe we're not blocking the right kinds of cells."
MEDICA.de; Source: John Hopkins Medicine