Must you be nearsighted?

Are you doing all that you can to reduce or eliminate your degree of nearsightedness?

Some call it nearsightedness, some myopia, and still others use the British term shortsighted. In any case, it all means the same thing. Vision at far distance is blurred, while vision at near distance is clear.

All this is common knowledge, however, what is not commonly known is that some children who have been diagnosed as nearsighted are not nearsighted, and still, others have to go through increases in prescription every few months, making their lenses even thicker.

Functional nearsightedness

Children who have frequent increases in their eyeglass prescription are most often diagnosed as functionally nearsighted by behavioral or developmental optometrists.

Typically, functional nearsightedness may begin as early as 5 to 7 years of age and usually starts with a low amount of prescription. It is common to initially associate it with eyestrain and frontal headaches related to sustained reading, computer, or writing tasks. Copying from the blackboard may especially cause inaccuracy and fatigue.

The first symptom that usually occurs is reduced distance vision, only after sustained near vision tasks. Typically, vision gradually improves when sustained near visual activities are suspended. Over time, however, the blurred distance vision remains and eventually worsens with length and demand of the near visual task.

Functional nearsightedness is different than genetic, in that genetic myopia is passed on from one generation to the next, regardless of how one uses his eyes. The genetic form of nearsightedness usually starts earlier in life, with children 2 to 5 years of age, has an initial moderate to high prescription, and is typically unrelated to eyestrain associated with near vision tasks.

For you, the parent, to understand the process of functional nearsightedness, the association or linkage of your child’s inside (ciliary) muscle for focusing and outside (extra-ocular) muscles for coordination must be understood.

There are six outside muscles surrounding each eye and one muscle that is inside the eye, controlling focus. This process occurs because the internal and external eye muscle systems are linked, allowing one system to support and compensate for the other.

Typically, extra effort to focus is needed when there is a lack of ability to coordinate and turn the two eyes inward. If extra effort is put into focus, that effort will translate into an increased ability to turn the two eyes inward. However, over time, the increased focusing leads to an internal muscle spasm and ultimately becomes what some call structured-in myopia.

At this time we don’t understand how that occurs, but we do knew when it does occur. The functional focusing spasm becomes myopia.

To summarize, if I can’t coordinate my two eyes together, enabling them to look at the same point in space at the same time, I can elect to over-focus, increasing my ability to coordinate these 12 external muscles (six for each eye), assisting the two eyes to turn inward together, preventing double vision and associated symptoms, and creating eye strain.

Eyestrain, often associated with functional myopia, ultimately becomes translated into true structural myopia through this process.

Treatment

Treatment of functional nearsightedness is different than the genetic type. Whereas treatment for genetic myopia is typically compensated through a nearsighted spectacle lens, treatment for functional nearsightedness is through remediation of the eye muscle inefficiency and imbalance.

Treatment for functional myopia may include: a therapeutic eyeglass prescription (which may be in the form of a bifocal), vision therapy (training), and proper visual hygiene and diet designed to reduce stress and strain of the visual system.

Therapeutic lenses are designed to reduce the need to over focus, while vision therapy potentially eliminates the need to compensate one system for another, it can resolve the eye coordination difficulty.

Proper visual hygiene may include diffuse uniform lighting and proper posture. In addition, some recent research suggests a properly balanced diet rich in chromium may reduce myopic effects. Personality may as well play a role in a child’s ultimate development.

There is a lot that is not known about myopia and its development, however, there are proven programs and procedures that have been proven to reduce or eliminate myopia.

Join me in reducing myopia in children today.

Joel H. Warshowsky is a behavioral and developmental optometrist who is Associate Clinical Professor Emeritus and founding chief of Pediatrics at SUNY State College of Optometry, where he had taught for 37 years. He has served as an optometric consultant to numerous schools for child development throughout New York and New Jersey. He is a fellow of the American Academy of Optometry and College of Optometrists in Vision Development, and has three pediatric practices in Roslyn, New York, Ringwood, New Jersey, and Riverdale.