TINY NEEDLES OFFER POTENTIAL NEW TREATMENT FOR TWO MAJOR EYE DISEASES
Needles almost too
small to be seen with the unaided eye could be the basis for new treatment
options for two of the world’s leading eye diseases: glaucoma and corneal
neovascularization.
The microneedles,
ranging in length from 400 to 700 microns, could provide a new way to deliver
drugs to specific areas within the eye relevant to these diseases. By targeting
the drugs only to specific parts of the eye instead of the entire eye, researchers
hope to increase effectiveness, limit side effects, and reduce the amount of
drug needed.
For glaucoma, which
affects about 2.2 million people in the United States and is the second leading
cause of blindness worldwide, the goal is to develop time-release drugs that
could replace daily administration of eye drops. A painless microneedle injection
made once every three to six months – potentially during regular office visits
– could improve treatment outcomes by providing consistent dosages, overcoming
patient compliance issues.
In the second disease,
corneal neovascularization, corneal injury results in the growth of unwanted
blood vessels that impair vision. To treat it, the researchers developed solid
microneedles for delivering a dry drug compound that stops the vessel growth.
“The power of
microneedles for treating eye conditions is the ability to target delivery of
the drug within the eye,” said Mark Prausnitz, a Regents’ professor in the
School of Chemical and Biomolecular Engineering at the Georgia Institute of
Technology. “We are developing different microneedle-based systems that can put
the drug precisely into the part of the eye where it’s needed. In many cases,
we hope to couple that delivery with a controlled-release formulation that
would allow one application to treat a condition for weeks or months.”
The research, which
was supported by the National Eye Institute of the National Institutes of
Health (NIH), was reported November 13 in the journal Investigative
Ophthalmology & Visual Science. The research was done using animal models,
and could become the first treatment technique to use microneedles for
delivering drugs to treat diseases in the front of the eye.
Glaucoma results from
elevated pressure inside the eye that can be treated by reducing production of
the aqueous humor fluid in the eye, increasing flow of the fluid from the eye,
or both. Glaucoma is now controlled by the use of eye drops, which must be
applied daily. Studies show that as few as 56 percent of glaucoma patients
follow the therapy protocol.
The microneedle
therapy would inject drugs into space between two layers of the eye near the
ciliary body, which produces the aqueous humor. The drug is retained near the
injection side because it is formulated for increased viscosity. In studies
with an animal model, the researchers were able to reduce intraocular pressure
through the injections, showing that their drug got to the proper location in
the eye.
Because the injection
narrowly targets delivery of the drug, researchers were able to bring about a
pressure reduction by using just one percent of the amount of drug required to
produce a similar decline with eye drops. The research team, which also
included Georgia Tech postdoctoral fellow Yoo Chun Kim and Emory University
Emeritus Professor of Ophthalmology Henry Edelhauser, hopes to produce a
time-release version of the drug that could be injected to provide therapy
lasting for months.
“The ultimate goal for
us would be for glaucoma patients visiting the doctor to get an injection that
would last for the next six months, until the next time the patient needed to
see the doctor,” said Prausnitz. “If we can do away with the need for patients
to use eye drops, we could potentially have better control of intraocular
pressure and better treatment of glaucoma.”
To treat corneal
neovascularization, the researchers took a different approach, coating solid
microneedles with an antibody-based drug that prevents the growth of blood
vessels. They inserted the coated needles near the point of an injury, keeping
them in place for approximately one minute until the drug dissolved into the
cornea.
In an animal model,
placement of the drug halted the growth of unwanted blood vessels for about two
weeks after a single application. In addition to the researchers already
mentioned, the corneal neovascularization research included Emory University
Professor of Ophthalmology Hans Grossniklaus.
While the research
reported in the journal did not include time-release versions of the drugs, a
parallel project is evaluating potential formulations that would provide that
feature.
Eye injections with
hypodermic needles much larger than the microneedles are routinely used to
administer compounds into the center of eye. These injections are well
tolerated, and Prausnitz expects the use of microneedles would also not cause
significant side effects.
“Increasingly, eye
drops are not able to deliver drugs where they need to go, so injections into
the eye are becoming more common,” said Edelhauser. “But hypodermic needles
were not designed for the eye and are not optimal for targeting drugs within
the eye.”
In contrast to the
larger hypodermic needles, the microneedles are tailored to penetrate the eye
only as far as needed to deliver the drugs to internal spaces within the layers
of the eye. For the glaucoma drug, for instance, the needle is only about half
a millimeter long, which is long enough to penetrate through the sclera, the
outer layer of the eye, to the supraciliary space.
Both potential
treatments would require additional animal testing before human trials could
begin.
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