Our eyes, like the rest of us, inevitably change with time. And almost everyone is going to need some help seeing the computer screen or the morning paper as middle age rolls around.
Other problems can be prevented, stalled or fixed if you get the proper medical attention and take care of your vision, experts say.
Too many people wait until they fail the vision test when they go to renew their driver’s licenses before seeking help, said a professor of clinical optometry.
“People are living longer, so they need to use their eyes longer. If we look at World War II (population) statistics and project those onto baby boomers, we’re going to see a doubling in the rates of legal blindness,” .
“The sad thing is, it’s preventable. Don’t wait until your vision is blurry. Come on in.”
After age 65, people need a dilated eye exam once a year.
“There are changes that take place in the eyes and all of the tissues around the eyes that occur with aging,” said an ophthalmologist. “Eyelids become more puffy, more droopy, and they may not make good contact with the eye. Eyes become drier with time.”
On top of that, a muscle inside the eye that controls the focusing mechanism weakens over time (hence the reading glasses or bifocals), and the lens starts to turn cloudy, leading to cataracts.
“If you live a normal-length life, you will develop cataracts,”. Most people have cataract surgery around age 71.
Cataract surgery used to be much more complex, and patients were prone to infections and had to wear thick glasses after surgery. Now, most people do well with a quick operation in which their clouded lens is replaced with an artificial lens.
Common cataract symptoms include trouble seeing at night or while driving in the rain, seeing halos around lights and needing more light to read.
Annual eye exams are important for a number of reasons, particularly for screening for glaucoma, which does not have any symptoms. Those with glaucoma, cataracts or macular degeneration might need to be seen more frequently.
Besides scheduling an annual exam with an optometrist or ophthalmologist, people can help protect their vision by wearing sunglasses that guard against ultraviolet rays, avoiding cigarettes and living a generally healthy life.
“I tell patients: ‘Try to adhere to good general health practices. Control your blood sugar, control your blood pressure, control your cholesterol. Take a multivitamin usually. Do not smoke,’”.
Protection from the sun helps prevent and slow the development of cataracts and macular degeneration, a disease of the center of the retina that can lead to blindness.
Treatment for macular degeneration has come a long way. “There used to be very little we could do except diagnose it early.”
Now, eye doctors understand that nutritional supplements, including antioxidants and lutein, can slow the progression of dry macular degeneration, in which the retina wastes away.
In the rarer and more-severe form, which is called wet macular degeneration, new blood vessels form, impairing vision. Doctors can inject a cancer drug to stop the growth of blood vessels.
The procedure often has to be done repeatedly and is costly and burdensome, but “ the alternative is to go totally blind,”.
Other potentially blinding diseases that increase with age are diabetic retinopathy (caused by a thickening of the arteries and high blood pressure) and glaucoma, a condition in which fluid pressure inside the eye increases because of slowed drainage from the eye.
“Particularly with diabetes or glaucoma, the treatment goal is to keep it from getting worse, but you can’t get vision back once it’s gone,” .
Good control of diabetes is the key to preventing diabetic retinopathy, or stalling the disease once it has already shown up, he said.
Glaucoma can be found early only through pressure tests and by examining the optic nerve to see if there’s change over time. People with high blood pressure, heart disease or diabetes are at higher risk of developing the disease, as are African-Americans and Latinos.
Glaucoma can be treated with drops, but if they don’t control the pressure, a doctor might recommend a laser procedure or surgery.
A 66-year-old , was in for his annual eye exam a few years ago and learned that the pressure was up in both eyes. He went to an ophthalmologist and found out he had a precursor to glaucoma. Now, eyedrops are preserving his vision.
“I don’t know of any family history, so it caught me by surprise,”.
More primary-care physicians should do vision screening and talk about risks with patients. Even just reminding patients that they should go to an eye-care provider could help, he said.
“They could very well be wearing glasses they got 15 years ago.”
Age and eyes
Age-related macular degeneration damages sharp, central vision. It’s the leading cause of vision loss in older adults.
PARTS OF THE EYE
Cornea: clear, outer layer of the focusing system at the front of the eye
Iris: colored part of the eye that regulates amount of light that enters the eye
Pupil: opening at the center of the iris, which adjusts to control the amount of light that enters.
Lens: clear part behind the iris that helps to focus light and images on the retina
TYPES OF DEGENERATION
If you notice symptoms of age-related macular degeneration, contact an eye-care professional to schedule a dilated-eye exam.
WET
What it is: Abnormal blood vessels behind the retina grow under the macula and leak blood and fluid, which can displace and damage the macula.
What you see: Straight lines appear wavy.
Retina: light-sensitive tissue lining the back of the eye; converts light into electrical signals for the brain
Optic nerve: millions of bundled nerve fibers that transmit signals from the retina to the brain
Macula: sensitive area at the center of the retina that gives central vision
Fovea: macula’s center that gives the sharpest vision
DRY
What it is: Cells in the macula break down gradually, causing blurred central vision in the affected eye. Yellow spots under the retina, known as drusen, are detected; it occurs in stages.
What you see: As it progresses, a blurred spot might appear and grow in the center of vision; extra light might be needed to focus; faces can be difficult to recognize.
Sources: Columbus Dispatch Article 03/01/12
Sources: National Eye Institute; National Institutes of Health; American Academy of Opthalmology
Thursday, March 1, 2012
Thursday, December 8, 2011
What is a Slit Lamp...History of a Slit Lamp...iBEX LED Slit Lamps
What is a Slit Lamp
The slit lamp is an instrument consisting of a high-intensity light source that can be focused to shine a thin sheet of light into the eye. It is used in conjunction with a biomicroscope. The lamp facilitates an examination of the anterior segment, or frontal structures and posterior segment, of the human eye, which includes the eyelid, sclera, conjunctiva, iris, natural crystalline lens, and cornea. The slit-lamp examination provides a stereoscopic magnified view of the eye structures in detail, enabling anatomical diagnoses to be made for a variety of eye conditions. An additional hand-held lens is used to examine the retina.[1]
History of a Slit Lamp
To fully understand the development of the slit lamp one must consider that with this invention and its improvements, it had to be accompanied by the introduction of new examination techniques. Two conflicting trends emerged in the development of the slit lamp. One trend originated from clinical research and aimed at an increase in functions and the introduction and application of the increasingly complex and advanced technology of the time. The second trend originated from ophthalmologic practice and aimed at technical perfection and a restriction to useful methods and the applications of the instrument. The first man credited with developments in this field was Hermann Von Helmholtz (1850) when he invented the ophthalmoscope.
In ophthalmology and optometry, the term “slit lamp” is the most commonly referred to term however it would be more correct to call it the “slit lamp instrument”. Today’s instrument however is a combination of two separate developments in instruments. The two developments are the corneal microscope and that of the slit lamp itself. Though the slit lamp is a combination of these two developments, the first concept of the slit lamp dates back to 1911 credited to Alvar Gullstrand and his “large reflection-free ophthalmoscope.” The instrument was manufactured by the company Zeiss and consisted of a special illuminator that was connected by a small stand base through a vertical adjustable column. The base was able to move freely on a glass plate. The illuminator employed a Nernst glower which was later converted into a slit through a simple optical system. However, the instrument never received much attention and the term “slit lamp” did not appear and any literature again until 1914.
It wasn’t until 1919 that several improvements were made to the Gullstrand slit lamp made by Vogt Henker. First, a mechanical connection was made between lamp and ophthalmoscopic lens. This illumination unit was mounted to the table column with a double articulated arm. The binocular microscope was supported on a small stand and could be moved freely across the tabletop. Later, a cross slide stage was used for this purpose. Vogt introduced Koehler illumination, and the reddish shining Nernst glower was replaced with the brighter and whiter incandescent lampSpecial mention should be paid to the experiments that followed Henker’s improvements in 1919. On his improvements the Nitra lamp was replaced with a carbon arc lamp with a liquid filter. At this time the great importance of color temperature and the luminance of the light source for slit lamp examinations were recognized and the basis created for examinations in red-free light.
In the year 1926, the slit lamp instrument was redesigned. The vertical arrangement of the slit projector (slit lamp) made it an easy to handle instrument. For the first time, the axis through the patient’s eye was fixed at a common swiveling axis. This was a fundamental principle that was adopted for every slit lamp instrument developed. A limitation still with the instrument was it lacked a coordinate cross-slide stage for instrument adjustment but only a laterally adjustable chin rest for the patient. The importance of focal illumination had not yet been fully recognized.
In 1927, stereo cameras were developed and added to the slit lamp to further its use and application. In 1930, a man named Rudolf Theil presented the further development of the slit lamp was encouraged by a company named Goldmann. Horizontal and vertical co-ordinate adjustments were performed with three control elements on the cross-slide stage. The common swivel axis for microscope and illumination system was connected to the cross-slide stage, which allowed it to be brought to any part of the eye to be examined. A further improvement was made in 1938. A control lever or joystick was used for the first time to allow for horizontal movement.
Following World War II the slit lamp was improved again. On this particular improvement the slit projector could be swiveled continuously across the front of the microscope. This was then improved again in 1950. In 1950, a company named Littmann redesigned the slit lamp again. The adopted the joystick control from the Goldmann instrument and the illumination path present in the Comberg instrument. Additionally Littmann added the stereo telescope system with a common objective magnification changer.[
In 1965, the Model 100/16 Slit Lamp was produced based on the slit lamp by Littmann. This was soon followed by the Model 125/16 Slit Lamp in 1972. The only difference between the two models was their operating distances of 100 mm to 125 mm. With the introduction of the photo slit lamp further advancements were possible. In 1976, the development of the Model 110 Slit Lamp and the 210/211 Photo Slit Lamps were an innovation by which each were constructed from standard modules allowing for a wide range of different configurations. At the same time, halogen lamps replaced the old illumination systems to make them brighter and essentially daylight quality. From 1994 onwards, new slit lamps were introduced which took advantage of new technologies. The last major development was in 1996 in which included the advantages of new slit lamp optic.[2]
How Slit Lamp excellence was created
In 2005 iBEX LED Slit Lamps were introduced, designed and built by Appasamy & Associates in collaboration with Trevi Technology. With Appasamy’s 2500 employees and a 600+ research and development team leading the way, Appasamy and Trevi promote a creative environment where research, development, clinical testing and manufacturing work seamlessly. The work is carried out with one objective — to build performance products that enhance clinical eye exams.
With modern optical design typical of high end surgical microscopes, iBEX Slit Lamps deliver high definition observation with reduced reflections and the widest field of view. Ultimately, the user achieves improved diagnosis and less observation strain.
LED Illumination
The proprietary LED delivers the industry’s brightest and most uniform illumination. Wavelengths are full spectrum and synced to maximize anterior and posterior observation. Most importantly, heat to the patient’s eye has been reduced by nearly 80% less compared to traditional illumination, resulting in greater patient comfort during intense and prolonged observation.
EZ Shipping and Setup
We’ve made the process simple. iBEX Slit Lamps are 95% pre-assembled and shipped direct to your office by FedEx. Unpacking and installation takes 20 minutes or less.
To learn about LED Powered Slit Lamps….Contact:
Trevi Technology, Inc.
info@ibexeye.com
Certifications
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References:
1. Wikapedia
2. Wikapedia
1. Wikapedia
2. Wikapedia
Tuesday, December 6, 2011
How the human eye works
The human eye is the organ which gives us the sense of sight allowing us to see and interpret the shapes, colors, and dimensions of objects in the world by processing the light they reflect or emit. The eye is able to detect bright light or dim light, but it cannot sense objects when light is absent.
Light enters the eye
Light waves from an object enter the eye first through the cornea, which is the clear dome at the front of the eye. The light then progresses through the pupil, the circular opening in the center of the colored iris.
Fluctuations in incoming light change the size of the eye’s pupil. When the light entering the eye is bright enough, the pupil will constrict or get smaller, due to the pupillary light response.
Initially, the light waves are bent or converged first by the cornea, and then further by the crystalline lens (located immediately behind the iris and the pupil), to a nodal point (N) located immediately behind the back surface of the lens. At that point, the image becomes reversed (turned backwards) and inverted (turned upside-down).
The light continues through the vitreous humor, the clear gel that makes up about 80% of the eye’s volume, and then, ideally, back to a clear focus on the retina, behind the vitreous. The small central area of the retina is the macula, which provides the best vision of any location in the retina. If the eye is considered to be a type of a complex camera, the retina is equivalent to the film inside of the camera, registering the tiny photons of light interacting with it.
Within the layers of the retina, light impulses are changed into electrical signals. Then they are sent through the optic nerve, along the visual pathway, to the occipital cortex at the posterior (back) of the brain. Here, the electrical signals are interpreted or seen by the brain as a visual image.
Actually, then, we do not see with our eyes but, rather, with our brains. Our eyes merely are the beginnings of the visual process.
myopia, hyperopia, astigmatism
When the incoming light from a far away object focuses before it gets to the back of the eye, that eye’s refractive error is called “myopia” (nearsightedness). When incoming light from something far away has not focused by the time it reaches the back of the eye, that eye’s refractive error is “hyperopia” (farsightedness).
In “astigmatism,” one or more surfaces of the cornea or lens (the eye structures which focus incoming light) are not spherical (shaped like the side of a basketball) but, instead, are cylindrical or toric (shaped a bit like the side of a football). As a result, there is no distinct point of focus inside the eye but, rather, a smeared or spread-out focus. Astigmatism is the most common refractive error.
presbyopia
After age 40, and most noticeably after age 45, the human eye is affected by presbyopia. This natural condition results in greater difficulty maintaining a clear focus at a near distance with an eye which sees clearly far away.
Presbyopia is caused by a lessening of flexibility of the crystalline lens, as well as to a weakening of the ciliary muscles which control lens focusing. Both are attributable to the aging process.
An eye can see clearly at a far distance naturally, or it can be made to see clearly artificially, such as with the aid of eyeglasses or contact lenses, or else following a photorefractive procedure such as LASIK (laser-assisted in situ keratomileusis). Presbyopia eventually will affect the near focusing of every human eye.
eye growth
The average newborn’s eyeball is about 18 millimeters in diameter, from front to back (axial length). In an infant, the eye grows slightly to a length of approximately 19½ millimeters.
The eye continues to grow, gradually, to a length of about 24-25 millimeters, or about 1 inch, in adulthood. A ping-pong ball is about 1½ inch in diameter, which makes the average adult eyeball about 2/3 the size of a ping-pong ball.
The eyeball is set in a protective cone-shaped cavity in the skull called the “orbit” or “socket.” This bony orbit also enlarges as the eye grows.
extraocular muscles
The orbit is surrounded by layers of soft, fatty tissue. These layers protect the eye and enable it to turn easily.
Traversing the fatty tissue are three pairs of extraocular muscles, which regulate the motion of each eye: the medial & lateral rectus muscles, the superior & inferior rectus muscles, and the superior & inferior oblique muscles.
eye structures
Several structures compose the human eye. Among the most important anatomical components are the cornea, conjunctiva, iris, crystalline lens, vitreous humor, retina, macula, optic nerve, and extraocular muscles.
Thursday, November 17, 2011
IBEX LED SLIT LAMPS #1 SELLING SLIT LAMP
| Black Friday deals for all of November |
# 1 Selling Slit Lamp is now available direct in the U.S.
| industry's widest field of view Industry’s Only Micro-Surgical Optical Head Wide spectrum LED wavelengths for detailed anterior & posterior views iBEX 2 – Step LED Slit Lamp Now: $2,995.00 (Reg. $3,995) iBEX 5 – Step LED Slit Lamp Now: $4,495.00(Reg. $6,495) |  | |||
| Call Now 614-754-7175 (Monday-Friday 9-4:30 EST) | Email Us |   | ||
| Don’t let the low price fool you! After years of researching, developing and clinical testing, this slit lamp is built to perform! | ||||
| Check out the latest reviews – | ||||
| “When I first looked through the iBEX Slit lamp, I noticed the brighter, truer color of the LED light source immediately. This has made a big difference for me, especially on my anterior segment photography. It really is apparent when I look back at the more yellow colors of the pictures on my previous slit lamp. The next thing I noticed was the superior optics and easy binocularity, even in the higher magnifications.” Dr. Michael Raies | “The iBEX 2 Step Led Slit Lamp offered a view of the cornea I was not prepared for. The light source, and optical quality combination allowed me to see each layer of the cornea, better than any of my other slit lamps in the office. I kept finding myself moving patients to the lane with the Ibex, when i needed a more accurate view of the anterior segment”. Dr. Patrick Dollenmayer | |||
| Visit our web site to learn more why you should be examining your patients using the iBEX LED Slit Lamps at: www.trevitechnology.com     | ||||
Monday, October 31, 2011
iBEX LED Slit Lamps
iBEX LED Slit Lamps
With modern optical design typical of high end surgical microscopes,
iBEX LED Slit Lamps deliver high definition observation with reduced reflections and the widest field of view.
Ultimately, the user achieves improved diagnosis and less observation strain.
LED Illumination
The proprietary LED for iBEX Slit Lamps deliver the industry’s brightest and most uniform
illumination. Wavelengths are full spectrum and synced to maximize anterior and posterior observation.
Most importantly, heat to the patient’s eye has been reduced by nearly 80% less compared to traditional illumination, resulting in greater patient comfort during intense and prolonged observation.
EZ Shipping and Setup
We’ve made the process simple. Ibex slit lamps are 95% pre-assembled and shipped direct to your office by FedEx.Unpacking and installation takes 20 minutes or less.
www.iBEXeye.com
We provide Optometrist and Ophthalmologist with an efficient and pleasant alternative to traditional purchasing and distribution of their new eye exam slit lamps.
Our website is fast, informative and straightforward so that you can access product detail 24/7 –
even purchase products online.
With modern optical design typical of high end surgical microscopes,
iBEX LED Slit Lamps deliver high definition observation with reduced reflections and the widest field of view.
Ultimately, the user achieves improved diagnosis and less observation strain.
LED Illumination
The proprietary LED for iBEX Slit Lamps deliver the industry’s brightest and most uniform
illumination. Wavelengths are full spectrum and synced to maximize anterior and posterior observation.
Most importantly, heat to the patient’s eye has been reduced by nearly 80% less compared to traditional illumination, resulting in greater patient comfort during intense and prolonged observation.
EZ Shipping and Setup
We’ve made the process simple. Ibex slit lamps are 95% pre-assembled and shipped direct to your office by FedEx.Unpacking and installation takes 20 minutes or less.
www.iBEXeye.com
We provide Optometrist and Ophthalmologist with an efficient and pleasant alternative to traditional purchasing and distribution of their new eye exam slit lamps.
Our website is fast, informative and straightforward so that you can access product detail 24/7 –
even purchase products online.
Friday, October 14, 2011
reviews of advantages of a using a iBEX LED Slit Lamp
Check out these awesome reviews we are getting about the advantages of a using an iBEX LED Slit Lamp.....
Better for Slit Lamp Imaging
Oct 07, 2011
When I first looked through the iBEX Slit lamp, I noticed the brighter,
truer color of the LED light source immediately. This has made a big difference
for me, especially on my anterior segment photography. It really is apparent
when I look back at the more yellow colors of the pictures on my previous slit lamp.
Then next thing I noticed was the superior optics. Great quality and easy
binocularity …even in the higher magnifications.
The other advantage of the iBEX slit lamp doesn’t happen in the exam room.
It happens when I’m on the phone. The customer service at Trevi Technology is second
to none. These guys CARE about what they are doing. Sure, they make a great product, but
they also want to make a difference for the practitioner and the patient as well. Just read
their mission statement and you’ll see what I mean. Genuine guys you can trust. – Dr. Michael Raies, Portsmouth, OH
NEW Slit Lamp Outstanding!
Jun 18, 2011
Amazing quality slit lamp and a pleasure to work with this company
Beautiful
Jun 14, 2011
Beautiful Slit Lamp. Great Price & Great Packaging. Thanks!!
iBEX 2-Step Slit Lamp by iBEXeye.com
Click here to read about the
2-Step LED Slit Lamp
View of the Cornea Excellent
Sep 26, 2011
The iBEX 2 Step Led Slit Lamp offered a view of the cornea I was not prepared for.
The light source, and optical quality combination allowed me to see each layer of the cornea,
better than any of my other slit lamps in the office. I kept finding myself moving patients to
the lane with the Ibex, when i needed a more accurate view of the anterior segment. A keeper in
our office for sure, I recommend the iBEX Led Slit Lamp without reservation. – Dr. Patrick Dollenmayer, Columbus Ohio
Better for Slit Lamp Imaging
Oct 07, 2011
When I first looked through the iBEX Slit lamp, I noticed the brighter,
truer color of the LED light source immediately. This has made a big difference
for me, especially on my anterior segment photography. It really is apparent
when I look back at the more yellow colors of the pictures on my previous slit lamp.
Then next thing I noticed was the superior optics. Great quality and easy
binocularity …even in the higher magnifications.
The other advantage of the iBEX slit lamp doesn’t happen in the exam room.
It happens when I’m on the phone. The customer service at Trevi Technology is second
to none. These guys CARE about what they are doing. Sure, they make a great product, but
they also want to make a difference for the practitioner and the patient as well. Just read
their mission statement and you’ll see what I mean. Genuine guys you can trust. – Dr. Michael Raies, Portsmouth, OH
NEW Slit Lamp Outstanding!
Jun 18, 2011
Amazing quality slit lamp and a pleasure to work with this company
Beautiful
Jun 14, 2011
Beautiful Slit Lamp. Great Price & Great Packaging. Thanks!!
iBEX 2-Step Slit Lamp by iBEXeye.com
Click here to read about the
2-Step LED Slit Lamp
View of the Cornea Excellent
Sep 26, 2011
The iBEX 2 Step Led Slit Lamp offered a view of the cornea I was not prepared for.
The light source, and optical quality combination allowed me to see each layer of the cornea,
better than any of my other slit lamps in the office. I kept finding myself moving patients to
the lane with the Ibex, when i needed a more accurate view of the anterior segment. A keeper in
our office for sure, I recommend the iBEX Led Slit Lamp without reservation. – Dr. Patrick Dollenmayer, Columbus Ohio
Wednesday, September 28, 2011
Trevi Technology
Trevi Technology, a medical device company that co-develops and distributes ibex ophthalmic diagnostic devices. We operate under one key principle – substance over image. All clinical field tests, product designs and manufacturing are seamlessly integrated so that the end result – the substance — is best in class. No short cuts and no excuses.
With modern optical design typical of high end surgical microscopes, iBEX LED Slit Lamps and iBEX LED Wireless Binocular Indirect Ophthalmoscopes delivers high definition observation with reduced reflections and the widest field of view. Ultimately, the user achieves improved diagnosis and less observation strain.
The proprietary LED delivers the industry’s brightest and most uniform illumination. Wavelengths are full spectrum and synced to maximize anterior and posterior observation. Most importantly, heat to the patient’s eye has been reduced by nearly 80% less compared to traditional illumination, resulting in greater patient comfort during intense and prolonged observation.
With modern optical design typical of high end surgical microscopes, iBEX LED Slit Lamps and iBEX LED Wireless Binocular Indirect Ophthalmoscopes delivers high definition observation with reduced reflections and the widest field of view. Ultimately, the user achieves improved diagnosis and less observation strain.
The proprietary LED delivers the industry’s brightest and most uniform illumination. Wavelengths are full spectrum and synced to maximize anterior and posterior observation. Most importantly, heat to the patient’s eye has been reduced by nearly 80% less compared to traditional illumination, resulting in greater patient comfort during intense and prolonged observation.
We’ve made the process simple. Ibex slit lamps are 95% pre-assembled and shipped direct to your office by FedEx. Unpacking and installation takes 20 minutes or less.
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