BRPI1005015A2 - intraocular prosthesis to displace the optic axis of the eye and alter the placement of retinal imaging - Google Patents

Abstract

INTRAOCULAR PROSTHESIS TO DISPLACE THE ATTIC AXIS OF THE EYE AND ALTER THE POSITIONING OF PROJECTION OF IMAGES ON THE RETINAL. The subject matter of this patent relates to a novel type of special intraocular device - either artificial lens replacing or adding to the natural lens or previously implanted Intraocular Lens - designed to displace the focused beam by the damaged posterior pole eye structures from the retina to pre-determined and preserved regions that contain an appreciable number of cones and rods, to improve as much as possible the vision of patients with macular diseases of various origins. The Intraocular Prosthesis for Dislocating the Attic Axis of the Eye and Changing the Positioning of Retinal Image Projection is transparent and has carefully controlled geometric shape and internal refractive index to ensure correct convergence and appropriate deviation of the optical axis of the eye. Considering that retinal damage is specifically localized to each patient's retina, the INTRAOCULAR PROSTHESIS TO SHIFT THE EYE AXIS AND CHANGE THE POSITION OF RETINAL IMAGE PROJECTION should be calculated in its parameters to generate the appropriate deviation for focal focus. optically competent retinal region for the individual.

Description

"INTRAOCULAR PROSTHESIS TO DISPLACE EYE OPTICAL AXIS AND CHANGE POSITIONING OF PROJECTION OF RETINAL IMAGES".

Fields of this Patent:

- Considerable improvement of vision quality for patients with macula diseases of various origins. - Ophthalmology.

The subject matter of this patent relates to a novel type of special intraocular device - either artificial lens replacing or adding to the natural lens or previously implanted Intraocular Lens - designed to displace the focused beam by the damaged posterior pole eye structures the retina, for preserved and previously determined regions, which contain an appreciable number of cones and rods, to improve, as much as possible, the vision of patients with macular diseases of various origins. State of the art.

Difficulties in seeing have always accompanied humanity as a cruel misery, and for the overwhelming majority of humanity the difficulty of vision comes inexorably with old age. Others, more unfortunate, have had them from birth or childhood, or have suffered injuries or illnesses that caused them to lose all or most of their vision.

Mighty men of the Roman Empire knew no way around visual difficulties.

The earliest reference to something similar to a lens used by older people for reading comes from Marco Polo in reports of his visit to China between 1271 and 1295.

Thus, the earliest lenses available to mankind were suitable for presbyopia, poor vision of the old, or hyperopia. Concave lenses for myopia emerged about 200 years later, according to references in Nicola Cusanus's book (1401-1464). In 1775, Benjamin Franklin, an American statesman and scientist, invented bi-focal glasses; By this time, the lenses were already placed on frames that rested on the nose and ears.

From there came astigmatism-correcting lenses, and then tailor-made lenses for each patient, which could simultaneously correct astigmatism, presbyopia, or myopia.

In November 1949, Dr. Nicholas Harold Lloyd Ridley performed the first implantation of an artificial Intraocular Lens - IOL, replacing a cataract lens. From that time to the present day Intraocular Lenses have received constant refinements and are produced

Flexible and foldable material that allows implantation through incisions of about 3 mm and is a valuable resource for Ophthalmology. However, until the moment of the object of this patent emerged, several pathologies that affect the human vision deeply compromising the patient's vision, did not receive effective solutions.

These conditions are related to damage to the retina in the fovea region or, to a greater extent, the macula as a whole.

Patients affected by the pathologies described briefly below become irreversibly limited to tasks such as reading, watching television, moving alone, in short, have their qualities.

dramatically reduced lives.

1. AMD - Age Related Macular Disease: - is defined as visual loss to varying degrees due to atrophy of retinal pigment epithelium or changes associated with subretinal neovascularization in individuals usually over 50 years of age. The condition is

often bilateral, but not always symmetrically. AMD causes severe vision loss, and among the 75-year-old, about 35% of them are affected to some extent.

2. Ocular toxoplasmosis. - congenital toxoplasmosis - acquired during pregnancy - is an endemic disease commonly leading to

inflammatory destruction of the macula. The onset may occur at birth or in its late form, between 10 and 30 years of age, severely compromising vision. Central lesions corresponding to the peri-macular and papillo-macular areas constitute between 36% and 50% of late toxoplasmosis cases.

3. Macular hole: - It is a pathology that can be idiopathic or caused by causes such as high myopia, trauma, solar retinopathy and

other causes.

4. Other pathologies compromise the macula such as central serosa, toxic and other maculopathies, but have lower incidence in the population.

Investigations into the use of stem cells to repair damaged regions are still in their early stages and have not yet yielded any applicable results, so it is not possible to state that this method will be able to restore a population of cones and rods equivalent to that of the region. damaged.

The currently existing optical resource for such pathologies is the use of magnifying glasses for image enlargement. This procedure, however, is

extremely uncomfortable and of use in very restricted situations. Advances in the state of the art brought about by the "INTRAOCULAR PROSTHESIS TO DISPLACE THE EYE OPTICAL AXIS AND CHANGE THE POSITIONING OF PROJECTION OF RETINAL IMAGES", object of this Patent.

The following are the anatomical, histological and physiological fields in which advances in the state of the art of the object of this patent are inserted.

1 - Anatomy of the human eye.

Figure 1 represents anteroposterior section of the human eye (1), in which we see the cornea (2), the ciliary body (3), the pupil (4), the iris (5), the Ligaments (6). ), crystalline lens (7), vitreous humor (8), sclerotic (9), choroid (10), retina (11), macula (12), fovea (13), blind spot (14) , located in the intraocular emergency of the optic nerve (15), which is also called the papilla.

Figure 2 is a schematic cross-sectional front view of the back of the human eye (1) to be seen compared to the front view of the intact eye, placed next to it in Figure 2, showing the fovea (13) , which is approximately circular in shape and about 1.5 mm in diameter and the macula (12), which is in the shape of a disk about 5.5 mm in diameter - with the fovea (13) at its center - composing the extrafoveal region with the rest of the retina (11); In the same Figure 2 we see the cornea (2), the pupil (4), the iris (5) and the optic nerve (15).

2 - Partial histology of the human eye.

Figure 3 schematically depicts the pattern of retinal nerve fiber pathways around the fovea (13) and the papilla or blind spot (14), at which point the optic nerve (15) enters the human eye (1). ). These fibers and nerve endings are composed of axons, dendrites and neuron endings and are connected to a population of cones and rods.

Rods and cones are photo-receptors involved in color and shape perception. Through specialized nerve endings, they turn incident light into nerve impulses that are transmitted to the brain to make up vision.

They are also responsible for peripheral vision. The graph in figure 3B shows the distribution of cones and rods in the human retina. There is a maximum concentration of cones in the fovea region; In the graph, the center of the fovea corresponds to the point with zero degree of perimeter, decaying in the macular region and remaining lower and approximately constant in the extra-macular regions of the retina. Rods, on the other hand, are virtually absent in the fovea and reach a high level outside this region and the rest of the retina. The distribution of cones and rods outside the fovea region is fundamental for peripheral vision in humans.

The nuclear innovations of the subject-matter of this patent, as described below, utilize the extra-foveal light sensitivity provided by these same cones and rods involved in peripheral vision in order to partially restore vision to those with severe foveal or macular lesions arising from the aforementioned pathologies. in this report.

3 - Physiology of human vision. Figure 3C shows in simplified schematic anteroposterior view the human eye (1) with the cornea (2), the Ligaments (6), the lens (7) and two rays of light - A and B - corneal incidents (2) which have their trajectories naturally converging on the fovea (13), which is the main focus of imaging in the eye; it also shows the blind spot (14) and the optic nerve (15).

The human eye behaves basically as an optical system of two conjugated lenses, the first being the cornea (2), a fixed convergence lens and the second, the crystalline (7), a variable convergence lens enabling the images of near and far objects can form equally focused on the fovea allowing clear vision.

Thus, the innovation core of the "INTRAOCULAR PROSTHESIS FOR DISPLACING THE EYE OPTICAL AXIS AND CHANGING THE POSITION OF RETINAL IMAGE PROJECT", object of this Patent, refers to the use of an intraocular optical device surgically implanted in the region of the or to replace it, change the direction of the focus of the light beam that would naturally be projected into the eye directly over the injured central regions and redirect it to other uninjured regions of the retina where the present cones and rods will generate the received images. by the eye and thus partially restore vision to patients with invaluable quality of life gains. Description and illustrations and operation of the state of the art advances brought by the "INTRAOCULAR PROSTHESIS TO DISPLACE THE EYE OPTICAL AXIS AND ALTER THE POSITIONING OF IMAGING PROJECTION IN THE RETINAL", object of this Patent. Ophthalmic examinations reveal that most patients with low or high severity macular lesions have visual perception of peripheral field. Clinical experience confirms that patients report poor visual perception in the direction of the axis of vision - which is true because objects are projected into focus over the damaged fovea / macula - but still have the vision of the presence of objects in the periphery of the field of vision. Of course, these objects can be perceived with less precision, since since their projections on the retina are naturally away from the focal point of focus, their images are projected out of focus on the retina, albeit in preserved regions of the retina, ie usually with lower concentration of cones and rods. The object of this patent is the use of an intraocular optical device to deflect the light beams by altering the focal projection point of the image over the fovea to other regions of the retina to form the focus outside the injured region. Figure 4 is a schematic representation of an anteroposterior human eye (1); in it we see the cornea (2), the ligaments (6) and the crystalline lens (7), which may be replaced or added to the device "INTRAOCULAR PROSTHESIS TO DISPLACE THE OPTICAL AXIS OF THE EYE AND ALTER THE POSITIONING OF IMAGE PROJECTION ON RETINA "(17), object of this Patent.

In this Figure 4 we see the blind spot (14), the optic nerve (15) and also the fovea (13) and an extra-foveal point (16), to which they were displaced, in focus previously calculated for the correct and exact fabrication of the artifact, the AeB light rays, incident on the cornea (2) and which, by the refractive conditions of the object of this Patent, assumed the directions of the light rays represented in the dashed EeFe shape focused on the extra-foveal region defining a new focal point - extra-foveal point (16) - where, as detected in the examinations prior to such an operation - there is sufficient ability to see through the presence of cones and rods allowing appreciable recovery of the patient's focused vision.

Figures 5 and 6 are simplified schematic representations to allow comparison between conventional intraocular lenses and "INTRAOCULAR PROSTHESIS TO DISPLACE THE EYE OPTICAL AXIS AND ALTER THE POSITIONING OF PROJECTION OF RETINAL IMAGES" (17).

Conventional Intraocular Lenses (18) can replace crystalline lens (7) that have become cataract-opaque or implanted in addition to it with correction function for high errors or refractive defects. The Intraocular Lenses (18) are transparent and have carefully controlled geometric shape and internal refractive index to ensure correct convergence and / or refractive correction of the eye.

Figure 5 illustrates the fact that current Intraocular lenses (18) direct the optical focus to the patient's fovea (13) as represented by the convergence of GeH light rays.

"INTRAOCULAR PROSTHESIS FOR DISPLACING THE EYE OPTICAL AXIS AND CHANGING THE POSITION OF RETINAL IMAGE PROJECTION" (17) may or may not replace the lens and may only be implanted in addition to the natural lens or an Intraocular Lens (18). ) previously implanted.

The "INTRAOCULAR PROSTHESIS FOR DISPLACING THE EYE OPTICAL AXIS AND CHANGING POSITION OF RETINAL IMAGE PROJECTION" (17) is transparent and has carefully controlled geometric shape and internal refractive index to ensure proper convergence and appropriate deviation of the optical axis of the eye. Figure 6 illustrates the fact that the "INTRAOCULAR PROSTHESIS TO SHIFT THE EYE OPTICAL AXIS AND CHANGE THE POSITION OF RETINAL IMAGE PROJECTION" (17) alters the optical axis by directing the main focus of the image to the preserved retinal region as depicted. in the convergence of light rays I and J thus defining a new focal point which is the extra-foveal point (16). Considering that retinal damage is specifically located on each patient's retina, the "INTRAOCULAR PROSTHESIS FOR DISPLACING THE EYE OPTICAL AXIS AND ALTERING THE POSITION OF PROJECTION OF RETINAL IMAGES" (17) should be calculated in its parameters to generate the deviation. suitable for focusing on the optically retinal region most competent for the individual. Similar to eyeglass, dental, intraocular or orthopedic prosthesis lenses that can be found on the market, the "INTRAOCULAR DENTURE TO SHIFT THE EYE OPTICAL AXIS AND ALTER THE POSITION OF PROJECTION OF RETINAL IMAGING" (17) can be manufactured on a robotic industrial scale in short time and at affordable costs.

Claims (3)

1. "INTRAOCULAR PROSTHESIS FOR DISPLACING THE EYE OPTICAL AXIS AND CHANGING THE POSITION OF RETINAL IMAGING", intended to partially restore vision to those with severe foveal or macular lesions, characterized by using the extra-foveal light sensitivity provided by the cones and rods involved in peripheral vision and be a special intraocular device or artificial lens replacing or adding to the natural lens or previously implanted Intra Lens, intended to alter the optical axis and displace the focused light beam through the damaged eye structures from the posterior pole of the retina, to previously determined and preserved regions, which contain appreciable numbers of cones and rods to form the focus outside the injured region. 2. "INTRAOCULAR PROSTHESIS FOR DISPLACING THE EYE OPTICAL AXIS AND ALTERING THE POSITION OF RETINAL IMAGE PROJECTION" according to claim 1, characterized in that it is transparent and has a carefully controlled geometric shape and internal refractive index. ensure correct convergence and appropriate deviation of the optical axis of the eye and be surgically implanted in or replacing the lens region. 3. "INTRAOCULAR PROSTHESIS FOR DISPLACING THE OPTICAL AXIS OF THE EYE AND ALTERING THE POSITION OF REJECT IMAGING" according to claim 1, characterized in that it generates a new focal point which is the extrafoveal point (16).