IT201800011177A1 - Method for managing the dynamic displacement of a contact lens placed on an eye - Google Patents

Description

Description of a patent for industrial invention for the invention entitled:

"METHOD FOR MANAGING THE DYNAMIC MOVEMENT OF A CONTACT LENS PLACED ON AN EYE"

The present invention relates to a method for managing the dynamic displacement of a contact lens positioned on an eye.

The contact lens, which in the posterior surface has the concave shape and in the anterior one convex, is constructed with the internal geometry with the same radii of curvature of the cornea. The contact lens consists internally of an optical zone, flanges and an edge.

The optical zone corresponds to the portion of the lens through which the optical correction occurs.

Flanges are the secondary curves or lens zones that begin immediately after the end of the optic zone in the inner surface of the lens and rise from the cornea to the edge of the lens.

Despite the precision in the construction of the lens curves, we are witnessing unexpected dynamics behaviors. The lenses do not center correctly on the cornea and the reasons depend on the corneal conformation, the balance of the lens weights, the quality and quantity of the tear film, the thrust exerted on the lens by the action of the eyelids, etc.

In this way, dynamic shifts of the lens occur, when applied to the cornea, which are managed in various ways.

In the event that the contact lens is decentralized upwards and downwards, according to a vertical axis, and specifically, if during application the tilting lens is off-centered upwards, it can be repositioned downwards by tightening the curvature of the lens. In the lens with the most closed curvature, the resultant of the forces in play is shifted back, ie towards the retina. In this way, the dynamics of the lens is changed and the lens repositions and tilts lower.

In the event that the contact lens is decentralized upwards or downwards, according to a vertical axis, and specifically, if during the application the tilting lens is decentralized downwards, it can be repositioned upwards, opening the curvature of the lens. In the lens with a more open curvature, the resultant of the forces at play is displaced further towards the cornea. In this way, the dynamics of the lens are changed and the lens repositions and tilts higher.

In the event that the contact lens is decentralized towards the nose or towards the temples, according to a horizontal axis, I can increase the optical zone or the diameters of the flanges to re-center the lenses that do not stabilize well on the center of the pupil or do not position themselves in cornea-centered manner. The thrust of the eyelids and the conformation of the sclera in the nasal area, which is more open or rather has wider radii of curvature, tends to decentralize the contact lens towards the temple on the temporal-nasal line.

To date, however, none of the operating systems allow us to control the dynamics of the lenses for centering the internal optical zone on the cornea with precision.

We constantly find ourselves having to decide to increase or decrease the radii of curvature or the diameters of contact lenses to try to find the best solution, but without ever having full control of the centering. The modifications that are made are made on the flanges in semi-scleral and scleral rigid contact lenses (lenses that have the characteristic of resting on the sclera, unloading the weight of the lens and forming once on the cornea) with the intention of uniformly unloading the weights deriving from the weight of the lens and the pushing action of the eyelids on the sclera.

This method is carried out empirically or with the support of new digital mapping systems of the sclera, but without any management of the centering of the internal optical zone.

In some cases the curves of the flanges are opened in the various areas as well as to better unload the weights of the contact lens also to avoid creating closures to the dynamics of the tear film or bottlenecks on the conjunctival vessels where the lens rests. This system is applied to all lenses but mainly to large diameter gas-permeable (hard) contact lenses: corneal, semi-scleral and scleral.

The object and function of the present invention is to obviate the aforementioned drawbacks and others, by providing a method that allows to control and manage the dynamic displacement of the geometry of the internal optical zone of a contact lens.

These purposes and advantages are all achieved, according to the invention, by a method as claimed.

The method according to the invention allows to control and manage the dynamic displacement of a contact lens applied to an eye, modifying and shifting the temporal-nasal / high-low dynamics of the internal / external geometries for precise control of the centering of the geometries, especially useful for multifocal or progressive lenses.

In other words, the management of the displacement of the centering of the lens occurs through the displacement of the resulting forces by means of the modification, in the internal surface of the lens, of the flanges (secondary curves) divided by quadrants.

The internal surface of the lens is, in fact, composed of the optical zone, the flanges (secondary curves) which can be single or multiple, spherical or aspherical, and the edge.

As the curvature of the quadrant flanges changes, it happens that the lens is pushed in the opposite direction to the applied force. By squeezing the radius (s) of curvature of the flange in a quadrant, in the flange area I apply a greater thrust to the cornea and send the lens in the opposite direction.

Further characteristics and details of the invention can be better understood from the following description, given as a non-limiting example, as well as from the attached drawing table in which:

Fig. 1 is a schematic front view of the contact lens, according to the invention, being used on an eye;

Figure 2 is a schematic front view of the contact lens of Figure 1.

With reference to Figures 1 and 2, 10 indicates a contact lens 10, suitable for being applied to an eye, on the cornea C, between the pupil and the eyelids, in particular the upper eyelid Ps and the lower eyelid Pi.

As in figure 1, the perfectly circular contact lens 10 is placed on the right eye (considering the position of the nose N) and has a diameter slightly larger than the diameter of the cornea C.

In particular, the contact lens 10 comprises an optical zone 12, a perimeter flange 14 and a perimeter edge 16.

The perimeter border 12 is around the border B which separates the cornea C from the sclera S.

The flange 14 has a curvature such as to lock the contact lens 10 in the desired position.

In particular, depending on the curvature of a portion of the flange 14, it is possible to move the contact lens 10 forward or backward on an axis orthogonal to the flange portion 14.

For ease of lens management, the perimeter flange 14 is divided into four quadrants by two orthogonal axes arranged at 45 ° with respect to a horizontal axis.

The four quadrants are a temple quadrant 18, an upper quadrant 20, a nasal quadrant 22 and a lower quadrant 24.

Consequently, by increasing the curvature of the temple quadrant 18, the contact lens 10 is moved towards the temple and vice versa, by decreasing the curvature of the temple quadrant 18, the contact lens 10 is moved towards the nose.

Similarly, by increasing the curvature of the nasal quadrant 22, the contact lens 10 is moved towards the eye and vice versa, by decreasing the curvature of the nasal quadrant 22, the contact lens 10 is moved towards the temple.

As regards the other two quadrants 20, 24, by increasing the curvature of the upper quadrant 20, the contact lens 10 is moved upwards and vice versa, by decreasing the curvature of the upper quadrant 20, the contact lens 10 is moved towards the low.

Similarly, by increasing the curvature of the lower quadrant 24, the contact lens 10 is moved downwards and vice versa, by decreasing the curvature of the lower quadrant 24, the contact lens 10 is moved upwards.

It should be noted that the correct centering of the lens can be carried out by simultaneously managing the curvature of all four quadrants of the flange.

So, if the lens 10 in situ remains off-center towards the temple, I can make three adjustments:

1. increase the radius of curvature of the flange in the nasal quadrant 22; 2. increase the radius of curvature of the flange in the nasal quadrant 22 and at the same time reduce the radius of curvature of the flange in the temple quadrant 18;

3. reduce the radius of curvature of the flange in the temple quadrant 18.

In essence, it is a question of generating or lightening the thrusts capable of modifying the positioning of the applied lens.

Similarly, in the event that the in situ lens is decentralized nasally, I can make three different modifications to the contact lens:

1. increase the radius of curvature of the flange 14 in the temple quadrant 18;

2. increase the radius of curvature of the flange 14 in the temple quadrant 18 and at the same time reduce the radius of curvature in the nasal quadrant 22;

3. reduce the radius of curvature of the flange 14 in the nasal quadrant 22.

In the event that the lens in situ is decentralized upwards, it is possible alternatively:

1. reducing the radius of curvature of the flange 14 in the upper quadrant 20;

2. reduce the radius of curvature of the flange 14 in the upper quadrant 20 and increase the radius of curvature of the flange 14 in the lower quadrant 24;

3. increase the radius of curvature of the flange in the lower quadrant 24.

In the event that the lens in situ is decentralized downwards, it is possible alternatively:

1. reducing the radius of curvature of the flange 14 in the lower quadrant 24; 2. reduce the radius of curvature of the flange 14 in the lower quadrant 24 and increase the radius of curvature of the flange of the upper quadrant 22;

3. increase the radius of curvature of the flange 14 in the upper quadrant 22.

This method, in addition to allowing to shift the balance of the lens through the management of the radii of curvature of the flange divided by quadrants to position the lens with a complete and precise control of the displacement, also allows to generate few tensions on the material in the optical zone and creates the advantage of not stressing the surface, avoiding making changes or alterations to the geometries of the external optical zone.

It is, in fact, important not to alter the external geometries in order not to alter the foci arriving on the retina, especially in multifocal or progressive geometries.

The method according to the invention, for its correct centering of a contact lens 10, has been described when applied to a contact lens 10 for the right eye, but it is of course also possible to apply it to a contact lens for the eye. left.

There are possible variants to be considered included in the scope of protection defined by the attached claims.

The flange can be divided into a number of portions different from the four quadrants described above, for example into six or eight or more portions of the same size.

Furthermore, since a contact lens can also have two or more flanges along its perimeter, these one or more flanges can all be divided into quadrants, as described above in the case of a single flange, so as to further improve the accuracy of the position. of the contact lens.

In this way, you can change the angle of curvature for each quadrant of each flange present on the contact lens.

Claims (10)

CLAIMS 1. Method for centering a contact lens (10) to be applied on the cornea C of an eye, and comprising a focal zone (12), a perimeter flange (14), and a perimeter edge (16), in which the flange (14) is curved according to a radius of curvature in order to hold the contact lens (10) in position with respect to the eye, characterized in that it comprises the following phases: - dividing the flange (14) into at least four portions (18, 20, 22, 24), each of said four portions having a respective radius of curvature; - increasing or decreasing the radius of curvature of at least one of said four portions (18, 20, 22, 24). Method according to the preceding claim, wherein the four portions of the contact lens (10) comprise a temple quadrant (18), an upper quadrant (20), a nasal quadrant (22) and a lower quadrant (24). Method according to the preceding claim, wherein by increasing or decreasing the curvature of the temple quadrant (18), the contact lens (10) is moved towards the temple or towards the nose, respectively. Method according to claim 2 or 3, wherein, by increasing or decreasing the curvature of the nasal quadrant (22), the contact lens (10) is moved respectively towards the nose or towards the temple. 5. Method according to one of claims 2 to 4, in which, by increasing or decreasing the curvature of the upper quadrant (20), the contact lens (10) is moved respectively upwards or downwards. 6. Method according to one of claims 2 to 5, in which, by increasing or decreasing the curvature of the lower quadrant (24), the contact lens (10) is moved respectively downwards or upwards. 7. Method according to one of claims 2 to 6, in which, in the event that the contact lens (10) positioned on the eye is decentralized towards the temple, it is possible to make three alternative adjustments: - increase the radius of curvature of the flange in the nasal quadrant (22); - increasing the radius of curvature of the flange in the nasal quadrant (22) and at the same time reducing the radius of curvature of the flange in the temple quadrant (18); - reduce the radius of curvature of the flange in the temple quadrant (18). 8. Method according to one of claims 2 to 7, in which, in the event that the contact lens (10) positioned on the eye is nasally decentralized, it is possible to make three alternative adjustments: - increase the radius of curvature of the flange (14) in the temple quadrant (18); - increasing the radius of curvature of the flange (14) in the temple quadrant (18) and at the same time reducing the radius of curvature in the nasal quadrant (22); - reduce the radius of curvature of the flange (14) in the nasal quadrant (22). 9. Method according to one of claims 2 to 8, in which, in the event that the contact lens (10) positioned on the eye is decentralized upwards, it is possible to make three alternative adjustments: - reducing the radius of curvature of the flange (14) in the upper quadrant (20); - reducing the radius of curvature of the flange (14) in the upper quadrant (20) and increasing the radius of curvature of the flange (14) in the lower quadrant (24); - increase the radius of curvature of the flange in the lower quadrant (24). 10. Method according to one of claims 2 to 9, in which, in the event that the contact lens (10) positioned on the eye is decentralized downwards, it is possible to make three alternative adjustments: - reducing the radius of curvature of the flange 14 in the lower quadrant 24; - reducing the radius of curvature of the flange 14 in the lower quadrant 24 and increasing the radius of curvature of the flange of the upper quadrant 22; - increase the radius of curvature of the flange 14 in the upper quadrant 22.