JPH02189146A - Contact lens - Google Patents

Abstract

PURPOSE:To cure astigmatism and to prevent the occurrence of astigmatism after operation by a method wherein an optical part forms an aspherical lens. CONSTITUTION:In order to cure astigmatism, the axes of an aspherical lens, i.e. positioning holes 16 and 16, are inserted in a horizontal state. A contact lens 10 inserted in a rear chamber has securing parts 14 and 14 cicatrically secured between the front and rear vesicae of the equatorial part of a crystalline lens. An optical part 10 permanently keeps its position at an insertion portion without movement, e.g. rotation. Thus, the axis of the aspherical lens is secured and astigmatism occurring to a patient can be cured by means of the aspherical lens. This constitution eliminates the need to wear a glasses and an HCL after operation, prevents infliction of a pain and uncomfortable feeling on a patient, and also enables curing of astigmatism already occurring before operation.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to an intraocular lens used in surgery for cataracts and the like.

[Prior art 1] During cataract surgery, after the nucleus in the crystalline lens is delivered, an intraocular lens, which is an artificial crystalline lens, is inserted to correct visual acuity.

However, corneal astigmatism occurs due to changes in the shape of the cornea due to incisions made in the corneal region during surgery, sutures using nylon threads, etc. For example, when nylon thread is used for suturing, the degree of corneal astigmatism that occurs is 0, 5 Dlopter (Dio
pter (hereinafter referred to as (D)) or higher.

In addition, this value of corneal astigmatism is the degree of astigmatism caused by surgery, and in the case of patients who already had astigmatism due to a disease etc. before surgery, the strength of astigmatism after surgery is determined by the degree of astigmatism caused by surgery. It can be considered that it is approximately equal to the sum of the strength of astigmatism and the strength of astigmatism before surgery.

Therefore, in order to correct this astigmatism, astigmatism has conventionally been corrected by using glasses or hard contact lenses (hereinafter referred to as HCL), or by performing surgical procedures such as corneal incision.

[Problems to be Solved by the Invention] However, it is difficult for glasses and HCL to correct astigmatism of 3 (D) or more, and wearing glasses and HCL are uncomfortable for patients.

Furthermore, the following problems exist regarding the corneal incision method.

■ Once a corneal incision or corneal suture is made during cataract surgery, it is difficult to perform surgery on the same area again.

■ Intentionally creating a wound on the cornea, which increases the possibility of corneal infection.

■　Irregular astigmatism may occur.

■ In addition to cataract surgery, it is necessary to perform a new surgery called corneal incision, which is painful for the patient.

■ Damaging healthy corneas is considered an ethical issue.

■ The degree of astigmatism varies from patient to patient, but correction by the surgeon relies on sensory techniques, and it may not be possible to completely correct astigmatism.

For the above reasons, a method of correcting astigmatism by making a corneal incision is not generally performed.

[Object of the Invention] Therefore, the present invention provides an intraocular lens that can correct astigmatism.

[Means for Solving the Problems] In the intraocular lens of the present invention, the optical part is made of an aspherical lens.

[Function] With the intraocular lens having the above configuration, astigmatism is corrected by the aspherical lens of the optical part, and astigmatism does not occur in the patient after surgery.

[Example] Hereinafter, one embodiment of the present invention will be described based on the drawings.

(10) is a shearing type intraocular lens made of a polymer compound such as PMMA (polymethyl methacrylate), which has an optical part (12) made of an aspherical lens and an optical part (12). It consists of J-shaped fixing parts (14) (14) that protrude from the opposing parts. (I
Q) (1B) is the positioning hole.

The aspheric lens power of the optical part (12) with the above configuration is 5 (D)
is determined as follows.

The corneal astigmatism power of the patient before cataract surgery is measured, and the corneal astigmatism power G (D), which is the sum of the measured corneal astigmatism power and the corneal astigmatism power generated by the surgery, is calculated.

Using equation (1), the astigmatic power G is converted into the power C (D) of the cylindrical lens required for the aspherical lens.

C-GXA...(1) However, A is 5 anders-Retzlal'f-K
This is the conversion ratio between the extreme lens power and the intraocular lens power according to the raN formula (SRK formula). Although the value of A varies depending on the individual, it generally takes a value of 1.2 to 1.7.

Next, the power S - (D) of the conventional intraocular lens, which is only a spherical lens, is calculated using equation (11).

S-"116. 5-2. 5XL-0,9XK...
...(11) However, L is the axial length (am) of the patient who inserts the intraocular lens (10), and K is the corneal refractive power (D) of the patient.
).

Next, the aspherical lens power S is determined by substituting S'' and C obtained above into the equivalent spherical equation (111).

S S ” -C, / 2...(ill) An intraocular lens (10) is manufactured using the aspherical lens determined above as the optical part (12).Then, the patient is given an intraocular lens by surgery. Just insert the lens (10).

For example, in the case of a patient who had shown direct astigmatism of 3 (D) by corneal refractive measurements before cataract surgery, it was inserted to reduce the total astigmatism to 0 (D) from 3 months after surgery. The aspheric lens power S of the intraocular lens (10) is determined as follows.

First, the patient's axial length and corneal refractive power K are measured in advance. In this patient's case, L-23.2, K-44
shall be.

Assume that 3 months after surgery, direct astigmatism of 0.5 (D) occurs due to surgery. Then, as described above, it is necessary to correct a total of 3.5 (D) of direct astigmatism, including the 3 (D) of direct astigmatism before the surgery, using the intraocular lens (10).

The power C of the cylindrical lens is 4.375 (D) according to formula (1).
That is, it is approximately 4.5 (D). However, A-1, 25
shall be.

<11) By substituting L-23,2 and K-44 into the formula, S
”-19.

Substituting 5--19, C--4,5 into formula (III), S
The result is 5-21.25.

Therefore, the aspherical lens power S required for this case is +
21.25(D), and the required power C of the cylindrical lens is -4.5(D)Axigo''.

In addition, it is generally written as follows.

S+21. 25D-C-4,5DAx180''
The axis of the aspherical lens is set at the positioning hole (1(i) (113) in Fig. 1. Figs. 2 and 3 show the aspherical state of the optical part (lO), which is an aspherical lens. 2 shows an end view taken along the line I-1 in FIG. 1, and FIG. 3 shows an end view taken along line I-1 in FIG.
−■ line end view is shown.

Intraocular lens (lO) with astigmatic power S set as above
is inserted using the same surgical method as before. The intraocular lens can be inserted by, for example, a compression method, a dialing method, or a closed procedure. In this case, in order to correct direct astigmatism, the axis of the aspherical lens, that is, the positioning hole (16) (1B), is inserted horizontally. FIG. 4 shows the state after insertion of the intraocular lens (10), with the patient's head in the upper part of the drawing. Note that (18) indicates the corneal part, and (20) indicates the anterior capsule.

As a result, the intraocular lens (10) inserted into the back
The fixing part (14) (14) is fixed in a ciliary sulcus or between the anterior capsule and the posterior capsule in the equatorial region of the crystalline lens. Therefore,
The optical part (lO) permanently maintains its position at the insertion site without rotation or other movement. Therefore, the axis of the aspherical lens is fixed, and direct astigmatism occurring in the patient can be corrected by the aspherical lens. Therefore, there is no need to wear glasses or HCL after surgery as in the past, and there is no pain or discomfort to the patient. It also has the effect of correcting astigmatism that the patient already had due to a disease or other reason before the surgery. Furthermore, unlike conventional corneal incision methods, this method has the effect of reliably correcting the desired degree of astigmatism.

In the above embodiment, the axis of the aspherical lens is set in the positioning hole, but in the case of a non-hole intraocular lens, the fixing part (14) (
14) may be set at the root, etc.

Furthermore, although the above-mentioned intraocular lens (lO) is a sharing type, the present invention can also be achieved by using an aspherical lens in the optical part of other posterior lenses such as piercing lenses and anterior chamber lenses instead. The effect is sufficient.

Further, in this embodiment, an intraocular lens made of a PMMA plastic lens is shown, but an intraocular lens such as a silicone lens may be used instead.

[Effects of the Invention] With the intraocular lens having the above configuration, astigmatism can be corrected because an aspherical lens is used in the optical part, and there is no risk of astigmatism occurring after surgery.

Since there is no need to use glasses, HCL, etc. or to make a corneal incision to correct astigmatism, there is no need to cause pain or discomfort to the patient.

Another advantage is that not only astigmatism caused by surgery, but also astigmatism that the patient already had due to disease or the like before surgery can be corrected at the same time.

Furthermore, unlike conventional corneal incision methods, this method has the effect of reliably correcting the desired degree of astigmatism.

[Brief explanation of the drawing]

FIG. 1 is a plan view showing an embodiment of the present invention, and FIG. 2 is a plan view showing an embodiment of the present invention.
FIG. 1 is an end view taken along line I-1 in FIG. 1, FIG. 3 is an end view taken along line ■--■ in FIG. 1, and FIG. 4 is a plan view of the intraocular lens inserted into the rear door. Explanation of symbols 10...Intraocular lens 12...Optical section 14...Fixed section Patent applicant: Genji Omi - ■

Claims (1)

[Claims] 1. An intraocular lens characterized in that the optical part consists of an aspherical lens.