RU2269327C1 - Method for removing corneal neoplasm of tumorous or non-tumorous genesis - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: method involves applying radio wave knife in completely filtered wave mode with output power of 27-34 W and frequency of 3,8 MHz. Wire electrode not longer than 500 mcm is set at an acute angle with respect to corneal surface in every action point not more than 1 mm far from it.

EFFECT: high ablasticity in removing malignant tumors; reduced relapse rate in removing other neoplasms; reduced risk of traumatic complications.

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Description

The invention relates to ophthalmology and is intended to remove various formations of the cornea.

The main method of treatment of tumors of a tumor and non-tumor nature of this localization is the surgical removal of the primary node with a metal or diamond knife. Surgical treatment is usually combined with local chemotherapy (0.04% mitomycin C) or brachytherapy for the prevention of relapse (Ophthalmic oncology. A guide for doctors. Moscow. 2001, p. 227).

Moreover, the removal of corneal tumors is accompanied by a number of difficulties. On the one hand, we should treat the tissues of the cornea sparingly, since it is one of the optical media of the eye involved in visual functions. The correct orientation of corneal fibroblasts is responsible for the preservation of its optical properties. When removed with a blade, tumors have to be removed with a supply of healthy tissues. This leads to an increase in the volume of resected tissues. However, the greater the volume of resected tissues and trauma, the greater the likelihood of disorientation of these fibroblasts during restoration of the cornea, and therefore, the greater the risk of clouding. In addition, the complex of ablastic measures includes the complete elimination or reduction of tumor contact with surgical instruments in order to prevent relapse and local dissemination. The latter, as a rule, is impossible when using simple metal or diamond knives. This becomes the cause of relapse in tumors of a tumor nature removed in this way.

In surgery of tumors of other locations, electroscalpels are widely used. However, for the formation of the cornea, this method is not suitable because of the main working effect - coagulation. The effect of coagulation causes a burn of the cornea and leads to clouding with a decrease in visual function.

The use of laser scalpels for these purposes is also difficult, since the main effect of CO ₂ laser exposure is vaporization - or evaporation of intercellular fluid and coagulation of biological tissues, including the cornea, as an object of exposure. The latter is accompanied by the occurrence of a burn, and then leads to the development of a thorn. Although, of course, the CO ₂ laser has antiseptic, ablastic properties. In addition, when working with a laser beam, visual control of the depth of dissection of tissues is impossible, which can lead to perforation of the cornea with the subsequent formation of a rough scar and a decrease in visual functions. Residual pigmentation at the site of exposure is also possible with an improperly selected radiation exposure regimen (Ophthalmic oncology. A manual for doctors, edited by A.F. Brovkina. Moscow. 2001, p. 113). This significantly worsens the cosmetic result of the operation.

In this regard, the search for methods of surgical treatment of tumors of the cornea of a tumor and non-tumor nature is extremely relevant and far from being resolved.

Meanwhile, the radio wave method of tissue dissection today has already found wide distribution in general surgery (John Stuart "Procedures in general practice" London, - 1997, - pp. 177). As for ophthalmology, it has already been successfully used to remove neoplasms of the adnexal apparatus of the eye - eyelids ("Eyelid tumors - clinical diagnosis and treatment." Jay Justin Older. - London, - 2003, - pp.128). However, the feasibility of using and the ability of the radio wave knife to remove tumors of the eyeball has not yet been disclosed. The modes and power range in which it is possible to work on the tissues of the eye, especially on the cornea, are not established. Meanwhile, the method has several advantages, is atraumatic, non-contact; which together increases the quality of the incision, and therefore the cosmetic effect of the postoperative scar.

Considering all of the above, the idea arose to remove corneal tumors using a radio wave knife. For preliminary studies, an experimental model of a corneal tumor (melanoma) was created on 30 Chinchilla rabbits. Upon reaching the maturity of melanoma, the animals were removed from the tumor using a radio wave knife, carefully working out the operating modes and selecting a range of working capacities.

In the course of experimental studies, it was empirically found that the optimal of the four possible modes - cutting (fully filtered wave), cutting-coagulation (fully straightened wave), coagulation (partially straightened wave), fulguration (intermittent spark wave) is cutting or the fully straightened wave mode .

When choosing a regime guided by two circumstances. The first circumstance was that the cornea is an avascular tissue, therefore there is no need for coagulation. The second point is due to the fact that the filtered wave, which is the current mechanism for dissecting tissues in the cutting mode, has the least damaging effect on neighboring neighboring tissues. This is very important to consider during operations on the cornea, which is one of the optical media of the eye.

Thus, we came to not only a theoretical conclusion, but also reinforced the conclusion with empirical data, according to which, when working on the cornea, the fully filtered wave mode should be used.

Next, the optimal power mode was selected. At the same time, it was experimentally established that the power developing at the tip of the radiosonde is optimal when the power control knob is located at the level from 27 W inclusive to 34 W inclusive. When selecting capacities, we were guided by the fact that the effect of adhesion of tissues to the radiosonde indicates insufficient power, and the effect of sparking indicates excessive. We observed in the experiment, working with corneal tumors, the adhesion of corneal tissue to the electrode (radiosonde) during operation in the power range from 4 W to 20 W, while arcing developed when the regulator was marked on the scale starting from 41 W. The former testified to insufficient exposure, the latter to excessive.

In the course of experimental studies, other subtleties of the radiosurgical method of dissecting the cornea were also noticed. So, the depth of the wound was directly proportional to the length of the radiosonde. In this connection, for the safety of corneal surgery, this value should not be increased by more than 500 microns. In addition, the probe should not be held strictly vertical (at an angle of 90 °) with respect to the surface of the cornea, but at an acute angle to it at each point of exposure. At the same time, the depth of the cut decreased as the angle of inclination decreased. The obtained empirical data do not contradict the basic laws of radiophysics. It is known that the power of radio wave exposure decreases in parallel with a decrease in the angle of inclination, and, since the depth of cut is directly dependent on the power, then, accordingly, with a decrease in the angle of inclination of the radiosonde, the depth of the wound decreases. In addition, working in such conditions on the cornea, it became possible to control the incision.

The exposure power also decreased as the tip of the probe was removed from the working surface of the fabric. (The law of radiophysics states that the power of radio wave radiation decreases in proportion to the square of the distance). Empirically, it was selected that when the tip of the probe was removed from the cornea by more than 1 mm, the corneal tissue did not dissect, the incision was not obtained.

Histological studies of the eyes enucleated after the completion of the experiment revealed the nature of reparative processes and morphological changes in the corneal tissues. Based on the data obtained, we were convinced of the safety of the method and in a good restoration of the structures of the cornea and its optical properties. In the presented figures 1 and 2, the minimal destruction of the structures of the corneal fibroblasts after exposure to the specified regime of the radio wave knife for excision of the corneal tumor with subsequent restoration of the defect in the cornea and its functions is shown (Figs. 1 and 2).

The studies carried out allowed the introduction of a radio wave method for removing corneal formations in the clinic. We performed a number of operations with pterygiums that have advanced and recurring, as well as with corneal melanoma. Long-term results showed no relapse and good functional and cosmetic results.

The obtained data formed the basis of our proposed method for removing various formations of the cornea.

The technical result of the invention is to increase ablasticity when removing malignant tumors and reduce relapses when removing the formation of tumor and non-tumor genesis, as well as reducing the decrease in visual functions by reducing trauma to the cornea when exposed.

The technical result is achieved by removing the formation of the cornea with a radio wave knife in a certain mode.

In our work, we used a Surgitron ™ radio wave knife manufactured by Ellman international. However, the method is feasible using any radio wave knife with output data that provides the mode selected by us.

The method is as follows.

Set the required length of the wire electrode (500 microns) by extending the probe, focusing on the readings on the micrometer scale.

The handle with the electrode fixed in it is brought to the cornea, no more than 1 mm.

The handle of the radiosonde is placed at an acute angle to the surface of the cornea at each point of impact.

Excision of the tumor is performed within healthy tissues, in the mode of a fully filtered wave with an output power of 27 W / 34 W, adjusting the depth of cut, varying the acute angle of the handle at each point of exposure.

EXAMPLE 1

A model of corneal melanoma was formed on the eye of a Chinchilla rabbit by forming a pocket in its middle layers and implanting a suspension of tumor cells of a hybridoma strain of melanoma in an amount of at least 5 million cells. The formed tumor spreads not reaching the pupillary margin of 2 mm. A rabbit with corneal melanoma was injected with i / m Hexenal at the rate of 0.2 mg per kg of body weight. Anesthetic Dikain 1% was instilled into the conjunctival cavity of the operated eye.

The animal was laid on a table with a passive electrode (antenna) under its head. The radio wave knife mode controller was set to the fully filtered wave mode, and the power controller was at 27 watts. The length of the wire electrode thread was controlled, so that it did not exceed 500 microns, focusing on standard indicators on the micrometer scale.

A handle with an electrode fixed in it was brought to the cornea, observing a distance of 1 mm between the surface of the cornea and the tip of the electrode and set at an acute angle at the point of impact.

1 mm apart from the visible borders of the corneal tumor, an incision was made. During excision, neoplasms were varied by the acute angle of the handle, focusing on the depth of tumor growth in the corneal stroma.

Example 2

Patient M., 45 years old. Diagnosis: recurrent complicated pterygium, reaching the optical center of the cornea. The third relapse.

Produced under local instillation anesthesia with a solution of dicaine 1% removal of pterygium with a radio wave knife in the filtered wave mode with an output power of 34 watts. Healing is good. Visual acuity without correction 0.8, with corr. Points - 1.0. The cornea at the site of exposure is transparent.

Over 12 months of observation, no signs of relapse were noted.

Thus, the proposed method provides the removal of corneal formations of various origins in compliance with the principle of ablasticity and the greatest safety of the cornea.

Claims (1)

A method of removing tumor formations of the tumor and non-tumor origin, characterized in that the removal is carried out using a radio wave knife in the fully filtered wave mode at an output power of 27-34 W and a frequency of 3.8 MHz, using a wire electrode with a length of not more than 500 μm, which positioned at an acute angle to the surface of the cornea at each point of exposure at a distance of not more than 1 mm from it.

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