MD1781Z - Ciliary muscle stimulator - Google Patents

Abstract

The invention relates to medicine, namely to ophthalmology, and can be used for stimulating the ciliary muscle and increasing muscle tone.The ciliary muscle stimulator comprises an electronic device (2), connected to a lens (3) and provided with a belt (5). The device (2) consists of a housing (7) and an electronic system (8). The lens (3) is made concave of medical silicone, in the center of which is made a through hole. On the inner part of the lens (3) are fixed twelve electrodes (4), arranged in two concentric circles, six electrodes at equal distances and connected between them by means of microcables (23 and 24), which are hidden in the silicone layer of the lens (3) and connected via an electrical microplug (25) to a microconnector (21) of the device (2).

Description

The invention relates to medicine, namely to ophthalmology, and can be used to stimulate the ciliary muscle and increase muscle tone.

The ciliary body represents the middle, thicker portion of the vascular tunic, between the serrata of the retina and the iris. Through its posterior edge, it presents the ciliary ring (orbiculus ciliaris), and corresponds to the serrata of the retina, with about 70 radially arranged apophyses (processus ciliares) and which are accentuated by the accommodation process. The multiple vessels of these apophyses produce an intraocular fluid - the aqueous humor (humor aquaeus). Anteriorly it joins the external edge of the iris.

The ciliary body contains smooth muscles with meridional fibers (when they contract, the choroid moves anteriorly - as a result, the degree of tension of the ciliary zonule to which the lens is fixed decreases. As a result, the lens capsule relaxes, the lens changes its curvature, becomes more convex, and its refractive capacity increases), radial and circular (their contraction also contributes to the relaxation of the lens support apparatus), which, as a whole, constitute the ciliary muscle. When the ciliary muscle contracts, the eye accommodates. The muscle intervenes on the lens through the suspensory ligament (Zinn's zonule), inserted on the external surface of the lens capsule, adapting it to see clearly at a short or long distance.

By contraction of the ciliary muscle, the zonula relaxes, releasing tension from the lens capsule. Changes in the curvature of the lens occur in the central region. The increase in the anteroposterior diameter produces an increase in the refractive index of the accommodated lens, determined by its lamellar structure. The ciliary processes (processus ciliares) represented by 70-80 triangular pyramidal formations, arranged meridianally, are formed by blood vessels and make up the ciliary crown (corona ciliaris). The ciliary processes have their base anteriorly, near the root of the iris, and their posterior tip, laora serrata. Being equivalent to the cerebral choroid plexuses, they intervene in the formation of aqueous humor. The aqueous humor is secreted in the posterior chamber and passes, through the pupil, into the anterior chamber from where it is filtered into the Schlemm canal. At the iridocorneal angle, the fluid circulation is normally from the anterior chamber to the Schlemm canal, because the intraocular pressure is higher than the episcleral venous pressure. In various genetic pathologies, the ciliary muscles lose their tone, atrophying, which leads to a decrease in visual acuity and a disruption of the metabolism in the lens, losing elasticity. Meridians are curves that pass through the centers of the anteroposterior axis, one is vertical, another is horizontal, the others are oblique.

A medical device Ocufit (Sooft) is known, which consists of special lenses and a calibrated power supply, to which the lenses are connected. A 20 mm polycarbonate scleral contact lens is used, equipped with four microelectrodes in four cardinal points positioned 3.5 mm outside the limbal area corresponding to the ciliary body region. The microelectrodes are connected by four electrical cables to the electrical generator. The lens is applied to the eye. The lens is joined to a tube which at the other end is connected to a syringe, intended for suctioning air from the space between the lens and the cornea, for fixing the lens to the eye. The electrostimulator (Sooft) generates biphasic compensated square waves for a low voltage microelectrostimulation of the ciliary muscles. After each treatment, two drops of antibiotic-steroid are instilled into each eye to prevent inflammation or infection. Treatment with this device includes four sessions of bilateral pulsatile microelectrostimulation (2 sec on; 6 sec off) with 26 mA for 8 minutes, at 2-week intervals [1].

The disadvantages of this device are that the lens of the device does not allow covering all the meridians of the ciliary muscle, namely vertical, horizontal and oblique, does not favor the adequate circulation of aqueous humor from the posterior chamber to the anterior chamber. At the same time, the lens that is fixed to the eyeball by gluing, after creating negative pressure with the help of a syringe, causes edema and microtraumas of the cornea, which require additional interventions with the administration of antibiotic and steroid preparations after the treatment procedure.

The problem, which the invention solves, consists in creating a device that can be used for prophylactic purposes against decreased visual acuity, against atrophy of the ciliary muscles, for stimulating the tone of the muscle and ciliary nerves, improving the circulation of aqueous humor, reducing edema and microtrauma of the cornea, which would not require procedures for the prophylaxis of possible complications after performing the electrostimulation procedure for improving blood circulation, namely for dilating the microcirculation with increasing blood supply to the muscle fibers, which leads to improving the trophism of the ciliary muscle whose function is disrupted due to prolonged vasospasm.

The stimulator, according to the invention, eliminates the disadvantages mentioned above by containing an electronic device, connected to a lens and equipped with a belt; the device consists of a housing and an electronic system, on the lower part of the housing, inside, a protective plate against electromagnetic waves is fixed, on the front part of the housing there is a digital screen, two "+" and "-" buttons for selecting the working power and the pulse characteristics, two off buttons, a RN-42 bluetooth module, a green LED and a red LED; the electronic system consists of a pulse generator, a frequency amplifier, a digital screen block, an ICM-7555 microprocessor, a power supply block, a charging block, a 3V battery, LED connections, the RN-42 bluetooth module, connections of twelve electrodes, an electrical micro-socket, which are placed and connected to each other on a motherboard; The lens is made concave from medical silicone with a diameter of 20…23 mm and a thickness of 1…2 mm, with a pierced hole made in the center of the lens, with a diameter of 10…13 mm, on the inner side of the lens are fixed twelve electrodes with a diameter of 1…2 mm, placed in two concentric circles of six electrodes at equal distances, and joined together by means of microcables hidden in the silicone layer of the lens, which are connected through the electrical microplug to the microsocket of the device.

The housing can be made round from medical plastic, with a diameter of 25...50 mm and a thickness of 8...12 mm.

The electrodes can be made of stainless steel or gold.

The belt can be made of natural leather or medical plastic with a width of 30 mm and a length of 50…65 mm and equipped with clips for fastening.

The result is that the device is equipped with a lens that is fixed on the eye above the ciliary body and stimulates the tone of the ciliary muscles and nerves, thus correcting visual acuity without tight adhesion to the cornea and without causing edema and miscotrauma to the cornea. At the same time, the result is that, by stimulating the regions of all the meridians of the eyeball, microcirculation dilation occurs with increased blood supply to the muscle fibers, which leads to improved trophism of the ciliary muscle.

The advantages of the ciliary muscle stimulator are that it helps prevent visual acuity loss, prevents atrophy of the ciliary muscles, stimulates the tone of the ciliary muscles, improves the circulation of aqueous humor from the posterior chamber to the anterior chamber of the eye, which improves the metabolism of the lens and cornea. It does not cause corneal complications, does not require the administration of antibiotics and steroids after each procedure, increases blood supply to the muscle fibers, which leads to improved trophism of the ciliary muscle. The gradual action of the electrodes in the peripheral row, then those in the center, stimulates some muscle bundles, then other muscle bundles of the ciliary muscle, contributing to adequate circulation of aqueous humor from the posterior chamber to the anterior chamber.

The invention is explained by the drawings in Fig. 1-4, which represent:

- Fig. 1, the ciliary muscle stimulator;

- Fig. 2, the electronic device;

- Fig. 3, lens with twelve electrodes;

- Fig. 4, the electronic system of the ciliary muscle stimulator.

The ciliary muscle stimulator 1 contains the electronic device 2 (fig. 1, 2), connected to the lens 3 and equipped with the belt 5, for fixing the device 2 on the head. The device 2 consists of the housing 7 and the electronic system 8, on the lower part of the housing 7, inside, the protective plate 9 against electromagnetic waves is fixed, on the front part of the housing 7 there is the digital screen 12, two buttons "+" and "-" 15 for selecting the working power and the pulse characteristics, two buttons off16, the RN-42 bluetooth module 6, the green LED 19 and a red LED 20. The electronic system 8 consists of the pulse generator 10, the frequency amplifier 11, the digital screen block 12, the ICM-7555 microprocessor 13, the power supply block 14, the charging block 17, the 3V battery 18, the LED connections 19 and 20, the RN-42 bluetooth module 6, the connections of twelve electrodes 4, the electrical microsocket 21, which are located and connected to each other on base plate 22. The lens 3 (fig. 3) is made concave from medical silicone with a diameter of 20…23 mm and a thickness of 1…2 mm, in the center of the lens 3 a pierced hole is made, with a diameter of 10…13 mm, on the inner side of the lens 3 twelve electrodes 4 with a diameter of 1…2 mm are fixed, placed in two concentric circles of six electrodes at equal distances, and connected to each other by means of microcables 23 and 24, which are hidden in the silicone layer of the lens 3 and connected by the electrical microplug 25 to the microsocket 21 of the device 2.

The housing 7 can be made round from medical plastic, with a diameter of 25…50 mm and a thickness of 8…12 mm. The electrodes 4 can be made from stainless steel or gold. The belt 5 for fixing the device on the head is made from natural leather or medical plastic with a width of 30 mm and a length of 50…65 mm with the possibility of adjustment and equipped with clips 26 for fixing.

Lens 3 is made concave, according to the concavity of the eyeball, and with a hole pierced in the center of the lens. The said hole is made to avoid irritation of the cornea during the procedure, which reduces patient discomfort and excessive tearing.

The charging block is of the 5V 3A SISO type.

The constructive connections of the electronic system are made according to figure 4. The motherboard 22 is the complex main board of the claimed electronic system on which the system components are mounted and represents the connecting element between all the components.

The operating modes of the device 2 are: electric current frequency of 1…120 Hz, electric current intensity of 10…35 mA and action time of 2 sec for the action of electrodes 4 in the circle on the periphery of lens 3, then 2 sec stimulation with electrodes 4 in the second circle, then 6 sec interruption of electric current, the total time of a cure is 10 sec, which can be repeated at an interval of 1…2 weeks.

It is considered that the treatment series includes several cycles gradually increasing the values, namely the lens 3 is applied over the eyeball and a cycle is performed with the intensity of the electric current of 10…35 mA with the frequency of the electric current of 1 Hz, for 2 sec with the electrodes 4 from the periphery of the lens 3, then 2 sec with the electrodes 4 from the second circle, then for 6 sec the electric current is interrupted, after which the analog stimulation is performed on the medial part of the eyeball. Then after 1…2 weeks another procedure is performed with the frequency of the electric current of 5 Hz, then after 1…2 weeks with 10 Hz, with the same current strength or increased depending on the individual sensory threshold. The frequency of the procedures may be diverse depending on the restoration of visual acuity, in some patients there may be 2…3 procedures, and in others 5…6 procedures may be performed, with an interval of 1…2 weeks. The interval between procedures is individual, also depending on the individual sensory threshold.

Embodiment of the invention

In one patient, local anesthesia was performed on the eyes and the lens 3 was applied over the eyeball, namely on the sclera and the ciliary body, after which the device 2 was connected and the RN-42 bluetooth module 6 was connected. The working power and pulse characteristics for the first cycle were selected with the buttons 15, namely the electric current intensity of 25 mA with the electric current frequency of 1 Hz, for 2 sec for the electrodes 4 in the circle on the periphery of the lens 3, then 2 sec for the electrodes 4 in the second circle, then for 6 sec the electric current was interrupted, after which the analog stimulation was performed on the medial part of the eyeball. After 1 week, the procedure was repeated with the electric current frequency of 5 Hz, then after another 1 week with 10 Hz with the same electric current strength. Three stimulation procedures were performed on the respective patient each week with the restoration of visual acuity. The selection of the electric current values is carried out under the supervision of an ophthalmologist. At the same time, the values can be changed, or the device can be connected or disconnected using a mobile phone via the RN-42 6 bluetooth module.

The ciliary muscle stimulator meets sanitary requirements and standards, and the conditions and parameters of the device are sufficient to solve the assigned tasks.

This device can be used for prophylactic purposes against atrophy of the ciliary muscle and the trigeminal and oculomotor nerves, thus being used in ophthalmology and optometry, for the treatment of pathologies related to visual acuity.

1. Luca Gualdi, Federica Gualdi, Dario Rusciano, Renato Ambrosio et al., Ciliary Muscle Electrostimulation to Restore Accommodation in Patients With Early Presbyopia: Preliminary Results, Journal of Refractive Surgery, SLACK Journals, 2017, Found on the Internet < https://journals.healio.com/doi/10.3928/1081597X-20170621-05>

Claims (4)

1. Ciliary muscle stimulator, which contains an electronic device (2), connected to a lens (3) and equipped with a belt (5); the device (2) consists of a housing (7) and an electronic system (8), on the lower part of the housing (7), inside, a protective plate (9) against electromagnetic waves is fixed, on the front part of the housing (7) there is a digital display (12), two buttons "+" and "-" (15) for selecting the working power and the pulse characteristics, two buttons off (16), a bluetooth module RN-42 (6), a green LED (19) and a red LED (20); the electronic system (8) consists of a pulse generator (10), a frequency amplifier (11), a digital display unit (12), an ICM-7555 microprocessor (13), a power supply unit (14), a charging unit (17), a 3V battery (18), LED connections (19 and 20), the RN-42 bluetooth module (6), twelve electrode connections (4), an electrical micro-socket (21), which are located and connected to each other on a motherboard (22); the lens (3) is made concave from medical silicone with a diameter of 20…23 mm and a thickness of 1…2 mm, in the center of the lens (3) a pierced hole is made, with a diameter of 10…13 mm, on the inner side of the lens (3) twelve electrodes (4) with a diameter of 1…2 mm are fixed, placed in two concentric circles of six electrodes at equal distances, and joined together by means of microcables (23 and 24), which are hidden in the silicone layer of the lens (3) and connected by the electrical microplug (25) to the microsocket (21) of the device (2). 2. Stimulator according to claim 1, wherein the housing (7) is made round from medical plastic, with a diameter of 25...50 mm and a thickness of 8...12 mm. 3. Stimulator according to claim 1, wherein the electrodes (4) are made of stainless steel or gold. 4. Stimulator according to claim 1, wherein the belt (5) is made of natural leather or medical plastic with a width of 30 mm and a length of 50…65 mm and equipped with clips (26) for fastening.