RU2469688C1 - Ultrasonic instrument of phacoemulsifier with composite ultrasonic vibrations - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: instrument comprises a body with an in-built wave guide containing ultrasonic vibration concentrator with a needle on a working end, a piezoelectric cell assembly and a bearing sleeve in the centre of which there is a canal for eye fluid aspiration. Between the body and the concentrator there is a space which is filled with in irrigation solution. Between the piezoelectric cell assembly and the concentrator from one side and the piezoelectric cell assembly and the bearing sleeve from the other side there are insert elements in the form of truncated cylinders with one basis having an angle of skew 75-85° and the other basis inclined 90° to a central axis of the wave guide from a material having a different ultrasound conduction velocity from primary materials of the wave guide of the ultrasonic instrument in 1.5-2 times. The bases of the concentrator and the bearing sleeve have an angle of skew 75 to 85°, while the concentrator and the bearing sleeve are positioned relatively to each other rotationally about the central axis at 0 to 180° with respect to the skewed planes.

EFFECT: use of the invention reduces a degree of manifestation of a repulsive phenomenon and provides the concentration of a cavitation cloud close to an end face of a hollow needle.

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Description

The invention relates to medicine, namely to ophthalmology, and can be used for cataract extraction by ultrasonic phacoemulsification.

The destruction of the cloudy lens by ultrasound is carried out using high-tech devices - phacoemulsifiers. One of the main elements of the phacoemulsifier is an ultrasound instrument, the working part of which is inserted into the anterior chamber of the eye through a self-sealing incision in the form of a hollow needle and a silicone cuff and crushes and aspirates the lens fragments, as well as delivers an irrigation solution.

As a rule, an ultrasonic instrument consists of a waveguide, which, in turn, consists of a hollow needle, an ultrasonic vibrations concentrator, a pair of piezoelectric elements and a support sleeve located in a hollow body.

The working part of an ultrasonic instrument in the form of a hollow needle produces ultrasonic vibrations that are used for crushing and emulsification of dense crystalline masses. The inner cavity of the needle is an aspiration channel for removing destroyed fragments of the lens masses. Through a silicone cuff coaxially positioned relative to the hollow needle, a replacement irrigation fluid is supplied.

The design of most ultrasound instruments involves the destruction of the lens through longitudinal ultrasonic vibrations of the hollow needle (Kelman C.D., 1967; Seibel B.S. et al., 1999; Packer M. et al., 2005; Fishkind W. et al., 2006). The disadvantage of such a system is the presence of the phenomenon of “repulsion” of lens fragments from the working end of the hollow needle under the action of ultrasonic waves acting in the longitudinal direction. The cavitation component during longitudinal ultrasonic vibrations at the moment of repulsion of the lens fragments affects mainly the surrounding intraocular structures, increasing the likelihood of their damage and the development of intra- and postoperative complications (for example, corneal edema associated with ultrasound damage to the endothelium) (Davison JA et al., 2008; Zeng M. et al., 2008). To eliminate this drawback, an important factor is the “retention” of the lens fragments (due to aspiration and partial or complete occlusion) at the working end of the cannula.

In order to increase the efficiency of emulsification of the lens masses, the use of composite ultrasonic vibrations is proposed.

Analogs of the proposed system are OZiL (Alcon Labs, USA) and Ellips (Abbott Medical Optics, USA) systems.

An ultrasonic instrument of the OZiL system means “an ultrasonic instrument having at least one pair of piezoelectric elements producing longitudinal oscillations when excited at the corresponding resonant frequency. Piezoelectric elements are assembled in an ultrasonic waveguide to which a hollow needle is attached. An ultrasonic waveguide and / or hollow needle contains many diagonal slits or grooves. Slots or grooves provide torsion vibrations on the hollow needle when excited at the second resonant frequency ”(US Patent 2010004586 A1, P.1). The disadvantage of this system is that it requires the tuning of the ultrasonic generator to two resonant frequencies (longitudinal and torsion), which significantly complicates the design of the system.

The ultrasonic instrument of the Ellips system is a “tip with a needle, the distal end of which oscillates in the longitudinal and transverse directions at the same working frequency”, this is ensured by “the displacement of the center of mass of the ultrasonic instrument relative to its central axis or by the action on the nodes and anti-nodes of the ultrasonic instrument” (US Patent 2008/0294087 A1). The disadvantage of tools of this design is their fragility, the displacement of the center of mass leads to the destruction of ceramics and other structural elements.

The closest analogue of the invention is the ultrasonic handle of the phacoemulsifier, comprising a housing with a waveguide located in it, consisting of a hub with a needle at the working end, a multiple of piezoelectric elements and a coupling, in the center of which passes an aspiration channel, there is a cavity between the housing and the hub that is configured to washing it off with irrigation solution, at the same time, at least 4 cuts symmetrically located relative to the axis of cuts with a width of at least 0.5 and more than 1.0 mm (patent RU 2271182, 2006).

The objective of the invention is to increase the efficiency of ultrasonic destruction of the lens by creating complex composite vibrations of the working end of the hollow needle.

The technical result achieved by using the invention is to reduce the severity of the “repulsion” phenomenon, increase the time spent by the lens fragments in the field of effective ultrasound exposure, as well as the concentration of the cavitation cloud near the end of the hollow needle and increase the cutting ability of the ultrasonic instrument.

The specified technical result is achieved by the fact that in the ultrasonic instrument of the phacoemulsifier containing a housing with a waveguide located in it, consisting of an ultrasonic vibrations concentrator with a needle at the working end, a piezoelectric element block and a support sleeve, in the center of which there is a channel for aspirating fluid from the eye, and between the housing and the concentrator there is a space that is filled with irrigation solution, according to the invention between the piezoelectric block and the concentrator on the one hand and the piezoelectric block combs and a support sleeve, on the other hand, inserts in the form of truncated cylinders with one base having a bevel angle of 75-85 ° and the other at an angle of 90 ° to the central axis of the waveguide, made of a material differing in the speed of conducting ultrasound from the materials of the concentrator and the support sleeve of the ultrasonic instrument is 1.5-2 times, while the base of the hub and the support sleeve have a bevel angle of 75-85 ° relative to the Central axis of the waveguide, and the hub and support sleeve are located relative to each other with rotation around In Central axis by an angle from 0 to 180 ° relative to the chamfered planes. The hub is made of VT-1 titanium, the support sleeve is made of VK-8 alloy, and the inserts are made of BR-6 bronze.

The introduction of additional inserts between the piezoelectric block and the concentrator on the one hand and between the piezoelectric block and the support sleeve on the other causes the formation of complex composite ultrasonic vibrations on the working end of the hollow needle at one resonant frequency, which more effectively destroy the lens material due to the concentration of the cavitation cloud on the working end hollow needles and reduce the phenomenon of "repulsion" of fragments of the lens from the tip.

It has been experimentally established that the optimal angle of inclination of the bases of the concentrator, the support sleeve and one of the bases of the inserts is in the range between 75 and 85 °, since an angle of more than 85 ° does not provide sufficient expression of composite vibrations, and the angle of inclination of less than 75 ° causes structural difficulties when assembly. By turning the concentrator and the support sleeve around the central axis by an angle from 0 to 180 °, it is possible to obtain longitudinal and transverse movements of the working end, as well as their various combinations, for example, in the form of the number eight or an ellipse at one working frequency (for example, 44 kHz ± 10 %).

The invention is illustrated by the following figures.

Figure 1 shows the proposed ultrasonic instrument of the phacoemulsifier, comprising a housing 1 with a waveguide 2 placed therein, consisting of an ultrasonic vibration concentrator 3, a hollow needle 4 attached to it with a silicone sleeve 5, a piezoelectric element block 6, a support sleeve 7, in the center of which passes channel 8 for aspiration of fluid and lens fragments from the eye, and between the body and the concentrator there is a space 9, which is filled with irrigation solution. The bases of the concentrator 3 and the support sleeve 7 have a bevel angle of 75 to 85 °, and inserts 11 are made in the form of truncated cylinders with one base having an angle between the piezoelectric element block 6 and the concentrator 3 on the one hand and the piezo element block 6 and the support sleeve 7 on the other bevel 75-85 °, and the other - located at an angle of 90 ° to the central axis 10 of waveguide 2, made of a material that differs in the speed of conducting ultrasound from the materials of the hub and the supporting sleeve of an ultrasonic instrument by 1.5-2 times.

Figure 2 shows the location of the concentrator 3 and the support sleeve 7 relative to each other with rotation around the central axis by an angle of 0 °.

Figure 3 presents the location of the concentrator 3 and the support sleeve 7 relative to each other with rotation around a central axis by an angle of 90 °.

Figure 4 shows the location of the hub 3 and the support sleeve 7 relative to each other with rotation around a central axis by an angle of 180 °.

The use of the invention is as follows. Turn on and prepare the phacoemulsifier for work. A hollow needle is connected to the working end of the hub by means of a threaded connection. Through a small self-sealing corneal incision, the cannula is brought to the lens and, under the influence of ultrasonic waves generated by the waveguide, is destroyed and aspirated. Due to the introduction of additional inserts made of a material that differs in the speed of conducting ultrasound from the main material of the waveguide of an ultrasonic instrument, complex composite ultrasonic vibrations (a combination of longitudinal and transverse vibrations of various amplitudes) arise at the working end of the hollow needle, which increase the efficiency of using ultrasonic energy at phacoemulsification, reducing the risk of intra- and postoperative complications associated with ultrasound damage to the endothelium I have corneas and other intraocular structures.

The effectiveness of the proposed ultrasonic instrument phacoemulsifier is illustrated by the following clinical examples.

Example 1. Patient B., 70 years old, diagnosis: OS: Mature age-related cataract. Visual acuity before surgery: OS - light sensing with the correct light projection. The density of endothelial cells before surgery is 2378 cells / mm ² . The cataract was removed in 65 seconds using the proposed ultrasonic phacoemulsifier instrument. A flexible intraocular lens was implanted. The operation and the postoperative period proceeded without complications. Visual acuity OS the day after surgery 0.7 without correction. The density of endothelial cells on the 30th day after surgery is 2093 cells / mm ² , the loss of endothelial cells is 11%.

Example 2. Patient G., 57 years old, diagnosis: OD: Incomplete complicated cataract. Visual acuity before surgery OS 0.05, does not correct. The density of endothelial cells before surgery is 2753 cells / mm ² . The cataract was removed in 32 seconds using the proposed phacoemulsifier ultrasound instrument. A flexible intraocular lens was implanted. The operation and the postoperative period without complications. The visual acuity of OD the next day is 0.9 without correction. The density of endothelial cells on the 30th day after surgery is 2490 cells / mm ² , the loss of endothelial cells is 9.6%.

Clinical use of the proposed ultrasonic phacoemulsifier instrument in Optimum Vision Recovery Centers with 30 eyes showed: by increasing the efficiency of ultrasonic lens destruction, the number of intra- and postoperative complications associated with the negative impact of ultrasound on intraocular structures, in particular postoperative corneal edema and burns in the area, is reduced corneal tunnel incision.

Claims (2)

1. An ultrasonic phacoemulsifier tool, comprising a housing with a waveguide placed therein, consisting of an ultrasonic vibrations concentrator with a needle at the working end, a piezoelectric element block and a support sleeve, in the center of which there is a channel for aspirating fluid from the eye, and there is a space between the body and the hub, which is filled with irrigation solution, characterized in that between the piezoelectric element block and the concentrator on the one hand and the piezoelectric element block and the support sleeve on the other are inserted in the form of cross-sectional cylinders with one base having a bevel angle of 75-85 °, and the other located at an angle of 90 ° to the central axis of the waveguide, made of material differing in the speed of ultrasound from the main materials of the waveguide of an ultrasonic instrument by 1.5-2 times, the bases of the hub and the support sleeve have a bevel angle of 75 to 85 ° relative to the central axis of the waveguide, and the hub and the support sleeve are located relative to each other with rotation around the central axis by an angle from 0 to 180 ° relative to the beveled bones. 2. The ultrasonic instrument according to claim 1, characterized in that the hub is made of VT-1 titanium, the support sleeve is made of VK-8 alloy, the inserts are made of BR-6 bronze.

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