RU2621421C1 - Electrode for cranial nerves identification - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: electrode contains a holder with a symmetry axis O-O1, connected via a spring with an active tip connected to the control unit by a conductor, while the thrust is fixed on the active tip with a shift relative to the O-O1 axis.

EFFECT: application of the invention allows to reduce the active tip invasiveness at the time of its contact with the affected zone and to extend device functionality.

9 cl, 6 dwg

Description

The device relates to medical equipment and can be used in neurosurgery for intraoperative identification of cranial nerves.

A known electrode containing a holder with an axis of symmetry O-O1 and an active tip connected to a conductor control unit (patent RU 2148394). This device is selected as a prototype of the proposed solution.

The disadvantage of this device is the hard interaction (impossibility of elastic interaction) of the active tip of the electrode at the time of its contact with the exposure zone, which can cause mechanical, traumatic damage to the underlying biological tissue and lead to a decrease in the functionality of the device.

The technical result of the invention is to reduce the morbidity of the interaction of the active tip of the electrode at the time of its contact with the exposure zone (underlying biological tissue) and expand the functionality of the device.

The specified technical result is achieved by the fact that in the electrode containing the holder with the axis of symmetry O-O1 and the active tip connected to the conductor control unit, the active tip is fixed to the holder by means of a spring module with the possibility of spring movement along the axis O-O1, as well as with the possibility spring displacement across its direction.

There is a variant in which the active tip has a spherical shape and is mounted on a holder on a coil spring.

There is an option in which the active tip is drop-shaped and mounted on a holder on a coil spring.

There is an option in which the electrode is equipped with a rod mounted on an active tip of a spherical shape with a shift relative to the axis of symmetry O-O1, while the rod has the ability to be fixed on the holder.

There is an option in which the electrode is equipped with a rod mounted on an active drop-shaped tip with a shift relative to the axis of symmetry O-O1, while the rod has the ability to be fixed on the holder.

There is a variant in which the active tip has a U-shape and is made of a spring wire of circular cross section.

There is a variant in which the active tip has a U-shape and is made of a spring element of rectangular cross section.

There is an option in which the electrode is equipped with a rod mounted on an active U-shaped tip made of a spring wire of circular cross section with a shift relative to the axis of symmetry O-O1, while the rod has the ability to be fixed on the holder.

There is an option in which the electrode is equipped with a rod mounted on an active U-shaped tip made of a spring element of rectangular cross section with a shift relative to the axis of symmetry O-O1, while the rod has the ability to be fixed on the holder.

In FIG. 1 shows a diagram of an electrode in general form.

In FIG. 2 shows a variant of an electrode with a spherical active tip.

In FIG. 3 shows a variant of an electrode with a drop-shaped active tip.

In FIG. 4 shows a variant of the electrode with a U-shaped active tip made of a spring wire of circular cross section.

In FIG. 5 shows a variant of an electrode with a U-shaped active tip made of a spring element of rectangular cross section.

In FIG. 6 shows a variation of the geometry of the position of the active tip.

The electrode contains a holder 1 (Fig. 1) with an axis of symmetry O-O1 and an active tip 2 connected to the control unit 3 by a conductor 4. The active tip 2 is mounted on the holder 1 by means of a spring module 5 with the possibility of spring movement along the axis O-O1, and also with the possibility of spring movement across its direction. As the material of the holder 1, you can use polystyrene. The diameter of the holder 1 can be in the range of 4-6 mm, and its length is 15-25 cm.

There is a variant in which the active tip 2 (Fig. 2) has a spherical shape 6 and is mounted on a holder 1 on a cylindrical spring 7. The diameter of the tip 2 of a spherical shape 6 can be in the range of 2-5 mm. As the material of the tip 2, you can use silver. The diameter of the coil spring 7 may be in the range of 2-5 mm, and its length is 5-12 mm. As the material of the coil spring 7, it is possible to use a wire of steel 65G with a diameter of 0.1-0.3 mm, coated with nickel.

There is a variant in which the active tip 2 (Fig. 3) has a teardrop shape 8 and is mounted on the holder 1 on a coil spring 7. The length of the tip 2 of the teardrop shape 8 can be 4-7 mm, and its diameter is 2-5 mm.

There is an option in which the electrode is equipped with a rod 10 (Fig. 2), mounted on the active tip 2 of a spherical shape 6 with a shift relative to the axis of symmetry O-O1, while the rod 10 can be fixed on the holder 1. As the material of the rod 10, you can use wire from steel 12X18H10T with a diameter of 0.1-0.5 mm. A hole can be made in the tip 2 of the spherical shape 6, in which the rod 10 can be fixed by soldering or loop. The rod 10 can be fixed in the holder 1 with a screw 12. The screw 12 in the holder 1 can be installed using a metal sleeve with an internal thread ( not shown).

There is an option in which the electrode is equipped with a rod 10 (Fig. 3), mounted on the active tip 2 of a teardrop shape 8 with a shift relative to the axis of symmetry O-O1, while the rod 10 has the ability to be fixed on the holder 1. In the tip 2 of a teardrop shape 8 a hole is made in which the rod 10 can be fixed by soldering or loop. The rod 10 can be fixed in the holder 1 with a screw 12. The screw 12 in the holder 1 can be installed using a metal sleeve with an internal thread (not shown).

There is a variant in which the active tip 2 (Fig. 4) has a U-shape 13 and is made of a spring wire of circular cross section. The radius R1 of the tip 2 of the U-shaped 13 can be in the range of 3-7 mm, and its height H1 is in the range of 3-7 mm. As the material of the tip 2 of the U-shaped form 13, you can use a wire of steel 65G with a diameter of 0.1-0.5 mm, coated with nickel.

There is a variant in which the active tip 2 (Fig. 5) has a U-shape 15 and is made of a spring element of rectangular cross section. The radius R2 of the tip 2 of the U-shaped 15 can be in the range of 3-7 mm, and its height H2 is in the range of 3-7 mm. As the material of the tip 2 of the U-shaped form 15, tin bronze of thickness E in the range of 0.1-0.3 mm and width C in the range of 2-5 mm and coated with silver can be used.

There is an option in which the electrode is equipped with a rod 10 (Fig. 4), mounted on the active tip 2 of a U-shape 13 with a shift relative to the axis of symmetry O-O1, while the rod 10 has the ability to be fixed on the holder 1 (the same as on Fig. 2, Fig. 3). The active tip 2 of the U-shape 13 can be connected to the rod 10 by spot welding.

There is an option in which the electrode is equipped with a rod 10 (Fig. 5), mounted on the active tip 2 of a U-shape 15 with a shift relative to the axis of symmetry O-O1, while the rod 10 is able to be fixed on the holder 1 (the same as on Fig. 2, Fig. 3). The active tip 2 of the U-shape 15 can be connected to the rod 10 by spot welding.

The electrode operates as follows.

In neurosurgical surgery, when removing various tumors of the base of the skull, it is extremely important to know the location of the cranial nerves under the conditions of altered topographic and anatomical relationships between the cranial nerves, normal tissue of the base of the skull and the tumor. Knowing the exact location of the cranial nerve avoids its iatrogenic intraoperative damage, which ensures its anatomical and functional safety and will not further lead to functional insufficiency of the cranial nerve and will ensure a high quality of life for the patient in the postoperative period.

In the area of the alleged passage of a cranial nerve, the neurosurgeon sets the tip of the electrode (spherical 6, drop-shaped 8 or U-shaped 13, 15), through which monopolar electrical stimulation is performed by rectangular pulses of 0.1 ms duration in the range from 1 to 10 mA.

An additional difference of this electrode is the fact that in addition to the stimulation function, it can be used as a recording sensor when recording direct sensory responses from nerve trunks.

The shape of the distal part of the electrode (spherical 6, drop-shaped 8 or U-shaped 13, 15) allows you to increase the contact area of the tip of the electrode with biological tissues (those or other underlying cranial nerves), which reduces the morbidity of the interaction of the distal part of the electrode with the underlying biological tissues, and increases sensitivity in identifying cranial nerves.

The presence of the spring module 5 allows you to move the distal part of the electrode (tip) along the O-O1 axis, which provides elastic interaction between the distal part of the electrode and the underlying biological tissue, which reduces the traumatic effect on the underlying biological tissues (cranial nerves). The presence of traction 10 and spring module 5 allows you to change the geometric shape of the distal part of the device, thereby expanding the available area for searching cranial nerves, which is especially important in minimally invasive surgery of skull base tumors, for example, with endoscopic endonasal removal of skull base tumors.

The fact that the active tip 2 is mounted on the holder 1 by means of a spring module 5 with the possibility of spring movement along the axis O-O1, as well as with the possibility of spring movement across its direction, reduces the invasiveness of the impact zone and extends the functionality of the device.

The fact that the active tip 2 has a spherical shape 6 and is mounted on the holder 1 on a coil spring 7, reduces the invasiveness of the impact zone and extends the functionality of the device.

The fact that the active tip 2 has a teardrop shape 8 and is mounted on the holder 1 on a coil spring 7, due to the lateral contact of the impact zone further reduces its invasiveness and expands the functionality of the device.

The fact that the electrode is equipped with a rod 10, mounted on the active tip 2 of a spherical shape 6 with a shift relative to the axis of symmetry O-O1, allows you to change the geometric position of the active tip 2 relative to the holder 1, facilitates diagnosis in hard-to-reach areas and extends the functionality of the device.

The fact that the rod 10 has the ability to be fixed on the holder 1, simplifies the operation of the device.

The fact that the electrode is equipped with a rod 10 mounted on an active tip 2 of a teardrop shape 8 with a shift relative to the axis of symmetry O-O1 allows you to change the geometric position of the active tip 2 relative to the holder 1, facilitates diagnosis in hard-to-reach areas and extends the functionality of the device.

The fact that the active tip 2 has a U-shape 13 and is made of a spring wire of circular cross section, reduces the invasiveness of the impact zone, because active tip 2 also has spring properties. This expands the functionality of the device.

The fact that the active tip 2 has a U-shape 15 and is made of a rectangular element further reduces the invasiveness of the impact zone, because the active tip 2 has spring properties, and by increasing the width C allows you to reduce the specific pressure on the impact zone. This expands the functionality of the device.

The fact that the electrode is equipped with a rod 10 mounted on the active tip 2 of the U-shape 13 with a shift relative to the axis of symmetry O-O1, allows you to change the geometric position of the active tip 2 relative to the holder 1, facilitates diagnostics in hard-to-reach areas and extends the functionality of the device.

The fact that the electrode is equipped with a rod 10, mounted on the active tip 2 of the U-shape 15 with a shift relative to the axis of symmetry O-O1, allows you to change the geometric position of the active tip 2 relative to the holder 1, facilitates diagnosis in hard-to-reach areas and extends the functionality of the device.

Claims (9)

1. An electrode for neurosurgery, comprising a holder with an axis of symmetry O-O1, connected by a spring with an active tip connected by a conductor to the control unit, characterized in that a rod is fixed to the active tip with a shift relative to the axis O-O1.  2. The electrode according to claim 1, characterized in that the active tip has a spherical shape, and the spring is cylindrical. 3. The electrode according to claim 1, characterized in that the active tip has a teardrop shape, and the spring is cylindrical. 4. The electrode according to p. 2, characterized in that the rod is made with the possibility of fixing on the holder. 5. The electrode according to p. 3, characterized in that the rod is made with the possibility of fixing on the holder. 6. The electrode according to claim 1, characterized in that the spring has a U-shape and is made of a spring wire of circular cross section. 7. The electrode according to claim 1, characterized in that the spring has a U-shape and is made with a rectangular cross section. 8. The electrode according to p. 6, characterized in that the rod is made with the possibility of fixing on the holder. 9. The electrode according to claim 7, characterized in that the rod is made with the possibility of fixing on the holder.

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