RU65382U1 - CANULA FOR REMOVAL OF INNER-BRAIN HEMATOMAS - Google Patents

Abstract

The utility model relates to medical equipment, namely to instruments used in neurosurgery, and can be used to remove intracerebral hematomas in hemorrhagic stroke, traumatic brain injury. The cannula for removing intracerebral hematomas is made in the form of a funnel having a height of 40-60 mm, the diameter of the larger base is 23-27 mm. the diameter of the smaller base is 13-17 mm, and a restrictive flange is installed on the larger base. Using the utility model allows to reduce the morbidity and simplify the surgical technique for removing intracerebral hematomas. The use of the claimed cannula does not require large osteoplastic trepanation of the skull, its installation can be performed under local anesthesia, which is very important for patients in serious condition and with concomitant pathology.

Description

The utility model relates to medical equipment, namely to instruments used in neurosurgery, and can be used to remove intracerebral hematomas in hemorrhagic stroke, traumatic brain injury.

It is known to use a special device that is rigidly fixed to a stereotactic frame. The device is made in the form of a cylindrical cannula, inside which a screw (plate spiral) is installed, designed to destroy blood clots. The rotation of the spiral at a given speed inside the cannula is provided by a miniature electric motor. Removal of blood clots is carried out according to the direct-flow principle with a conventional aspirator interacting with the device. The mechanical rotation of the spiral ensures the passage of blood clots along the cannula to which the suction is connected (V.V. Perecedov. Differentiated surgical treatment of non-traumatic supratentorial intracerebral hemorrhages. - Author. Diss. MD, Moscow, 1990, 44 p.).

The disadvantage of this device is the need for rigid fixation to the stereotactic frame, which reduces the control of the adequacy of hematoma removal. During the removal of the hematoma, a vacuum effect is observed, which requires the use of an additional method of compensating injection of saline into the lateral ventricle of the opposite hemisphere.

There is also some cumbersomeness of the entire system and the need for additional equipment - an electric motor.

It is known to use tubular cannulas to remove intracerebral hematomas (V.V. Lebedev, Yu.S. Ioffe. I.M. Ostrovskaya. Surgery of acute cerebral strokes.- M., 1970, p.223). Cannulas are made of stainless steel in the form of thin-walled tubes of different lengths. The edges of the tubes are polished, a metal handle is soldered to one of the edges. After diluting the white matter of the brain with spatulas, one or another cannula is inserted into the wound depending on the depth of the hematoma and the width of the wound, after which the spatulas are removed. Inspection of the cavity and the evacuation of the hematoma is carried out by instruments inserted through the internal opening of the cannula. After the end of all manipulations, the tube is removed from the brain wound.

The use of the tube does not provide the creation of a wide drainage channel, which allows to fully drain the hematoma cavity. In addition, the need for a wide osteoplastic or resection craniotomy and encephalotomy with brain spatulas, after which tubes are inserted into the wound, leads to additional brain injury.

The technical result achieved by the utility model is to create a wide drainage channel, reduce trauma and simplify the operating technique for removing intracerebral hematomas.

The essence of the utility model is to achieve the specified technical result in the cannula for removing intracerebral hematomas, which is made in the form of a funnel having a height of 40-60 mm, the diameter of the larger base is 23-27 mm, the diameter of the smaller base is 13-17 mm, and on the larger a restriction flange is installed on the base.

The indicated dimensions of the funnel-shaped cannula allow the most complete drainage of the hematoma cavity at any location. The presence of a restrictive flange enables reliable fixation of the cannula in the wound.

The drainage channel is created by widespread circular dilution of the brain tissue with the help of established successively expanding brain extender tubes and a funnel-shaped cannula. With this sequence, the brain tissue is stretched evenly and, therefore, is less injured than with encephalotomy. Creating a wide drainage channel into the hematoma cavity using

a funnel-shaped cannula makes it easy to remove most of the hematoma with an electric suction device. As a result, the critical volume of the intracerebral hematoma decreases, which leads to the elimination of the syndrome of dislocation and compression of the brain and creates favorable conditions for the restoration of vital body functions.

The funnel-shaped cannula can be left in the wound for up to 12-24 hours and the hematoma cavity can be drained during this time. Under the influence of natural pulsation and due to the presence of a wide drainage channel, the brain pushes the remnants of blood clots through a funnel-shaped cannula expanding outward. Evacuation of blood leads to subsidence and elimination of the hematoma cavity, which contributes to the normalization of hemodynamics, a decrease in cerebral edema and vascular disorders.

The cannula can be installed under local anesthesia, which is very important for patients who are in serious condition and have a concomitant pathology.

The figure 1 presents a General view of the cannula; figure 2 - layout of the cannula during drainage of the hematoma cavity.

The cannula is made in the form of a funnel 1 having a height h of 40-60 mm. The diameter d _{1 of the} larger base 2 is 23-27 mm, the diameter d _{2 of the} smaller base 3 is 13-17 mm. On a larger base 2, a restrictive flange 4 is installed (Fig. 1).

The cannula is set, for example, as follows.

After stereotactic calculations in the hematoma projection, a trimming hole is placed in the bone with a crown cutter, the diameter of which corresponds to the diameter d _{1 of the} larger base 2 of the funnel-shaped cannula. The bone disc is temporarily removed. The dura mater is opened. Using installed successively increasing the size of the brain tubes of dilators spend a funnel-shaped cannula 1 to place its smaller base 3 in the cavity of the hematoma 5 (figure 2) and carry out the removal of the hematoma through the funnel-shaped cannula 1.

If necessary, a funnel-shaped cannula is left in the wound for 12-24 hours. After completion of the drainage, the funnel-shaped cannula is removed, the dura mater is sutured, the bone disc is placed in place and the wound is closed.

The utility model is illustrated by the following clinical example.

Patient K., 54 years old, was admitted with a diagnosis of "Acute cerebrovascular accident in the pool of the right middle cerebral artery by hemorrhagic type. Intracerebral hematoma in the right parietal-temporal region." The severity of the condition and the disorder of consciousness on the Glasgow coma scale at admission was 8 points, which corresponded to stupor. The patient had left-sided hemiplegia with hemianesthesia. Computed tomography revealed lateral hemorrhage in the right parietal-temporal region with a volume of about 90 cm ³ , which caused a significant displacement of the middle structures of the brain. An operation was performed during which a linear incision of the skin and soft tissues with a length of 3.5-4.0 cm was made in the right parietal-temporal region. The periosteum is skeletonized. A crowning cutter with a 2.5 cm diameter was placed on the bone with a treforation hole and the bone disc was temporarily removed. The dura mater is opened by a cruciform incision. In the avascular zone, the cerebral cortex is coagulated. A tube-expander, the outer diameter of which is 6 mm, was used to puncture the hematoma cavity through the parenchyma and thick, black blood was obtained at a depth of 3.0-3.5 cm. About 4.0 ml of blood was sucked off with a syringe. Next, a second larger tube is drawn along the first expander tube, the inner lumen of which fits tightly with the outer diameter of the first, and the outer diameter is 15 mm. Then, a funnel-shaped cannula 40 mm high with a diameter of a larger base of 25 mm and a diameter of a smaller base of 15 mm was passed through a second tube-expander. The base of the cannula, having a restrictive flange, was fixed in the bone window. After removing both dilator tubes, hematoma clots began to stand out. An electric suction device removed most of the hematoma. A rubber reservoir is placed on the larger base of the funnel-shaped cannula to collect the remaining blood clots. A temporary bed was made for the bone disc in the subaponeurotic space. About 20 ml of blood clots were released during the day. The funnel-shaped cannula and drainage are removed, the dura mater is sutured. The bone disc is removed from the subaponeurotic space and laid in its place. The periosteum, aponeurosis, skin are sutured. The patient underwent control computed tomography, where about 10-15 ml of the remaining blood was determined, and no displacement of the median structures of the brain was detected. The patient's condition has improved. The patient was discharged on the 15th day. The state of consciousness was estimated at 15 points, which corresponded to clear consciousness. When discharged from the patient, complete restoration of movements and

sensitivity in the left leg and monoparesis with restoration of sensitivity in the left hand.

Using the utility model allows to reduce the morbidity and simplify the surgical technique for removing intracerebral hematomas. The use of the claimed cannula does not require large osteoplastic trepanation of the skull, its installation can be performed under local anesthesia, which is very important for patients in serious condition and with concomitant pathology.

Claims (1)

Cannula for removing intracerebral hematomas, characterized in that it is made in the form of a funnel having a height of 40-60 mm, a diameter of a larger base 23-27 mm, a diameter of a smaller base 13-17 mm, and a restrictive flange is installed on a larger base.