RU2108063C1 - Ultrasonic method for examining brain - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: method involves applying unidimensional ultrasonic detection and ranging. Brain mantle index is calculated as ratio of distance from lateral wall of temporal horn to the terminal complex to distance from temporal bone to median line. Brain trunk index is additionally calculated as ratio of distance from epiphysis to the terminal complex to distance from the vertex to the terminal complex. Cerebellum index is calculated as ratio of distance from the fourth ventricle to the terminal complex to distance from frontal bone to the terminal complex. The third ventricle index is calculated as ratio of distance between two signals from the third ventricle wall to distance from temporal bone to median line. Increase in the number and amplitude of echo signals and brain index values, drop in the third ventricle index value and growth of echo signals pulsation being observed, brain swelling growth is considered to be the case. Pulsation heights lowering down to complete vanishing in process dynamics, terminal brain state is determined. Increased amplitude of echo signals from ventricle walls, reduced brain index, increased third ventricle index, grown echo signals pulsation being observed, growing hydrocephalus is considered to be the case. Following drop in pulsation heights lowering down to complete vanishing and the third ventricle wall tremor in the pulse rhythm being observed, complete occlusion is diagnosed. EFFECT: enhanced accuracy and completeness of brain state diagnosis. 2 cl

Description

 The invention relates to medicine and can be used in neurology, neurosurgery, in intensive care and emergency care, in any emergency department, in a clinic and outside a medical institution for emergency diagnosis of diseases, injuries and volumetric processes of the brain and subsequent monitoring of the process.

 The studies were performed on ultrasonic devices of one-dimensional location of the brain (Echo-11, Echo-12, EMU-A-2, etc.).

 Known methods for ultrasound examination of the brain, described in the work of Skorunsky I.A., and the closest analogues published in the work "Clinical Echoencephalography" edited by Bogolepova N.K. and others, do not allow the study to be carried out in full.

 The objective of the invention is to develop a more complete diagnosis of the state of the brain, adapted to the conditions of emergency diagnosis.

 The method is as follows. The patient usually lies on his back or sits, the device is installed in a position convenient for the researcher, sensors with a frequency of 0.88 MHz for adults and 1.76 MHz for small children (1 and 1.5 MHz, respectively) are used, the diameter of the working surface is 35 mm. the surface of the sensor is lubricated by the contact medium, the study is performed on a closed skull.

 To measure the patient’s head, the sensors are mounted on the temporal bones symmetrically 5 cm above the external auditory canal along the auricular vertical, the study is carried out in transmission mode, then the device is switched to location mode and the following measurements are made: the location of the midline structures of the brain in the midline area is determined: a) determine the location of the transparent septum from the symmetrical points of the anterior temporal bones on the border with the frontal on one side and the other, from the same points this size is checked in the tra mode smissii, normally it is about 10 mm shorter than the size of the head, resulting in a first dimension; b) from symmetrical points from the temporal bones 4-5 cm above the external auditory meatus and 2 cm anterior to the auricle, a reflection is obtained from the 3rd ventricle in the zone of intermediate mass. Normally, this size coincides with the size obtained in the first dimension; c) from the middle of the line connecting the external auditory meatus with the middle of the occipital protuberance, they are reflected from the pineal gland from symmetrical points, normally this size also coincides with the first measurement, sometimes 1-2 mm more, which depends on the shape of the head.

 All measurements are made only on the leading edge of the signal, only dominant signals are taken into account.

 The location of the pineal gland in the anteroposterior dimension is determined. The sensor is installed on the border of the scalp, on the forehead in the midline, the beam is directed to the inner plate of the occipital bone, while at a depth of 60-65% (in indices 0.60-0.65) from the frontal bone, they are reflected from the pineal gland in the form dominant weakly pulsating echo.

 The offset of the pineal gland in the upper lower dimension is determined. The sensor is installed on the top of the head, the beam is sent to the base of the skull along the midline, normally the pineal gland is located at a distance equal to the distance from the temporal bone to the pineal gland, 4 mm.

 The index of the brain cloak in the area of the temporal horn of the lateral ventricle is determined. The sensor is installed on a point to determine the location of the pineal gland from the temporal bone (2, b or 2, c), the beam is directed to the opposite temporal bone; at a depth of 0.36-0.44 from the temporal bone to the median structures (3 ventricles or pineal glands) receive a high signal from the lateral wall of the temporal horn of the lateral ventricle; calculated by the ratio of the distance from the lateral wall of the temporal horn to the inner wall of the temporal bone to the distance from the temporal bone to the pineal gland.

 Cloak Index: 0.36-0.44 normal.

 The cerebellum index is determined. In the anteroposterior measurement, at a depth of 0.15-0.18 from the inner surface of the occipital bone, a signal is received from the wall of the ventricle 4, in height it is 1 / 2-1 / 3 of the height of the signal from the pineal gland. The calculation is based on the ratio of the distance from the wall 4 of the ventricle to the occipital bone to the distance from the frontal to the occipital bone.

 The brain stem index is determined by the ratio of the distance from the pineal gland to the base to the distance from the top of the head to the base of the skull, normally 0.33-0.39.

 The ventricular index 3 is determined. The sensor is installed at point b) when determining the midline, while a high signal along the midline is obtained from the optic tubercle near the intermediate mass, the second reflection from the wall in the 3rd ventricle is received from the wall in the zone of its expansion in the anterior sections, the distance between these signals is normal 2.5-3.5 mm, therefore, when conducting a study with a sensor with a frequency of 0.88 mm, for which each signal has a dead zone of 5 mm, these signals overlap each other and are separated only in the upper part; the distance between these signals, measured at the upper points and referred to half the size of the head, gives an index of 3 ventricles, which is normally 0.036-0.050.

 Use the pulsation of the echo signals and its changes in various pathological processes for diagnostic purposes. Pulsation of echoes appears due to a change in the angle of inclination of the boundaries of the media of the brain (cerebrospinal fluid) relative to the incident ultrasound beam, these movements of the borders are caused by different blood supply to the systole and diastole, normally the pulsation of echoes is 10-20% of the signal height ( consider from the top point of the signal) in the convex and lateral ventricles of the brain, when viewed from the forehead, the pulsation of the echo signals in zone 3 of the ventricle is 60-70%.

 Volumetric changes in the brain and changes in the pulsation of echo signals during the development of various pathological processes in dynamics are as follows.

 a) With an increase in brain swelling, its volume increases, its folds, convolutions become more prominent, higher reflections appear from them, and a lot of additional echo signals appear on the screen, which with an increase in brain swelling become higher, brain indices increase, decreases ventricular index 3. With severe swelling of the brain, the screen is clogged with high echo signals, and the determination of the median structures of the brain becomes impossible. The pulsation of the echo signals first increases and remains high until the cerebrospinal fluid flow is preserved, and then begins to decline, the swollen brain displaces the cerebrospinal fluid, complicates the flow of blood through small vessels, complicates the venous outflow and flow of cerebrospinal fluid until the blood flow through the brain stops in the terminal stage. The lack of pulsation of echo signals in all parts of the brain during repeated studies in dynamics allows us to confirm the absence of blood flow through the brain, that is, death of the brain, if it is possible to achieve regression of brain swelling, then the changes during echo-examination are in the reverse order.

 b) The development of hydrocephalus. With an increase in the volume of the cerebrospinal fluid system (for any reason), the ventricles of the brain increase, their walls are smoothed, which gives rise to high single signals from the walls of the lateral ventricles, the brain indices decrease, and the 3 ventricle index increases. When the intermediate mass is preserved along the midline, a dominant signal is obtained, and the reflection from the wall 3 of the ventricle looks like the letter M, with a further increase in the index of the 3 ventricle, in the form of two separate signals with one along the midline. In the absence of an intermediate mass, there is no echo in the midline. Instead, two high signals from two walls of the 3rd ventricle do not appear. With severe hydrocephalus, high signals appear from the walls of the body of the lateral ventricles, and then at the midline there are 4 symmetrically located high echo signals and not a single one along the midline, the same picture is obtained when locating from a symmetrical point on the other side. In the stage of increasing hydrocephalus, enlarged ventricles squeeze the small vessels of the surrounding brain, impede venous outflow, and the pulsation of echo signals increases. With occlusal hydrocephalus, the pulsation of the echo signals first increases and then decreases until it completely disappears with complete occlusion at the level of the sylvian aqueduct, while in the region 3 of the ventricle there is a yeast of the walls in the rhythm of the pulse (the outstretched walls of the 3rd ventricle resonate on the tremors of the vilizius circle, which begin to be carried out compacted brain). Trembling in zone 3 of the ventricle in the absence of pulsation of the echo signals in this area is a sign of complete occlusion and serves as an indication for urgent surgery that relieves the cerebrospinal fluid system, otherwise a fatal outcome will quickly occur. If hydrocephalus is associated with atrophic processes in the brain and the brain is not compressed by the dilated ventricles, then the pulsation of the echo signals is normal.

 c) In a targeted search for a volumetric process in the “sick” hemisphere or in the posterior cranial fossa (hematomas, cysts, abscesses, tumors that have borders), they suggest looking for a high echo or two echo signals in an empty space, not pulsating, since the volumetric process does not change its volume in the rhythm of the pulse and its border is stationary.

 Thus, the proposed method for studying by ultrasonic location of the brain can significantly expand the diagnostic capabilities of diseases, injuries and brain tumors, especially for emergency diagnostics, when other methods of adequate research (angiography, CT of the brain, brain MRI) are impossible for any reason.

 For example, Patient G., husband. 35 years old (1978), in which, against the background of a long inflammatory process in the lungs, focal symptoms of the left temporal region began to rapidly increase, accompanied by high temperature, and then within a few hours the symptoms of the dislocation syndrome developed in the form of increasing impaired consciousness to a degree of stupor. An ultrasound examination of the brain was performed on a portable device Echo-12 in conditions of non-core separation, a shift of the middle structures of the brain from left to right by 7 mm was detected, a shift of the epiphysis backwards in the anteroposterior change (67%) and reflection from the volumetric process by 40 mm from the left temporal bone were revealed. With a diagnosis of a brain abscess, the patient was transferred to the neurosurgical department of the S.P.Botkin hospital, where he was operated on for urgent indications, a large abscess was removed from the left temporal lobe, the patient was further discharged in satisfactory condition after treatment.

Claims (2)

 1. The method of ultrasound examination of the brain, including one-dimensional location of the boundaries of the media of the brain with different densities, determining the location of the pineal gland, measuring the brain cloak and the third ventricle, characterized in that the index of the brain cloak is calculated as the ratio of the distance from the lateral wall of the temporal horn to the final complex to the distance from the temporal bone to the midline, the brain stem index is additionally calculated as the ratio of the distance from the pineal gland to the final complex to the distance from the crown to the final lump plexus, cerebellum index - as the ratio of the distance from the fourth ventricle to the final complex to the distance from the frontal bone to the final complex, the third ventricle index - as the ratio of the distance between two signals from the wall of the third ventricle to the distance from the temporal bone to the midline and with an increase in the number and amplitudes of echo signals, an increase in brain indices, a decrease in the index of the third ventricle, and an increase in pulsations of echo signals determine an increase in brain swelling, and with a subsequent decrease in the height of their pulse tions to complete disappearance - determine the terminal state of the brain, with an increase in the amplitude of echo signals from the walls of the ventricles, a decrease in brain indices, an increase in the index of the third ventricle, and an increase in pulsations of the echo signals, increasing hydrocephalus is determined, and with the next decrease in the height of the echo signals until they disappear completely and the appearance of trembling of the walls of the third ventricle in the rhythm of the pulse - determine complete occlusion.  2. The method according to claim 1, characterized in that the normal index of the brain coat is 0.36-0.44, the index of the brain stem 0.33-0.39, the index of the cerebellum 0.15-0.18, the index of the third ventricle 0.036 - 0.050.