RU2533968C1 - Method for determining intracerebral growth volume - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: intracerebral growth is visualised by means of tomography, and two maximum remote points are localised on the border of the intracerebral growth on axial scans. Inclining from the axial to frontal scanning surface makes the surface pass through these points. The in-between distance A is measured. A plane of scanning is rotated about these points to locate the most remote points on the border of the intracerebral growth arranged in a line perpendicular to the axis. The distance B is measured between these points. A plane of scanning perpendicular to the axis is drawn through these points. A perpendicular to the line B connecting the points on the border of the intracerebral growth is located thereon. The in-between distance C is measured. The intracerebral growth volume V is calculated by formula: V=(A×B×C):2+5%.

EFFECT: method provides the high accurate determination of the intracerebral growth volume.

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Description

The invention relates to medicine, namely to neurosurgery, neurology and radiation diagnostics, and can be used to determine the volume of intracerebral formation in traumatic brain injury and brain diseases.

It is known that one of the essential parameters when choosing a treatment strategy for intracerebral formation of various etiologies is the volume of brain damage.

A known method for determining the volume of intracerebral formation (RF patent No. 2338466, published November 20, 2008), in which the length, width and height of the formation are measured in the process of brain tomography, the volume of education is calculated as the product of the length, width and height of the tumor divided by 1 , 91. The disadvantages of the method: inaccuracy in determining the volume of intracerebral formation due to the choice of its sizes in standard planes, which complicates the treatment, the possibility of use only in determining the tumor volume of the posterior cranial fossa.

A known method for determining the volume of intracerebral education (Dreval ON, Neurosurgery. - M .: GEOTAR-Media, 2012. - P.58). A tomography of the brain is performed, formation values located at right angles are measured, education volume is calculated on the basis of modified ellipsoid volume (MEO) according to the formula MEO = A + B + C / 2, where A, B and C are orthogonal (located at right angles) the magnitude of education. The disadvantage of this method is the choice of the sizes of education to be measured in standard planes, because of which it is impossible to accurately calculate the volume of education and adequately determine the tactics of treatment.

Closest to the claimed is a method for determining the volume of intracerebral education (Grinberg MS Neurosurgery. - M .: MED-press-inform, 2010. - P.886), adopted as a prototype.

Perform a tomography of the brain. The diameters of the formation are measured in the axial, frontal and sagittal planes. The volume of education is calculated by the equation of volume of the ellipse as the product of its 3 diameters divided by 2.

However, the prototype is not accurate enough, because: 1) the diameters of the formation are measured in standard axial, frontal and sagittal planes, while they are not always the maximum diameters of the formation, 2) the calculation of the volume of education by the formula for the ellipse of the correct shape, which leads to an erroneous decrease in the true the volume of education and makes it difficult to choose a treatment.

The invention is aimed at creating a method for determining the volume of intracerebral formation, providing increased accuracy.

The specified technical result in the implementation of the invention is achieved by the fact that in the method for determining the volume of the intracerebral formation, including performing tomography of the brain, visualization of the intracerebral formation and calculation of its volume, the feature is that two axially scanned points are determined on axial scans intracerebral formation, tilt from axial towards the frontal scan plane so that the plane passes through these points, measure the distance A between them, rotate the scanning plane around the axis passing through these points, until the points are located as far as possible from each other on the border of the intracerebral formation located on a line perpendicular to the axis, the distance B between these points is measured, the points perpendicular to the axis are drawn through these points the scanning plane, find on it a perpendicular to line B, connecting the points on the border of the intracerebral formation, measure the distance C between them, the volume V of the intracerebral formation is calculated by the formula: V = (A × B × C): 2 + 5%.

The method is as follows. For patients with traumatic brain injury or brain diseases, they perform magnetic resonance imaging of the brain in SPGRT ₁ mode or spiral computed tomography of the brain in spiral mode. Visualize intracerebral formation. Axial scans determine two points as far as possible from each other on the border of the intracerebral formation. The scanning plane is tilted from axial toward the front so that the plane passes through these points. Measure the distance A between them. Rotate the scanning plane around the axis passing through these points until the points located at the most distant from each other on the border of the intracerebral formation located on a line perpendicular to the axis. Measure the distance B between these points. A scanning plane is drawn through these points perpendicular to the axis. Find on it a perpendicular to line B, connecting the points on the border of the intracerebral formation. Measure the distance C between them, the volume V of the intracerebral mass is calculated by the formula: V = (A × B × C): 2 + 5%.

The claimed method for determining the volume of intracerebral education passed clinical trials in the treatment of 52 patients with traumatic brain injury and brain tumors, in which the volume of intracerebral hematoma or tumor was reliably established.

We give clinical examples - extracts from medical records.

Example 1. Patient B., 46 years old, source of illness 12385, was taken to the St. Petersburg Road Hospital by ambulance. At the time of inspection, no complaints due to the severity of the condition. Found on the street with trauma on the head and body. Upon receipt, the condition is serious. Neurologically: consciousness is disturbed to the level of stupor, signs of damage to the left frontal and parietal lobe, meningial symptoms. Multiple bruising and abrasions on the scalp and face.

A comprehensive examination of the patient. In spiral computed tomography, intracerebral hematoma was found in the mediobasal parts of the left frontal and parietal lobes. According to the claimed method, two points maximally distant from each other at its boundary are defined in the axial plane, it is inclined from the axial scanning plane so that the plane passes through these points, the distance between them is measured A = 6.2 cm, rotation is performed the scan plane around the axis passing through the points, until the points are located as far as possible from each other on the border of the intracerebral formation, located on a line perpendicular to the axis, the distance B = 4.3 cm between timey points through these points held scanning plane perpendicular to the axis, located on it perpendicular to the line B, connecting points on the boundary of the formation of cerebral; measured distance C = 2,7 cm therebetween, the volume V calculated intracerebral hematoma:

V = (A × B × C): 2 + 5% = (6.2 × 4.3 × 2.7): 2 + 5% = 36.0 + 1.8 = 37.8 cm ³ .

Given the significant amount of intracerebral hematoma, it was decided to perform an open operation on an emergency basis. Resection craniotomy was performed in the left frontotemporal-temporal region, and the removal of acute intracerebral hematoma. The postoperative period without complications. A regression of neurological symptoms was noted, by 8 days - a clear consciousness, right-sided hemiparesis was preserved. The wound healed by primary intention. Discharged on the 28th day from the moment of receipt for treatment by a neurologist at the place of residence.

Final diagnosis: closed craniocerebral trauma, severe brain contusion with compression of the left hemisphere by intracerebral hematoma.

Thus, the determination of the volume of intracerebral hematoma, which turned out to be significant, made it possible to decide on open surgical intervention in an emergency.

Example 2. Patient L., 62 years old, source of illness 4391, was admitted to the Road Hospital of St. Petersburg in a planned manner with complaints of constant headache, blurred vision, memory impairment. Sick for about 3 months. Upon receipt, the condition is serious. Neurologically: cognitive impairment, signs of brain damage at the level of the posterior parts of the third ventricle, coordinating impairment.

A comprehensive examination of the patient. Magnetic resonance imaging revealed a volumetric formation at the level of the posterior parts of the third ventricle. According to the claimed method, two points maximally distant from each other at its boundary are defined in the axial plane, it is inclined from the axial scanning plane so that the plane passes through these points, the distance between them is A = 1.1 cm, rotation is performed the scan plane around the axis passing through the points, until the most distant points are located on the border of the intracerebral formation located on a line perpendicular to the axis, the distance B = 1.5 cm between timey points through these points held scanning plane perpendicular to the axis, located on it perpendicular to the line B, connecting points on the boundary of the formation of cerebral; measured distance C = 1,4 cm therebetween, the volume V calculated intracerebral formation:

V = (A × B × C): 2 + 5% = (1.1 × 1.5 × 1.4): 2 + 5% = 1.2 + 0.1 = 1.3 cm ³ .

Given the small volume of the tumor, it was decided to send the patient for radiation treatment using the gamma knife radiosurgical unit, which was carried out as planned. Examined outpatiently 8 months after treatment. A regression of cognitive impairment was noted, the headache does not bother. Observed by a neurologist at the place of residence.

Final diagnosis: Volumetric formation of the posterior parts of the third ventricle.

Thus, the determination of the volume of the intracerebral tumor allowed us to make a decision on minimally invasive radiation treatment using a gamma knife radiosurgical unit.

Claims (1)

A method for determining the volume of an intracerebral formation in trauma and diseases of the brain, including performing tomography of the brain, visualizing the intracerebral formation and calculating its volume, characterized in that two axially most points are located on axial scans at the border of the intracerebral formation, inclined from the axial towards the frontal scanning plane so that the plane passes through these points, measure the distance A between them, rotate the scanning plane in the circle of the axis passing through these points, until the points most distant from each other on the border of the intracerebral formation located on a line perpendicular to the axis are measured, the distance B between these points is measured, the scanning plane perpendicular to the axis is drawn through these points, the perpendicular to the line B connecting the points on the border of the intracerebral formation, measure the distance C between them, the volume V of the intracerebral formation is calculated by the formula: V = (A × B × C): 2 + 5%.