RU2505267C1 - Method for determining volume of membrane intracranial new growths - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: spiral computed or magnetic resonant brain imaging is formed to visualise an intracranial new growth. Two maximally spaced points are found on an axial scan on the border of the intracranial new growth, connected by a straight line A, and a distance A between the two points is measured. A length h1 of the greatest perpendicular to the line A from an inner table of skull is determined. A length h2 of the greatest perpendicular to the line A form an internal border of the intracranial new growth with a minus sign provided the perpendiculars h1 and h2 are on the same side of the line A, and with a plus sign provided they lie on the different sides. A frontal side is used to determine the two maximally spaced points on the border of the intracranial new growth to be connected by a straight line, and a distance B between the two points is measured. The membrane intracranial new growth volume V is measured by formula: V=π/6×(h1³+h2³)+π/8×A×B×(h1+h2).

EFFECT: higher accuracy of the membrane intracranial new growth volume calculation ensured by taking into account the individual shape characteristics.

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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 shell intracranial formation with traumatic brain injury, brain tumors, diagnosis of early complications after craniotomy.

One of the most important stages of radiation diagnosis in the shell of intracranial formation of various etiologies is the calculation of its volume, the determination of which affects the choice of treatment tactics, prognosis of the disease, and the determination of this indicator in dynamics provides an opportunity to assess the adequacy of the therapeutic effect on the pathological process.

A known method for determining the volume of shell intracranial education (RF patent No. 2338466, published November 20, 2008). Calculate the volume of intracranial education according to computer or magnetic resonance imaging. Volume is defined as the product of the length, width and height of the intracranial mass divided by 1.91. The disadvantage of this method is its inaccuracy, because the shape of all intracranial formations is taken as ellipsoidal.

Closest to the claimed is a method for determining the volume of shell intracranial formation (Ericson K., Hakanson S. Computed tomography of epidural hematomas. Association with intracranial lesions and clinical correlation // Acta radiol. - 1981. - Vol.22, No. 5. - P .513-519.) Adopted as a prototype. Computed tomography is performed, the volume (V) of intracranial formation is calculated according to the formula V = π / 6 × A × B × C, where A, B, C are the main diameters of the intracranial formation. The disadvantage of the prototype: inaccuracy due to the assumption that all intracranial formations are approximately ellipsoidal in shape. However, this statement is true only for intracerebral processes. With convexital localization (epidural or subdural hematoma, extra-brain tumor), the formation, as a rule, has the form of a biconvex or concave-convex (positive meniscus) lens, the calculation of the volume of which according to the ellipsoid formula gives a significant error.

The invention is aimed at creating a method for determining the volume of shell intracranial education, providing increased accuracy by taking into account the individual characteristics of the form of education.

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 shell intracranial formation by performing tomography of the brain on which the intracranial formation is visualized, the feature is that two points at the border of the intracranial formation are determined on the axial scan , connect them with a straight line A, measure the distance A between the points, determine the length h1 of the greatest perpendicular drawn to the line and A from the inner plate of the bones of the skull, measure the length h2 of the largest perpendicular drawn to line A from the inner border of the intracranial formation, which is taken into account with a minus sign if the perpendiculars h1 and h2 are located on one side of line A, and with a plus sign in the case locations on opposite sides, then on the frontal scan, two points are located as far as possible from each other at the border of the intracranial formation, connect them straight and measure the distance B between them, the volume of the intracranial shell Hovhan V is calculated according to the formula: V = π / 6 × (h1 + h2 ^{3 3)} + π / 8 × A × B × (h1 + h2).

The method is as follows. Victims with a traumatic brain injury or a patient with a brain tumor undergo a spiral computed or magnetic resonance imaging of the brain, on which the shell intracranial formation and its borders are visualized. On the axial scan, two points most distant from each other on the border of the intracranial formation are determined and connected by a straight line A (Fig. 1). Measure the distance A in cm between the points. The length h1 in cm of the largest perpendicular drawn to line A from the inner plate of the bones of the skull is determined. Measure the length h1 in cm of the largest perpendicular drawn to line A from the inner border of the intracranial mass, which is taken into account with a minus sign if the perpendiculars h1 and h2 are located on the same side of line A, and with a plus sign if they are located on opposite sides (Fig. .2). Then, on the frontal scan, two points most distant from each other are determined on the border of the intracranial formation, they are connected by a straight line and the distance B is measured in cm between them (Fig. 3). The volume of the intracranial shell formation V is calculated by the formula:

V = π / 6 × (h1 ³ + h2 ³ ) + π / 8 × A × B × (h1 + h2).

The claimed method for determining the volume of intracranial shell formation has been developed and passed clinical trials in the treatment of 83 patients with traumatic brain injury and brain tumors, which, as a result of the examination, the volumes of shell traumatic hematomas and convexital brain tumors were confirmed, confirmed for surgery or autopsy.

We give clinical examples - extracts from medical records.

Example 1. Patient K., 32 years old, East. Disease 9143/2012, delivered to the Road Clinical Hospital of St. Petersburg by ambulance 28 minutes after the injury, was hit by a car. According to the ambulance doctor, loss of consciousness, vomiting was noted at the site of the injury. At the time of the initial examination in the hospital, he was somewhat retarded, didn’t remember the circumstances of the injury, pulse of 94 beats per 1 min, satisfactory properties, rhythmic, blood pressure and 65 mmHg, topical abrasions, subaponeurotic hematoma of the left parietal-temporal region . Pupils of the correct form, the same size, the reaction to light is lively, friendly. Deep reflexes are low, without a difference of sides, abdominal reflexes are not caused. Babinsky symptom on the left, shell symptoms. A comprehensive examination of the victim was started, during which there was a violation of consciousness by the type of stupor, the appearance of anisocoria, a pulse of 58 beats per 1 minute, blood pressure of 130 and 70 mm Hg. Spiral computed tomography of the brain revealed a subdural hematoma in the right frontoparietal-temporal region. According to the claimed method, on the axial scan, we determined two points most distant from each other on the border of the subdural hematoma, connected them by a straight line A, distance A = 9 cm, the largest perpendicular to line A from the inner plate of the bones of the skull h1 = 3.4 cm, the largest perpendicular to the line A from the inner border of the hematoma h2 = -1.6 cm, on the frontal scan two points most distant from each other were determined on the border of the hematoma, connected by a straight line and measured the distance B = 7 cm.The volume of the subdural hematoma was calculated: V = π / 6 × (h1 ³ + h2 ³ ) + π / 8 × A × B × (h1 + h2) = 3.14: 6 × [3.4 ³ + (- 1.6) ³ ] +3.14: 8 × 9 × 7 × [3, 4 + (- 1.6)] = 63 cm ³ .

Given the large volume of hematoma, an operation was performed urgently for health reasons: decompressive trepanation of the skull in the right frontoparietal-temporal region, removal of a subdural hematoma with a volume of about 50 ml in the form of clots and liquid blood. The postoperative course is smooth, the wound healed by primary intention. Discharged under the supervision of a neurologist at the place of residence on the 14th day after the injury in satisfactory condition.

Thus, the determination of the volume of the intracranial shell formation - the subdural hematoma - made it possible to choose the optimal amount of surgical intervention.

Example 2. Patient I., 76 years old, East. illness 10658/2012, was admitted to the Road Clinical Hospital of St. Petersburg in a planned manner with complaints of headache. I fell home 1.5 months ago, there was a short-term loss of consciousness, I did not go to the doctor. Consciousness is not impaired, pulse 110 beats 1 minute, atrial fibrillation, blood pressure 160 and 95 mm Hg Pupils of the correct form, the reaction to the light is alive. Deep reflexes are low, higher on the right, abdominal reflexes are not caused. Symptom of Babinsky on the right. No sheath symptoms. A comprehensive examination of the victim was carried out. Spiral computed tomography of the brain revealed chronic epidural hematoma in the right frontal, parietal and temporal lobe. According to the claimed method, two maximally distant points on the border of the epidural hematoma were determined on an axial scan, connected by a straight line A, distance A = 7 cm, the greatest perpendicular to line A from the inner plate of the bones of the skull h1 = 1 cm, the largest perpendicular to the line And from the inner border of the hematoma h2 = 1.5 cm, on the frontal scan, we determined two points most distant from each other on the border of the hematoma, connected them by a straight line and measured the distance B = 3 cm.The volume of the subdural hematoma was calculated: V = π / 6 × ( h1 + h2 ^{3 3)} + / 8 × A × B × (h1 + h2) = 3,14: 6 × (1 ³ 1.5 ³⁾ 3.14 8 × 7 × 3 × (1 + 155) = 23 ^cm3.

Given the small amount of epidural hematoma and the presence of severe concomitant pathology, it was decided to abstain from surgical treatment. Received treatment: dehydration therapy, nootropic drugs, vascular drugs. Discharged under the supervision of a neurologist.

Example 3. Patient G., 39 years old, source of illness 4269/2012, was hospitalized in the Road Clinical Hospital of St. Petersburg in a planned manner with complaints of headache, weakness in the right hand, convulsive twitching in it. The state of admission is satisfactory, the consciousness is clear, heart sounds are muffled, rhythmic, pulse 74 in 1 minute, blood pressure 130 and 80 mm Hg, hemiparesis on the right (4 points), muscle tone is slightly higher on the right, deep reflexes are higher on the right. The patient considers himself to be about 3 years old, over the past 6 months there has been weakness in the arm, seizures of convulsions in the right hand without loss of consciousness. Magnetic resonance imaging of the brain revealed a tumor - meningioma - in the left temporal lobe. According to the claimed method, on the axial scan, we determined two points most distant from each other at the border of the tumor, connected them by a straight line A, distance A = 4.5 cm, the largest perpendicular to line A from the inner plate of the bones of the skull h1 = 0.7 cm, the largest the perpendicular to line A from the inner border of the hematoma is h2 = 2.5 cm, two points most distant from each other at the border of the tumor were determined on the frontal scan, connected by a straight line and measured the distance B = 4 cm. The tumor volume was calculated:

V = π / 6 × (h1 ³ + h2 ³ ) + π / 8 × A × B × (h1 + h2) = 3.14: 6 × [0.7 ³ +2.5) ³ ] +3.14 : 8 × 4 × 4.5 × (0.7 + 2.5) = 31 cm ³ .

The operation was performed as planned - osteoplastic trepanation in the left frontotoparietal-temporal region, removal of the tumor of the left frontal and temporal lobe. In the immediate postoperative period, the patient's condition is compensated, the consciousness is clear, hemiparesis regressed. Histological conclusion and immunohistochemistry data: meningioma. Discharged for outpatient treatment by a neurologist at the place of residence.

Claims (1)

A method for determining the volume of an intracranial shell formation, including tomography of the brain, on which an intracranial formation is visualized, characterized in that two points at the border of the intracranial formation are determined on an axial scan, connected by a straight line A, the distance A between the points is measured, determine the length h1 of the largest perpendicular drawn to line A from the inner plate of the bones of the skull, measure the length h2 of the largest perpendicular drawn to line A from the inner border of the intracranial mass, which is taken into account with a minus sign if the perpendiculars h1 and h2 are located on one side of line A, and with a plus sign - if they are located on opposite sides, then two maximally distant from each other are determined on the frontal scan points on the border of the intracranial mass, connect them with a straight line and measure the distance B between them, the volume of the shell intracranial mass V is calculated by the formula: V = π / 6 × (h1 ³ + h2 ³ ) + π / 8 × A × B × (h1 + h2).

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