RU2621580C1 - Method for non-invasive intracranial pressure measurement - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: mechanical vibrations of the patient's head are measured with a vibration sensor from the occipital part of the patient's head, and converted to an electrical signal. The amplitude-frequency spectrum of the electrical signal is identified in the frequency range from 0.5 to 46 Hz. In the same frequency range, the total energy of mechanical head vibrations and vibration energy in the frequency spectrum region from 2 to 4 Hz are determined. The value of intracranial pressure is calculated as a ratio of the vibration energy in the frequency region from 2 to 4 Hz and the total energy of the signal in the entire frequency range, taking into account the coefficients of linear dependence.

EFFECT: method allows to increase the reliability of non-invasive determination of intracranial pressure, which is achieved by recording the head oscillations from the occipital region in the indicated frequency range and calculation of the obtained values ratio.

3 cl, 3 dwg

Description

The invention can be used in medicine, namely in neurosurgery, neurotraumatology, neurology and other medical fields for non-invasive determination of intracranial pressure (ICP).

The measurement of intracranial pressure in humans is normal and, especially, in pathology is an important biomedical problem, since the level of ICP determines the degree of blood supply and vascularization of the brain, which ultimately determines the activity of cerebral metabolism. Estimation of ICP as a vital parameter is necessary for the treatment of diseases associated with hydrocephalus, strokes, hemorrhages, tumors, cerebral edema with traumatic brain injury and neuroinfectious diseases.

A high level of ICP in children leads to encephalopathy, a delay in mental, intellectual, speech and motor development, aphasia, cerebral palsy, epileptic syndromes, mental retardation (oligophrenia) of varying severity, leading to disability of children in connection with neuropsychiatric disorders.

High intracranial pressure in adults leads to headache, cerebration, depression, decreased performance, chronic fatigue syndrome, hypertension, ischemic and hemorrhagic strokes, cerebral infarctions, paralysis and paresis of people of mature working age, and their premature disability. Prevention of these diseases in children and adults depends on early diagnosis, ongoing monitoring of ICP values and the use of timely effective therapy.

The most accurate methods for measuring ICP are methods for direct invasive measurement of cerebrospinal fluid pressure. This is achieved by measuring it with direct pressure gauges, which requires penetration into the cranial cavity or spinal canal. It is obvious that, as with any invasive procedures, the method can be accompanied by various complications associated with the possibility of damage to functionally important areas of the brain and blood vessels and their infection.

For this, complex expensive devices of the Codman brand (USA) and LiquoGuard (Germany) with disposable sensors are currently used. The readings of these instruments reflect intracranial pressure in mmHg. Art.

Invasive methods of ICP registration are of limited use and are absolutely unsuitable for preventive monitoring purposes during recreational activities among the general population, as well as in medical and rehabilitation medicine. Therefore, the world has long been searching for and developing non-invasive methods for evaluating ICP for widespread practice. The most common among them are ultrasonic research methods (ultrasound): neurosonography, echoencephalography. These methods well record the boundaries of brain cavities, reflect the severity of hydrocephalus, and indirectly, based on the increase in the volume of brain cavities, suggest an increase in ICP. But ultrasound methods do not reflect the early stages of intracranial hypertension, when there is still no shift in the boundaries of the brain cavities. And they are absolutely not informative with microcrania, when the compression of the brain increases up to gross ischemia and anoxia, and there are no hydrocephalus and changes in the boundaries of the brain cavities. Ultrasound methods are also uninformative for tumors and parasitic lesions of the brain.

Of the non-invasive methods for determining intracranial pressure, in addition to radiological, electroencephalographic, ultrasound, the following are known:

- optoacoustic methods based on measuring the displacement of the eardrum;

- calculation methods using measurements of arterial and venous pressures and, in particular, pressure in the retinal vein;

- methods based on the assessment of measurements of the electromagnetic impedance of the brain;

- a method based on the processing of dopplerographic examination of cerebral vessels.

However, all of the above methods for determining intracranial pressure do not allow objective and quantitative measurement of intracranial pressure, as they assess the state of blood vessels, especially venous and arterial blood flow and other characteristics of various organs and parts of the body, i.e. based on the processing of indirect data on the state of the brain.

These methods are usually associated with the mathematical processing of a large number of parameters, and their accuracy depends on the interpretation of various specialists. In addition, the use of these methods is often limited by the condition of the patient. For example, when a patient is in a coma, diagnostic procedures are difficult, and time for assessing vital parameters is limited.

In connection with the foregoing, in neurology, it remains relevant to develop methods for the non-invasive determination of intracranial pressure, allowing quantitative measurement of the level of its increase.

Known (see RF patent No. 2185091, published July 20, 2002, “Method for the non-invasive determination of intracranial pressure,” which is determined by measuring pressure in the central retinal vein (CVS). In patients without craniotomy, the pressure in CVS corresponds to intracranial pressure. In patients with craniotomy, the correction factor is used: at a pressure in the CVC of 10-20 mmHg, the correction coefficient is 0.7; at a pressure in the CVC of 21-30 mmHg and 31-45 mmHg. the conversion factor is 0.5 and 0.4, respectively. By increasing the pressure in CVC in mmHg and multiplying it by the corresponding correction factor, an ICP expressed in mmHg is obtained in patients with craniotomy. The method increases the reliability of the study of intracranial hypertension, which makes it possible to establish the extent of this condition and to carry out its appropriate correction, and also allows you to study ICP without resorting to traumatic and invasive manipulation.However, this method is difficult in practical implementation, which limits its application.

Known (see RF patent No. 2372838, published on November 20, 2009, “Method for determining intracranial pressure according to AP Efimov”), which consists in recording mechanical vibrations of the patient’s head for 5-10 seconds and converting them into an electrical signal with a sensor, which is located in the region of the patient’s frontal bone, with the subsequent calculation of the ratio of the energy component of the frequency range of the 3 Hz spectrum to the frequency spectrum from 0.5 to 46 Hz and the diagnosis of increased ICP when the value of the calculated ratio is above 20%. In this case, the registration of mechanical vibrations is carried out while the patient is lying on his side with a freely fixed head, vertically fixed with an elastic tape. The sensor is placed in the middle of the frontal part of the head with the orientation of the sensor axis perpendicular to the axis of the patient’s body.

The above method is the closest to the claimed method in technical essence and therefore is selected as a prototype.

The disadvantage of this method is the low reliability of determining ICP due to the placement of the vibration sensor on the frontal part of the head. The presence on the frontal part of the frontal muscles and a large number of nerve endings of the facial nerves, which affect their contraction from various nervous diseases not related to intracranial pressure, can lead to a large error in determining ICP. In addition, hanging the head on a tripod in a lateral position is completely unacceptable for seriously ill patients in a coma, as they can be on the bed only in a supine position.

The technical problem to be solved is the creation of a method for non-invasive determination of ICP with increased reliability.

Achievable technical result is to reduce the measurement error by placing the vibration sensor on the occipital part of the head by eliminating local mechanical (facial) vibrations of the frontal part of the head from contractions of the frontal muscles, which coincide in the frequency range with head vibrations proportional to the ICP.

To achieve a technical result in the method of non-invasive determination of intracranial pressure, which consists in measuring the mechanical vibrations of the patient’s head with a vibration sensor, converting them into an electrical signal, isolating the amplitude-frequency spectrum of the electrical signal in the frequency range from 0.5 to 46 Hz, in this range frequencies find the total energy of the mechanical vibrations of the head E _total and energy Ε _{1 of the} oscillations of the frequency spectrum from 2 to 4 Hz, calculate the ratio of energy Ε ₁ to the total signal energy of the entire range it frequencies E _total , new is that the measurement of mechanical vibrations is carried out from the occipital part of the patient’s head, the value of intracranial pressure is determined by the formula:

where A = 0.2 ... 0.4; B = 0.1 ... 0.2 - linear dependence coefficients obtained experimentally by calculation, while at A = 0.2 V = 0.2, and at A = 0.4 V = 0.1.

In children and patients unconscious, the electrical signal is recorded in a time interval of up to 4 s and at least 10 s in adult conscious patients. When measuring in a supine position, an elastic stand is used, which is installed under the patient’s head so that the oscillations of the head are not limited.

Measurement of mechanical vibrations is carried out from the occipital part of the patient’s head, because there is the strongest rhythmic signal generated by the human brain, the so-called alpha rhythm. It is detected as vibrations with a characteristic frequency of about 10 Hz, which, when measured electrically, are most noticeable in the occipital part of the head. These measurements can reduce the measurement error, i.e. increase the accuracy of the information.

The value of intracranial pressure is determined by the formula using the coefficients A and B, which are obtained experimentally by calculation based on the analysis of statistical results of studies of patients, which allows to obtain ICP values with the smallest error. To construct the dependence of the ICP on the ratio of the energies E ₁ and E _total , the least squares method was used and the linear regression equation was chosen, according to which the smallest measurement error of the ICP was obtained.

The analysis of scientific, medical and patent information, reflecting the current level of technologies for determining the non-invasive method of ICP, did not reveal identical technologies. Thus, the proposed method for non-invasive determination of ICP pressure is new. The relationship and interaction of the essential features of the proposed method achieve a new medical result in solving the problem, namely: to determine the ICP with increased reliability in patients of different ages with different diagnoses. Thus, the proposed technical solution has an inventive step.

The method is implemented by the device shown in FIG. 1, 2, 3.

The figure 1 presents a method of non-invasive determination of ICP of a patient in a sitting position. The vibration sensor 1 is located on the occipital part of the head and is fixed in this position, for example, using an elastic tape 3. The electrical signal from the sensor, proportional to the vibrations of the human head, is recorded in the microprocessor-based recording and control unit 2, in which it is converted and issued on the digital indicator of the device in pressure values in mmHg. Art.

The figure 2 presents a method of non-invasive determination of ICP of a patient in a supine position. The vibration sensor 1 is located in the elastic support 4 of the support 5 so that the occipital part of the head is located on the vibration sensor 1. This allows you to determine the ICP when the patient is in an unconscious state.

The figure 3 presents the stand 5, in which the vibration sensor 1 is fixed in an elastic support 4.

The proposed method is as follows. To control the ICP in a sitting position (Fig. 1), the patient is seated on a chair with a back that allows you to maintain the vertical position of the spine, which should be free of stress, and the vibration sensor 1 is fixed to the back of the patient using a rubber ring or elastic tape 3. To control the ICP bedridden patients (Fig. 2), it is necessary to install a special stand 5 under the patient’s head (Fig. 3), having previously installed a vibration sensor 1 interacting with the occipital part of the head in the elastic support of the stand. This position of the patient allows you to determine ICP when he is in an unconscious position. Then, the mechanical vibrations of the patient’s head are measured with vibration sensor 1 and converted into an electrical signal, which is recorded in children and patients unconscious in a time interval of up to 4 s and at least 10 s in adult conscious patients. Determine the total energy (E _total ) of mechanical vibrations in the frequency range from 0.5 to 46 Hz by obtaining the amplitude-frequency spectrum of the head’s vibrations, from which a part of the frequency spectrum from 2 to 4 Hz is allocated, which corresponds to the part that is most responsive to changes in the ICP, find the ratio of the vibrational energy E _{1 of the} signal component in the selected portion of the spectrum to the total signal energy of the entire frequency range and determine the ICP from the ratio:

where A = 0.2 ... 0.4; B = 0.1 ... 0.2 - linear dependence coefficients obtained experimentally by calculation, while at A = 0.2 V = 0.2, and at A = 0.4 V = 0.1;

E ₁ - the vibrational energy of the frequency spectrum from 2 to 4 Hz, most intensively responding to changes in ICP;

E _total - the total vibrational energy of the entire range of measurement frequencies from 0.5 to 46 Hz.

The efficiency of the method was tested and confirmed by the protocol of clinical trials, which were carried out on the basis of the City Clinical Hospital No. 39 of N. Novgorod, where direct ICP measurements are performed in severe patients with neurosurgical brain pathology, mainly in patients with severe traumatic brain injury. The tests were carried out using a prototype of a portable microprocessor device "Vibroneuron", developed and manufactured by LLC GlobalTest. As a result of the tests, it was noted that the response of the device to the oscillatory movements of the patient’s head is different when the vibration sensor is installed in different places of the head. When installing the sensor in the area of the large occipital foramen, the smallest error in the ICP change was noted using the Vibroneuron device (www.vibroneuron.com).

Full-scale experimental studies have made it possible to estimate the error in the measurement of ICP within ± 10%. Observations were made of patients in whom intracranial pressure was measured by the direct (invasive) method and five-time measurements by the non-invasive method. The obtained results confirmed the linear dependence of the readings of the Vibroneuron instrument on the ICP values measured directly. The procedure is non-invasive, painless, harmless and can be repeated many times, since in it, in contact with the patient, only a vibration sensor is used, which has a protective resonant cover and an integrated cable for connecting to the microprocessor recording and control unit.

Currently, the Vibroneuron device is undergoing official registration with the Russian Ministry of Health.

The technical result of the proposed method is to provide the possibility of objective control of ICP in a non-invasive way.

The method can be widely used not only in neurosurgical and neurological practice, but also in domestic conditions.

Claims (6)

1. The method of non-invasive determination of intracranial pressure, which consists in measuring the mechanical vibrations of the patient’s head with a vibration sensor, converting them into an electrical signal, isolating the amplitude-frequency spectrum of the electrical signal in the frequency range from 0.5 to 46 Hz, in this frequency range they find the total the energy of the mechanical vibrations of the head E _total and the energy E _{1 of the} oscillations of the frequency spectrum section from 2 to 4 Hz, calculate the ratio of the energy E ₁ to the total signal energy of the entire frequency range E _general , characterized in that measurement of mechanical vibrations is carried out from the occipital part of the patient’s head, the value of intracranial pressure is determined by the formula: P = A (E ₁ / E _total ) + B, where A and B are the coefficients of linear dependence, taking values: A = 0.2 and B = 0.2 or A = 0.4 and B = 0.1. 2. The method according to p. 1, characterized in that in children and patients unconscious registration of the electrical signal is carried out in the time interval of up to 4 s and at least 10 s in adult patients who are conscious. 3. The method according to p. 1, characterized in that when measuring in a supine position, an elastic stand is used, which is installed under the patient’s head so that the oscillations of the head are not limited.

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