RU75560U1 - DEVICE FOR MEASURING INNER CRACIAL PRESSURE IN NEWBORNS AND CHILDREN OF BREAST AGE AND SUPPORT ELEMENT FOR THIS DEVICE - Google Patents

Abstract

The utility model relates to portable medical equipment for pediatrics, intended for the functional diagnosis of cerebral hemo- and liquorodynamics, and can be used in clinical practice for non-invasive painless and risk-free, rapid and accurate measurement of intracranial pressure (ICP) in young children with the use of short-term dynamic deformation of the large fontanel when examining sick children for the presence of brain diseases, monitoring the correctness of their treatment hospital and at home. The technical result of the utility model is to increase the accuracy of ICP measurement on fontanels of various shapes, including concave, flat, convex, reduce the time for the measurement procedure as a whole several times, simplify and ease the measurement procedure, and make it possible to perform ICP measurements in a hospital and parents children on their own. A device for measuring intracranial pressure in newborns and infants includes a housing, a supporting element with a leveling surface at the end, a movable sleeve with the specified supporting element coaxially mounted on it, mounted in the housing with the possibility of limited reciprocating movement to create a static load on the large fontanel , a rod with a flat base mounted in the cavity of the movable sleeve with the possibility of movement relative to the support element and create shock Procedure for large fontanel deformation, ensuring displacement rod system arranged at least one measuring winding connected to the control unit, processing, and

indications configured to convert the signal from the measuring winding to determine intracranial pressure and display the results. The supporting element has an external limiter of deformation of the large fontanel with static load, the leveling surface of the supporting element protrudes beyond the contact surface of the specified limiter, while the contact surface is inclined to a plane perpendicular to the axis of the movable sleeve and tangent to the leveling surface of the supporting element, with increasing distance from it to this plane in the direction to the periphery of the deformity limiter of the large fontanel with a static load.

Description

The utility model relates to portable medical equipment for pediatrics, intended for the functional diagnosis of cerebral hemo- and liquorodynamics, and can be used in clinical practice for non-invasive painless and risk-free, rapid and accurate measurement of intracranial pressure (ICP) in young children with the use of short-term dynamic deformation of the large fontanel when examining sick children for the presence of brain diseases, monitoring the correctness of their treatment hospital and at home.

There are many devices for indirect ICP research. In infants, for example, such a diagnosis is performed using ultrasound of the skull through a large fontanel. In older children, using computed tomography (CT) and magnetic resonance imaging (MRI). These devices do not give an objective assessment of ICP, are complex, high cost, they cannot be used by parents for multiple ICP control at home.

Under these conditions, the development of devices for rapid non-invasive determination of ICP, which would allow safe and, if necessary, multiple measurements of this parameter, including by parents of children on their own, is of great importance.

Known devices for determining intracranial pressure, based on measuring the magnitude of the displacement of the membrane (RF patent No. 2163090) or on the assessment of changes in the electromagnetic impedance of the brain (US patent No. 4690149 and US No. 4819648), ultrasonic device for determining the ICP (US patent No. 5388583 and US No. 5411028). These devices are complex, expensive and applicable only in stationary conditions.

A device for determining ICP with a sensitive device containing a solid ring with a flexible membrane located at its opening and adapted for installation on a large fontanel of a child using straps is known, the solid ring and membrane being fixed with the formation of a cavity for the liquid in which the pressure sensor is installed (patent US No. 4995401, IPC А61В 5/00, publ. 1991). In this device, deformation of the skin covering the fontanel causes a corresponding deformation of the flexible membrane and, thus, changes the pressure of the fluid within the cavity.

The use of belts complicates and lengthens the ICP measurement procedure by a known device.

A device for measuring ICP through the fontanel of a child, including a solid device for installing pressure control with a membrane, fixed with an adhesive connection (DE patent No. 3928554, IPC AB 5/03, publ. 1991).

The complexity of fastening, centering, application of glue lengthens and complicates the ICP measurement procedure, making it painful with repeated ICP measurements.

Closest to the proposed is a device for measuring ICP in newborns and infants, containing a housing, a support with two wedge-shaped protrusions, between which there is an annular protrusion with a leveling platform, made at a height of 3-5 mm from their base, a movable sleeve for mounting the support installed in the housing with the possibility of limited reciprocating movement to create a static load on the large fontanel, a rod with a flat base installed in the cavity of the sleeve with awn movement relative to the support and to create impact for large fontanel deformation, a mechanical system for moving the stem, formed with at least one measuring coil,

connected to the control unit, processing and indication, configured to convert the signal from the measuring winding to determine intracranial pressure and display the results, moreover, the wedge-shaped protrusions of the support are equidistant to a distance of 7 ÷ 10 mm from the axis of movement of the rod, and their supporting surfaces are located below the leveling platform ring protrusion (RF patent No. 2303946, IPC A61B 3/16, publ. 08/10/2007).

The known device does not allow to measure the ICP with sufficient speed and accuracy of measurement on fontanels of a flat and concave shape due to the location of the supporting surfaces of the wedge-shaped protrusions much lower than the leveling area of the annular protrusion. This does not allow widespread use of the device in clinical practice.

Thus, none of the known non-invasive devices does not provide sufficient clinical accuracy, speed, painlessness and ease of use. There is still a need to develop an inexpensive non-invasive device for measuring intracranial pressure, characterized by simplicity and ease of use, sufficient accuracy and the ability to conduct multiple repeated measurements of ICP on fontanels of various shapes.

Closest to the proposed is a support element for a device for measuring intracranial pressure in newborns and infants, made in the form of a sleeve having a channel for moving the rod of the device for measuring ICP, openings for air outlet when moving it and a leveling surface at the end, and the surface is made between two wedge-shaped protrusions with supporting surfaces located below the specified

leveling surface (RF patent No. 2303946, IPC АВВ 3/16, publ. 08/10/2007).

The location of the supporting surfaces of the wedge-shaped protrusions is significantly lower than the leveling surface of the annular protrusion does not allow to ensure high measurement accuracy on fontanelles of a flat and concave shape, as well as guarantee the safety of use.

The utility model solves the problem of increasing the operational properties of the ICP measurement device through the large fontanel in newborns and infants.

The technical result of a useful model of a device for measuring intracranial pressure in newborns and infants is to increase the accuracy of ICP measurement on fontanelles of various shapes, including concave, flat, convex, reducing the time for the measurement procedure as a whole by several times, simplifying and convenient procedure measurements, the ability to make ICP measurements in a hospital and by parents of children independently.

The technical result of a useful model of a support element for a device for measuring intracranial pressure in newborns and infants is to create the possibility of increasing the accuracy of ICP measurement in simplicity, convenience and safety of application on fontanels of various shapes, including concave, flat, convex.

The technical result is achieved by the fact that in the device for measuring intracranial pressure in newborns and infants, comprising a housing, a support element with a leveling surface at the end, a movable sleeve with said support element coaxially mounted on it, installed in the housing with the possibility of limited reciprocating displacement to create a static load on the large fontanel, flat stock

a base mounted in the cavity of the movable sleeve with the ability to move relative to the support element and create impact for deformation of the large fontanel, a rod movement support system made with at least one measuring winding connected to a control, processing and indication unit, configured to convert the signal with a measuring winding for determining intracranial pressure and displaying the results, according to a utility model, the supporting element has On the outside, the limiter of deformation of the large fontanel by static load, the leveling surface of the supporting element protrudes beyond the contact surface of the specified limiter, while the contact surface is inclined to a plane perpendicular to the axis of the movable sleeve and tangent to the leveling surface of the supporting element, with increasing distance from it to this plane in direction to the periphery of the deformity limiter of the large fontanel with static load.

It is advisable to have a deformation limiter of the large fontanel with a static load in the form of at least one protrusion on the lateral surface of the support element, the angle of inclination of the contact surface of which to the indicated plane is 5 ÷ 15 °.

It is preferable that the distance from the plane tangent to the leveling surface to the point of the contact surface of the deformation limiter of the large fontanelle maximally distant from it with a static load is 0.5 ÷ 1.0 mm.

It is advisable to limit the fontanel deformation by a static load in the form of a pair of symmetrically arranged petals, the contact surface of each of which is smoothly interfaced with the leveling surface of the support element.

It is preferable to have each petal with an aperture angle of 70 ÷ 85 °, a length along the common axis of symmetry of the petals of 2 ÷ 3 mm, a width of 4 ÷ 6 mm in the fontanel deformation limiter with a static load.

It is advisable to have a movable sleeve and a supporting element with corresponding cavities and openings for air outlet when moving the rod.

Preferably, the support element is made with lateral viewing windows in the form of U-shaped recesses or holes symmetrically located between the petals.

Preferably, the leveling surface of the support element is in the form of a continuous or split ring and is rounded in axial section.

It is advisable to perform the stock with a flat base with an area of 0.2 ÷ 1.5 mm ² .

Preferably, the support element is in the form of a removable sleeve.

Preferably, the system for ensuring the movement of the rod is made electromagnetic and includes a permanent magnet mounted on the rod, a measuring winding located in the movable sleeve, located relative to the permanent magnet with the ability to control the direction and speed of movement of the rod.

It is advisable that the control, processing, and indication unit be configured to create opposite polarities on the measuring winding to divert the rod to its original position and subsequently create a pulse of rod movement in the direction of the support element.

It is advisable to have a non-contact signaling device of the presence of a given static load on a large fontanel when measuring,

moreover, the specified detector to perform in the form of a sensor position of the sleeve relative to the housing.

Preferably, the position sensor of the movable sleeve relative to the housing is made comprising a generator, an additional sleeve with a cavity and a coil mounted respectively on the movable sleeve and the housing with the possibility of changing the inductance of the coil winding when moving the movable sleeve, and the coil winding should be included in the generator circuit.

It is advisable to connect the generator of the position sensor of the movable sleeve relative to the housing with a control unit for processing and displaying measurement data.

The technical result is also achieved by the fact that the support element for the device for measuring intracranial pressure in newborns and infants, having a body with a leveling surface at the end, according to a utility model, has an external limiter for deforming the large fontanel with a static load, its leveling surface protrudes beyond the contact surface the specified limiter, while the contact surface is made inclined to a plane tangent to the leveling surface, with increased by taking the distance from it to this plane in the direction to the periphery of the deformity limiter of the large fontanel with static load.

It is advisable that in the supporting element the limiter of deformation of the large fontanel with a static load is at least one protrusion on its lateral surface, made with a contact surface, the angle of inclination of which to the indicated plane tangent to the leveling surface is 5 ÷ 15 °.

Preferably, in the support element, the distance from the specified plane tangent to its leveling surface, to

the maximum point of the contact surface of the deformation limiter of the large fontanel with a static load was 0.5 ÷ 1.0 mm.

It is preferable to perform a fontanel deformation limiter with a static load in the form of a pair of symmetrically arranged petals, the contact surface of each of which smoothly mates with the leveling surface.

Moreover, in the limiter of deformation of the fontanel with a static load, each lobe preferably has an aperture angle of 70 ÷ 85 °, a length along the common axis of symmetry of the lobes 2 ÷ 3 mm, a width of 4 ÷ 6 mm.

It is advisable to carry out the supporting element with lateral viewing windows in the form of U-shaped recesses or holes located opposite each other between the petals.

Preferably, the leveling surface of the support element is rounded in axial section and has the form of a continuous or split ring.

Preferably, the support element is made in the form of a sleeve with a channel for moving the rod of the device for measuring intracranial pressure and openings for air outlet when moving the specified rod.

The essence of the utility model lies in the fact that the introduction of the fontanel deformation limiter by the static load provides an increase in the ICP measurement accuracy, while the use of an electromagnetic rod motion control system ensures the speed and ease of use of the device.

When conducting patent research, no solutions were found that are identical to the declared one, and, therefore, the claimed utility model meets the criterion of "novelty."

Figure 1 shows a device for measuring ICP in the context.

Figure 2 shows a support element with a limiter of fontanel deformation by static load from the contact surface side (bottom view).

Figure 3 depicts an embodiment of the support element in the context of the inspection window and the leveling surface in the form of a split ring.

Figure 4 depicts another embodiment of the support ring in section with a viewing window and a leveling surface in the form of a continuous ring.

Figure 5 depicts the position of the rod in the support element before measuring ICP.

Figure 6 shows the maximum output of the rod beyond the leveling surface of the support element.

7 is a communication diagram of the main parts of the device for measuring ICP, explaining its operation.

On Fig shows the location of the device on the fontanel of the child at the time of measuring ICP.

The device for measuring ICP contains (Fig. 1) a plastic housing 1, a movable sleeve 2 with a support element 3 made in the form of a tip, mounted in the housing 1 with the possibility of limited reciprocating movement to create a static load on the large fontanel of the child. The rod 4 of non-magnetic material is installed in the cavity of the movable sleeve 2 with the possibility of movement relative to the support element 3 for deformation of the fontanel with a short-term shock action.

The system for moving the rod 4 of the device is electromagnetic and includes a permanent magnet 5 mounted on the rod 4, a coil 6 placed in the wall of the movable sleeve 2 and made with at least one measuring winding 7,

mounted relative to the permanent magnet 5 with the ability to control the direction and speed of movement of the rod 4. The measuring winding 7 is connected through terminal 8 to the block 9 of the control, processing and display (Fig.7).

The rod 4 is made of plastic and has a flat base 10 with an area of 0.2-1.5 mm ² . With an area of less than 0.2 mm ² , a painful sensation of the measurement procedure is possible, with an area of more than 1.5 mm ² , guaranteed compression of the skin in the region of the large fontanel is not provided. The supporting element 3 is made in the form of a sleeve and has a channel (figure 3) with a diameter (G) of 3.0-3.5 mm for moving the rod 4.

The lower and upper sliding bearings 11 and 12, formed in the movable sleeve 2, provide free longitudinal movement of the rod 4 inside the coil 6 and the supporting element 3. The movement of the rod 4 down is limited by the surface 13 of the lower sliding bearing 11. The installation of the rod 4 in the upper initial position inside the movable sleeve 2 is limited by the surface 14 of the protrusion of the rod 4 and the upper sliding bearing 12.

A longitudinal slot 15 is made in the housing 1, into which a mechanical limiter 16 is installed, made integral with the movable sleeve 2 to limit its vertical reciprocating movement and to exclude rotational movement relative to the housing 1. To connect the measuring winding 7 to the control unit 9, processing and indication applied pin 8, part of which is built into the cavity of the mechanical limiter 16.

The ICP measuring device is equipped with a non-contact signaling device of the presence of a predetermined static load on the fontanel during measurement, made, for example, in the form of a sensor 17 (Fig. 7) of the position of the movable sleeve 2 relative to the housing 1. The specified sensor 17 contains an additional sleeve 18 and a fixed coil 19, mounted respectively on the movable sleeve 2 and the housing 1,

moreover, the winding 20 of the fixed coil 19 is connected through the terminal 21 to the circuit of the generator 22, which is connected to the control, processing and display unit 9 (Fig. 7).

The value of the static load when measuring (formed by the mass of the movable sleeve 2 with the supporting element 3, the measuring winding 7 and the additional sleeve 18, as well as the mass of the rod 4 with a permanent magnet 5) should be from 20 to 30 grams. With a mass of less than 20 grams, the required degree of stabilization of the position of the movable sleeve 2 with the supporting element 3 is not provided, with a mass of more than 30 grams, a significant increase in tonometric intracranial pressure occurs due to excessive deformation of the fontanel.

The supporting element 3 (Figs. 1, 2, 3) has, on the outside, a limiter 23 for deformation of the large fontanel with a static load with a contact surface 24, for example, in the form of a rotation surface, and is made with a leveling surface 25 at the end of its body. In this case, the supporting element 3 is preferably made in the form of a removable sleeve with a channel for moving the rod 4, which is the tip of the device for measuring intracranial pressure.

The fontanel deformation limiter 23 by a static load is located on the side wall of the support element 3 between the movable sleeve 2 and the leveling surface 25 and is configured to increase the fontanel’s contact area with the contact surface 24 while decreasing the ICP value. For this, the alignment surface 25 of the support element 3 protrudes beyond the contact surface 24 of said stop 23, which is inclined to a plane perpendicular to the axis of the movable sleeve 2 and tangent to the alignment surface 25 of the support element, with increasing distance from the contact surface 24 to this plane in the direction the periphery of the specified limiter 23.

Moreover, the angle (α) of the inclination (Fig. 3) of the contact surface 24 to the indicated plane is preferably 5-15 °.

The supporting element 3 may have various options, including with a leveling surface 25, rounded in axial section and having the shape of a split ring (figure 3) or a solid ring (figure 4).

In the preferred embodiment (figure 2), said stopper 23 can be made in the form of two petals symmetrically positioned relative to the leveling platform 25 with an angle (β) of an aperture of 70-85 ° smoothly interfaced with the leveling surface 25 made with a fillet radius (R ₁ ) 0.1-0.3 mm.

The fontanel deformation limiter 23 by a static load is coupled to the leveling surface 25 with the formation of concavity (Fig. 2,3) with a radius (R ₂ ) of 2-3 mm and has petals with a rounding of their contour with a radius (R ₃ ) of 0.3-0.5 mm .

The contact surface 24 of the limiter 23 of the deformation of the large fontanel with a static load (Fig. 3) has a maximum height (N) of 0.5 - 1.0 mm from the plane tangent to the leveling surface 25 of the support element 3, the length (S) of 2-3 mm ( figure 1), the width (B) is 4-6 mm (figure 2) and is formed by rounding with radii R ₄ and R ₅ equal to 1.5-2 mm and 4-6 mm, respectively.

Other embodiments of the limiter 23 are possible, including with one petal or in the form of a single annular protrusion (not shown in the drawings) with an inclined contact surface 24.

The supporting element 3 is fixed in the lower part of the movable sleeve 2 with an elastic retainer 27 (Fig. 1), which, if necessary, rotates the supporting element 3 around its axis, as well as removing it in order to remove the rod 4 for preventive cleaning of contaminants.

The rod 4 is installed in the cavity of the movable sleeve 2 in the original

position (figure 5) so that its flat base 11 is located at a distance (E) of 4.5 - 5.0 mm from the plane tangent to the leveling surface 25 of the support element. The maximum distance of the rod 4 from the cavity of the movable sleeve 2 is (W) 3.0-4.0 mm (Fig.6).

The housing 1 can be placed in a removable plastic protective casing 28, rigidly connected to the housing 1 by means of a decorative sleeve 29. In this case, the specified protective casing 28 and the housing 1 are mounted with the possibility of their vertical reciprocal movement relative to the movable sleeve 2 with the supporting element 3 ( figure 1) within a distance (L) of 4-6 mm

The movable sleeve 2, the stationary coil 19 and the support element 3 have corresponding cavities 30, 31, 32 and an opening 33 for air outlet when moving the rod 4.

The supporting element 3 is made with lateral viewing windows 34 in the form of U-shaped recesses (figure 3) or through holes (figure 4), symmetrically located between the petals of the fontanel strain limiter 23. The viewing windows 34 have a width (B) of 2-3 mm and a height (K) of 2.8-3.5 mm, which ensures air outlet when the rod 4 is moved, the leveling surface 25 of the support element 3 is visible when the device is installed on the center of an open fontanel, and simplifies installation of the device on the fontanel.

The supporting element 3 (figure 2, 3, 4) may additionally have broadening pads 35 to ensure stable operation of the device in metrological tests, made rounded radius R ₆ equal to 1.5-2 mm

To improve the stabilization of the position of the movable sleeve 2 and the support element 3 when measuring the ICP, the petals of the fontanel strain limiter 23 with a static load can be made with recesses 36 (Fig. 4) or with through holes (not shown in the drawings)

shown) with the formation of the contact surface 24 along the contour of the petal.

To simplify the operation of the device, the supporting element 3 with the fontanel deformation limiter 23 due to static loading can be made of transparent non-toxic material, which provides additional visibility to the leveling platform 25 of the support 3 when the device is installed on the center of a large fontanel.

For ease of disinfection and manufacture, the support element 3 is made in one piece with the fontanel deformation limiter 23 by a static load from a hygienically non-toxic material, for example, medical plastic compound. For ease of disinfection, the supporting element 3 is made removable and removable.

Unit 9 of the control, processing and indication provides switching, amplification, analog-to-digital conversion and signal processing by the microprocessor and includes a power source. The specified block 9 provides switching signals for changing the direction of the current in the measuring winding 7 in order to change the direction of movement of the rod 4 and create a metered shock effect on the fontanel and is controlled by a microprocessor.

The protective casing 28 (Fig. 8) combines the components of the device into a single design. On the front side of the protective casing 28 there is a button “OPERATION” 37 and a display 38 for displaying the ICP measurement results in digital form, which are included in the control, processing and display unit 9. The tonometer power supply consists of two rechargeable batteries with a total voltage of 2.4 V, which are located in a special tonometer power compartment on the back of the protective casing 28 (not shown in the drawings).

The principle of operation of the device is based on processing the function of the speed of movement of the rod 4 of a certain mass under the influence of a dosed magnetic field and the interaction of the rod with the elastic surface of the skin in the fontanel.

The essence of the invention lies in the use of shock for deformation of a large fontanel of a child when creating a constant static load, which ensures stabilization of the position of the measuring part of the device, and in the use of a special form of the support part of the meter, which allows to reduce the deformation of the fontanel when exposed to the specified static load. The device for measuring ICP provides the creation of a dosed pulse of movement of the rod 4 for deformation of the fontanel and the conversion of its speed (as a result of interaction with the elastic surface of the fontanel) into electric current signals.

The device is used as follows. The support element 3 and the lower part of the stem 4 are disinfected. The child is placed on the hands of the mother or nurse so that the surface of the large fontanel is horizontal. Hair in the fontanel should be combed in the direction from the back of the head to the forehead. During the ICP measurement procedure, the child should be at rest or sleeping. Determine the location of the center of the fontanel surface and mark it with a spot of brilliant green with a diameter of 1-2 mm.

The device has a support 3 down (Fig) and by pressing the button 37 "WORK" turn on the power. The device is mounted vertically on the child’s head in the fontanel so that the tonometer stem 4 base is installed in the center of the fontanel surface area indicated by green. The protective casing 28 of the device is gently lowered, maintaining its vertical position, until a characteristic sound of vibration of the rod 4 when it moves, accompanying the ICP measurement process, appears. The device is held in this position motionlessly (not more than 1 s) until the sound of vibration of the rod 4 ends, after which it is removed from the fontanel with the digital ICP value displayed on the display 38.

At low ICP, the contact area increases

fontanel with a contact surface 24 of the limiter 23 deformation of the fontanel by static load, which eliminates an unacceptable degree of deformation.

The deformation limiter 23 provides accurate ICP measurement due to the guaranteed contact of the leveling surface 25 with the fontanel in any form (flat, concave, convex). This is due to the location of the entire contact surface 24 of the deformation limiter 23 above the leveling surface 25 of the support member 3.

When lowering the protective casing 28 together with the housing 1, the movable part of the device (consisting of a movable sleeve 2 with a measuring winding 7, an additional sleeve 18 and a supporting element 3) moves upward relative to the housing 1. As a result of this, an additional sleeve 18 made, for example, of brass, moving over the stationary coil 19, changes the inductance of the winding 20, thereby changing the frequency of the generator 22, into the circuit of which it is connected through terminal 21.

At a certain frequency of the specified generator 22 by the control, processing, and indication unit 9, a direct current voltage of a certain polarity is automatically supplied to the measuring winding 7 through terminal 8, as a result of which the rod 4 moves upward by the electromagnetic field of the measuring winding 7 and is set to its original position.

After a certain time, the previously applied DC voltage is automatically removed from the measuring winding 7 of the coil 6 and a short voltage pulse of the opposite polarity is applied. As a result of this, the rod 4 receives a dosed impulse of movement in the direction of the fontanel and with its flat base 10 deforms it.

Permanent magnet 5 located on the rod 4, passing downward when moving towards the fontanel creates in the measuring winding 7

coil 6 voltage, which is further amplified and used to convert into digital values processing and analysis of the function of the velocity of the rod 4 and in the form of the measurement result of the ICP is displayed on the display 38.

In the process of operation of the device, the upper and lower bearings 12, 11 provide free longitudinal movement of the rod 4 inside the coil 6 and the support element 3. The movement of the rod 4 down is limited by the surface 13 of the lower sliding bearing 11. The installation of the rod 4 in the upper position is limited by the surface 14 of the protrusion of the rod 4 and the upper bearing 12 sliding. The hole 33 in the support element 3, the cavity 30, 31 inside the movable sleeve 2 and the cavity 32 in the stationary coil 19 allow air to escape when the rod 4 is moving. A mechanical stop 16 installed in the longitudinal slot 15 of the housing 1 prevents rotation of the movable sleeve 2 about its axis .

The conversion of the analog signal from the measuring winding 7 to digital form, software control of the operating modes, digital processing and analysis of the motion function of the rod 4 are carried out by a microprocessor, which is part of the block 9 of the control, processing and display.

In the inventive device, the stability of the value of the static load on the fontanel is ensured during measurement (due to the introduction of a non-contact signaling device of its predetermined value and the formation of a command for automatic measurement), which increases the accuracy of ICP measurement. The installation of a permanent magnet 5 on the rod 4 allows you to apply forced controlled movement of the rod 4 under the influence of the electromagnetic field of the coil 6 with the measuring winding 7. This greatly reduces the requirement for vertical installation of the device during measurement, and also creates the possibility of automatic installation of the rod 4 in its original position and several

ICP measurements for one installation of the device on the fontanel.

The device for measuring intracranial pressure is convenient due to the combination of all elements in one housing with overall dimensions of not more than 174 × 26 × 20 mm, weighing no more than 100 grams.

The proposed device for measuring ICP differs in the informative accuracy of setting the static load in the process of measuring IOP, which increases the accuracy and speed of measurement. The measurement procedure is painless. The measurement of ICP in mm Hg is provided. with an accuracy of ± 0.4 mm Hg Measurement time no more than 1 second.

Conducting on one child multiple measurements of ICP during the day with minimal time is very important for monitoring the correctness of the chosen method of treatment and can significantly increase its effectiveness. This eliminates the risk of infection during measurement due to the lack of direct contact of the device with the brain.

The simplicity of the design of the claimed device allows it to be manufactured at affordable prices, and the ease of use allows it to be used not only in clinical conditions, but also at home. The proposed technical solution allows to increase the accuracy of ICP measurement and provides the ability to track its changes during treatment. The advantages of the device are:

- non-invasive ICP measurement;

- Painless ICP measurement;

- high measurement accuracy on fontanelles of various shapes, including concave, flat, convex;

- reduction of the total time of the ICP measurement procedure;

- reducing the time of orientation of the device to the working position;

- application in any conditions without special staff training;

- improvement of consumer properties of the device (comfort,

ease of use, stability of parameters);

- simplification of the operation of the device.

The proposed device is convenient and reliable in operation, simple and economical to manufacture, safe and versatile in use, does not require belts, adhesive joints, long-term operation and is suitable for repeated disinfection in accordance with the requirements of sanitary standards.

Claims (23)

1. A device for measuring intracranial pressure in newborns and infants, containing a housing, a support element with a leveling surface at the end, a movable sleeve with the specified support element coaxially mounted on it, mounted in the housing with the possibility of limited reciprocating movement to create a static load on a large fontanel, a rod with a flat base mounted in the cavity of the movable sleeve with the ability to move relative to the support element and create an impact action for deformation of the large fontanel, a system for providing movement of the rod, made with at least one measuring winding connected to the control unit, processing and display, configured to convert the signal from the measuring winding to determine intracranial pressure and display the results, characterized in that the supporting element has, on the outside, a limiter of deformation of the large fontanel with static load, a leveling surface of the supporting element of the protrusion beyond the contact surface of the specified limiter, the contact surface being inclined to a plane perpendicular to the axis of the movable sleeve and tangent to the leveling surface of the support element, with an increase in the distance from it to this plane in the direction to the periphery of the deformation limiter of the large fontanel with a static load. 2. The device according to claim 1, characterized in that the limiter of deformation of the large fontanelle by static load is at least one protrusion on the side surface of the support element, the angle of inclination of the contact surface of which to the specified plane tangent to the leveling surface is 5 ÷ 15 ° . 3. The device according to claim 1, characterized in that the distance from the plane tangent to the leveling surface, to the point of contact surface of the deformation limiter of the large fontanel as far as possible from the plane, with a static load of 0.5 ÷ 1.0 mm. 4. The device according to claim 1, characterized in that the fontanel deformation limiter is subjected to a static load in the form of a pair of symmetrically arranged petals, the contact surface of each of which is smoothly interfaced with the leveling surface of the support element. 5. The device according to claim 4, characterized in that in the fontanel deformation limiter with a static load, each lobe has an aperture angle of 70 ÷ 85 °, a length along the common axis of symmetry of the lobes is 2 ÷ 3 mm, a width of 4 ÷ 6 mm. 6. The device according to claim 1, characterized in that the movable sleeve and the support element have corresponding cavities and openings for air outlet when moving the rod. 7. The device according to claim 4, characterized in that the supporting element is made with lateral viewing windows in the form of U-shaped recesses or holes located opposite each other between the petals. 8. The device according to claim 1, characterized in that the leveling surface of the support element has the form of a continuous or split ring and is made rounded in axial section. 9. The device according to claim 1, characterized in that the rod is made with a flat base with an area of 0.2 ÷ 1.5 mm ² . 10. The device according to claim 1, characterized in that the supporting element is made in the form of a removable sleeve with corresponding holes for moving the rod and air outlet when moving it. 11. The device according to claim 1, characterized in that the system for ensuring the movement of the rod is electromagnetic and includes a permanent magnet mounted on the rod, a measuring winding located in the movable sleeve, located relative to the permanent magnet with the ability to control the direction and speed of the rod. 12. The device according to claim 1, characterized in that the control, processing and display unit is configured to create voltage of opposite polarities on the measuring winding to divert the rod to its original position and then create a pulse of movement of the rod in the direction of the support element. 13. The device according to claim 1, characterized in that it is equipped with a contactless signaling device of the presence of a given static load on the large fontanel during measurement, said signaling device being a sleeve position sensor relative to the housing. 14. The device according to item 13, wherein the position sensor of the movable sleeve relative to the housing contains a generator, an additional sleeve with a cavity and a coil mounted respectively on the movable sleeve and the housing with the ability to change the inductance of the coil of the coil when moving the movable sleeve, and the coil of the coil is turned on into the generator circuit. 15. The device according to 14, characterized in that the generator of the position sensor of the movable sleeve relative to the housing is connected to a control unit for processing and displaying measurement data. 16. A support element for a device for measuring intracranial pressure in newborns and infants, having a body with a leveling surface at the end, characterized in that it has an external limiter for deformation of the large fontanel with a static load, its leveling surface protrudes beyond the contact surface of the specified limiter, the contact surface is inclined to the plane tangent to the leveling surface, with increasing distance from it to this plane in the direction enii the periphery deformation limiter large fontanel static load. 17. The support element according to clause 16, characterized in that the limiter of deformation of the large fontanel by static load is at least one protrusion on its side surface, made with a contact surface, the angle of inclination of which to the specified plane tangent to the leveling surface is 5 ÷ 15 °. 18. The supporting element according to clause 16, characterized in that the distance from the specified plane tangent to its leveling surface, to the point of contact surface of the deformation limiter of the large fontanel with a maximum static load is 0.5 ÷ 1.0 mm. 19. The support element according to clause 16, wherein the fontanel deformation limiter is subjected to a static load in the form of a pair of symmetrically arranged petals, the contact surface of each of which is smoothly interfaced with the leveling surface. 20. The support element according to claim 19, characterized in that in the fontanel deformation limiter with a static load, each lobe has an aperture angle of 70 ÷ 85 °, a length along the common axis of symmetry of the lobes is 2 ÷ 3 mm, a width of 4 ÷ 6 mm. 21. The support element according to claim 19, characterized in that it is made with lateral viewing windows in the form of U-shaped recesses or holes located opposite each other between the petals. 22. The support element according to clause 16, wherein the leveling surface thereof is made rounded in axial section and has the form of a continuous or split ring. 23. The supporting element according to clause 16, characterized in that it is made in the form of a sleeve with a channel for moving the rod of the device for measuring intracranial pressure and openings for air outlet when moving the specified rod.