RU2125471C1 - Device for removal of milk and prophylaxis of women's galactia - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: device has removing head with flexible cover-plate and mechanism actuating the latter and provided with compression chambers. Device includes milk collector coupled to removing head through mild outlet branch pipe, vacuum source, pneumatic supply source and pneumatic pulse forming unit which contains vacuum pulse former connected with its input to vacuum source and with its output, to mild collector. Device also includes compression pulse former, input of which is connected to pneumatic supply source and output, to compression chambers of mechanism actuating the flexible cover-plate. Pneumatic supply source is of vibration pulse type. It is provided with level regulator of pneumatic supply steady component. EFFECT: removal of milk at higher sensitivity of papilla and its nimbus under conditions of compression and strain. 4 cl, 4 dwg

Description

 The invention relates to medicine, namely to means for the selection of milk, and can be used to remove milk from the breast of a woman and for the prevention of hypogalactia in the postpartum period.

 Known electric suction pump of breast milk for one patient EOM-1 [1], containing a vacuum source in the form of a membrane compressor, a vacuum pulse shaper in the form of a pulsator, a pulse amplitude regulator, a glass remote pad and a milk collector. A disadvantage of the known device is the lack of effectiveness in stimulating the reflex of milk transfer and milk removal, especially in the case of tight mammary glands, which is due to the use of only a pulsating vacuum to separate the milk.

 Known combined apparatus for removing milk from the mammary gland and feeding the baby [2], which contains a vacuum source, a source of compressed gas, an elastic conical tube with a circular chamber, with which you can clamp the mammary gland overpressure, and milk collector. However, the presence of a circular pinch pneumatic chamber also cannot sufficiently provide stimulation of the milk flow reflex, since when excess pressure is applied, the elastic walls of the circular chamber form a star-shaped structure, into the folds of which the breast skin can fall and get pinched, causing a woman's combat sensations.

 A device for expressing milk [3] is known, comprising an electric motor with a reducer connected by means of an eccentric to a vacuum pulse generator made in the form of a plunger pump, a vacuum pulse amplitude regulator, a rigid plate and a milk collector. However, the known device is not effective enough to stimulate the reflex of milk transfer, since it has only a vacuum component for the isolation of milk, and in some cases does not provide a sufficiently complete removal of milk from the woman’s gland.

 A device for milk removal and prevention of hypogalactia in women is known [4], including a remote head with an elastic pad and a mechanism for acting on an elastic pad with compression and extension chambers, a milk collector connected to the portable head through a milk outlet, a vacuum source, a source of compressed gas, a unit for generating pneumatic pulses, including a vacuum pulse shaper, connected by an input to a vacuum source, and an output to a milk collector, and compression and tension pulse shapers, under closed by the entrance to the source of compressed gas, and by the exit to the compression and extension chambers.

 The external head of the device acts on the nipple and the area of the mammary gland with impulses of vacuum, compression and tension, which in many cases allows for effective removal of milk from the gland.

 Common essential features of the known and claimed device are the presence of a remote head with an elastic pad and a mechanism for acting on the elastic pad, a milk collector connected to the remote head through a milk outlet, a vacuum source, a pneumatic pulse generating unit, including a vacuum pulse shaper and a compression pulse shaper. The known device is selected as the closest analogue.

 A disadvantage of the known device is that, in case of increased pain sensitivity of the nipple and areola area (lactostasis, mastitis, injuries and inflammatory phenomena in the mammary gland), the action of compression and extension pulses on the nipple and areola area is excluded, which does not allow to realize the advantages of the known device in fully. An effective method of expressing milk from the gland in such cases is the impact on the nipple and areola by vibration together with vacuum pulses. With this effect, in a patient who does not experience noticeable pain, the nipple and areola mechanoreceptors are excited, the milk flow reflex is caused, and milk is removed from the gland. In addition, vibration, penetrating into the tissues of the gland, has a direct effect on the myoepithelial cells of the mammary gland, causing their contraction, which also helps to remove milk from the gland. It should be noted that the combined action of vibration and compression stimuli on the nipple and areola of the mammary gland leads to an increase in the milk yield reflex.

 The problem solved by the invention is to increase the efficiency of excretion of milk from the gland with increased pain sensitivity of the nipple and areola, as well as increasing the reflex of milk flow during normal pain sensitivity.

The technical result of the claimed invention is as follows:
1) milk is removed from the gland in case of increased pain sensitivity of the nipple and areola when they are compressed and stretched,
2) the reflex of milk flow is enhanced with normal pain sensitivity of the nipple and areola, which allows more effective correction of hypogalactia.

 The problem is solved in that in the known device for milk removal and prevention of hypogalactia in women, containing a remote head with an elastic pad and a mechanism for acting on this pad equipped with compression chambers, a milk collector connected to the portable head through a milk outlet, a vacuum source, a pneumatic supply source and a unit for generating pneumatic pulses, including a vacuum pulse shaper, connected by an input to a vacuum source, and an output to a milk collector, and a compression pulse shaper, connected an input with a pneumatic power source, and an output with compression chambers of the mechanism for acting on an elastic pad, in accordance with the invention, the pneumatic power source is made vibropulsing and is equipped with a level regulator for the constant component of pneumatic power.

 The problem is also solved by the fact that the device is equipped with a key "vibration on / off" installed on the output of the pneumatic power source.

 In addition, the mechanism of action on the elastic pad is equipped with a tensile chamber, which is connected to a pneumatic power source.

 In addition, the pneumatic impulse formation unit is equipped with a stretch pulse shaper, the input of which is connected to the pneumatic supply source, and the output - with the stretching chamber of the mechanism for acting on the elastic pad.

 The essence of the invention lies in the fact that vibration, acting on the mechanoreceptors of the nipple and areola, causes a milk flow reflex that is not accompanied by painful sensations even in case of increased pain sensitivity. Vibration, combined with impulses of vacuum, compression and tension, applied to the nipple, enhances the reflex of milk flow, which allows you to effectively deal with hypogalactia.

 The invention is illustrated in FIG. 1 to 4. In FIG. 1 is a block diagram of a device in which vibration pulses are supplied to the mammary gland through a compression pneumatic chamber connected to a compression pulse shaper. In FIG. 2 is a block diagram of a device in which vibration pulses are supplied to the mammary gland through a compression pneumatic chamber connected to a compression pulse shaper, and continuous vibration is supplied to the mammary gland through a tension pneumatic chamber. In FIG. 3 is a block diagram of a device in which vibration pulses are supplied to the mammary gland through a compression pneumatic chamber connected to a compression pulse shaper, and through a tension pneumatic chamber connected to a tension pulse shaper. In FIG. Figure 4 shows the cyclograms of vacuum pulses and pneumatic pulses supplied to the mechanism of action on the elastic pad: here a is the cyclogram of vacuum pulses, b, c, d is the cyclogram of pneumatic pulses at the output of the compression pulse shaper (b - vibration pulses when the constant component of the vibration signal is derived to zero, in - vibration pulses with a nonzero constant component, g - pneumatic pulses at the output of the compression pulse shaper when the key position is “vibration is on”), d, f - diagrams of pressures supplied to the pneumatic chamber in the absence of a stretch pulse shaper (d is the constant component of the vibratory pulsed power is zero, e is the constant component of the vibratory pulsed power is not zero), g, h, and are the pulses of the pneumatic pulses at the output of the stretch pulse shaper (w is the constant component of the vibratory pulsed power is zero, h - the constant component of the vibratory-pulsing power is nonzero, and - the pneumatic pulses at the output of the stretch pulse shaper in the key position "vibration off").

 The device (Fig. 1) contains a vacuum source 1 and a source of vibratory pulsating pneumatic supply 2, which can be used, for example, a membrane or piston compressor with an electric drive, operating in air discharge mode or in suction mode. The regulator of the constant component of the pneumatic supply 3 is connected to the output of the source of the vibrating pulsating pneumatic supply 2 — an adjustable pneumatic throttle connected to the atmosphere. In addition, the device comprises a pneumatic pulse generating unit 4, an external head 5 with a milk collector 6, and a vibration-on-off key 7 associated with the output of the vibratory pulsating pneumatic power supply 2 and pneumatic capacity 8. The pneumatic pulse generating unit 4 includes a vacuum pulse shaper, a shaper compression pulses and a cam mechanism 9, driven by an electric motor with a gear 10. The vacuum pulse shaper consists of a vacuum amplitude regulator 11 and a limit switch 12 connected with a cam mechanism 9. The compression pulse generator is a limit switch 13 connected to the cam mechanism 9. The extension head 5 comprises a rigid body 14, an elastic pad 15 with a milk outlet 16 and an air-controlled compression mechanism 17 of the elastic pad 15. The output of the compression pulse shaper is connected a pneumatic actuator with a pneumatically controlled compression mechanism 17 of the external head 5, and the output of the vacuum pulse shaper through the milk collector 6 is connected by pneumatic pipelines to the milk outlet 16 Oh lining 15.

 In the particular case of the device (Fig. 2), the remote head contains a pneumatically controlled stretching mechanism 18 of the elastic pad 15. In this case, the pneumatically controlled stretching mechanism 18 is directly connected to the output of the vibratory pulsating pneumatic power supply 2.

 In the particular case of the device (Fig. 3), a pulser of stretching pulses is introduced into the pneumatic pulses generating unit 4, which is a limit switch 19 connected to the cam mechanism 9. The input of the limit switch 19 is connected to a vibratory pulsating pneumatic power supply 2, and the output to a pneumatically controlled stretching mechanism 18 elastic pads 15.

 The operational characteristics of the device are determined by the operation of the vibratory pulsating pneumatic power supply 2, for which, for example, a membrane or piston compressor with an electric drive can be used. In this case, the vibration pulsation frequency is determined by the rotation speed of the electric motor and the compressor design. A vibratory pulsating pneumatic supply will work efficiently if the pneumatic capacity of the load connected to its output is commensurate with the volume of air pumped by the compressor in one cycle. The pneumatic throttle 3 connected to the output of the vibratory pulsating pneumatic supply 2 is connected with the atmosphere and is a regulator of the constant component of the pneumatic supply 2. In the case when the throttle 3 is maximally open, the amount of air pumped by the compressor in one cycle has time to bleed through the throttle 3 into the atmosphere until the next portion arrives air from the compressor (Fig. 4-d). If the throttle 3 is partially blocked, then at the output of the pneumatic supply 2 a constant component appears (Fig. 4), the amplitude of which depends on the degree of overlap of the throttle 3. The volume of the air capacity 8 (Fig. 1-3) is many times larger than the volume of air pumped compressor in one cycle, so connecting with the key 7 of this capacity to the output of the pneumatic supply 2 reduces the amplitude of the variable component at the output of the pneumatic supply 2.

 The device as a whole works as follows. When the pneumatic supply 1 and 2 are connected and the electric motor 10 is turned on, the final pneumatic switches 12 and 13, connected with the cam mechanism 9, begin to produce pneumatic pulses shifted in time relative to each other (Fig. 4-a is a sequence of vacuum pulses at the output of the vacuum pulse shaper); b - the sequence of pneumatic pulses at the output of the compression pulse generator, when the pneumatic capacity 8 is disconnected from the output of the pneumatic supply 2, and the pneumatic throttle 3 is in the position that is maximally open; c - a sequence of pneumatic pulses at the output of the compression pulse shaper when the pneumatic capacity 8 is disconnected from the output of the pneumatic supply 2, and the pneumatic throttle 3 is in a partially closed position; d - the sequence of pneumatic pulses at the output of the compression pulse generator, when the pneumatic capacity 8 is connected to the output of the pneumatic supply 2, and the pneumatic throttle 3 is in a partially closed position).

 From the output of the vacuum pulse shaper 11 - 12, vacuum pulses, adjustable in amplitude by the vacuum amplitude regulator 11, are fed to the milk collector 6, connected through the milk pipe 16 with an elastic pad 15 of the remote head 5.

From the output of the compression pulse former 13, pneumatic pulses (Figs. 4-b, c, d) are fed to the pneumatically controlled compression mechanism 17 of the elastic pad 15. As can be seen from FIG. 4, vacuum pulses begin before pulses generated by the compression pulse shaper. As a result, when using the device, the nipple and areola of the mammary gland are first sucked in by the neck of the elastic lining 15 (Fig. 1), after which they are affected by the compression mechanism 17 through the elastic lining 15. A vibrating pulsating pneumatic power supply 2 is also connected to the compression chamber through a compression pulse shaper 13, which provides vibrations to the mammary gland simultaneously with compression pulses. The remote head of the device that does not contain a stretching mechanism can be small in size and convenient for use as an individual device. In such a device, it is possible to implement the following modes of exposure to the mammary gland:
1) exposure to packets of vibration pulses - in case of increased pain sensitivity of the nipple and areola, when their compression causes pain;
2) exposure to compression impulses with vibration superimposed on them - to enhance the milk flow reflex with the threat of hypogalactia;
3) the impact of compression pulses with a negligible vibration amplitude - in the case of a sufficiently selected milk yield reflex when expressing milk after feeding the baby.

 An additional effect on the mammary gland is achieved by introducing vibration through the pneumatically controlled stretching mechanism 18 of the elastic lining 15, the pneumatic chamber of which is directly connected to the source of vibrating pulsating pneumatic supply 2 (Fig. 2). In the case when the remote head 15 of the device is equipped with a stretching mechanism 18 connected with a vibrating pulsating source 2 of pneumatic supply through a shaper of stretching pulses 19 (Fig. 3), vibration is supplied to the mammary gland both through the compression mechanism and through the stretching mechanism, which ensures high efficiency excretion of milk. A device made in accordance with FIG. 3, is intended primarily for treatment rooms.

Sources of information
1. An electric suction device for breast milk for one patient EOM-1, 1986. Technical characteristic. 1986 year

 2. US patent N 4323067, MKI A 61 M 1/06, 1982

 3. Engel breast pump. Type SMB. Technical specifications. 1993 year

 4. RF patent N 2063773, IPC 6 A 61 M 1/06, publ. 1996 year

Claims (4)

 1. A device for the removal of milk and the prevention of hypogalactia in women, containing a remote head with an elastic pad and a mechanism for acting on this pad equipped with compression chambers, a milk collector connected to the remote head through a milk outlet, a vacuum source, a pneumatic feed source and an air pulse formation unit, including a vacuum pulse shaper connected by an input to a vacuum source, and an output to a milk collector, and a compression pulse shaper connected by an input to a pneumatic source tions, and output - with compression chambers feedback mechanism to the elastic pad, characterized in that the source pnevmopitaniya configured vibropulsiruyuschim and level regulator provided with a constant component pnevmopitaniya.  2. The device according to p. 1, characterized in that it is equipped with a key "vibration on / off" installed at the output of the pneumatic power source.  3. The device according to p. 1, characterized in that the mechanism of action on the elastic pad is equipped with a tensile chamber, which is connected to a pneumatic power source.  4. The device according to paragraphs. 1 and 3, characterized in that the pneumopulse forming unit is equipped with a stretch pulse shaper, the input of which is connected to the pneumatic supply source, and the output - with the stretching chamber of the mechanism of action on the elastic pad.

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