DK152609B - Apparatus for electrical stimulation - Google Patents

Description

The invention relates to an apparatus for electrical stimulation and of the kind set forth in the preamble of claim 1, which apparatus is used medically or veterinarily for the electrical stimulation of mammary glands. The appliance can be used on cattle farms and / or specialized. hospitals.

Various apparatus are known which are capable of electrically affecting the organs or tissues of living organisms and which can find medical use, including electrical stimulation devices which give out signals in the form of continuous or interrupted trains of pulses of a certain shape and length, the parameters of the pulses, e.g. amplitude and frequency, change according to certain rules. There are universal apparatus of the kind in question, in which the parameters are varied within wide limits, as well as specialized apparatus, for example. can be used for electrical stimulation of skeletal muscles and which has only a limited number of parameters. Many companies in different countries manufacture such appliances.

In the area concerned, a method of stimulating the milk production reflex during machine milking is known, but at present, machine milking of cattle on cattle farms cannot ensure adequate stimulation of the mammary receptors, resulting in reduced milk production and increased mastitis frequency. To stimulate the mammary receptors, use a mechanical massage by hand or otherwise, and wash the udder with warm water. This stimulation elicits centripetal impulses that cause a reflex stimulation of neurohumoral systems and a reflex change of tone in the smooth muscles of the udder, thereby achieving a significant increase in milk production and quality.

However, this conventional method of affecting the mammalian receptor area requires a great deal of physical effort when there are many animals to be treated, resulting in poor treatment, less milk production and a higher frequency of mastitis. Therefore, new methods are needed to influence the mammary receptor domain.

From German Patent Specification No. 1,764,454, an apparatus of the kind specified in the preamble of claim 1 is known, in which the stimulus pulse polarity automatically changes. The stimulation pulses are distributed over several channels by means of an output device. Instead of multiple muscle portions, more patients or animals can be connected to the different channel outputs, when they only need one channel separately. The method is also used in clinics using such devices.

However, it is not profitable for an apparatus with e.g. 10-12 channels to end more than 5-6 persons or animals, since the treated person or animal must be near the amplitude control circuit for that channel.

However, when it is necessary to perform simultaneous treatment of e.g. a hundred animals or more, the signals must be transmitted to the treatment site. In addition, the amplitude at each treatment site must also be regulated and the following requirements must be met: (a) avoiding distortion of the pulse shape throughout the amplitude control range; (b) for varying numbers of connected patients, there must be no mutual influence between the different regulatory circuits; (c) for technical reasons, excessive cable length must not be used; (d) the signal energy must be utilized to the maximum; and (e) a local supply at the processing site is undesirable.

The apparatus known from the above disclosure specification cannot effectively meet these requirements, since the output unit e.g. must have 200 secondary windings and 200 wires for patients. Another disadvantage of the known apparatus is also the mutual dependence between the channels, since the windings are in the common output unit and affect each other electrically. Due to the inductance of the windings and in the e.g. 100 m long lines to the treatment sites and the load capacitance make it difficult to maintain the signal shape.

German patent specification No. 976,354 discloses an electrical stimulation apparatus for generating electrical impulses to nerves, tissues or muscles, with the possibility of changing the pulse shape, duration and amplitude. The apparatus also includes a polarity switch, which allows you to change the pulse polarity. The polarity switch is a manually operated switch that provides only positive signal polarity or negative signal polarity. This is a common element in modern electrostimulation technology. An automatic signal polarity reversal according to a given rule is neither present nor obvious in the prior art apparatus, nor can it satisfy the above conditions a) -e).

German Patent Specification No. 1,589,503 discloses an apparatus in which a control device in the form of a preprogrammable coupler automatically changes the polarity of the stimulation pulses and the pause between these pulses. However, this apparatus is a typical single channel apparatus which cannot meet the above conditions.

The invention provides an apparatus for electrical stimulation of mammary glands, with a central single-channel electrostimulator of said kind, by which, in several patients or animals in a larger room, treatment can be done with due regard to individual needs, without distortion of the pulse form. The device must also be used both for the treatment of large herds and for medical treatment in hospitals.

To this end, the apparatus is designed as defined in the characterizing part of claim 1.

According to claims 2-4, the apparatus can be used for stimulation of mammary glands in cows during milking, for prophylaxis and treatment of mastitis, and for normalization of mammary gland tone in non-pregnant women and for stimulation of mammary glands in nursing women.

The benefits of using the appliance are as follows: - prevention and treatment of mastitis, - greater milk yield and quality, - normalization of the mammary gland, - shorter milking, - elimination of manual milking, - effective preparation of udders in cows that calve. for the first time, and - high yield for cows starting to produce milk.

The apparatus according to the invention is compatible with the conventional treatments, e.g. when milking on cattle farms. The electrical stimulation can take place during the milking itself.

In the case of non-milking, separate electrodes placed on the animal's udder and the overlying area are used. Up to 100 animals can be treated simultaneously. The flexible structure of the output signal allows to meet different stimulation purposes depending on the physiological state of the individual animals in a given herd.

There is separate signal level control for the individual animals, taking into account the individual excavability. The apparatus according to the invention can be used by personnel without special expertise.

The apparatus according to the invention can be used very effectively on large cattle farms where the animals do not live under natural conditions and where the operation is affected by the following factors: lack of exercise, machine milking, lack of ability to control the quality of udder care.

With the apparatus according to the invention, a daily improvement of milk production of 10-15% is observed compared to a control group using a manual udder massage. This means an annual milk production of 3000-3500 kg. The fat content of the milk is increased from 3.3 to 3.6 percent and the milking time is reduced by 1-1.5 minutes.

The invention is explained in more detail below with reference to the schematic drawing, in which fig. 1 is a block diagram of one embodiment of the apparatus for the electrical stimulation of mammary glands; FIG. 2 is a functional diagram of the apparatus according to the invention; FIG. 3 is a circuit diagram of an output unit and unit for changing the stimulus pulse polarity; and FIG. 4 time diagrams to explain the shape of the output of the apparatus according to the invention.

The apparatus according to the invention comprises a main oscillator 1 (Fig. 1) which emits an impulse train, a frequency modulator 2 arranged to perform a frequency modulation of these pulses, the input of the modulator being connected to the output of the main oscillator 1, a stimulation pulse generator 3 which emits pulses of given length and shape corresponding to the pulses of the main oscillator 1, the input of this generator being coupled to the output of the frequency modulator 2.

An amplitude modulator 4 serves for amplitude modulation of the generated pulse train, the input of this modulator being coupled to the output of the generator 3. The apparatus further comprises a modulation signal generator 5 and a unit 6 arranged to generate activation and gap periods, with its input coupled. to the output of the generator 5 connected to a control input to the frequency modulator 2. The output of the unit 6 is coupled to a control input to the amplitude modulator 4 and to another control input to the frequency modulator 2.

The apparatus further comprises a unit 7 for changing the polarity of the stimulation pulses, which unit has its input connected to the output of the amplitude modulator 4. The apparatus further comprises a unit 8 for automatically controlling the polarity of the stimulation pulses, the output of this unit being coupled to a control input to the unit. 7, while its inputs are coupled to the output of the pacing pulse generator 3 and another output of the modulation signal generator 5, respectively.

An output unit 9 has its input connected to the output of the unit 7 and its output coupled to a distribution line 10 with wires 11 ^ ...... 11 ^, which wires connect to respective points 12- ^ ...... 12 ^ subjected to electrical stimulation.

Each of these wires 11 ^ ...... 11 ^ is connected to a circuit 13 for adjusting the amplitude of the pacing pulses, which circuit has its output connected to an adapter 14. The output of the adapter 14 is connected to surface electrodes 15 which is fixed to the being not shown in the drawing.

The apparatus comprises an indicator unit 16 whose input is connected to the output of the output unit 9 and the output of which is connected to an indicator line 17 comprising wires 18 ^ ...... 18 ^ for the respective points 12 ^ ..... 12 ^ which is set for electrical stimulation. Lamps 19 are connected to the wires 18 ^ ..... 18 ^. A measuring unit 20 has its input for bound with the output of the output unit 9.

The output unit 9 consists of a combination of two unipolar signal amplifiers ^ with common load 21 (Fig. 2) to produce an output signal if the polarity changes according to a given rule.

The amplifier which outputs a signal of a first polarity comprises a preamplifier 22 and an emitter follower 23 with separate feed line 24.

The amplifier providing the second polarity signal comprises a preamplifier 25 and an emitter follower 26 with a separate supply line 27.

The pacing pulse polarity modifier unit comprises two switching circuits 28 and 29 and a phase inverter built around a transistor 30 having loads 31 and 32. Switching circuits 28 and 29 are coupled to loads 31 and 32, respectively, and to preamplifiers 22 and 25. respectively. transistor 30 is coupled to the output of amplitude modulator 4.

The automatic pulse pulse polarity control unit 8 comprises an RST flip-flop 33, an adaptation circuit built around a transistor 34 having a load 35 and coupled to an output of the RST flip-flop 33, and a switching unit 36, coupled to the inputs of the RST flip-flop 33 and to a control signal unit 37 for determining the rule for changing the polarity of the pacing pulses.

The load 35 on the adapter circuit and the second output of the RST flip-flop 33 are coupled to the control inputs of the switching circuits 28 and 29, respectively.

The inputs of the control signal unit 37 are coupled to the stimulation pulse generator 3 and to another output of the modulation signal generator 5.

The circuit 13 for adjusting the amplitude of the stimulation pulses at the points 12 ^ ..... 12N, ^ is u <^ "set for an electrical stimulation comprises a potentiometer 38.

The adapter unit 14 comprises transistors 39 and 40 with mutually opposite conductances, as well as diodes 41 and 42 and an emitter load 43.

The output of potentiometer 38 is coupled to the bases of transistors 39 and 40, whose emitters are coupled to the emitter load 43 and whose collectors are connected to the distribution line 10 through diodes 41 and 42. The anode in diode 41 and cathode in diode 42 are connected to distribution line 10.

FIG. 3 shows changes in the output unit 9 and in the unit 7 to change the polarity of the stimulation pulses.

The emitter sequences 23 and 26 (Fig. 2) use combinations of transistors 44 (Fig. 3), 45/46 and 47.

The preamps 22 (Fig. 2) and 25 use transistors 48 (Fig. 3) and 49 with loads 50 and 51 and base resistors 52 and 53, respectively.

The switching circuits 28 (Fig. 2) and 29 use transistors 54 (Fig. 3) and 55 with loads 56 and 57 and base resistors 58 and 59, respectively.

FIG. 4 shows time diagrams for the output signal.

The principle of the apparatus according to the invention is that an electrical impulse signal is applied to the mammary receptors by surface electrodes to influence these receptors. The resulting centripetal impulses serve to normalize and stimulate the physiological functions of the organism, whether in a human or an animal.

Referring now to the block diagram of FIG. 1. The main oscillator 1 emits a continuous pulse train of given polarity and repetition frequency. The main oscillator 1 is built around a unijunction transistor. The pulse repetition rate is determined by the time it takes a non-displayed capacitor to charge. The desired frequency range is selected by switching between capacitors of different values.

The capacitor is charged through a transistor used as controlled resistance. This transistor together with a control circuit constitutes the frequency modulator 2. There are two different modes of operation: constant frequency manually selected by means of a dial, and frequency modulation where the frequency is automatically varied within given frequency ranges, e.g. 4 to 20 Hz, 20 to 100 Hz and 100 to 500 Hz.

The signal from the frequency modulator 2 is applied to the stimulation pulse generator 3, which for each pulse from the main oscillator 1 produces a stimulation pulse of a given length, e.g. from 0.2 to 25 ms, and at a given duration for the leading edge of the pulse, e.g. from 0.1 to 0.5 ms.

The pacing pulse generator 3 is constituted by a controlled multivibrator. The step of propagating the leading edge of the pulse comprises a capacitor whose charge time constant determines the width of the leading edge.

In this way, the main oscillator 1, the frequency modulator 2, and the stimulation pulse generator 3 are capable of delivering a continuous sequence of unipolar pulses of a given length and with the edge of a given duration. These pulses of constant or modulated frequency are applied to the input of the amplitude modulator 4.

The modulation signal for modulating the frequency and amplitude is generated by the generator 5, which outputs a continuous signal having the form of straight-legged triangles. The duration of these triangles is selected from e.g.

1 second to 30 seconds and determines the duration of the cycle to stimulate the patient. The triangular signal is provided by conventional circuits for charging / discharging a capacitor, with square pulses being applied to the step of charging / discharging. Square pulses are supplied to the unit 8 for automatic control of the polarity of the pacing pulses and they are used as marking pulses to mark the end of the cycle. A triangular signal is applied to an input to the frequency modulator 2 and used in one of said frequency modulation modes. This signal is further processed in the unit 6 which is arranged to establish the activation periods and the interval periods. The unit 6 is arranged to undercut the triangular signal and output an output having the form of straight-legged triangles separated from each other by zero-level spaces. The period in which the unit 6 emits a signal corresponds to the excitation period, while the interval period corresponds to the period in which the signal from the unit 6 has zero level. By adjusting the cut-off level, different ratios can be obtained within the same cycle between the excitation period and the interval period, e.g. ratio 1/1 to 1/3. The output of the unit 6 is applied to the amplitude modulator 4 and the frequency modulator 2.

The amplitude modulator 4 is a voltage divider with an adjustable resistance from which the modulated signal is taken out. The adjustable resistance is constituted by a transistor which is controlled so that the modulating signal, namely pulses of the form of straight-leg triangles, is subjected to over-cutting, whereby the envelope signal is trapezoidal with rise and fall at the beginning and end of the excitation period respectively. The amplitude modulator 4 serves to control the signal level.

The circuits denoted by 1-6 determine the signal structure as shown in FIG. 4th

At the output of the amplitude modulator 4 (FIG. 1), it is obtained at A in FIG. 4, comprising excitation periods 60 and space periods 61 in each excitation cycle 62. The length of the excitation cycle and of the excitation period and the interspace period, respectively, are determined by the shape of the modulating signal. When the amplitude modulator 4 receives no modulating signal, a continuous excitation signal is obtained, as shown by B in FIG. 4th

Within the excitation periods 60, there is a train of pulses 63 whose repetition frequency is determined by the frequency modulator 2 (Fig. 1). When the modulating signal is not present, the repetition frequency is constant and the mode of operation I (Fig. 4) is selected in the main oscillator 1 (Fig. 1).

In the case of frequency modulation (mode II, Fig. 4), the signal for modulating the signal A is constituted by the output of the unit 6 (Fig. 1), ie. a signal having the shape of straight-legged triangles separated from each other by spaces. In that case, higher frequency corresponds to higher signal level. Since the same signal is used for amplitude modulation, a synchronous amplitude / frequency modulation with frequency maximum is obtained at the middle of the excitation period. In the case of signal B (Fig. 4), the modulating signal is a triangular signal originating from the output of the modulation signal generator 5 (Fig. 1).

In units 7 and 8, the signal polarity is established, but the signal parameters are not changed. The various ways to change the signal polarity are shown in FIG. 4a-4e. FIG. 4a and 4b show signals of positive and negative polarity, respectively. FIG. 4c shows a signal whose polarity changes for each other impulse while in FIG. The signals shown in 4d and 4e change the polarity of each other cycle and after a certain time interval.

The output unit 9 (Fig. 1) aims to increase the signal power and adapt the output of the apparatus to the distribution line 10, whose wires 11 ^ .... 11 ^ serve to transmit the signal to points 12 ^ ... 12 ^ stimulation.

In this way, group treatment of N patients, humans or animals can be done, with N e.g. can be equal to 100.

The circuit 13 for adjusting the pacing pulse amplitude is arranged to select the signal level required for a given patient, the signal through the adapter 14 being applied to the surface electrodes 15. In this way, it is possible to take into account the individual excitability of the patients.

The indicator unit 16 ensures proper operation of the apparatus according to the invention. The unit 16 comprises a separate supply source which, through an adjustable resistor in the form of a transistor, feeds the indicator line 17. This line comprises the wires 18 ..... 18 ^ which are connected to the lamps 19 corresponding to the respective points 12 ... .. 12 ^ subjected to electric path modulation. The control input of the adjustable resistance not shown in the drawing is fed to the signal from the output unit 9. When the device is switched on and the signal is not available, the lamps illuminate at a given brightness. When the signal is present, the brightness changes according to the signal amplitude and synchronously with the excitation period. In this way, one is able to monitor the apparatus and ascertain the presence of the signal over the distribution line 10 to the respective points 121 .... 12N subjected to electrical stimulation.

The measuring unit 20 serves to measure and indicate the amplitude of the output signal.

FIG. 2 shows in more detail the circuits 7, 8, 9, 13 and 14 which are included in the output circuits of the apparatus.

The circuit structure of the units 7 and 81 is selected according to the type of the output unit 9.

The output unit 9 comprises two separate unipolar signal amplifiers having common load 21.

The first amplifier gives signals of positive polarity, while the second amplifier gives signals of negative polarity. The positive signal is derived from the first amplifier comprising the preamplifier 22 and as the output stage the emitter follower 23 at load 21. This step is fed with power through a separate supply line 24.

The negative signal is output from the second amplifier, it is supplied with power through a separate supply line 27, and comprises the preamplifier 25, and as the output stage the emitter follower 26 which is coupled to the load 21. The output of the amplitude modulator 4 has the same polarity and is output to the unit 7. , namely to the input of the phase inverter built around the transistor 30 with similar collector / emitter loads 31 and 32. From this, signals of the same amplitude and opposite polarity are obtained in relation to the feed lines 24 and 27. This implies, the load 31 gives a negative signal to the line 24, while the load 32 gives a positive signal to the line 27. These signals are applied to the inputs of the respective amplifiers 22 and 25, respectively, through the switching circuits 28 and 29, respectively.

The input of the respective preamplifiers 22 or 25 is fed to the signal only when the respective switching circuits 28 or 29 are conductive, and the load 21 only outputs the respective signals under these conditions. At a given time, only one of the switching circuits 28 or 29 is conductive, and only one amplifier in the output unit 9 is active, whereby the output emits a signal of a given polarity. By keeping the switching circuits 28 and 29 in the required state, it is possible to generate output signals of different polarity and in different sequences. The switching of the switching circuits 28 and 29 takes place within the intervals between the pulses or within the intervals between the excitation periods.

The unit 8 for automatically controlling the stimulation pulse polarity is used to control the state of the switching circuits 28 and 29. The main component of the unit 8 is the RST flip-flop 33. The Q output of the RST flip-flop 33 controls the switching circuit 28, while the Q output of the flip-flop controls switching circuit 29. To generate the control signal for controlling switching circuit 28 relative to line 24, the Q output of the RST flip-flop 33 is coupled to an adaptation circuit constituting of the transistor 34, whose load 35 outputs this control signal. The adaptation circuit does not invert the signal.

The state of the RST flip-flop 33 is determined by the incoming input signals. FIG. 2 shows a change in the wiring diagram of the RST flip-flop 33. At any point in time, a pair of switches in the switch 36 are closed. When this switch engages the S or R input of the RST flip-flop 33 to the control signal unit 37, the flip-flop is brought into the corresponding state which determines whether the signal should have positive or negative polarity. The RST flip-flop 33 automatically changes state when activated via the input T, thereby changing the polarity of the output signal. The control pulses from the output of the control signal unit 37 are applied to the T input of the flip-flop and the polarity changes when the signal is not present, ie. in the intervals between the pulses or between the periods of exertion.

This is achieved by providing in the control signal unit 37 the signals for controlling the RST flip-flop 33. To keep the flip-flop in a state determined by the S or R input, the respective input is coupled to the flip. the flop's O-lead, provided control pulses that control the state of the RST flip-flop 33 relative to the T input. The input of the control signal unit 37 is fed to the stimulation pulses of the stimulation pulse generator 33, as well as the pulses of one of the outputs of the modulation signal generator 5, which pulses are used to indicate that a given cycle has ended. In the mode in which the polarity is changed for each other pulse, the control pulses are provided at the time that coincides with the rear edge of the stimulation pulses.

When the polarity is alternated in each other cycle, the control pulses are provided at the time coinciding with the trailing edge of the pulses ending a cycle in the middle of the interval between excitation periods. When a continuous stimulation signal is used, the polarity is shifted at the time when the termination of the cycle coincides with the termination of the relevant stimulation pulse.

For the purpose of changing polarity after the expiry of a certain time interval, e.g. after a time interval of 1-5 minutes, the control signal unit 37 produces the electronic timing circuitry pulses after a given time interval. The polarity of the output signal shifts when there is coincidence between the end of the given time interval and the end of one or the other pulse cycle, ie. of signal A or signal B (Fig. 4J.

FIG. 3 shows another embodiment of the output unit 9, wherein the amplifier for the signal of positive polarity comprises the transistors 44, 45 and 48.

The signal from phase inverter load 31 is transmitted through resistors 56, 52 when transistor 54 in the switching circuit is blocked. In that case, there is logically "0" over the Q output of the RST flip-flop 33 (Fig. 2). When transistor 54 (Fig. 31 is saturated), there is no signal for the input of the preamplifier.

The output stage of the negative polarity signal is constructed in the same way, but the transistors 46, 47 and 49 have opposite conductivity, and the switching circuit comprises transistor 55.

The advantages of the output unit 9 are that there is no need for balancing with respect to the zero potential since no direct current component is above the output when the signal level is equal to zero, which is important in an apparatus that affects living organisms. Another advantage is that the amplifier uses no power when the signal is not present.

The stimulation pulses from the load 21 (Fig. 2) to the output unit 9 are delivered to the distribution line 10 if the line 11 ... .... 11N is connected to the patients to be stimulated. A proper connection between the patient and the distribution line 10 must meet the following requirements: When the signal amplitude is adjusted at each of the points 12 ^ .... 12N subjected to eelectric stimulation, the signal shape and especially the width of the leading edge of the pulse must not vary. Within the entire range of adjustment at N points for electrical stimulation, the amplitude of the stimulation pulse along the distribution line 10 must not vary. The potentiometers 38 must not cause a marked increase in the power consumed. These requirements are met with the embodiment described with reference to FIG. 2nd

The circuit 13 (Fig. 11 for adjusting the stimulus-pulse amplitude comprises the potentiometer 38 (Fig. 2), whose nominal power is several times (e.g., fera times) the load (patient's) power, in which case the extra power consumption does not exceed 20. The adapter unit 14 comprises transistors 39 and 40 with mutually opposite conductivity, diodes 41 and 42 and emitter load 43. The circuit consists of two stages which act as emitter sensors with common load. In the case of a positive polarity output signal, diode 41 is conductive. and the step including the transistor 39 is active. The diode 42 is non-conductive and the collectors of transistor 40 are disconnected from the distribution line 10, while the polarity of the signal over the potentiometer 38 is such that the base-emitter stretch of the transistor 10 is blocked. In other words, the circuit with the transistor 40 has no influence on the active stage.

After changing the polarity of the output signal, the diode 42 is made conductive and the signal is applied to the load (patient) through the step comprising the transistor 40. This small output impedance of this step causes a small time constant to charge the load capacitor. As a result, a change in the width of the leading edge will be within the permissible limits across the range of signal level adjustment.

The correct choice of the signal structure and of the rule for changing the signal polarity allows for an appropriate stimulation effect for groups of humans or animals under different physiological conditions.

A flexible signal structure and the given range of the adjustment parameter allow for electrical stimulation of varying nature, e.g. a strong excitation of the mammary receptor region, a normalizing effect or a healing effect in the case of a pathological process.

There are contraindications of a general nature in the case of the application of a pulsating electric current

Claims (4)

1. Single-channel electrical stimulation apparatus - electrostimulator with a pacing pulse sequence generator and with a modulation signal generator and an amplitude modulator with which the pacing pulse sequence can be amplified, and with a unit for automatically changing the polarity of the pacing pulses in accordance with a given rule , and with an output unit and a connected peripheral coupling with branches to various processing sites terminated by surface electrodes, characterized in that the electrostimulator comprises a frequency modulator (2) wherein the stimulation pulse sequence is frequency-modulated, there is a unit (8) for tuning of the polarity change rule that the branches (11 ^ -11n) are connected together by a main line (10), that at each treatment site (12 ^ -12) there is a potentiometer (38) for individual and the other treatment sites independent adjustment of the stimulation pulse amplitude, that by knowing A processing circuit (14) comprising two transistors (39, 40) of each conduit type and with the bases connected to the outlet of the potentiometer (38) and with the collectors connected to the branch wires (11Γ11η) there is provided. the respective processing site (12 ^ - 12n) over respective diodes (41, 42), interconnected in respective through directions corresponding to the respective pacing pulse polarity, while the emitters are connected to a common emitter resistor (43), thereby providing the pacing pulse itself with power supply, and the adaptation circuit (14 ) is coupled to the surface electrode (15). Use of the apparatus according to claim 1 for stimulation of mammary glands in cows during milking. Use of the apparatus according to claim 1 for prophylaxis and treatment of mastitis. Use of the apparatus of claim 1 for normalization of mammary gland tone in non-pregnant women and for stimulation of mammary gland in lactating women.