EP1214004A1 - Balloon for preparing for and easing human birth - Google Patents

Abstract

The invention relates to a balloon for preparing for and easing human birth. During use, said balloon is located at least partially inside the vagina of the pregnant woman. In its inflated state, the balloon has an application area (P) between its outer end (A), which has a fitting for a flexible tube (1); and its crown section with the largest diameter (D). The balloon is conically shaped in this application area (P). The application area is located approximately within the middle third of the length of the balloon between the outer section (b) and an inner section (a) of the balloon, the cone angle beta being 25 DEG or less in the application area.

Description

 Balloon to prepare and facilitate human birth

The invention relates to a balloon for preparing and facilitating human birth, which, when used, is at least partially inside the vagina of the pregnant woman and which is substantially conical in an application area between its outer end, which has a tube attachment, and its apex section with the largest diameter is shaped.

Such a balloon, which in the inflated state has an elongated shape, which has a waist-like constriction in a central section, is described in German Offenlegungsschrift 19715724. When used, the waist is in the area of the birth canal exit. By activating the pelvic floor muscles, the pregnant woman can train her to squeeze the balloon out of her vagina and thus simulate the birth process. The section of the balloon part located inside the vagina, which tapers conically towards the waist, causes the birth canal opening to expand, similar to the expulsion of the child's head.

It has been shown that the conical section mentioned is particularly advantageous in terms of the gymnastic effect of the balloon. The present invention is therefore based on the object of increasing this effect by a suitable design of the balloon. In this sense, it is provided according to the invention that the application area of the balloon adjoins its apex area within its conical section, where it extends approximately within the middle third of the balloon length between an outer section and an inner section of the balloon and that the cone angle in the application - range is 25 ° or less.

It is useful if, in the inflated state, the cone angle between 5 and 15 ° and the diameter of the balloon in the apex area is about 9 cm and if its length measured from the inner end to the outer end of the application area is 10 to 15 cm.

In the case of a balloon designed in this way, a cone surface that is significantly elongated compared to the known balloon is provided, which extends at least over its entire application area, which makes up approximately the middle third of the total length of the balloon. The outer portion of the balloon adjoining it to the outside forms approximately its outer third, which is also expediently conical, in such a way that it continues the cone of the application portion in the direction of decreasing diameter. When the gymnastic exercises are taken up, this cone-shaped outer section comes into effect by gently transferring to a constantly increasing stretching action during the squeezing exercises and thus ensuring a practically painless increase in the progress of the exercise.

In order not to endanger the cervix, it is expedient that the part of the Balloons when inflated have a length of less than 15 cm. Its largest diameter in the apex area between the application section and the inner section is 9 to 10 cm in the maximum inflated state, corresponding to the size of the child's head at birth.

The various methods for realizing the cone shape of the balloon result from the designs of the empty balloon envelope or the balloon balloon just inflated claimed in the subclaims, the internal pressure of the balloon corresponding approximately to the ambient pressure or being slightly greater.

Basically, it is possible to achieve the shape of the balloon in the inflated state either by a corresponding wall thickness profile with an essentially cylindrical balloon shape or by a corresponding conical envelope shape. In the first case it is essential that the envelope wall thickness decreases in the direction of the increasing balloon diameter; in the second case the cone angle of the envelope should be approximately equal to that of the inflated balloon.

Finally, the shape of the inflated balloon can also be achieved by stretching it accordingly. The associated overstretching effect or the stretching of the shell material achieved by the stretching beyond the reversible elastic limit causes a preferred stretching within the stretched sections during later inflation, so that any cross-sectional configurations that expand in the manner of a cone shape can be achieved. As for the cone angle of the inflated balloon, it should preferably be below 25 °. In practice, an angle of around 10 ° has proven to be a value that is perceived by the practitioners as pleasant, while at the same time preventing overstretching of the muscle tissue.

Preferred materials for the balloon are thermoplastic elastomers or silicone rubber, which have a favorable combination of mechanical properties, durability of the material and biocompatibility. Polyvinyl chloride is also suitable.

The invention is explained below using various exemplary embodiments. It shows

1 shows a longitudinal section through an inflated balloon,

2 shows a longitudinal section through a balloon envelope with different wall thicknesses,

3 shows a longitudinal section through a conically pre-shaped balloon envelope,

4 and 5 envelope and balloon with stretched middle section,

6 and 7 waisted balloon envelope and balloon.

Fig. 1 shows a longitudinal section through an inflated balloon B. In this state, its internal pressure Pi is greater than its external pressure p _a . In its maximally stretched final shape, the largest diameter D of the balloon B is 9 to 10 cm, corresponding to the size of the child's head. Its length from its inner end I to its outer end A is in fully inflated about 20 to 24 cm. The total length of the balloon B is divided into three sections, each about a third of its length, namely an inner section i between its apex region with the largest diameter D and the inner end I; a central section m between its inner section i and an outer section a, the central section m being substantially conical in shape and corresponding to the application area P of the balloon B; the outer section a extends from the middle section m to the outer end A of the balloon B; 1 is also conical, namely as a continuation of the conical shape of the central section m. At its outer end A, the balloon B has a tubular connector 1 which is stiffened by a tubular insert 2. The tubular insert 2 has approximately in the middle a collar 3, on the opposite sides on the one hand the connector 1 of the balloon B, on the other hand the end of a hose 4 is connected, which the balloon B with a filling device, not shown, for. B. connects a hand pump.

When used in the context of obstetric gymnastics, the pregnant woman inserts the flaccid balloon B into the vagina, after which she inflates it progressively as the training progresses and presses it with the outer part A of the vagina against the vaginal exit by exertion of the pelvic floor muscles and vaginal muscles. The cone shape of the balloon B in the area of its application section P increases the spreading of the birth canal exit. A suitable cone angle for the balloon shape is less than 25 °, preferably between 5 and 15 °, ideally about 10 °.

Fig. 2 shows a longitudinal section through a just inflated, but not expanded balloon envelope Hl, the internal pressure p _x corresponds approximately to the external pressure p _a . The cylindrical peripheral wall of the balloon envelope Hl is shaped so that its wall thickness decreases from the outer end A to the inner end I. If the balloon envelope H1 is inflated, the result is a balloon that runs conically over its entire length, with diameters increasing from the outer end A to the inner end I. The apex region of the balloon with the largest diameter D moves in the direction of the inner end I compared to the embodiment according to FIG. 1.

Fig. 3 shows a cross section through an elongated, substantially conically shaped balloon envelope H2, the cone angle being about 5 to 10 °. 3 shows the balloon envelope H2 at p ₁ = p _a , that is to say in the state of pressure equalization between the interior of the balloon envelope and its surroundings. The balloon envelope H2 has a constant wall thickness over the entire cross-section. Because of its conical initial shape, when inflated it results in a balloon shape which corresponds approximately to FIG. 1.

The balloon envelopes H1 and H2 according to FIGS. 2 and 3 thus enable the realization of very similar balloon shapes, measured by their inflated state "p _^^ > p _a ", despite different conditions. 5 shows, in the partially inflated state of a balloon envelope H3, the stretching of this envelope in the area of its central section, ie a conical application area P is created between the apex area with the largest diameter D and the upper end 5 of a retaining ring 6. The initial shape of the envelope H3 is shown in Fig. 4 at p _L = p _a . Similar to the embodiment according to FIG. 2, it is cylindrical over the entire length, but unlike FIG. 2, it has a constant wall thickness corresponding to the conical envelope H2, which is shown in FIG. 3. By stretching the envelope H3 in the application area P, so that the desired conical shape is created when the balloon is inflated, the production of an envelope with different wall thickness is unnecessary, which simplifies the manufacture. In addition, stretching makes it possible to set the cone angle β in the application area P to a value which can be selected between wide limits. After stretching the envelope material according to FIG. 5, when inflating the envelope H3 without the retaining shape shown in FIG. 5, a final balloon shape is obtained, which essentially corresponds to FIG. 1. As in the variants according to FIGS. 2 and 3, it is therefore possible to dispense with their graphic representation.

An embodiment of the balloon with a slight deviation from the balloon shape according to FIG. 1 is shown in FIG. 7. There is a slight constriction 7 in the application area P, which corresponds to the central section m. This is caused by the waist 8 present in the middle section of the associated sheath H4 shown in FIG. 6 The approximately conical shape of the inflated balloon shown in FIG. 7 in the area of its middle section m and its outer section a results from a greater wall thickness of the envelope H4 in the area of its outer and middle section compared to its inner, approximately cylindrical shape with constant wall thickness Section.

In the embodiment of the balloon according to FIG. 7, its constriction 7 causes an increased resistance in the direction of expulsion R due to the weak constriction 7 in the transition area from the conical shape to the inner section i, that is to the apex region of the balloon characterized by the largest diameter D. This balloon shape enables the realization of a certain pressure point when the balloon is expelled from the birth canal through the pelvic floor muscles and vaginal muscles of the woman, similar to the increased resistance when the child's head passes through the birth canal exit.

In addition, in the embodiment according to FIGS. 6 and 7, the positioning of the sheath H4 is particularly simple insofar as it is initially sufficient to insert the sheath H4 into the vagina up to the waist 8. As the balloon is inflated, the waist 8 then moves further inwards, so that the application area P of the balloon shown in FIG. 7 is located directly inside the vaginal exit, while the outer section a of the balloon is outside the vagina.

Claims

 Expectations

Balloon for preparing and facilitating human birth, which is at least partially inside the vagina of the pregnant woman during use and which is located in an application area (P) between its outer end (A), which has a tube attachment (1), and its apex section with the largest diameter (D) is essentially conical, characterized in that the application area (P) of the balloon adjoins the apex area within a conical section, where it is approximately within the middle third of the balloon length between an outer section (a ) and an inner portion (i) of the balloon and that the cone angle (β) in the application area is 25 ° or less.

Balloon according to claim 1, characterized in that the cone angle (β) when the balloon is inflated is between 5 and 15 °.

Balloon according to claim 1, characterized in that in the inflated state its diameter (D) in the apex area is approximately 9 cm and that its

Length measured from the inner end to the outer

End of the application area (P) is 10 to 15 cm.

4. Balloon according to claim 1, characterized in that its pressure-free envelope (Hl) has a wall thickness which decreases from the outside inwards at least in the application area.

5. Balloon according to claim 1, characterized in that its pressure-free envelope (H2), measured in the state of pressure equality of external and internal pressure has a conical shape corresponding to the application area (P).

6. Balloon according to claim 1, characterized in that its pressure-free envelope (H3) in

Application area (P) is stretched in such a way that the application area (P) in the inflated state of the balloon has a shape which widens as desired from its outer section (a) to its inner section (i).

7. Balloon according to claim 1, characterized in that its pressure-free envelope (H4) measured in the state of pressure equality of external and internal pressure in the application area (P) is narrowed like a waist and that the wall thickness in the adjoining the waist (8) outer section the casing (H4) is stronger than the application area (P). Balloon according to claim 4, characterized in that its unpressurized envelope (Hl) with the equality of

External and internal pressure has a cylindrical shape and that the wall thickness of the envelope (Hl) decreases from the outside inwards.

Balloon according to claim 1, characterized in that at its outer end (A) a tubular one

Connection piece (1) is formed, which is stiffened by a tubular insert (2).