NO138716B - SLIM EXAMINATION DEVICE - Google Patents

Description

The present invention relates to a device for determining the phases of the menstrual cycle and more specifically,

for indicating the rheological properties of mucus, particularly from the cervix and/or oral cavity in order to be able to predict initiation and detect a present ovulation. The invention is thus related to fertility control. It has been established that mucus samples from the vaginal cavity and the oral cavity show clear, phase-dependent, rheological changes during the menstrual cycle. Although the change in the mucus from the cervix is more noticeable than the changes in the mucus from the oral cavity, both changes can be easily detected. In the phase immediately before ovulation, during a period of one to three days under estrogen dominance, the mucus is very abundant and watery. In the phase after ovulation, the secretion phase, the mucus is less abundant and more viscous. In healthy women with a normal menstrual cycle, ovulation will usually occur between the 12th and 14th day before the next menstrual period (and not after the previous period), which is satisfactorily documented in the medical literature. In particular, mucus from the cervix is most watery at the time of ovulation as it contains 97 to 98% water, while at other times it is relatively dehydrated and only contains 80 to 90% water. After drying, the solid residue can vary from 2% during ovulation to 20% at other times, which represents a tenfold increase. Prediction of ovulation on the basis of the previous menstrual period by counting the number of days elapsed between the end of the previous period and the assumed ovulation in the middle of the cycle (the rhythmic method) can give erroneous results because it is impossible to predict the beginning of the next menstrual period. It is possible to predict ovulation on the basis of hormonal changes in the blood or chemical changes in the mucus, but the known methods for such

analyzes are applicable only in special cases, as they entail lengthy and expensive processes. The present invention aims to provide a simple and inexpensive device which, on the basis of a mucus examination "on the spot", can provide the necessary information, so that it is possible during or immediately after the examination of a patient to predict or confirm ovulation.

According to the invention, a device is thus provided for testing the viscosity of mucus from body cavities between relatively movable test surfaces, comprising a shaft element on which a ring element is rotatably supported, which elements respectively have an external bearing surface and an internal bearing surface which make up said test surfaces and exhibit a mutual clearance of between 0.25 µm and 250 µm, characterized in that the bearing faces have a roughness which implies an average distance between the highest and lowest points of the surfaces of between 0.2 µm and 3.0 µm, that the axes of the shaft element and the ring element are substantially horizontally oriented, that the device includes indicator means for reading the position of the ring element in relation to the shaft element, as well as a tensioning means, e.g. in the form of a plumb bob or a spring, attached to the ring element for tangential loading of it in relation to the shaft element, the tensioning force exerted by the tensioning member being adjustable so that the tensioning member causes the ring element to rotate freely when the slime is watery, while the ring element does not rotate when the slime is very viscous, and that the ring element and the shaft element can be completely separated from each other for cleaning or replacement.

Embodiments of the invention will be described in more detail in the following with reference to the drawing, where: Fig. 1 shows a perspective view of a device according to the invention, where the parts are assembled for carrying out certain steps in the examination process. Fig. 2 shows the device according to fig. 1 where the parts have been dismantled for carrying out certain other steps in the examination process, Fig. 3 shows an auxiliary instrument for use in connection with the device according to the invention,

Fig. 4 shows another auxiliary instrument,

Fig. 5 shows a front view of another device according to the invention, Fig. 6 shows a side view of the device according to fig. 5, Fig. 7 shows an axial section of a component for use in connection with operation of the device according to fig. 6, Fig. 8 shows a front view of a further device according to the invention, Fig. 9 shows a perspective view of another device according to the invention where parts have been dismantled for carrying out certain steps, and Fig. 10 shows a perspective view of the device according to fig. 9 where the parts are assembled for carrying out the second step in the examination process.

The device according to fig. 1 generally comprises an inner bearing element 20, an outer bearing element 22, a clamping member 46, a support frame 24 and markings 26. The support frame 24, which comprises a horizontal base 28 and a vertical plate 30, is made of a suitable plastic material, e.g. . methyl methacrylate or polycarbonate. The central part of the plate 30 is provided with a horizontal groove 32 of rectangular cross-sectional shape whose central axis runs vertically on the main surfaces of the plate 30.

The inner bearing element 20 is designed as a short, cylindrical rod which is provided in the axial direction with a rearward-directed extension or wedge 34 and a forward-directed, cylindrical bearing surface 36. The wedge 34, which is precisely and demountably fitted into the groove 32, fixes the bearing element 20 central axis in a horizontal position when the bearing element 20 is mounted to the support frame 24. The outer bearing element 22 is arranged in the form of a disc with a front and a rear end surface 38 and 40 which are located parallel at a distance from each other along the central axis of the disc which is enclosed by a cylindrical outer surface 42 and an inner, cylindrical bearing surface 44. The outer bearing surface 36 and the inner bearing surface 44 are rotatably fitted into each other with minimal clearance when the bearing elements 20 and 22 are joined together.

According to the invention, each of the storage rafts 36 and 44 must necessarily have a structure with a surface quality which implies an average height between valleys and peaks of from 0.2 mm to 3.0 mm, and preferably 60 to 95 particles per square meter. cm 2. There is further a clearance or tolerance between the bearing surfaces of 0.0003 mm to 0.25 mm and preferably 0.025 mm to 0.125 mm. The outer bearing element 22 preferably has an axial thickness of 6.4 mm to 50.8 mm. Each of the bearing elements is preferably made of dimensionally stable, sterilizable material, e.g. a vitreous material such as glass, a metallic material such as stainless steel or a plastic material such as methyl methacrylate.

A bore 45 extends through the outer surface 42 of the outer bearing element 22 and into the bore of the element. An internally threaded sleeve 47, e.g. of plastic or metal is anchored by friction in the bore 45. The clamping member 46 is in the embodiment in fig. 1 in the form of an externally threaded gravity plug, e.g. of metal or the like, which is screwed into the sleeve 47. The plug 46 is provided with an outer screwdriver slot which enables a precise adjustment of the position of the plug in relation to the axis of the outer bearing element.

The marking 26 includes an outwardly directed arrow 50 on the outer bearing element 22 and an inwardly directed arrow 52 on the plate 30. When the inner and outer bearing elements are fitted with a slime test between the bearing surfaces of the elements, the gravity plug 46 will be in position to produce a turning movement of the outer bearing element in relation to the inner bearing element. The plate 30 is provided immediately at the arrow 52 with a green spot 54 and adjacent to the outer bearing element 22 with a red spot 56 which is situated at a 90° angle with the green spot 54. The arrangement is such that if the slime between the bearing surfaces is relatively water-containing, the gravity plug 46 will cause the outer element 22 to turn clockwise, so that the arrow, -50 points towards the red spot 56. If, on the other hand, the slime is relatively viscous, the gravity plug 46 will be unable to turn the outer bearing element 22, so that the arrow 52 will still point towards the green spot 54.

A method according to the invention is based on the use of sterile, inner and outer bearing elements 20 and 22, as described in the following. Initially, the inner bearing element 20 is mounted to the plate 30 by inserting the wedge 34 into the groove 32. Next, a mucus sample is provided from the cervix by inserting a disposable probe 60 through the vaginal cavity and into contact with the cervix, the outer end of which is provided with an elastomer spoon 62, in which it is collected a sample of mucus 63 from the cervix. This mucus sample from the cervix is then transferred to one of the bearing surfaces 36 and 44, and the inner and outer bearing elements are brought together by fitting the outer bearing element 22 onto the inner bearing element 20, the mucus from the cervix being thereby extruded between the bearing surfaces<*>. Next, the outer bearing member 22 is manually rotated a preselected number of revolutions, usually one to three full revolutions, until the arrows 50 and 52 are aligned with each other. Then the outer bearing element 22 is released. Finally, the resting position of the arrow 50 in relation to the green spot 54 and the red spot 56 will give an indication of whether or not ovulation has occurred.

In an alternative method, oral mucus, i.e. saliva, is extracted using an eye dropper 64 which consists of a tube 66 with a narrowed end 68 and an elastomer ball 70. The saliva sample is placed on one of the bearing surfaces 36 and 44 by manually squeezing the ball 70, whereby the saliva is pressed out through the opening 68. The procedure is otherwise identical to the previously described procedure in connection with mucus samples from the 1ivmorh alsen.

The device according to fig. 5, 6 and 7 comprise a base 71 with a bearing cup 72. The bearing cup 72 receives a rod 74 which extends forwards to receive a ring 76. The front end part of the rod 74 and the inner wall of the ring 76 form bearing surfaces of the same type as previously described , for recording mucus samples. A release element 78 projects downwards from the ring 76. A console shaft 80 which extends forwards from the base 71 serves to support a tongue 82 which is forced into contact with the release element 78. The pressing or tensioning effect is produced in this embodiment by a plumb bob 84 which is attached to a threaded screw 86 and whose position can be adjusted by turning the screw. In connection with the rod 74, an ironing rod 87 with an outer coating 88 of rubber is used. By manually guiding the rod 87 from one end to the other in contact with the outer side of the rod 7.4, the rod 74 will complete a preselected number of revolutions. That is when the rod 87 is manually pressed against the rod 74 and guided across it, the rod 74 will, due to the friction between the rod surface and the rod's rubber surface, cause the rod 74 to run through a predetermined number of revolutions.

When using the device, mucus is transferred to the front end of the rod 74 by means of a spoon or an eye dropper of the same type as described in connection with the device according to fig. 1, as the ring 76 is thereby removed. The ring 76 is then introduced on the end of the rod 74, and the rod 87 is manually stroked from one end to the other along the outside of the rod 74, whereby the rod is rotated. If, however, the slime is relatively viscous, the rotation of the rod 74 will cause movement of

the release element 78.

The device according to fig. 8 is in all respects analogous to the device according to fig. 5, 6 and 7, except that the trigger system 82, 84 and 86 is replaced by a calibrated tension meter 90 comprising a trigger tongue 92 which is tensioned by a plumb bob, a spring or the like, a memory pointer 96 and an indicator light 98.

The device according to fig. 9 and 10 comprise an elongated, cylindrical probe 100 whose front end part is provided with a cylindrical extension 102 of reduced diameter which is isolated from the rest of the probe by means of a shoulder part 104. The outer end of the extension 102 is rounded at 106. The probe 100 can be connected to a ring part 108 which comprises an internal bore 110 as well as front and rear planar, parallel end surfaces 112 and 114. The outer bearing surface of the extension 102 and the inner bearing surface of the bore 110 are fitted with minimal clearance in each other when the ring 108 and the probe 100 are brought together. An adjustable nut 118 is screwed onto a threaded shaft 116 which extends outward from the outer surface of the ring 108 whereby the shaft and nut produce an adjustable torque. The probe 100 and the ring 108 are made of the same materials as the corresponding parts according to fig. 1 and 2. The dimensions and particle sizes that characterize the extension bearing surface 102 and the bore bearing surface 110 are likewise the same as for the corresponding parts according to fig. 1 and 2.

When using the device according to fig. 9 and 10, the probe 100 is first introduced through the vaginal cavity, so that the extension 102 is brought into contact with the cervix, whereby a certain amount of mucus from the cervix is retained on the bearing surface of the extension 102. The probe 100 is then withdrawn from the vaginal cavity and brought together with the ring 10B, whereby the extension 102 is introduced into the bore 110, and the backward movement of the ring 108 is limited by the shoulder part 104. The mucus sample from the cervix is extruded at this point between the bearing surfaces of the bore 110 and the extension 102. The operator, who thereby holds the probe 100 horizontally in one hand, then brings the shaft 116 into a horizontal position with the other hand. When the shaft is then released, the ring 108 will, under the influence of the torque produced by the parts 116 and 118, rotate or not rotate in relation to the probe 100. The menstrual cycle phase will thereby be able to be indicated according to the invention.

It is pointed out that the device's movement is described as rotating, as opposed to reciprocating. However, the principles of the invention have the same validity in connection with reciprocating bearing elements, even if such devices are less preferred.

Claims (1)

Device for testing the viscosity of mucus from body cavities between relatively movable test surfaces, comprising a shaft element (20, 74, 100) on which a ring element (22, 76, 108) is rotatably supported, which elements respectively have an external bearing surface (36, 102 ) and an internal bearing surface (44, 110) which constitutes said test surfaces and exhibits a mutual clearance of between 0.25 µm and 250 µm, characterized in that the bearing surfaces (36, 102 and 44, 110) have a roughness which implies an average distance between the highest and lowest points of the surfaces of between 0.2 µm and 3.0 µm; that the axes of the axle element (20, 74, 100) and the ring element (22, 76, 108) is substantially horizontally aligned, that the device includes indicator means (26, 50, 52, 90) for reading the position of the ring element in relation to the shaft element, as well as a clamping means (46, 84), e.g. e.g. in the form of a plumb bob or a spring, attached to the ring element for tangential loading of it in relation to the shaft element, the tensioning force exerted by the tensioning member being adjustable, so that the tensioning member causes the ring element to rotate freely when the slime is watery, while the ring element does not rotate when the slime is very viscous, and that the ring element and the shaft element can be completely separated from each other for cleaning or replacement.