RU172322U1 - Urogenital probe - Google Patents

Abstract

The utility model relates to the field of gynecology, namely, devices for taking biological material for further research. The technical result of the utility model is to increase the productivity of collecting biomaterial, making it possible to simultaneously obtain biomaterial from the cervical canal and from the outside of the cervix. Use of the utility model is implemented as follows . Upon examination of the patient, the multilayer packaging is opened. The probe is removed from the polymer tube, starting from the handle 1. Holding the probe by the handle 1, the probe is inserted into the vagina and the working part 7 of the probe is sent to the cervical canal. After the introduction of the working part 7 of the probe into the cervical canal, the working part 7 is pressed against the surface of the cervix and make several circular movements. While the ends of the first bristles 10 are in contact mainly with the surface of the cervical canal, and the ends of the second bristles 9 are in contact with the surface of the outer part of the cervix. The ends of the first bristles 10 and the second bristles 9 scrape and hold the biomaterial (for example, dead cells or secretions) from the respective surfaces. Then the probe is removed. The holder 6 and the working part 7 fixed in it with the collected biomaterial are broken off from the handle 1. In this case, the weakened element 5 is destroyed. The holder 6 and the working part 7 fixed in it with the collected biomaterial are placed, for example, in a test tube that is closed and sent for further investigation.

Description

Technical field

The utility model relates to the field of gynecology, and in particular to devices for taking biological material for further research.

State of the art

In order to identify gynecological diseases, in particular, cytological and bacteriological studies of tissues or biological fluids are carried out. Moreover, to obtain the most complete picture of the patient’s health, biomaterials are taken from various parts of the genital organs. For example, biomaterials from the cervical canal and from the outside of the cervix are often required at the same time. Both of these elements are areas of the cervix that are quite close together. Biomaterials are obtained using special sampling devices.

The closest technical solution (prototype) is the cytobrush (gynecological probe) "DIATEST" for taking diagnostic samples (RF patent 157878, publ. 20.12.2015). The cytobrush contains a handle and a working part with bristles; the bristles have a non-smooth surface. Moreover, the working part is close in shape to a truncated cone. The biomaterial is prepared as follows. The cytobrush is introduced into the cervical canal, pressed against the wall of the cervical canal and make several circular movements. The preparation for the study is obtained by rolling the cytobrush on a glass slide.

A disadvantage of the known technical solution is low productivity, the inability to effectively collect biomaterial in one go from the cervical canal and from the outside of the cervix. This is due to the fact that the bristles at the base of the working part, which do not enter the cervical canal, due to their flexibility, do not fit tightly on the outer part of the cervix and deviate in the opposite direction, i.e. the bristles at the base of the working body cannot collect biomaterial from the outer part of the cervix.

The technical result of the utility model is to increase the productivity of collecting biomaterial, making it possible to simultaneously obtain biomaterial from the cervical canal and from the outside of the cervix.

The specified technical result is achieved due to the fact that in the urogenital probe containing the handle, holder, working part, the handle connected to the holder and the holder connected to the working part, while the working part includes a central element, first bristles and second bristles, intended for collecting biomaterial, the first bristles are fixed on the central element, oriented away from it and are located on the side of the central element opposite the handle, the second bristles are made longer than torn bristles, mounted on the central element, oriented near the central element away from it, located between the first bristles and the holder, the second bristles are bent to the side opposite to the holder, in addition, the first bristles are located within the first zone, the ends of the second bristles are located in within the second zone, between the second zone and the holder there is a third zone in which the remaining parts of the second bristles are located, the diameter of the second zone and the diameter of the third zone being larger than the diameter of the first zones; in the particular case, the length measured along the axis of the second zone is less than the length of the third zone and the first zone; in the particular case, the first zone is made in the shape of a cylinder; in the particular case, the first zone is made in the shape of a cone; in the particular case, the third zone is made in the shape of a ball segment; in a particular case, between the holder and the handle a weakened element is made; in the particular case, the handle, holder, working part are located coaxially; in a particular case, the central element is made of twisted together wires; in a particular case, the wires are made of metal.

Brief Description of the Drawings

The utility model is illustrated by the drawing, which shows the view of the urogenital probe (hereinafter sometimes, for simplicity, referred to as the probe) from the side, while the aspect ratio in the drawing is arbitrary.

Utility Model Disclosure

The drawing shows: handle 1, end part 2, central part 3, longitudinal protrusion 4, weakened element 5, holder 6, working part 7, central element 8, second bristles 9, first bristles 10, first zone 11, second zone 12, third zone 13.

Pen 1 is the element that holds the probe. The handle 1 is made as a unit or as a connection (in any way) of the following elements: the end part 2, the central part 3 and the longitudinal protrusions 4 on it, for example, so that the handle 1 as a whole has a longitudinal axis.

The end part 2 is an element of elongated shape, close, for example, to a cylinder (circular or elliptical) or cone. The length of this element significantly exceeds the dimensions of its cross section.

The central part 3 is an element of elongated shape, close, for example, to a cylinder (circular or elliptical) or cone. The length of this element significantly exceeds the dimensions of its cross section. Opposite ends of the Central part 3 and the end part 2 can be rounded.

The longitudinal projections 4 are located on the surface of the central part 3, while they are located along the generatrix of the surface on which they are placed (for example, cylindrical or conical, as indicated above), or along the axis. The number of longitudinal protrusions 4 can be arbitrary (in the drawing, the number is shown conventionally 3, the fourth is not visible).

The holder 6 is an element of elongated shape, close, for example, to a cylinder (circular or elliptical) or cone. The length of this element significantly exceeds the dimensions of its cross section. The ends of the holder 6 can be rounded. At one end, the holder 6 is connected to the central part 3 of the handle 1 coaxially with the weakened element 5. The weakened element 5 is an element of arbitrary shape, all linear dimensions of which differ slightly. For example, the weakened element 5 in shape may be close to a cylinder whose height and diameter are approximately equal. The dimensions of the weakened element 5 are smaller than the sizes of the holder and the central part, therefore, under transverse action, it is destroyed first. From the other end to the holder 6 is attached the working part 7.

The working part 7 is an element for performing the direct function of the probe (collecting biomaterial from the corresponding surface). The working part 7 consists of a central element 8, the first bristles 10 and the second bristles 9. In this case, the working part 7 can be divided into three zones: the first zone 11, the second zone 12, the third zone 13.

The central element 8 is an elongated shape element for securing the first bristles 10 and the second bristles 9. The central element 8 is mounted on the holder 6, usually aligned with it. The central element 8 can be fixed in the holder, for example, by pressing or pre-installing the working part 7 in the mold when casting the holder 6, the weakened element 5 and the handle 1.

The bristles are rigid elastic thread-like elements made of a polymer material. The first bristles 10 are located on the part of the central element 8, located farther from the holder 6 in comparison with the second bristles 9. The ends of the first bristles 10 are directed away from the central element 8. The first bristles 10 form their free ends first zone 11. In the first zone 11 ends the first bristles 10 may be within, in general, in the form of a rotation element. This rotation element is formed by rotating a straight line about an axis, while this straight line and the axis of rotation are in the same plane. In particular, such an element may be a cylinder or cone. The second bristles 9 are located on the part of the central element 8, which is closer to the holder 6. The length of the second bristles 9 mainly increases when approaching the holder 6. The second bristles 9 have bends directed in the direction opposite to the handle 1 and holder 6. The area in which the second bristles 9 have bends, is the third zone 13 (in particular, in this zone the ends of the second bristles 9 may not exist at all). The second zone 12 corresponds to the location of the ends of the second bristles 9. Moreover, in the second zone 12, in the particular case, the ends of the second bristles 9 are approximately located in the plane perpendicular to the axis of the handle 1 and close to it at the interface between the first bristles 10 and the second bristles 9 . Moreover, the length along the axis of the third zone 13 is greater than the length along the same axis of the second zone 12, and the diameter of the third zone 13 and the diameter of the second zone 12 are larger than the diameter of the first zone 11 (the diameter is meant in the plane perpendicular to the axis and along the outer contour) .

The working part 7 can be performed as a whole. In this case, the central element 8, the first bristles 10 and the second bristles 9 are made of the same material and constitute a single element.

The working part 7 may be integral. In this case, the first bristles 10 and the second bristles 9 are clamped by a central element 8 made, for example, of metal wire (one or two). The materials of the wire can be, for example, steel, aluminum, copper. The central element 8 in this case is a wire folded in half and twisted in a spiral. The first bristles 10 and second bristles 9 are sandwiched between the halves of the wire, while the ends of the bristles are also generally arranged in a spiral.

The material for the handle 1, the holder 6 and the weakened element 5 can be various plastics, for example polystyrene, polyvinyl chloride, high density polyethylene.

During storage, the probe is placed in a polymer tube and multilayer packaging to prevent damage and maintain sterility.

Utility Model Implementation

In the case of using the above elements, the utility model can be implemented as follows.

If the working part 7 is composite, for the manufacture of the central element 8, for example, one section of a metal wire of the required length is pre-cut. This piece of wire is bent in half, getting a U-shape. Between the two halves of the wire are pre-obtained pieces of polymer thread. The length of these segments should be greater than the length of the first bristles 10 and second bristles 9, so that it is possible after trimming them to trim to the required length. Pieces of polymer thread are positioned, starting from the bend and ending when the required length of the working part 1 is reached. Then, the piece of wire bent in half with the pieces of polymer thread located between its halves is twisted in a spiral. As a result, segments of the polymer thread are clamped by twisted wire. This twisted wire in the present embodiment is a central element 8. Twisting the halves of the wire also provides increased rigidity of the working part 7 of the device. Moreover, the length of the central element 8 should be greater than the length of the working part 1 by an amount sufficient to secure the central element 8 in the holder 6. There are no lengths of polymer thread on the excess length of the central element 8. Pieces of polymer thread are cut to the required length. When forming the first bristles 10 in the case of a cylindrical shape of the first zone 11, this length is constant (or has slight differences) or does not exceed a predetermined one, with the first bristles 10 starting from the bend of the wire. When forming the second bristles 9, their length increases, starting from the interface of the first bristles 10 and the second bristles 9. The execution of the Central element 8 of twisted metal wires provides a simple design of the working part 7 and simplifies its manufacture.

Then, for example, for the case of the execution of the handle 1, the holder 6 and the weakened element 5 as a whole, the working part 7 is fixed in the mold for casting the handle 1, the holder 6 and the weakened element 5 coaxially to these elements. The alignment of the elements provides ease of use of the probe by increasing the accuracy of positioning of the working part 7. In this case, the portion of the central element 8 without the first bristles 10 and second bristles 9 should be located inside the mold. Further, for example, using the injection molding method, molten plastic is used to fill the mold for casting the handle 1, holder 6 and the weakened element 5. The mold for casting corresponds to the shapes and relative positions of the elements, as described above. The molten plastic surrounds the region of the central element 8 without first bristles 10 and second bristles 9. After the plastic has solidified, the working part 7 is fixed in the holder 6 by the central element 8. After the plastic has solidified, the probe is removed from the casting mold. After removing the probe from the mold for casting it is placed in a polymer tube, starting with handle 1.

The formation of bends on the second bristles 9 is carried out before being placed in the polymer tube for storage, or it occurs when the probe is stored in a polymer tube, the diameter of which is less than the length of the second bristles 9. The second bristles 9 take on a bent shape, because are in this state (with a bend) when storing the device in a polymer tube.

The probe in the polymer tube is sterilized, for example, by a gas method. Then the probe in the polymer tube is placed in a sealed multilayer package.

Using the utility model is implemented as follows.

Upon examination of the patient, the multilayer packaging is opened. The probe is removed from the polymer tube, starting from the handle 1. Holding the probe by the handle 1, the probe is inserted into the vagina and the working part 7 of the probe is sent to the cervical canal. After the introduction of the working part 7 of the probe into the cervical canal, the working part 7 is pressed against the surface of the cervix and make several circular movements. While the ends of the first bristles 10 are in contact mainly with the surface of the cervical canal, and the ends of the second bristles 9 are in contact with the surface of the outer part of the cervix. The ratio of the diameters of the first zone 11 and the second zone 12 ensures the fit of the ends of the first bristles 10 and second bristles 9 to the corresponding surfaces due to the repetition of the working part 7 of the shape of the studied physiological object. Repetition of the shape of the investigated physical object is achieved due to the following. First, by performing the first zone 11 in the form of an elongated rotation element, such as a cylinder or cone. Secondly, due to the shorter length of the second zone 12 compared with the length of the first zone 11 and the length of the third zone 13, which ensures that the ends of the second bristles 9 are approximately in the same plane. The execution of the third zone 13 in the form of a segment of the ball, the presence of smooth bends in the third zone 13 (and, as a consequence, the possibility of moving the ends of the second bristles in the direction of the axis of the probe) provide a soft, but sufficient for taking biomaterial, effect of the ends of the second bristles 9 on the corresponding surface. The fit of the ends of the first bristles 10 and the second bristles 9 simultaneously to all the studied surfaces of the physiological object and ensuring optimal effort due to the shape of the third zone 13 create the conditions for quick and reliable production of biomaterial. The ends of the first bristles 10 and the second bristles 9 scrape and hold the biomaterial (for example, dead cells or secretions) from the respective surfaces. Then the probe is removed. The holder 6 and the working part 7 fixed in it with the collected biomaterial are broken off from the handle 1. In this case, the weakened element 5 is destroyed. The holder 6 and the working part 7 fixed in it with the collected biomaterial are placed, for example, in a test tube that is closed and sent for further investigation.

Thus, the presence on the working part of two types of bristles (first bristles 10 and second bristles 9), the configuration of their location and the possibility of quick separation of the part with biomaterial from the handle 1 makes it possible to quickly obtain biomaterial from the cervical canal and from the outer part of the cervix, their direction for research immediately after receiving it, with a minimum exposure in the open air and natural and artificial lighting, without additional preparation.

Claims (9)

1. A urogenital probe containing a handle, holder, working part, the handle connected to the holder and the holder connected to the working part, the working part comprising a central element, first bristles and second bristles for collecting biomaterial, the first bristles are fixed to the central element, oriented away from it and located on the side of the central element opposite to the handle, the second bristles are made longer than the first bristles, mounted on the central element, orient are mounted near the central element, located between the first bristles and the holder, the second bristles are bent to the side opposite to the holder, in addition, the first bristles are located within the first zone, the ends of the second bristles are located within the second zone, between the second zone and the holder is the third zone in which the remaining parts of the second bristles are located, and the diameter of the second zone and the diameter of the third zone is larger than the diameter of the first zone. 2. The device according to claim 1, characterized in that the length measured along the axis of the second zone is less than the length of the third zone and the first zone. 3. The device according to claim 1, characterized in that the first zone is made in the shape of a cylinder. 4. The device according to claim 1, characterized in that the first zone is made in the shape of a cone. 5. The device according to claim 1, characterized in that the third zone is made in the shape of a segment of the ball. 6. The device according to claim 1, characterized in that between the holder and the handle a weakened element is made. 7. The device according to claim 1, characterized in that the handle, holder, working part are located coaxially. 8. The device according to claim 1, characterized in that the central element is made of twisted wires together. 9. The device according to claim 8, characterized in that the wires are made of metal.

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