RU2143282C1 - Blood transfusion device - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: device has series-connected needle for coupling to blood vessel, microfilter consisting of cylindrical body and cover with branch pipes for inlet and outlet of blood. Branch pipes accommodate filtering element dividing microfilter volume into spaces for unfiltered and filtered blood. Device also has dropper, as well as mainline tube and clamp. Needle is coupled to microfilter through main-line tube. Microfilter consists of hermetically joined body and cover between which flat filtering element is positioned. Space for unfiltered blood of microfilter is formed by flat filtering element above which distributor is positioned and by cover. The latter is made as cone resting with its base on distributor and provided with cylindrical bead along base edge for attachment to microfilter body. Filtered blood space is formed by flat filtering element and tapered bottom of microfilter body. Microfilter is rigidly connected to dropper body through drop former. EFFECT: enhanced efficiency of filtration. 4 cl, 4 dwg

Description

 The invention relates to medical equipment and can be used, in particular, in transfusiology for blood transfusion, suspension, blood substitutes and infusion solutions.

 Known blood microfilter (A. with. The USSR N 1409280), made in the form of a filter element located in a cylindrical body with the formation of cavities for unfiltered and filtered blood.

 However, the known microfilter does not provide effective filtration with simultaneous control of the transfusion rate and cannot be used for blood transfusion without connecting additional elements to it using main tubes, such as a needle for connecting to a blood vessel, a dropper and a clamp.

 A device for blood transfusion and delay microaggregates, manufactured by Be..co. (Italy), containing a needle for connection to polymer containers, a dropper, tube, clamp and microfilter having a filter element located in the housing with the formation of cavities for unfiltered and filtered blood. The filter element has a folded configuration.

 The disadvantages of the known device are as follows.

 The inconvenience of using the device when filling and displacing air from the microfilter and dropper due to their separate location, which in turn increases the time to prepare the device for operation.

 Large cavities between the filter element of the folded configuration and the wall of the body are stagnant zones for transfused blood, in which a significant amount of blood remains after transfusion.

 The complex folded configuration of the filter element does not allow to displace all the air and the remaining air volume significantly reduces the efficiency of the microfilter. In addition, this design of the filter element requires the manufacture of complex technological assembly equipment, which increases the cost of the product.

 The presence of a single-channel polymer needle, combined directly with the microfilter body, does not provide blood transfusion from glass bottles.

 The device contains serially connected needles for connection to a blood vessel, a microfilter consisting of a cylindrical body and a cap with nozzles for blood input and output, inside of which there is a filter element that separates the microfilter volume into cavities for unfiltered and filtered blood, a dropper, and also a main tube and clamp.

 The device allows to increase the efficiency of blood filtration, increase the flow rate by reducing the flow resistance and more uniform distribution of blood throughout the filter element, as well as increase the usability of the device and simplify its design.

 The technical result is achieved due to the fact that the needle is connected to the microfilter through a main tube. The microfilter consists of a hermetically connected housing and a cover, between which a flat filter element is installed.

 The cavity for unfiltered blood of the microfilter is formed by a flat filter element, over which a distributor is installed, and a lid. The cover is made in the form of a cone resting on the distributor with its base and is equipped with a cylindrical collar along the edge of the base for fastening to the microfilter body. The cavity for the filtered blood is formed by a flat filter element and a conical bottom of the microfilter body. The microfilter is rigidly connected to the dropper body by means of a droplet former.

 The distributor installed inside the microfilter housing above the filter element is a grating, the ribs of which in cross section have the shape of a triangle, the apex of which is turned towards the filter element, and a supporting cylindrical protrusion 1.0 to 1.5 mm high is made along its edge and directed to side of the microfilter cover.

 The droplet generator connecting the microfilter with a dropper is made in the form of two coaxial cylinders placed on an annular conical base, the outer surface of which is provided with conical protrusions from the side of the filter element.

 The conical bottom of the microfilter housing and the annular conical base of the dropping agent installed in it make up one common conical surface, the conical tops of the protrusions of both parts placed on this surface form a horizontal support plane for the filter element.

 The invention is illustrated by drawings, where in FIG. 1 shows a device for blood transfusion, a General view, in FIG. 2 is a section A-A of a microfilter with a dropper, in FIG. 3 is a plan view of a dispenser; FIG. 4 - section BB of the distributor.

 The device for blood transfusion contains a needle 1 for connecting to containers, a microfilter 2, combined with a dropper 3, tubes 4 and 5, and a clamp 6.

 The microfilter has a cylindrical housing 7 with nozzles 8 for input and 9 for output of blood. The filter element 10, located in the housing 7, divides the internal volume into a cavity 11 for unfiltered blood and a cavity 12 for filtered blood. A distributor 13 is installed above the filter element 10. The filter element 10 is made in the form of 3 disks of needle-punched non-woven fabric, with varying degrees of delay of micro- and macrobloods.

 The cover 14 of the microfilter is made in the form of a cone, supported by a distributor 13, and provided with a cylindrical bead 15 along the edge for connection with the housing.

 The dropper 3 is connected to the housing 7 of the microfilter by means of a droplet former 16, the design of which is two coaxially located on the annular conical base of the cylinder. The base of the droplet former has the same taper as the bottom of the microfilter body and forms one common conical surface with it. On this conical surface, on both parts, conical protrusions are made, the vertices of which form a horizontal support plane for the filter element.

 The distributor 13 is a grating, the ribs 17 of which in cross section have the shape of a triangle, and on the periphery of it a support cylindrical protrusion is made with a height of 1.0 - 1.5 mm, directed towards the microfilter cover.

 The device operates as follows.

The needle 1 is connected to a container with blood or suspension mounted on a tripod at a height of about 1 meter. Then the microfilter 2 with a dropper 3 is turned 180 ^o and, holding in this position, filled with blood, displacing the air in them. When 1/3 of the dropper is filled with blood, the microfilter and dropper are returned to their original position and the air continues to be displaced from the tube connected to the dropper.

 After the air is displaced from the system, the necessary transfusion rate is established by the number of drops falling into the dropper using a clamp.

 The main advantage of the proposed device is to increase the safety of blood transfusion by holding a microfilter of macro- and microclots of blood larger than 30 microns, with a degree of delay of up to 96%. The combination of a dropper with a microfilter eliminates the additional resistance of the tube. The installation of the distributor in the microfilter prevents clogging of the hole of the blood supply nozzle, which is possible when the filter element swells, provides a more uniform distribution of blood over its entire area, the conical protrusions on the bottom of the case and the base of the droplet formation prevent the outlet opening from overlapping due to the swelling of the filter material, and the conical the shape of these protrusions, as well as the triangular shape of the cross section of the ribs of the distributor, allows to minimize hydraulic resistance e in these areas.

Claims (4)

 1. A device for blood transfusion, containing a needle for connecting to a container with blood, a microfilter consisting of a cylindrical body and a cap with nozzles for blood input and output and a filter element that separates the internal volume of the microfilter into cavities for unfiltered and filtered blood, a dropper, main tube and clamp, characterized in that the needle is connected by a main tube to the microfilter, the cavity for unfiltered blood of the microfilter is formed by a flat filter element, over which a dispenser, and a lid made in the form of a cone resting on the distributor base and provided with a cylindrical collar along the edge of the base for fastening to the microfilter body, and the filtered blood cavity is formed by a flat filter element and a conical bottom of the microfilter body connected to the dropper body by means of a droplet .  2. The device according to claim 1, characterized in that the distributor is made in the form of a lattice, the ribs of which in cross section have the shape of a triangle, the apex of which is turned towards the filter element, and along the edge of the distributor there is a supporting cylindrical protrusion with a height of 1 - 1.5 mm, directed towards the microfilter cover.  3. The device according to claim 1, characterized in that the droplet is made in the form of two coaxial cylinders placed on an annular conical base, the outer surface of which is provided with conical protrusions from the side of the filter element.  4. The device according to claim 1, characterized in that the conical bottom of the microfilter housing and the annular conical base of the droplet mounted in it comprise a common conical surface, and the conical protrusions placed on this surface form a horizontal support plane for the filter element.

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