RU2169022C1 - Device for ultraviolet blood irradiation - Google Patents

Abstract

FIELD: medical engineering. SUBSTANCE: device has casing with ultraviolet lamp mounted inside, power supply unit, mechanism for fastening physiological system having quartz capillary tube. The capillary tube is placed under the ultraviolet lamp in parallel to it and is joined by means of tubes to puncture needle and receiving reservoir. The device has microswitch member for making engagement with cover, governing photoelectric cells for controlling medium density in the physiological system and controlling electronic clock unit, microscreen filter set between the quartz capillary tube and puncture needle, additional reservoir for keeping blood stabilizer solution, dropping tube with member for controlling tube lumen cross- section. The receiving reservoir is flexible sack graduated in volume levels enclosed into hard transparent container with nipple. The ultraviolet lamp is mounted on inside of quartz tube so that closed sealed space is created as ring-shaped gap filled with air. EFFECT: high level of safety; reliable control of unit operation. 5 cl

Description

 The invention relates to medical equipment, namely, devices for ultraviolet irradiation (UV) of blood.

 A device for ultraviolet irradiation of blood is known, comprising a housing with an ultraviolet lamp installed in it, a power supply unit and a physiological system mounting mechanism, including a quartz capillary located parallel to it under the ultraviolet lamp and connected by tubes with a puncture needle and receiving container and a pump with check valves for pumping air (RU 2076755, A 61 N 5/06, publ. 04/10/1997).

 The disadvantage of this device, taken as a prototype, is that it has direct contact of blood with atmospheric air, which does not exclude the possibility of its microbial contamination. In addition, the implementation of the return of blood to the vein due to direct air pressure on the blood does not exclude the possibility of air embolism in case of delay with compression of the return line of the physiological system.

 Another disadvantage of the known device is that it does not ensure uniform mixing of blood with a preservative, and therefore the formation of microbunches and aggregates of blood cells and their embolism are not excluded.

 In addition, the determination of the rate of return of blood to reduce its level in the receiving container of large diameter is inaccurate, and the adjustment of this speed due to changes in pressure in the capacity of the pump for air transfer is inconvenient, while the ultraviolet ultraviolet is uneven and it is difficult to maintain the estimated exposure time.

 Another disadvantage of the known device is the possibility of ultraviolet radiation service personnel in case of accidental opening of the housing cover. In addition, the surrounding ozone is influenced by the formation of ozone, which is toxic when it is concentrated in excess.

 And finally, there are certain difficulties for the visual control of the operation of an ultraviolet (UV) lamp: you have to look at places where light from its work breaks through (violet range).

 The task to which the present invention is directed is to ensure the safety of blood ultraviolet radiation for both patients and maintenance personnel, to optimize blood ultraviolet regimes and to increase the reliability of monitoring the operation of the device.

 This is achieved by the fact that the device for ultraviolet irradiation of blood, comprising a housing with an ultraviolet lamp installed therein, a power supply and a mechanism for attaching a physiological system including a quartz capillary located parallel to it under the ultraviolet lamp and connected by tubes with a puncture needle and receptacle, and a pump with non-return valves for pumping air, equipped with a switch for interacting with a cover mounted on the housing, photocells for controlling the optical density water in the physiological system and control an electronic clock, a filter installed between a quartz capillary and a puncture needle, an additional solution container with a blood stabilizer and a dropper with a regulator of the tube cross-section, the receiving container made in the form of an elastic plastic bag with volume graduation and enclosed in a solid a transparent container with a fitting for attaching a pump for pumping air and creating positive or negative pressure in it, and an ultraviolet lamp Position the inside of the quartz tube to form a hermetically closed space in the form of an annular gap filled with air.

 In addition, two photocells can be located in the end walls of the housing at the points of entry and exit of the tubes of the physiological system.

 In addition, the physiological system and the container can be made in the form of a module to ensure the possibility of change in a single application.

 In addition, a window can be made in the device closed by a glass opaque to ultraviolet rays in a hinged lid of the housing that covers the UV lamp, or in the end wall of the housing opposite the puncture needle in the compartment with the UV lamp.

 In addition, the pump for pumping liquid can be performed manually or with an electric drive.

 These signs are significant and interconnected causal relationship with the formation of a set of essential features sufficient to achieve the specified technical result.

 The drawing shows a device for ultraviolet blood.

 The device comprises a housing 1, in which a UV lamp 2 is placed in a quartz tube 3 with the formation of an air annular gap 4 and a power supply unit (not shown) is placed behind the dividing partition 5. Photocells 8 and 9 are located on the end walls 6 and 7 of housing 1, and a microswitch 10 is installed on the dividing partition 5 to interact with a cover (not shown) pivotally connected to the housing 1. A quartz capillary 11 is located parallel to the UV lamp 2 and is mounted to the dividing wall 5 by means of elastic grippers 12 and 13 with the possibility of removal. A micro-mesh filter 26, a dropper 27, a puncture needle 28, a needle 29 for attaching an additional container 30, a receiving container 31, placed in a transparent transparent container 32 with a fitting 33 for connecting to a quartz capillary 11 through pipelines 14 - 22 and tees 23, 24 and 25 are connected connecting the hand pump 34 with check valves 35 and inlet 36 and outlet 37 fittings for connecting to the fitting 33 of the container 32 through the pipe 38. On the pipe 18 connecting the dropper 27 and the quartz capillary 11, the passage cross-section regulator is placed the tube 39 in the form of a screw or roller clamp.

 Pipelines 14 and 18 in the end walls 6 and 7 of the housing 1 are located in the grooves made at the same time with the grooves of the photocells, respectively 8 and 9 and in the working position are held by a cover (not shown).

 A window is closed in the lid of the housing 1, closed by a glass opaque to UV rays. This window can also be made in the end wall 7 of the housing 1. Instead of a manual pump 34 for pumping air, an electric pump can be used.

The physiological system and the container 32 with solid walls can be made in the form of a single-use module. The container 32 is located next to the housing 1 of the device on the table, and an additional container 31 is suspended on a nearby rack for transfusion of medicinal solutions,
A device for ultraviolet blood is as follows.

 An additional container 30 containing physiological saline with a blood preservative (heparin or sodium citrate) is connected to the finished system for single-use UFO blood through a needle 29 to prevent blood coagulation during the procedure, the pipeline 20 is closed with a clamp and the additional container 30 is suspended on a rack for drug transfusion solutions. A pipe 38 is connected to the fitting 33 of the container 32, and the outlet fitting 37 of the hand pump 34 is connected to its free end.

 The operation of the hand pump 34 in the container 32 creates excessive pressure, due to which the residual air is expelled from the receiving tank 31 through pipelines 22, 17 and 16 and the puncture needle 28 to the outside. The pipelines 21 and 17 are closed with clamps. The clamp is removed from the pipeline 20 and the stabilizer solution is sequentially filled in the pipeline 20, the tee 24, the pipeline 19, the dropper 27 on 1/2 - 3/4 of its volume, the pipeline 18, the quartz capillary 11, the pipeline 14, micro-mesh filter 26 with complete air displacement, then pipe 15, tee 23, pipe 16 and puncture needle 28. The pipe 15 is closed by a clip and the pipe 18 is blocked by the regulator 39. The physiological system is installed in the housing 1, and pipelines 18 and 14 are inserted fall into the slots of the photocells 8 and 9, and the quartz capillary 11 into the elastic grips 12 and 13. The manual pump 34 is connected to the pipe 38 by the inlet fitting 36 and negative pressure is created in its container 32. The clamp is removed from the pipe 21 and through the tee 25, the pipe 22 the solution enters the receiving tank 31. After the receipt of 15-20 ml of the solution, the pipe 21 is closed by the clip, the hand pump 34 is connected to the pipe 38 by the outlet fitting 37 and the pump 34 creates excess in the container 32 pressure. The clamp is removed from the pipe 17 and the air from the receiving tank 31 is forced out by the preservative solution sequentially through the pipe 22, the tee 25, the pipe 17, the tee 23, the pipe 16 and the puncture needle 28 to the outside. After filling this part of the physiological system with a preservative solution, the pipeline 16 is closed by a clamp, and the manual pump 34 is switched to the mode of pumping air from the container 32 by connecting its inlet fitting 36 to the pipeline 38, and the negative pressure is created in the receiving tank 31 by the operation of the manual pump 34.

 A venous tourniquet is applied to the patient’s shoulder. A saphenous vein is punctured with a puncture needle 28, the clamp is removed from the pipe 16 and blood from the vein begins to flow into the receiving container 31 through the pipe 16, the tee 23, the pipe 17 the tee 25 and the pipe 22. The clip is removed from the pipe 15 and the passage speed controller 39 sets the required speed receipt of a stabilizer solution in the blood, controlled by the number of drops. The stabilizer solution from the additional tank 30 enters the blood, sequentially passing the path of filling this part of the physiological system through the tee 23, mixes with the blood and then into the receiving tank 31. After collecting the estimated amount of blood in the receiving tank 31, which is equal to the difference in volume in this tank, determined by the volume graduation level minus the volume of the used preservative solution, the tourniquet is removed from the patient’s shoulder, the pipeline 17 is compressed. The preservative solution then enters the patient’s vein, displacing unstable blood from pipeline 16. After filling the pipeline 16 with a preservative solution, it is blocked by a clamp, the clamp is removed from the pipeline 17 and the preservative solution enters the receiving tank 31, displacing the blood. After that, the pipes 17 and 20 are closed by clamps, the UV lamp 2 is turned on, the clip is removed from the pipe 21, the hand pump 34 is connected to the pipe 38 by the outlet fitting 37. The pump 34 creates excessive pressure in the solid container 32, the clip is removed from the pipe 16 and first the solution, and then the blood begins to flow into the patient’s vein, passing through conduit 22, tee 25, conduit 21, tee 24 conduit 19, dropper 27, conduit 18, quartz capillary 11, conduit 14, fine mesh filter 26, conduit 15, 23, pipe 16 and puncture needle 28. The rate of blood return is regulated by the operation of the pump 34 and the regulator 39 of the passage 39, and is controlled by the number of drops in the dropper 27 and by the level in the receiving tank 31. When the blood reaches photocell 8, the electronic clock is turned on (not shown) and a real-time counting of the UFO blood begins. After all the blood is displaced from the receiving tank 31, the blood flow through the dropper 27 stops, the pipeline 21 is closed by a clamp, the clip is removed from the pipeline 20 and the solution with preservative begins to flow into the physiological system, displacing the blood. Upon reaching an optically transparent mixture of blood with a preservative photocell 9, audible and visual signals are given for the end of the procedure, and the time of ultraviolet radiation is recorded. The above signals are also given if air somehow passes through the photocells 8 and 9.

 It is possible to use a solid container in the device both in the variant for its multiple use, and for single use, when it is made in the form of a module with a physiological system.

 When using a pump for pumping air powered by an electric drive, the operating procedure remains the same as described above.

 The use of a microswitch ensures that the UV lamp turns off when the device cover is accidentally opened and prevents UV radiation from others and, above all, exposure to unprotected eyes. This stops the countdown time of the procedure. When the lid is closed, the UV lamp lights up again and the countdown of the procedure continues.

 The use of two photocells to control the optical density of the medium in the physiological system, located at the inlet and outlet of the quartz capillary, allows you to record the true time of the ultraviolet radiation of the blood and give alarms when air appears in the system.

 The use of a fine-mesh filter in the physiological system located at the blood outlet from the quartz capillary in front of the puncture needle and working only at the stage of blood return eliminates the possibility of embolism with microbunches and aggregates of blood cells.

 The use of an additional container for a solution with a blood stabilizer provides an airless filling of the physiological system, a complete return of blood to the patient, and in combination with a dropper, the dosed introduction of a preservative during the procedure and its uniform mixing with blood, which prevents the formation of microbunches and aggregates of blood cells, speed control return of irradiated blood using a passage regulator.

 The implementation of the receiving container in the form of a plastic bag with a volume graduation and enclosed in a solid transparent container eliminates the contact of blood with atmospheric air, prevents the possibility of air entering the physiological system, and the use of a single-use system simplifies the procedure of blood ultraviolet.

 The location of the UV lamp inside the quartz tube with the formation of a closed annular gap filled with air contributes to the retention of hard ultraviolet blood due to its interaction with the resulting ozone. At the same time, much less ozone enters the atmosphere and its harmful effect on others is mitigated.

 The presence of a window closed by a glass opaque to UV rays makes it possible to visually control the operation of a UV lamp without affecting these rays on the organs of vision.

Claims (7)

 1. Device for ultraviolet irradiation of blood, comprising a housing with an ultraviolet lamp installed in it, a power supply unit and a physiological system mounting mechanism, including a quartz capillary located under the ultraviolet lamp parallel to it and connected by tubes with a puncture needle and receptacle, and a pump with check valves for pumping air, characterized in that it is equipped with a switch for interacting with a cover mounted on the housing, photocells for controlling optical density environment in the physiological system and control an electronic clock, a filter installed between a quartz capillary and a puncture needle, an additional container for a solution with a blood stabilizer, a dropper with a regulator of the tube cross-section, and the receiving container is made in the form of an elastic plastic bag with volume graduation and enclosed in a solid a transparent container with a fitting for connecting the pump to transfer air and create positive or negative pressure in it, and an ultraviolet lamp located inside the quartz tube with the formation of a closed sealed space in the form of an annular gap filled with air.  2. The device according to claim 1, characterized in that in the end walls of the housing at the points of entry and exit of the tubes of the physiological system are two photocells.  3. The device according to claim 1, characterized in that the physiological system and the container are made in the form of a module to ensure the possibility of change with a single use.  4. The device according to claim 1, characterized in that the window closed by a glass not transparent to ultraviolet rays is made in the hinged lid of the housing covering the ultraviolet lamp.  5. The device according to claim 1, characterized in that the window closed by a glass not transparent to ultraviolet rays is made in the end wall of the housing opposite from the puncture needle in the compartment with the ultraviolet lamp.  6. The device according to claim 1, characterized in that the pump for pumping air is made manually.  7. The device according to claim 1, characterized in that the pump for pumping air is made with an electric drive.