SU660718A1 - Robot for separating blood and flushing the heavier fraction - Google Patents

Description

The invention relates to the field of medical technology, namely, rotors designed to separate blood into plasma and formed elements and wash the heavy blood fraction (erythrocyte mass) from cryoagents after long-term storage. A rotor for separating blood and washing a heavy fraction is known, comprising a housing with a bottom, a cone-shaped insert disposed therein to form an annular working cavity between them and consisting of a bottom bottom cap and a stand located vertically along the axis of the rotor, fixedly fixed, concentric to the rack, tube for supplying blood, washing liquid and draining the washed heavy fraction, device for draining the light fraction mounted on the latter above the insert, the shutter rotor containing the stationary sleeve with atrubkom for discharging the light fraction. In a known rotor, the housing with the bottom and the insert are permanently fixed together 11 |. A disadvantage of the known rotor is the impossibility of its repeated use, which increases the cost of the washing blood DOSE and worsens the quality of the separated fractions. The purpose of the present invention is to improve the quality and yield of the separated blood fractions while maintaining their biological activity. The goal is achieved by the fact that the rotor bolt is provided with a rim-mounted disk placed on the rotor case on the damping seal and a ring rigidly connected with the sleeve with the cavity between them for supplying coolant and having openings for the latter to pass over the surface. the cover of the insert is fixed to the rack with nuts and a sleeve with a hole connecting the internal cavities of the insert and the rotor, the bottom of the insert and the body being tapered and removable . The drawing shows a General view of the rotor in the section. The rotor is collapsible and comprises a housing 1 with a bottom 2, to which a screw 3 is attached with a cone-shaped insert 4 consisting of a rack 5 and a cap 6, which are hermetically interconnected by means of nuts 7 and 8.

For sealing the inner cavity of the insert, two sealing rings 9 and 10 are provided. The rack 5 in its lower part has stiffening ribs 11 for maintaining the geometric shape of the cone-shaped insert 4 with increasing air pressure in it during autoclaving. The nut 8 has a hole 12 connecting the internal cavity of the insert 4 and the annular working cavity of the rotor formed by the housing 1 and the cap 6. Outside the housing 1 there is a movable part of the shutter - a disk 13 with a rim 14 along the inside perimeter on the damping seal 15. The rim 14 is designed to protect the annular working cavity from the ingress of lubricating fluid after stopping the rotor. To reduce the coefficient of friction, the disk 13 is made of low friction material.

The fixed part of the shutter, made in the form of a sleeve 16 with a nozzle 17, is fixed by a nut 18 on the tube 19 for supplying blood, washing liquid and draining the washed heavy fraction. A ring 20 is rigidly fixed at the bottom of the sleeve 16 so that an annular cavity 21 is formed between it and the sleeve 16 to supply coolant through the brush 22. The ring 20 has several capillary holes 23 for the passage of coolant to the sliding surfaces of the gate.

For removal of the light fraction of blood, sleeves 24 and 25 inserted into each other are mounted on tube 19 above insert 4 in such a way that a narrow slit-like space is formed between them, starting in the working cavity of the rotor and ending in the upper part of the sleeve 16 by a sleeve 17. 2 rotors made conical and removable.

The operation of the rotor is as follows.

A rotor assembled from clean parts with an incompletely tightened screw 3 and nut 18 is sterilized in an autoclave. After the rotor has cooled, screw 3 and nut 18 are tightened with a .0.0 stop. The rotor is placed on the plate of the drive unit (not shown in the drawing), and the tubes from the pump of saline solution and the drain coolant tank are connected to the clampers 22. Communication from the blood supply pump is connected to the supply pipe 19, and a tank for collecting plasma is connected to the pipe 17. Prior to rotating the rotor, follower 22 supplies sterile saline at a low pressure, after which the rotor drive unit is activated.

When the rotor rotates through the supply pipe 19, blood is pumped by the pump, which, entering the lower part of the annular working cavity of the rotor, is thrown by centrifugal force to its periphery and is divided into fractions: heavy (erythrocyte mass) and light

(plasma) located closer to the center of the rotor. When a layer of plasma reaches the outer sleeves 24 and 25, the plasma of the subsequent portions of blood entering the rotor will be forced into the slit space inside the sleeve 16 and discharged by the nozzle 17 into a special container. After the working cavity of the rotor is filled with an erythrocyte mass corresponding to a single dose of blood, the blood supply stops, the rotor stops, after which the physiological saline pump is turned off and the erythrocyte mass flows to the lower part of the rotor, from where it is withdrawn into a special container by the return pump of the blood supply through tube 19.

5 The washing of the blood cells from the cryoagents is carried out in a similar way, after feeding the thawed red blood cells through the tube 19 to the rotor is continuously pumped to wash the solutions of a certain composition. The washed blood cells are taken after

0 stop of the rotor by the reverse flow of the blood supply pump.

Due to the implementation of the movable part of the shutter in the form of a disk with a rim along the inner perimeter mounted on the damping box, it is compacted, and its fixed part is in the form of a sleeve disposed on the blood supply tube and containing an annular cavity for coolant, connected capillary holes for the passage of fluid to the rubbing surfaces

0 gate, the temperature of the parts in contact with the blood components is reduced, which, in turn, improves the quality and yield of the separated fractions while maintaining their biological activity. In addition, performing a rotor insert from two parts — a stand and a cap, sealed together with a nut with holes — allows for a decrease in air pressure when the rotor is heated, and it eliminates the possibility of deformation of the insert.

with heat sterilization.

Therefore, due to the design features of the proposed rotor, the possibility of its multiple use was created, which reduces the cost of washing and separating a single dose of blood compared to

 with the famous. The separation of the rotor design allows for thorough treatment of all surfaces in contact with the blood, which eliminates the possibility of infection of the separated components and ensures complete safety for the health of the patient.

Claims (1)

1. B1 1 is laid down for France and No. 2294757, l. B 04 B 15/00, 1976.