SU1292783A1 - Apparatus for hemosorption - Google Patents

Abstract

The invention relates to perfusion and transfusion, intended for extracorporeal purification of blood and ensures uniform distribution of blood flow in the sorbent when using fiber sorbent. The device comprises a body of parts 1 and 2 with fittings 3 and 4, layers of filtering of its material 5 and 6, a cover 7, a base 8 with internal cavities in the form of grooves, a sorbent 10 in the form of a rope, expansion projections 11, openings 13 and 14 The cross-section of the gutter is 20-30% more than the total length of the cross section of the bundle laid in it and 25-30% less than the total length of the tow, the cross-section of the extension. The blood passes through the nozzle 3, passes the layer 5, through the opening 13 enters the patient's body, passes through the sorbent and through the holes 14 enters the nozzle 4 after being cleaned from toxic substances. The areas of grooves and expansions were selected taking into account that the fibers of the sorbent swell upon contact with blood and increase in cross section, which contributes to the uniform distribution of blood in the volume of sorbent 5 sludge. P (L K5; D to 00 with

Description

The invention relates to medicine and medical technology, in particular to perfusion and transfusion, and can be used for extracorporeal blood purification.

The aim of the invention is to ensure uniform distribution of blood flow in the sorbent volume when using fiber sorbent.

FIG. 1 shows a device for hemosorption, general view, incision; in fig. 2 shows section A-A in FIG. 1 in the case of a single gutter; in fig. 3 - the same, in case of using two troughs; in fig. 4 shows a section BB in FIG. 2; in fig. 5 shows a section B-B in FIG. 2

The device for hemosorption comprises a housing consisting of two mating parts 1 and 2 with an inlet 3 and an outlet 4 with blood plugs, layers 5 and 6 of filtering material and intersecting between the layers mating lid 7 and base 8, which form an internal cavity or cavities in the form of gutters or gutters 9. Fiber sorbent 10 in the form of harnesses is laid in the gutter or gutters 9. The base 8 has protrusions 11 for fixing the sorbent 10 located at the ends of the grooves 9. The portions of the groove or grooves 9 adjacent to the protrusions 11 have extensions 12 placed opposite the apertures 13 for introducing blood in the lid 7 and the apertures 14 for expelling blood in the base 8 Holes 13 and 14 are located at opposite ends of the gutter or gutters 9. The cross-sectional area of the gutter 9 is 20-30% higher than the cross-sectional area of the sorbent harnesses 10 laid in the gutter 9, and the cross-sectional area of the gaps 12 is 25- 30% exceeds transverse area echeni trough 9.

The device for hemosorption works as follows.

Blood is supplied through shtutser 3, passes through the filtering layer 5, the opening 13 in the lid 7 and enters the chute 9. At the section of the chute 9 having an extension 12, the blood is distributed between the fibers of the sorbent 10 and passes between them to the final expansion 12, thus freeing itself from toxic substances. Through the hole 14 and the filter layer, the blood enters the outlet fitting 4.

The fibers of the sorbent 10 laid in the chute 9 swell with contact with blood, increasing their cross-section by 20, therefore the cross-sectional area of the chute 9 should be 20-30% higher than the cross section of the sorbent 10.

If less than 20% is exceeded, the hydraulic resistance of the device increases dramatically and the blood distribution is disturbed.

in the volume of the sorbent, and when exceeding more than 30%, the distribution of blood is also disturbed due to the formation of flows outside the volume of the sorbent, as a result of which its absorption capacity drops markedly.

In order for the sorbent not to overlap the holes for the input 13 and output 14 of the blood, the cross-sectional area of the extensions 12 should be 25-30% higher than the cross-sectional area of the groove 9, since with a smaller cross-sectional area of the extensions 12 the uniform distribution of blood in the volume sorbent, which leads to a significant decrease in the absorptive capacity of the device; with a larger area of expansion 12, the initial volume of filling the device with blood without any change in its absorption capacity is unnecessarily increased.

The proposed device has 3-4 times less hydraulic resistance compared to the known, all other conditions being equal. At the same time, the resistance, provided adequate heparinization within an hour increases by no more than 15-18%, and the sorption capacity of the device in low- and medium-molecular toxic substances exceeds the sorption capacity of the known device by 30-45%, which is due to uniform distribution of blood in the amount of sorbent.

Claims (1)

Invention Formula A device for hemosorption, comprising a housing in the form of two mating parts with fittings for blood inlet and outlet, layers of filter material in the housing and a sorbent between the layers, characterized in that, in order to ensure uniform distribution of blood flow in the sorbent volume when using fiber the sorbent, between the layers of the filtering material are placed adjacent to the perimeter and adjacent to the layers of the base and the cover, forming a cavity for the sorbent in the form of one or more grooves, and the base It has protrusions at the ends of the grooves for fixing the sorbent, and the areas of the grooves adjoining the protrusions have extensions opposite diametrically placed blood inlet openings in the cap and blood outlet openings in the base, with a cross section of each groove 20-30% larger than the cross-sectional area of the sorbent bundles laid in the groove and the cross-sectional area of each expansion is 25-30% higher than the cross-sectional area of the groove. / 5 7  L Bb FIG. four Phage. Compiled by O. Kabanov Editor A. LezhninaTehred I. VeresKorrektor A. Tsko Order 308/6 Circulation 596 Subscription VNIIPI USSR State Committee for Inventions and Discoveries  113035, Moscow, Zh-35, Raushsk iab., 4/5 Production Facility, Lygraphic Enterprise, Uzhgorod, ul. Project, 4