REGIONAL S COAGULATION SYSTEM FOR AN EXTRACORPOREAL CIRCULATION CIRCUIT

Abstract

The present invention concerns an extracorporeal circuit for regional scoagulation of blood comprising a line for taking the blood from the patient, a first filtering unit, and a line for returning the blood to the patient defining a main circuit, the extracorporeal circuit comprising a secondary circuit for recirculation of the plasma water comprising: a calcium removal assembly adapted to provide a solution with low calcium content in said main circuit;
the extracorporeal circuit further comprising: first means for the infusion of said solution with low calcium content into said main circuit upstream of said first filtering unit and of said calcium removal assembly with respect to the blood flow direction in the main circuit and second means for the infusion of an electrolytic re-establishment solution located downstream of said first means with respect to the direction of the blood flow in said main circuit.

Claims

1. Extracorporeal circuit (1, 100) for regional scoagulation of blood comprising a line for taking the blood (2) from the patient, a first filtering unit (6), and a line for returning the blood (5) to the patient defining a main circuit (12), the extracorporeal circuit (1, 100) being characterised in that it comprises a secondary circuit (32) for recirculation of the plasma water comprising: a calcium removal assembly (4) adapted to provide a solution with low calcium content (30, 40a) in said main circuit (12); said extracorporeal circuit (1, 100) further comprising: first means (13, 14) for the infusion of said solution with low calcium content (30, 40a) into said main circuit (12) upstream of said first filtering unit (6) and of said calcium removal assembly (4) with respect to the blood flow direction in the main circuit (12) and second means (19) for the infusion of an electrolytic re-establishment solution (29) located downstream of said first means (13, 14) with respect to the direction of the blood flow in said main circuit (12).

2. Extracorporeal circuit (1, 100) for regional scoagulation of blood according to claim 1, characterised in that said first filtering unit (6) is selected from the group consisting of a haemodiafilter, a haemofilter, a dialyser and a plasma filter.

3. Extracorporeal circuit (1) for regional scoagulation of blood according to claim 1 claim, characterised in that said calcium removal assembly (4) comprises a cartridge (10) comprising an ionic exchange cationic resin loaded with sodium, potassium, chlorine and bicarbonate.

4. Extracorporeal circuit (1) for regional scoagulation of blood according to claim 1 claim, characterised in that said calcium removal assembly (4) comprises a precipitate removal unit (20) and an electrodialyser (28) arranged in series; said electrodialyser (28) comprising a basic chamber (25), adapted to generate a basic solution (40b) which is recirculated upstream of the precipitate removal unit (20) to allow precipitation of the calcium, and an acid chamber (24) adapted to generate a solution with low calcium content (40a).

5. Extracorporeal circuit (1) for regional scoagulation of blood according to claim 1 claim, characterised in that a fraction of said solution with low calcium content (30, 40a) is returned to the main circuit 12 at the haemofilter 6 via the line 13.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0032] The present invention will now be described in detail with reference to the figures of the accompanying drawings, in which:

[0033] FIG. 1 illustrates a first embodiment of the invention;

[0034] FIG. 2 illustrates a second embodiment of the invention;

[0035] FIG. 3 illustrates a detail of the electrodialyser of the extracorporeal circulation system of FIG. 2. In said embodiment the electrodialyser is optimised with the application of a semipermeable membrane permeable to cations only;

[0036] FIG. 4 illustrates a detail of the electrodialyser of the extracorporeal circulation system of FIG. 2. In said embodiment the electrodialyser is optimised with the application of a semipermeable membrane permeable to anions only.

BEST MODE FOR CARRYING OUT THE INVENTION

[0037] In FIG. 1 the number 1 indicates as a whole an extracorporeal circulation system according to a first embodiment of the present invention.

[0038] The circuit 1 comprises a line for taking the blood 2 from the patient, on which a peristaltic pump 3 acts, a first filtering unit 6 and a line for returning the blood 5 to the patient, which define a main circuit 12.

[0039] In the embodiment illustrated in FIG. 1, the first filtering unit 6 is a haemofilter.

[0040] The circuit 1 further includes a calcium removal assembly 4 which comprises a cartridge 10 including an ionic exchange cationic resin for the calcium previously loaded with a solution of sodium, potassium, chlorine and bicarbonate.

[0041] In use, the blood removed from the patient via the line 2 is sent, by the action of the pump 3, to the haemofilter 6. The haemofilter 6 separates the plasma water which is conveyed via the line 7, by means of the pump 9, to the ionic exchange cationic resin 10 in which the calcium ions are removed, generating a solution 30 with low calcium content. Said solution 30 is enriched with sodium ions exchanged by the resin 10 in return for the calcium ions removed by said resin 10.

[0042] A fraction of the solution 30 with low calcium content is sent back to the main circuit 12 at the haemofilter 6 via the line 13.

[0043] A fraction of the solution 30 with low calcium content can be recirculated at the re-joining point 15 arranged on the line 2 upstream of the haemofilter 6 with respect to the blood flow direction in the main circuit 12 via the line 14 by the action of the pump 11. Said line 14 can be connected to the line 2 both before and after the pump 3.

[0044] In this embodiment, the solution with low calcium content 30, by diluting the blood flow in the line 2 and circulating in the haemofilter 6, allows dilution and reduction of the calcium concentration in the blood until obtaining scoagulation thereof.

[0045] To maintain the sodium balance, since the resin 10 retains the calcium but releases sodium into the plasma water, it is further possible to remove part of the plasma water, for example along line 7 or alternatively along line 13, by the action of the pump 8. In this case, the quantity of plasma water removed by the pump 8 must be such as to contain a quantity of sodium corresponding to the quantity released by the resin 10 in the same unit of time, in order not to increase the concentration of sodium returned to the patient. Alternatively, it is possible to fit along the line 13 a fine mesh filter able to retain any fragments released by the cartridge 10.

[0046] To restore the hydro-electrolytic balance of the remaining ions involved in the process, before the blood is returned to the patient, along the line 5, and the normal haematic concentration of calcium, in addition to magnesium, potassium and chlorine, an electrolytic re-establishment solution 29, contained in the bag 17, is infused via the line 19 by means of a pump 18. Alternatively said solution 29 contained in the bag 17 can be infused to a central or peripheral venous access in order to restore the systemic hydro-electrolytic balance.

[0047] For example, said solution 29 can contain cations at a concentration ranging from approximately 125 to 175 mEq/L, in particular in the form of calcium (110 to 140 mEq/L), magnesium (10 to 40 mEq/L) and a small quantity of potassium, corresponding to the plasma concentration range (2 to 5 mEq/L). The solution 29 can further contain anions in a concentration ranging from 125 to 175 mEq/L in particular in the form of chlorides (90 to 120 mEq/L) and organic ions (for example bicarbonates, lactates, acetates, gluconates) in order to achieve electroneutrality of said solution (60 to 30 mEq/L).

[0048] The quantity of the solution 29 infused in the unit of time corresponds to the volume removed through line 7 by means of the pump 8, thus maintaining the hydro-electrolytic balance.

[0049] The extracorporeal circuit 1 described above can therefore be easily integrated with the most appropriate devices for carrying out the extracorporeal therapy necessary to support the patient.

[0050] Said therapy can be, for example, a renal function replacement therapy, an extracorporeal removal of CO.sub.2 or a removal of excess substances present in the blood, for example cytokines, toxins, myoglobin, lactate, electrolytes or drugs.

[0051] Said extracorporeal therapy can be performed by positioning the appropriate device along the line 5 downstream of the filtering unit 6 but upstream, in the direction of the blood flow in the main circuit 12, of the point where line 19 re-joins line 5. Alternatively, in the embodiment that entails recirculation of part of the solution 30 upstream of the filtering unit 6, the device for the extracorporeal therapy can be arranged on the line 2 between the re-joining point 15 and the filtering unit 6.

[0052] For example, if the device for the extracorporeal therapy is an artificial lung or a bubble oxygenator for the removal of carbon dioxide which require treatment of the plasma water, the device can be inserted along the line 7, 14 or 13.

[0053] If on the other hand the patient requires renal replacement therapy, it can be operated directly by selecting a haemofilter as filtering unit 6. This therapy can be performed in post-dilution infusing the renal replacement therapy solution directly into the blood line 5.

[0054] Alternatively, the renal replacement therapy can be performed in pre-dilution, infusing the renal replacement therapy solution into the line 2 upstream of the filtering unit 6 or into the line 14.

[0055] Where the renal replacement therapy is performed using a dialyser as the filtering unit 6, the renal replacement therapy solution can be infused into the line 13.

[0056] In the embodiment for renal replacement therapy, in order to maintain the scoagulation effect of the reduced calcium content, the renal replacement therapy solution shall preferably have an almost nil calcium content and a reduced sodium content to balance the release of sodium by the resin 10.

[0057] As regards the loss of plasma water necessary for performing the renal replacement therapy, this can be done through the line 7 by the pump 8, or alternatively the plasma water can be removed along the line 13.

[0058] The system of FIG. 1, in which the filtering unit 6 is a haemofilter, was tested in a pig model. The blood flow was set in a range from 150 to 400 ml/min, the flow into the pump 9 in a range from 600 to 2400 ml/min and the flow of the pump 11 in a range from 300 to 800 ml/min. Removal of the calcium by the calcium removal assembly 4 allowed the calcium concentrations to be reduced along the haematic circuit to values comparable with those obtained via the use of an administration of sodium citrate, obtaining a regional scoagulation, measured with an elongation of the activated clotting time—ACT.

[0059] FIG. 2 illustrates a second embodiment of the extracorporeal circuit 100 according to the present invention. The details similar or identical to those already described are indicated for the sake of simplicity by the same reference numbers.

[0060] In this embodiment, the circuit 100 comprises a calcium removal assembly 4 which in turn comprises an electrodialyser 28. In particular, the blood removed from the patient via the line 2 is sent, by the action of the pump 3, to the first filtering unit 6, in this case, for example, a haemodiafilter. The haemodiafilter 6 separates the plasma water which is conveyed via the line 7, by means of the pump 9, to the electrodialyser 28.

[0061] As illustrated in FIG. 3, the electrodialyser 28 is provided with a first electrodialysis chamber 24 and a second electrodialysis chamber 25 separated by an ionic membrane 35.

[0062] Each chamber is separated from the corresponding electrode 31,33 by means of a bipolar membrane 36,37. The positive electrode 31, or anode, is arranged in a first chamber 32 immersed in a solution of anolyte, for example sodium sulphate or sodium phosphate, and the negative electrode 33, or cathode, is arranged in a second chamber 34 immersed in a solution of catholyte, for example sodium chloride.

[0063] According to FIG. 3, the ionic membrane 35 is a cationic membrane, the electrodialysis chamber 24 associated with the anode 31 is adapted to generate an acid solution and the electrodialysis chamber 25 associated with the cathode 33 is adapted to generate a basic solution.

[0064] As illustrated in FIG. 2, part of the plasma water, pushed by the pump 9, reaches the first chamber 24 of the electrodialyser 28, via the line 21. The remaining part of the plasma water is introduced into the second chamber 25 by the action of the pump 23 via the line 22.

[0065] Inside the electrodialyser, proportionally to the electrical current applied, the plasma water that enters the second chamber 25, i.e. the “basic” chamber, receives cations from the plasma water present in the first chamber 24, i.e. the “acid” chamber. Since the main cation in the plasma water is Na.sup.+, the plasma water that flows in the second chamber 25 is enriched in Na.sup.+ ions while the OH.sup.− ions are provided through the bipolar membrane 36. In the first chamber 24 a flow of an acid solution, the acid plasma water 40a, therefore forms, while in the second chamber 25 a flow of basic plasma water 40b forms.

[0066] Alternatively the ionic membrane 35 can be an anionic membrane, as illustrated in FIG. 4. In this case the flow of the ions into the electrodialyser 28 will be as shown.

[0067] In this case, the plasma water that enters the chamber 25, i.e. the basic chamber, releases anions to the solution present in the chamber 24, i.e. the acid chamber. Since the main anion in the plasma water is Cl.sup.−, the solution that flows in the chamber 24 is enriched in Cl.sup.− ions, generating, proportionally to the electrical current applied, a solution rich in chlorine.

[0068] Other configurations of the electrodialyser 28 having, for example, a plurality of acid chambers and basic chambers are equally functional for the purpose of the present invention.

[0069] The application of an electrodialysis technique on the plasma water, whether a dialysate or an ultrafiltrate, allows the selective separation of anions and cations present in the solution.

[0070] The solution 40b generated by the chamber 25 is recirculated via the line 26 to the electrodialyser 28.

[0071] Upstream of the electrodialyser 28, on the recirculation circuit 7 of the plasma water, there is a calcium precipitate removal unit 20, for example a filter or a tangential filter or a centrifuge separator, to remove the precipitate. Said unit 20 is able to remove the calcium precipitates that form in the solution 40b, thus reducing the calcium content of the plasma water which is then returned to the filtering unit 6.

[0072] The solution 40a coming out of the chamber 24 is partly sent via the line 13 to the filtering unit 6 and partly via the line 2 by means of the pump 11 to the re-joining point 15 upstream of the filtering unit 6. The solution 40a therefore derives from the plasma water, the calcium concentration of which is reduced by the recirculation action of the solution 40b and the action of the unit 20. Therefore, the solution 40a which is returned to the main circuit at the re-joining point 15 and the solution provided inside the filtering unit 6 has a low calcium content and scoagulates the blood.

[0073] If necessary, by setting the appropriate process parameters, the calcium crystals can be subsequently re-dissolved by means of acidification and if necessary the calcium recovered can be re-infused into the patient.

[0074] Along the line 5, the normal blood concentration of calcium and magnesium will be obtained by infusion of a solution with high calcium content 29, contained in the bag 17, via the line 19 by means of a pump 18. The ion content of the bag 17 can be defined in the most appropriate way as required.

[0075] As for the circuit 1 previously described, the scoagulated blood can undergo the same extracorporeal treatment in the same positions along the line 2 or 5.