EP0051659A4 - PRODUCTION OF A BICARBONATE DIALYSATE. - Google Patents

PRODUCTION OF A BICARBONATE DIALYSATE.

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Publication number
EP0051659A4
EP0051659A4 EP19810901432 EP81901432A EP0051659A4 EP 0051659 A4 EP0051659 A4 EP 0051659A4 EP 19810901432 EP19810901432 EP 19810901432 EP 81901432 A EP81901432 A EP 81901432A EP 0051659 A4 EP0051659 A4 EP 0051659A4
Authority
EP
European Patent Office
Prior art keywords
dialysate
solution
molar
conductivity
aqueous
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn
Application number
EP19810901432
Other languages
German (de)
English (en)
French (fr)
Other versions
EP0051659A1 (en
Inventor
Albert L Babb
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Individual
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Individual
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Publication date
Priority claimed from US06/209,742 external-priority patent/US4326955A/en
Application filed by Individual filed Critical Individual
Publication of EP0051659A1 publication Critical patent/EP0051659A1/en
Publication of EP0051659A4 publication Critical patent/EP0051659A4/en
Withdrawn legal-status Critical Current

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Classifications

    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61MDEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
    • A61M1/00Suction or pumping devices for medical purposes; Devices for carrying-off, for treatment of, or for carrying-over, body-liquids; Drainage systems
    • A61M1/14Dialysis systems; Artificial kidneys; Blood oxygenators ; Reciprocating systems for treatment of body fluids, e.g. single needle systems for hemofiltration or pheresis
    • A61M1/16Dialysis systems; Artificial kidneys; Blood oxygenators ; Reciprocating systems for treatment of body fluids, e.g. single needle systems for hemofiltration or pheresis with membranes
    • A61M1/1654Dialysates therefor
    • A61M1/1656Apparatus for preparing dialysates
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61MDEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
    • A61M1/00Suction or pumping devices for medical purposes; Devices for carrying-off, for treatment of, or for carrying-over, body-liquids; Drainage systems
    • A61M1/14Dialysis systems; Artificial kidneys; Blood oxygenators ; Reciprocating systems for treatment of body fluids, e.g. single needle systems for hemofiltration or pheresis
    • A61M1/16Dialysis systems; Artificial kidneys; Blood oxygenators ; Reciprocating systems for treatment of body fluids, e.g. single needle systems for hemofiltration or pheresis with membranes
    • A61M1/1654Dialysates therefor
    • A61M1/1656Apparatus for preparing dialysates
    • A61M1/1666Apparatus for preparing dialysates by dissolving solids

Definitions

  • This invention relates to hemodialysis and, in particular, a system and compositions for the preparation of a bicarbonate-containing dialysate for dialyzing the blood of a patient across a semi-permeable membrane.
  • Background of the Invention It has been recognized for some time that human blood may be conditioned through dialytic action with a selected exchange fluid.
  • Dialysis is performed on patients whose kidneys are not capable of adequate purification of blood and elimination of excess water. This is usually accomplished by circulating a portion of the patient's blood through a dialysis cell in which the patient's blood passes on one side of a semi-permeable membrane and a dialysate solution on the other side.
  • the semi-permeable membrane passes waste materials and water from the patient's blood to the dialysate.
  • Dialysis is literally a life-saving process; however, sometimes undesirable side effects such as hypotension, fatigue, nausea, and the like, are encountered. Research is continuing to counter the adverse side effects and to further improve the efficacy of hemodialysis, including investigations to improve the composition of the exchange fluid, i.e., the composition of the dialysate.
  • Dialysate liquids must contain an alkalizing salt.
  • sodium bicarbonate was used as the alkalizing agent.
  • sodium acetate was substituted for sodium bicarbonate as an alkalizing agent more than fifteen years ago.
  • Even today dialysis solutions usually contain sodium acetate as the alkalizing agent.
  • Sodium acetate solutions are more easily maintained than sodium bicarbonate solutions in a state of sterility; sodium acetate being subsequently metabolized in the bloodstream to sodium bicarbonate.
  • evidence is accumulating that the increased transfer of acetate occurring in large surface dialyzers using sodium acetate dialysates is not without shortcomings.
  • sodium bicarbonate rather than sodium acetate should be the alkalizer of choice in dialysate liquids.
  • sodium bicarbonate solutions present practical problems because these solutions are not bacteriostatic and thus may present sterility problems.
  • Aqueous sodium bicarbonate solutions unlike aqueous sodium acetate solutions, are not self-sterilizing and cannot be prepared in advance of their use for dialysis. Common infectious organisms can survive and proliferate in sodium bicarbonate solutions; and infection of the patient is thus possible when there is even a minor and inadvertent departure from sterile technique in the handling of the dialysis process.
  • the present invention permits the in situ preparation of a bicarbonate-containing dialysate suitable for use in a dialysis machine from bacteriostatic starting solutions and also contemplates a proportioning system for such preparation.
  • a proportioning system for such preparation.
  • an aqueous hydrochloric acid-containing solution and an aqueous carbonate-ion containing solution are combined, and the conductivity as well as the hydrogen ion activity of the produced, bicarbonate-containing dialysate is monitored.
  • This invention can be practiced using presently known dialysis equipment in conjunction with a dialysate compounded in two stages from two or three previously prepared bacteriostatic solutions. In this manner prolonged existence of sodium bicarbonate in the dialysate liquid prior to use is avoided, rather the sodium bicarbonate is prepared in situ in a desired concentration shortly before the dialysate liquid contacts the dialysis membrane.
  • Aqueous acetic acid solutions are bacteriostatic and self-sterilizing, and therefore contaminant-free prior to blending with the sodium carbonate solution.
  • aqueous sodium carbonate solutions are inherently bacteriostatic, but the aqueous sodium carbonate solutions are not bacteriostatic at all concentrations.
  • aqueous sodium carbonate solutions having a sodium carbonate concentration of less than about 20 grams per liter of solution are capable of supporting bacterial growth.
  • Such dilute aqueous sodium carbonate solutions can be used to generate sodium bicarbonate in situ when freshly prepared; however, these dilute solutions are not suitable for extended storage and shipment from a manufacturing facility to the intended end use station.
  • aqueous sodium carbonate solutions containing sodium carbonate in a concentration of about 20 grams or more per liter of solution are bacteriostatic.
  • the present invention contemplates a bacteriostatic aqueous sodium carbonate solution and a concentrated aqueous hydrochloric acid solution that are suitable for the compounding of a hemodialysis dialysate.
  • the sodium carbonate solution comprises water, and at least about 20 grams of sodium carbonate per liter of solution.
  • the amount of sodium carbonate present is calculated as anhydrous sodium carbonate; however, the hydrated forms of sodium carbonate, e.g., sodium carbonate monohydrate or sodium carbonate hexahydrate, are also well suited for preparing the aforementioned sodium carbonate concentrates.
  • the bacteriostatic aqueous sodium carbonate solution and aqueous acid concentrate are in the form of physically discrete units that are suitable as unitary dosages for each dialysis session, each unit containing a predetermined quantity calculated to produce the desired therapeutic effect when diluted and combined to produce a hemodialysis dialysate.
  • the preferred unit dosage forms are sealed unit dose containers, more preferably sealed, collapsible unit dose containers that can be emptied without the need for venting.
  • the sealed unit dose containers preferably contain about one liter to about 50 liters of the bacteriostatic solution or concentrate, more preferably about 2 liters to about 20 liters.
  • a preferred embodiment of the system of this invention includes a source of aqueous carbonate ion concentrate, a source of aqueous hydrochloric acid-containing concentrate, a source of physiologically tolerable water, and means for commingling an aqueous stream from each of the aforementioned sources to produce a bicarbonate-containing dialysate.
  • the system includes a potentiometric means for monitoring hydrogen ion activity in the produced dialysate and providing an output indicative of the hydrogen ion activity (e.g., a pH probe or meter), conductivity sensing means for monitoring the conductivity of the produced dialysate and providing an output indicative of the conductivity thereof, and a flow control means that is responsive to both of the foregoing outputs and is adapted to interrupt normal flow of the produced dialysate when the value of either of these outputs deviates from a set magnitude by a predetermined amount.
  • a potentiometric means for monitoring hydrogen ion activity in the produced dialysate and providing an output indicative of the hydrogen ion activity
  • conductivity sensing means for monitoring the conductivity of the produced dialysate and providing an output indicative of the conductivity thereof
  • a flow control means that is responsive to both of the foregoing outputs and is adapted to interrupt normal flow of the produced dialysate when the value of either of these outputs deviates from a set magnitude by
  • FIGURE 1 is a block diagram illustrating, a system embodying the present invention
  • FIGURE 2 is a graphical representation of the conductivity and pH of an aqueous stream obtained by combining an aqueous sodium carbonate stream and an aqueous hydrochloric acid-containing stream;
  • FIGURE 3 is a semi-schematic representation of a flow system designed to provide two reaction stages between the aqueous sodium carbonate and the hydrochloric acid and to substantially prevent the formation of calcium carbonate precipitate when the reactants are mixed;
  • FIGURE 4 is a block diagram of a preferred proportioning system embodying the present invention. Description of Preferred Embodiments
  • the concentrated bacteriostatic sodium carbonate solution is first diluted with water, preferably deionized or tempered water, to provide a carbonate ion concentration that is sufficiently low to avoid the precipitation of any cations that may be present as additional constituents in the aqueous acid concentrate solution and that can form insoluble carbonates.
  • the bacteriostatic, concentrated sodium carbonate solution can contain sodium carbonate in an amount of about 20 grams per liter of solution up to about 150 grams per liter of solution, and preferably about 105 to about 115 grams per liter solution, thus prior to use the concentrated sodium carbonate solution should be diluted sufficiently to avoid the formation of undesirable precipitates when combined with the aqueous acid concentrate.
  • the bacteriostatic solution can be packaged in the aforementioned quantities in sealed containers, e.g., collapsible hermetically sealed containers, so as to avoid undesirable pick-up of carbon dioxide from ambient atmosphere.
  • sealed containers e.g., collapsible hermetically sealed containers
  • the dissolved carbon dioxide concentration in the concentrated sodium carbonate solution is less than about 0.5 molar.
  • Presently known dialysis equipment can be used in conjunction with a dialysate compounded using the aforementioned bacteriostatic sodium carbonate solution. Prolonged existence of sodium bicarbonate in the dialysate liquid prior to use is avoided; instead, sodium bicarbonate is generated in a flowing stream in situ within the dialysis machine and in a desired concentration shortly before the dialysate liquid contacts the dialysis membrane.
  • the proportioning systems available on present dialysis equipment vary, thus the dilution ratios for each of the concentrates that are to be combined to form the ultimate dialysate may be different and in some instances may be as high as 60:1. However, in all instances the produced bicarbonate-containing dialysate has a pH in the range of about 7:1 to about 7:4 and an osmolality of about 200 to about 280 milliosmoles.
  • the preferred acid solution for producing the dialysate is a hydrochloric acid solution which produces no sodium acetate.
  • acetic acid produces equimolar amounts of sodium bicarbonate and sodium acetate; and acetic and hydrochloric a mixtures produce even less sodium acetate.
  • a minimum alkalizing level of 35 milliequivalents per liter of sodium bicarbonate may be taken as standard; and a level of sodium carbonate in a standard solution may be selected to produce 30 or 35 milliequivalents of sodium bicarbonate ion per liter when the sodium carbonate is diluted and then reacted with hydrochloric acid.
  • a level of sodium carbonate in a standard solution may be selected to produce 30 or 35 milliequivalents of sodium bicarbonate ion per liter when the sodium carbonate is diluted and then reacted with hydrochloric acid.
  • the standard sodium carbonate solution would be reacted with an aqueous acid solution containing only hydrochloric acid.
  • the additional five milliequivalents may be obtained from the same standard sodium carbonate solution that provides 35 milliequivalents of sodium bicarbonate by substituting acetic acid for the hydrochloric acid equivalent of five milliequivalents per liter.
  • the substituted acetic acid will react with the sodium carbonate not only to produce immediately the same amount of sodium bicarbonate as the hydrochloric acid that it replaces (5 milliequivalents per liter) but it will also produce 5 milliequivalents per liter of sodium acetate which converts in the body to sodium bicarbonate.
  • partial substitution of acetic acid for hydrochloric acid in a reaction with a standard minimum sodium carbonate solution increases the ultimate level of sodium bicarbonate to the extent of such substitution on a mol for mol basis.
  • addition of acetic acid can be dispensed with by increasing the amounts of hydrochloric acid and sodium carbonate that are reacted.
  • the amounts of other constituents of the dialysate fluid d ed for proper electrolyte balance e.g., Nacl, KCl, CaCl 2 , MgCl 2 , etc. are based on clinical requirements. These salts may be dissolved in the concentrated acid-containing solution, or may be supplied as a t solution, as desired.
  • the aqueous acid concentrate solutions within the purview of the present invention can be prepared by dissolving the solid salts in water, preferably deionized or tempered water, and adding hydrochloric acid.
  • the relative amounts of constituents are selected so as to provide in the concentrated solution a chloride ion concentration of about 3.5 to about 4.7 Molar, sodium ion concentration of about 1.9 to about 2.7 Molar, and a pH value of about 1 to about 2.5
  • the pH value of the aqueous acid concentrate is about 1.8 to about 2.0.
  • the aqueous acid concentrate can contain the acetate group in a concentration up to about 0.525 Molar, preferably in a concentration of about 0.15 Molar to about 0.35 Molar. Since aqueous solutions of acetate group-containing compounds contain ionized as well as unionized forms thereof, the term "acetate group" as used herein and in the appended claims includes both such forms.
  • the aqueous acid concentrate can also contain potassium ion in a concentration up to about 0.14 Molar, calcium ion in a concentration up to about 0.125 Molar, and magnesium ion in a concentration up to about 0.09 Molar.
  • Dextrose can be present in a concentration of about 0 to about 0.4 Molar, preferably in a concentration of about 0.2 to about 0.35 Molar.
  • the dialysate is preferably provided to the membrane through a proportioning apparatus into which three liquids are directed as separate streams at controlled rates, namely (1) a bacteriostatic stock sodium carbonate concentrate, (2) a bacteriostatic acid concentrate containing the remaining dialysate solute constituents, and (3) water, e.g., tempered water.
  • the sodium carbonate concentrate and the tempered water are first combined; and the diluted sodium carbonate solution thus obtained is then combined with the acid concentrate, usually at a 34:1 or 36:1 dilution ratio.
  • the acid concentrate may also be diluted to a predetermined concentration before the bicarbonate is generated. The dilution ratios in any given instance will depend on the type of dialysis equipment and associated proportioning devices that are used, and also on the particular concentrations of the aqueous sodium carbonate concentrate and the acid concentrate that are utilized in any given instance.
  • the relative proportions and flow rates of the three liquid streams may be calculated and controlled by a suitable computer or microprocessor device; and the operation of the system may be monitored by a continuous reading of either the conductivity or the pH value of the final composite stream to the dialysis unit. Preferably both the conductivity and the pH of the obtained dialysate are monitored.
  • a sodium bicarbonate level of 35 milliequivalents per liter usually is suitable for patients having a minimal alkalizing requirement in their dialysate fluid.
  • a standard, bacteriostatic concentrated sodium carbonate solution is prepared containing 1891 grams of sodium carbonate in a 4.5 U.S. gallon batch, i.e., containing 111 grams of sodium carbonate per liter of former solution, which is then diluted with tempered water in a water-to-concentrate volume ratio of about 28 to 1. This ratio may be varied, however, to adjust bicarbonate and pH levels as needed.
  • hydrochloric acid in an amount that slightly exceeds the stoichiometric amount needed for conversion of sodium carbonate to sodium bicarbonate and in other instances it may be desirable to increase the amount of sodium carbonate.
  • the remaining solute constituents of the dialysate solution as prescribed by the attending physician can be added to the acid-containing solution or can be provided to the dialysate as a stream of a separate solution.
  • the diluted sodium carbonate solution is combined with the aforementioned acid-containing solution in a volumetric ratio of, for example, 34 to 1, i.e., 34 parts by volume of the diluted sodium carbonate solution to one part by volume of the acid-containing solution.
  • the acid-containing solution also contains the prescribed additional constituents needed for proper electrolyte balance, the acid-containing solution should be added only to the diluted sodium carbonate solution because otherwise a calcium carbonate and/or magnesium carbonate precipitates in the dialysate may be formed.
  • a pH monitor in conjunction with the conductivity sensor to insure that undiluted acid concentrate does not come in contact with the dialysis membrane in the event the supply of diluted aqueous sodium carbonate solution that is to be combined therewith is reduced or interrupted due to equipment malfunction or for some other reason.
  • the bacteriostatic aqueous sodium carbonate concentrate that is diluted 36-fold and combined with the foregoing acid concentrate after approximate dilution contains 169.64 grams of Na 2 CO 3 .H 2 O (mol. wt. 124.01) per liter which is equivalent to about 145 grams per liter calculated on the basis of anhydrous sodium carbonate.
  • the foregoing sodium carbonate concentrate can also be used at a 36-fold dilution to provide a dialysate having a pH of 7.2 to 7.4 and the following composition:
  • the aqueous acid concentrate again to be diluted 36:1, has the following composition: NaCl (mol.wt. 58.45) 134.67 grams/liter
  • each concentrate can be selected as desired, and the amounts of the constituents present in each concentrate can be scaled up or down accordingly within their respective solubility limits.
  • Bacteriological testing of concentrated aqueous sodium carbonate solutions indicates that these solutions will not support the life of microorganisms that can be potential contaminants, i.e., Bacillus cereus, Pseudomonas stutzeri as well as yeasts, molds, and members of Serratia and Staphylococcus.
  • samples of the concentrated solutions were challenged by introducing about 1000 bacteria of a specific type and checking these samples periodically over a time period of several days. For each sample two types of control were also used. First a sample of nutrient broth was challenged with the same type and member of bacteria and periodically checked for growth to determine that the bacteria used in each instance were viable (a positive growth control). Additionally, an aliquot of each solution sample was left unchallenged but otherwise handled in the same manner as the challenged samples (a negative growth control).
  • aqueous sodium carbonate test solutions and a control were challenged with various microorganisms and cultured to ascertain whether these solutions support microorganism growth.
  • the five test solutions contained sodium carbonate in the following concentrations: 20 grams/liter, 40 grams/liter, 60 grams/liter, 80 grams/liter, and 100 grams/liter.
  • the five test solutions and TSY Broth were each divided into seven 20-milliliter aliquots and seeded with approximately 1000 microorganisms each.
  • the microorganisms that were used were Pseudomonas stutzeri, Bacillus cereus, Candida albicans (a yeast), members of Serratia and Staphylococcus , and a mold.
  • Suitable freezing point depressants for this purpose are physiologically tolerable liquid mono- or polyhydric alcohols such as ethanol, propylene, glycol, glycerin, and the like, as well as mixtures of such alcohols.
  • the amount of the freezing point depressant that is added will vary with the particular organic compound utilized and will depend also on the expected ambient temperatures during shipment and storage.
  • FIGURE 1 The basic elements of a system to mix the bacteriostatic aqueous sodium carbonate solution and aqueous acid concentrate are illustrated in FIGURE 1.
  • An aqueous stream from carbonate source 10 and an aqueous stream from acid source 11 are combined in mixing chamber 12.
  • the carbonate source can be a supply of a water-soluble, physiologically tolerable alkali metal carbonate, e.g., sodium carbonate in anhydrous or hydrated form, dissolved in physiologically tolerable water such as conditioned water, e.g., deionized water, distilled water, or the like, at a concentration sufficiently dilute upon combination with the acid source so as not to bring about the precipitation of any insoluble carbonates upon addition of the aqueous acid solution that could otherwise result due to the presence of small amounts of cations such as calcium or magnesium that may be present in the acid solution.
  • conditioned water e.g., deionized water, distilled water, or the like
  • the acid source can be a supply of hydrochloric acid alone or hydrochloric acid admixed with acetic acid in a predetermined ratio as prescribed by the attending physician.
  • Other constituents such as sodium chloride, calcium chloride, magnesium chloride, and the like, can also be dissolved with the acid.
  • Mixing chamber 12 is of sufficient holding capacity to provide adequate mixing and residence time for the carbonate-to-bicarbonate conversion to take place. If desired, a separate holding tank may be provided downstream of mixing chamber 12 for this purpose.
  • FIGURE 3 a preferred system to mix the carbonate and acid solutions is shown in FIGURE 3.
  • an aqueous sodium carbonate solution (about 3.8 g/liter) is flowed through line 110 at the rate of about 500 ml/min. with a portion thereof, preferably about 450 ml/min. passing upwardly through line 112 into reservoir 113 and another portion, preferably about 50 ml/min. continuing through line 114 and then upwardly through line 116 into reservoir 117.
  • Valves 118 and 119 in lines 112 and 116, respectively, are used to balance the flow of aqueous sodium carbonate solution into the two reservoirs preferably in a ratio of about 9:1.
  • the sodium carbonate solution passing through line 112 into reservoir 113 passes first into sparger 121 comprising a tube, centrally located in the reservoir, closed at its upper end and containing side performations which propel incoming solution into the body of fluid contained in the reservoir.
  • Reservoir 117 contains a similar sparger 122 for similar introduction of the sodium carbonate solution from line 116.
  • the aqueous a c solution, containing hydrochloric acid (about 1.4 N) and other dialysate components is introduced through the closed upper end of reservoir 113 through line 111 at a flow rate of about 14 ml/min.
  • the flow of acid through line 111 is stoichiometric to the flow of sodium carbonate solution through line 110 but is in excess of that needed to convert all of the sodium carbonate flowing into reservoir 113 to sodium bicarbonate.
  • the half life of the sodium carbonate introduce therein i bou 15 ites.
  • Reservo ir 113 preferabl s to ovide res. ce t of bout one f te abou hree lf-li s) for e aqueou sodiu m carbonate so lution introduced therein and constitutes the first conversation stage.
  • about 89 to 90% of the sodium carbonate introduced into reservoir 113 is converted to sodium bicarbonate before the bicarbonate-containing liquid stream flows out of the reservoir 113 and into reservoir 117 through line 124.
  • the solution in reservoir 113 remains acidic because some of the hydrochloric acid introduced remains unreacted.
  • a subsequent stage that includes reservoir 117, where the remaining, nreacted sodium carbonate portion is introduced, the esidence time is abou he same as in the first itage (reservoir 113) further conversion of sodium carbonate to sodium bicarbonate takes place, preferably a further 10-fold reduction in the carbonate concentration. In this manner an overall conversion of sodium carbonate to sodium bicarbonate of about 98 to 99 percent is obtained.
  • the pH never rises above about 7.4, and calcium carbonate is not formed in sufficient quantity to come out of solution.
  • the produced bicarbonate-containing dialysate is conveyed through line 17 to a suitable hemodialysis apparatus, not shown.
  • each carbonate conversation stage should preferably be at least about 0.45 to 0.6 minutes. Preferably, at least about 80% of the total sodium carbonate flow should be directed to the first stage and the remainder to each subsequent stage. In determining the residence time in each stage after the first stage the volume of the lines connecting the stages has to be taken into account of course. Under some conditions, the acidity in reservoir 113 may be sufficient to decompose some sodium bicarbonate and produce free carbonic acid in the reaction mixture.
  • the preferred acid solution for producing the dialysate is an aqueous hydrochloric acid solution which produces no sodium acetate.
  • acetic acid produces equimolar amounts of sodium bicarbonate and sodium acetate; and acetic and hydrochloric acid mixtures produce even less sodium acetate.
  • Such solutions are therefore preferable to the sodium acetate-alkalized dialysate solutions now used inasmuch as the concentration of acetate ion in the dialysate is minimized or completely obviated.
  • pH probe 13 (FIGURE 1) or a similar potentiornetric means for monitoring the hydrogen ion activity of the aqueous solution leaving mixing chamber 12, is provided downstream from mixing chamber 12 in addition to conductivity probe 14.
  • pH Probe 13 provides an output that is indicative of hydrogen ion activity in the produced solution, and conductivity probe 14, in turn, provides an output that indicates the conductivity of this solution. Both of these outputs are transmitted to valve control means 15 which is suitably programmed to energize by-pass valve 16 so as to divert to drain any portion of the produced bicarbonate solution when the value of the outputs of either probe 13 or probe 14 deviates from a set magnitude by a predetermined degree.
  • auxiliary unit 20 may contain the dispensing system for the aqueous carbonate solution together with the indicator and control means for the entire proportioning system embodying this invention while a dialysis machine 21 may be equipped with the remainder of the necessary system components.
  • auxiliary unit 20 The functions performed by auxiliary unit 20 include metering of a controlled amount of concentrated aqueous carbonate solution and combining the metered amount with conditioned water, monitoring of conductivity of the resulting dilute aqueous carbonate solution, monitoring the hydrogen ion activity or pH of the dialysate produced, and protecting the patient against errors induced by equipment malfunction, improper starting solutions, and the like occurrences.
  • Auxiliary unit 20 includes carbonate concentrate pump 22, a metering pump usually having a capacity of zero to about 50 milliliters/minute, and associated pump control means 24, mixing unit or tank 26, temperature-compensated conductivity probes 28 and 30, and appropriate indicators and controls in module 32, including, for example, a conductivity meter, a pH meter, various indicator lights, audio alarms, and the like.
  • Carbonate concentrate pump 22 communicates with carbonate concentrate source 34 by means of flexible conduit 36 and functions to convey a concentrated aqueous carbonate solution to mixing tank 26 via conduit 37.
  • the concentrated aqueous carbonate solution is diluted in mixing tank 26 with conditioned water supplied through flexible conduit 38 at a predetermined, substantially constant volumetric rate.
  • the resulting dilute aqueous carbonate solution (about 28:1 dilution in case of sodium carbonate monohydrate solution) is then fed to proportioning unit 40 in dialysis machine by means of conduit 39.
  • Conditioned water can be supplied, usually at a constant temperature of about 98 °F. (37°C), to mixing tank 26 directly from an external source (not shown) by means of a separate pump means (not shown) via conduits 81, 82 and 38 which together with valves 83 and 84 form a continuous confined flow passageway for the conditioned water.
  • proportioning unit 40 that is installed in the dialysis machine 21
  • all or a portion of the total amount of conditioned water needed to constitute the dialysate can be passed through proportioning unit 40 with the amount needed for preparing a dilute carbonate solute being pumped to mixing tank 26 via conduits 85 and 86 upon appropriate setting of valves 83 and 84 while utilizing the pumping device or devices normally present in proportioning unit 40.
  • Probe 28 is provided associated with mixing tank 26 and controls operation of pump 22 to produce the diluted aqueous carbonate solution.
  • Probe 28 provides an output signal that is received by pump control means 24 and regulates the rate of introduction of the concentrated carbonate solution into mixing tank 26.
  • the purpose of this conductivity control loop is to maintain a substantially constant carbonate ion concentration in the diluted aqueous carbonate solution. Inasmuch as conductivity is a function of concentration as well as solution temperature, a temperature-compensated signal to pump control 24 is desirable. Preferably, all conductivity values are referenced to 98°F. (37°C.).
  • the signal or signals emanating from probe 28 can be first transmitted to control circuitry module 32 and then an appropriate signal transmitted to pump control means 24.
  • Conductivity probe 30 is also temperature-compensated and provides an output signal that is received by indicator and control circuitry module 32 which, in turn, provides a visual and/or audio indication of the conductivity of the diluted carbonate solution stream leaving auxiliary unit 21, and flowing to proportioning unit 40, for example. Additionally, module 32 is operably connected and supplies information to main control circuitry module 42 via cable 44. The redundancy afforded by a pair of temperature-compensated conductivity probes provides a further assurance that the diluted carbonate solution fed to dialysis machine 21 for further compounding into a dialysate solution has the desired concentration at all times.
  • Stabilization chamber or tank 58 is provided between probes 28 and 30 in order to stabilize the diluted carbonate solution and also to provide a reserve supply.
  • a chamber volume of about 250 cubic centimeters is usually adequate for this purpose; however, larger or smaller volume chambers can be used as required in any given instance.
  • Aqueous acid concentrate source 46 supplies the aqueous acid concentrate to proportioning unit 40 by means of flexible conduit 48.
  • Proportioning unit 40 meters the diluted carbonate solution and the acid concentrate solution to provide a stream of each solution in a predetermined volume ratio, usually about 34:1, to mixing tank 50.
  • the volume ratio may vary, however, depending on the type of proportioning unit used and the concentration of the diluted aqueous carbonate solution used in any given instance.
  • each stream is supplied to mixing tank 50 separately, e.g., the dilute carbonate stream is supplied through conduit 52 and the acid concentrate stream is supplied through conduit 54.
  • Deaeration pump 56 can be optionally provided in conduit 52 to remove any air that may be present in the diluted carbonate stream.
  • the aqueous acid concentrate can also be diluted with conditioned water in proportioning unit 40 before being combined with the dilute carbonate stream.
  • conduit 39 can lead directly to pump 56, and conduit 52 can be eliminated between proportioning unit 40 and pump 56.
  • Mixing tank 50 can be a vortex-type mixing chamber so as to rapidly achieve good and thorough mixing of the incoming streams. Preferably, however, mixing tank 50 is the system shown in FIGURE 3. From mixing tank 50 the combined streams are conveyed further by means of conduit 62, equipped with air trap 59, to a dialysis cell (not shown) for use in a dialysis cell or unit as the dialysate for dialyzing a patient.
  • pH sensor 64 and dialysate conductivity probe 66 are provided downstream from dialysate mixing tank 50 and air trap 59.
  • An output signal generated by pH sensor 64 can be transmitted to indicator and control module 32, and an output signal generated by dialysate conductivity probe 66 is transmitted to main control module 42.
  • both of these output signals can be first transmitted to main control module 42 and appropriate information thereafter transmitted to indicator and control module 32 via cable 44.
  • a temperature sensor-compensator may also be desirable for the pH sensor.
  • temperature probe 68 is provided in conduit 62 and generates an output signal indicative of dialysate temperature at the time the conductivity thereof is measured.
  • the output signal from temperature probe 68 is also transmitted to control module 42 where it is integrated with the other received signals using appropriate circuitry, e.g., a suitably programmed microprocessor, or the like.
  • Temperature probe 68 can be a thermistor, a thermocouple, or a similar temperature sensing device.
  • the output signal from temperature probe 68 can also be used to compensate the output signal from pH probe or sensor 64 as well as to regulate the heat input to the stream of conditioned water that enters the present system via conduit 81.
  • the output signal from pH sensor 64 can be further utilized to control the operation of carbonate concentrate pump 22 alone or together with the output signal from conductivity and temperature probe 28, as desired.
  • By-pass valve 70 is positioned in conduit 62 downstream of probes 64, 66.and 68 and is operably associated with control module 42 so that any deviation from normal operating conditions or dialysate characteristics will cause by-pass valve 70 to be actuated so as to divert the dialysate stream passing through conduit 62 to drain via drain passageway 72 and to interrupt the dialysate flow to a dialysis cell (not shown).
  • Turbidity detector 87 in drain passageway 72 serves to detect any undesirable precipitate that may be present.
  • Detector 87 can be a conventional blood leak detector usually present in dialysis machines.

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EP19810901432 1980-05-09 1981-04-21 PRODUCTION OF A BICARBONATE DIALYSATE. Withdrawn EP0051659A4 (en)

Applications Claiming Priority (4)

Application Number Priority Date Filing Date Title
US14820080A 1980-05-09 1980-05-09
US148200 1980-05-09
US06/209,742 US4326955A (en) 1979-06-14 1980-11-24 Hemodialysis with sodium bicarbonate dialysate prepared in plural stages
US209742 1980-11-24

Publications (2)

Publication Number Publication Date
EP0051659A1 EP0051659A1 (en) 1982-05-19
EP0051659A4 true EP0051659A4 (en) 1982-11-08

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EP19810901432 Withdrawn EP0051659A4 (en) 1980-05-09 1981-04-21 PRODUCTION OF A BICARBONATE DIALYSATE.

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EP (1) EP0051659A4 (it)
JP (1) JPS57500565A (it)
AU (1) AU7176881A (it)
CA (1) CA1166966A (it)
GB (1) GB2084484B (it)
IT (1) IT1170954B (it)
SE (1) SE8200109L (it)
WO (1) WO1981003180A1 (it)

Families Citing this family (16)

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Publication number Priority date Publication date Assignee Title
US4489535A (en) * 1980-10-02 1984-12-25 Veltman Preston Leonard Materials and method for preparing dialysis solutions containing bicarbonate ions
US5092838A (en) * 1989-11-30 1992-03-03 Baxter International Inc. Histidine buffered peritoneal dialysis solution
AU627309B2 (en) 1989-05-26 1992-08-20 Terumo Kabushiki Kaisha Preparation for blood dialysis and method for production thereof
DE4122754A1 (de) * 1991-07-10 1993-01-21 Martin Prof Dr Med Vlaho Herstellung einer substitutionsloesung fuer die haemofiltration bei dialyseverfahren
DE4211455C1 (de) * 1992-04-06 1993-12-16 Schael Wilfried Verfahren und Vorrichtung zur Bereitung von Dialysierflüssigkeit für die Hämodialyse
US5383324A (en) * 1993-04-23 1995-01-24 Baxter International Inc. Method for manufacturing and storing stable bicarbonate solutions
CA2211848C (en) * 1997-07-28 2002-06-11 Joseph E. Dadson Peritoneal dialysis apparatus
DE60039978D1 (de) 1999-04-26 2008-10-02 Edwards Lifesciences Ag Substitutions-infusionflüssigkeit und zitratanticoagulation
US8105258B2 (en) 1999-04-26 2012-01-31 Baxter International Inc. Citrate anticoagulation system for extracorporeal blood treatments
US7186420B2 (en) 1999-04-26 2007-03-06 Edwards Lifesciences Corporation Multi-part substitution infusion fluids and matching anticoagulants
JP5803543B2 (ja) * 2011-10-11 2015-11-04 ニプロ株式会社 透析液調製装置の診断方法と透析液調製装置
KR101458174B1 (ko) 2012-08-31 2014-11-04 김영기 혈액투석용 투석액 제조방법
JP5840248B2 (ja) * 2014-03-19 2016-01-06 株式会社日本トリム 透析液の製造装置
DE102016009442A1 (de) * 2016-08-03 2018-02-08 Fresenius Medical Care Deutschland Gmbh Verfahren zur Überwachung des Bicarbonat-Gehalts und des Natrium-Gehalts einer Dialyselösung
WO2023144901A1 (ja) * 2022-01-26 2023-08-03 ニプロ株式会社 透析液の調整方法
US11925703B1 (en) 2022-07-29 2024-03-12 Xellia Pharmaceuticals Aps Liquid composition comprising glucose

Family Cites Families (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3352779A (en) * 1965-10-23 1967-11-14 Sweden Freezer Mfg Co Hemodialysis system
US3962075A (en) * 1973-09-10 1976-06-08 Tri-Flo Research Laboratories, Ltd. Hemo dialyzer employing two dialysate solutions
US4202760A (en) * 1978-07-24 1980-05-13 Cordis Dow Corp. Apparatus and method for preparation of a hemodialysis solution optionally containing bicarbonate

Also Published As

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GB2084484B (en) 1984-08-22
GB2084484A (en) 1982-04-15
AU7176881A (en) 1981-11-26
IT8148421A0 (it) 1981-05-08
JPS57500565A (it) 1982-04-01
WO1981003180A1 (en) 1981-11-12
SE8200109L (sv) 1982-01-11
IT1170954B (it) 1987-06-03
EP0051659A1 (en) 1982-05-19
CA1166966A (en) 1984-05-08

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