US2946665A

US2946665A - Method and means for the determination of carbon dioxide in biological fluids

Info

Publication number: US2946665A
Application number: US612299A
Authority: US
Inventors: Leonard T Skeggs
Original assignee: Technicon Instruments Corp
Current assignee: Bayer Corp
Priority date: 1956-09-26
Filing date: 1956-09-26
Publication date: 1960-07-26
Anticipated expiration: 1977-07-26
Also published as: DE1236240B; FR1182716A; GB816815A

Description

July 26, 1960 Filed Sept. 26, 1956 L. T. SKEGGS METHOD AND MEANS FOR THE DETERMINATION OF CARBON DIOXIDE IN BIOLOGICAL FLUIDS FIGJ 2 Sheets-Sheet 1 INVENTOR. Leonard 7. S/reyys BY v- (BL ATTOR NEYS July 26, 1960 L. T. SKEGGS 2,946,665

METHOD AND MEANS FOR THE DETERMINATION OF CARBON DIOXIDE IN BIOLOGICAL FLUIDS Filed Sept. 26, 1956 2 Sheets-Sheet 2 PIC-3.3 211 ,22, 24 I 72 lemar/ Z' JA eyys ATTORNEYS te tt METHOD AND MEANS FOR THE DETERMINA- ON DIOXIDE IN BIOLOGICAL Leonard T. Skeggs, Cleveland, Ohio, assignor, by mesne' assignments, to Technicon Instruments Corporation,

Chauncey, N .Y., a corporation of New York Filed Sept. 26, 1956, Ser. No. 612,299 11 Claims. (01.23-230) Another object of the invention is to enable the quantitative analysis of blood in respect to the CO content thereof to be carried out under conditions appropriate to the demands of a busy hospital or biological laboratory.

A further object of the invention is to provide apparatus operable automatically to determine and record automatically in succession the quantity of CO in each of a series of different specimens.

The above and other objects, features and advantages of this invention will be apparent from or further explained in the following detailed description of the presently preferred mode of carrying out the present invention, reference being had to the accompanying illustrative drawings, in which:

Fig. 1 is a more or less diagrammatic view of apparatus embodying the present invention, and is illustrative of the method employed pursuant to this invention;

Fig. 2 is a view, partly in section, showing part of the apparatus;

Fig. 3 is a sectional view, on a larger scale, on the line 3-3 of Fig. 1;

Fig. 4 is a top plan view of apparatus for supplying a plurality of plasma samples successively to the apparatus illustrated in Fig. 1; and

Fig. 5 is a side view partly in section, of the supply device illustrated in Fig. 4.

The general procedure heretofore employed for blood analysis is Well described in Practical Physiological Chemistry, by Philip B. Hawk, Bernard L. Oser, and William H. Summerson, twelfth edition, published by The Blakiston Company, Philadelphia, Pa. Briefly and specifically in respect to the analysis for CO as there described the blood sample is centrifuged for separating the 1 action of an acid, such as heretofore used in known methods, for example lactic acid, sulphuric acid, etc., as a result of which the CO which is normally present in blood containing the same in a combined form, mainly,

i.e., about 95% of the CO in blood plasma, NaHCO is liberated in the form of a gas according to the follow- .ing equation when sulphuric acid is employed.

, 2,946,665 Patented July 26, 1960 In accordance with this present invention, gaseous pressure changes in accordance with the quantity of liberated CO in the sample under analysis are utilized for obtaining the quantitative CO indications. The manner in which this is accomplished pursuant to the present invention in its presently preferred form will now be described.

Referring to the. drawings, there is shown a pump 10 of the type which comprises resiliently compressible tubing acted upon by pressure rollers or the like to cause fluids to travel through the tubing in the direction 'of the length of the latter from a source of supply to a point of delivery. In Fig. 1, the resiliently compressible tubing, preferably Tygon tubing, which automatically regains its shape or expanded condition upon release of external pressure thereon, is designated by the

numerals

12, 14 and 16. This tubing, forming the fluid conduits of the pump it are disposed on a bed or platen 18 against which they are pressed progressively along their lengths in the direction of the arrows by rollers 20, carried 'by and extending between the endless sprocket chains 22 operated by the sprocket Wheels 24. The particular pump here shown is more fully described in the copending application of Andres Ferrari, -Jr., and Jack Isreeli, Serial No. 463,860, filed October 22, 1954, now Patent No. 2,865,303. It will be understood, however, that any .suitable proportioning pump may be used.

Thetube 12 is here shown connected to a flask 26 which may be considered as containing the sample of plasma of the blood to be analyzed while the

tubing

14 and 16 are shown connected to the flask 28 which may be considered as containing the acid employed for liberating the CO as described above. As here shown, the acid is supplied by two tubes 14 and-16 from flasks 28, but only one tube of the proper internal diameter is necessary, the two tubes being here shown only because the tubing employed is of the same diameter as the tubing 12 for the blood plasma, and it was considered convenient to use such tubing of a single size in the pump illustrated by Fig. l. The

tubings

12, 14 and 16 are joined at the junction 32 where the fluids pumped through said tubes meet and are delivered to a conduit chamber 34. Conduit 34 is preferably incompressible and non-expansible,

i4 and 16. The discharge end of conduit 34 is connected 7 to the inlet end of the resiliently flexible Tygon or other tube 36 of the pump 10. The fluids are discharged fromthe outlet end 37 of tube 36 and are discarded. Tube 36 must have a greater volumetric pumping capacity and have a greater diameter than the combined diameters of

tubes

12, 14 and 16 so that a vacuum is present in conduit chamber 34 during the operation of the apparatus. A partial vacuum or sub-atmospheric pressure in chamber 34 is necessary to achieve a rapid release o f'the carbon dioxide for increasing the gaseous pressure in said chamber according to the quantity of CO in the plasma. Preferably the vacuum should be about %.I

A manometer 38 is connected to conduit chamber 34 by a tube 40 which is non-compressible and non-expansible so that, like conduit 34, it remains constant in crossscctional area during the flow of the fluids through the apparatus. As illustrated in Fig. 2, the manometer comprises a plastic block 42 having

bores

44 and 46 drilled therein providing in effect a U-tube. Manometer liquid, for example mercury, is indicated at 48. An electrode 50 having a higher resistance than mercury is disposed in one arm of the manometer U-tube and extends vertically thereof, terminating in spaced relation to a companion electrode 52.

Electrodes

50 and 52 are in series with a source of electric voltage, here shown as a battery 54, and with a resistance 56 across which a voltage drop is developed for operating an electronic control device (not shown) of the recorder schematically illustrated at 58. As a recorder of the indicated type is well known and does not per se form part of the present invention, further description thereof is unnecessary. The stylus or pen of the recorder is schematically illustrated at 60. It will be understood that the stylus or pen 60 is caused to move in opposite directions as indicated by the arrow A, while the chart paper is moved in a transverse path as indicated by the arrow B, the chart paper being moved at a constant rate by a suitable motor conventionally included in a recorder while the excursion of the stylus 60 is determined by the voltage variations impressed on the terminals 62 under the control of the fluid pressureelectric manometer 38.

It is to be observed that the manometer is illustrated as of the closed end capillary mercury type with a substantially complete Torricellean vacuum above the liquid in arm 44 so that normally the mercury tends to rise in the arm 44 of the manometer tube. When the flow of fluids through conduit chamber 34 is induced by the operation of pump 10, the pressure communicated to the arm 46 of the manometer U-tube varies according to the quantity of C gas liberated from the blood when the acid pumped through the

tubes

14 and 16 encounter the blood at the junction point 32. The fluctuation in pressure of the resultant fluid containing liquid and gaseous CO is proportional to the CO content of the blood specimen and induces corresponding variations in pressure which are communicated to the manometer 38. The rise and fall of the mercury in the arm 44 of the manometer U-tube results in corresponding variations in the electric resistance of the electric circuit which includes the battery 54, so that corresponding voltage variations are impressed on the terminals 62 of the control apparatus of the recorder, and of course a record is obtained of these variations. Any other suitable pressure-responsive device may be used in lieu of manometer 38 for controlling an electrical signalling device for providing the signals to the recorder.

Fig. 2 is illustrative of the response of the apparatus. The three high points hl, h2, and k3 of the chart illustrated by way of example in Fig. 2 are representative of the quantitative response of the recorder according to three runs oftwo minutes duration each with three different NaHCO solutions of gradually increasing strength, with an interspaced run of distilled water in lieu of NaHCO of a duration of l or 2 minutes between successive two runs of NHHCOg. Cf course, these values are merely illustrative for explanatory purposes in describing the present invention.

The recorder may be calibrated in any suitable Way by the use of solutions of sodium bicarbonate in a series of known different concentrations.

it will be understood that a series of blood tests may be made in a very simple manner and at a comparatively rapid rate by intermittently pumping ditferent blood samples and the acid reagent to the junction 32 of the conduit 34, with intervening rinsing operations of the apparatus by applying distilled water to the tube 12, and if necessary, through the

acid supply tubes

12 and 14, or through the single acid supply tube when the pump is made to operate with one such tube.

It will be observed that it is not necessary to separately measure the quantity of blood plasma and the 4 quantity of acid, as the pump is automatically operative to supply the correct amount of acid in accordance with the quantity of blood pumped through the tube 12, said pump being inherently a proportioning pump according to the selected internal diameter of the tubing through which the blood plasma and acid flow, respectively.

In my U.S. application Serial No. 547,087, filed November 16, 1955, for Automatic Analyzing Apparatus, now Patent No. 2,879,141, there is shown a liquid feeding device for supplying a plurality of ditferent samples automatically to an analyzer; such feeding device may be provided in lieu of the flask 26 so that tube 12 will be supplied automatically with different samples of blood in succession and in spaced time relation when pump 10 is operated. Distilled water or other suitable fluid may be introduced into tube 12 automatically by said feed device to space the samples from each other as they flow through tube 12, and the recorder will antomatically record the CO contents of the different samples on the chart paper in clearly distinguishable relation on the latter. Thus, as illustrated by Figs. 4 and 5 the supply device comprises a turntable 64 provided with a plurality of wells 66 disposed laterally of each other in a circular row. The turntable 64 is rotated at a suitable speed by a shaft 68 in the direction of the arrow A (Fig. 4) and a sample pick-up tube 70 is pivotally mounted on a suitable stationary post 72 as indicated at 74 so that as table 64 turns the lower end of pick-up tube 70 moves in succession into and out of the several wells 66 to supply the samples seriatim to the tube of pump 10, taking the place of the single sample flask 26 shown in Fig. 1. It will be understood that the shaft 68 may be intermittently rotated by any suitable mechanism (not shown).

When the turntable is to be used it is advisable to make provision to compensate for loss of CO For this reason it is desirable to maintain an atmosphere containing a quantity of carbon dioxide comparable with the quantity thereof in alveolar air, i.e., a 5.5 percent carbon dioxide-air mixture from a suitable tank. For this purpose the supply device is provided with a hood 76 preferably formed of a suitable transparent plastic material. An opening 77 is provided in said hood to accommodate the movement of the pick-up tube 76 during the turning of the turntable 64. The carbon dioxideair mixture may be supplied to the hood by a tube 78 from a supply tank (not shown). Said hood is supported in stationary position over the turntable 64 in any suitable way as by the bracket arm 80 pivotally mounted on the post 72 as indicated at 82. The carbon dioxide air mixture may be allowed to flow continuously at a low rate into and out of the hood, and it will be understood that the flow of this mixture from the hood may occur without the provision of a special outlet opening inasmuch as a slight clearance will ordinarily exist between the skirt 84 of the hood and the peripheral edge 86 of turntable 64.

Although the invention has been described in detail with reference to the presently preferred mode of practicing the invention, it will be understood by those skilled in the art, in view of the present disclosure, that various changes and modifications may be made without departing from the spirit of the invention and the scope of the appended claims.

Having thus described my invention, what I claim and desire to secure by Letters Patent, is: i

1. Apparatus for analyzing a liquid for determining the presence therein of a substance which is capable of being liberated in gaseous form by the addition of a reagent to said liquid, comprising a conduit, pump means for elfecting a flow of the liquid and the reagent in predetermined proportions to a junction point at which reaction of said reagent with said substance occurs and which is in fluid-flow communication with said conduit and a flow of the resulting fluid through said conduit occurs, pump means connected to said conduit at said reaction point for providing sub-atmospheric pressure at said reaction point, said conduit having an enlarged part through which the fluids are transmitted by said first and last mentioned pump means, and pressure responsive means connected to said enlarged part of said conduit for indicating pressure changes therein during the flow of said fluid through said conduit and thereby indicating the quantity of the liberated gaseous substance 2. Apparatus for analyzing a liquid fordetermining the presence therein of a substance which is capable of being liberated in gaseous form by the addition of a reagent to said liquid, comprising a conduit, a proportioning pump for effecting a flow of the liquid and the reagent in predetermined proportions to a junction point at which reaction of said reagent with said substance occurs and which is in fluid-flow communication with said duit occurs, pump means connected to said conduit at said reaction point for providing sub-atmospheric pressure at said reaction point, said conduit having an enlarged part through which the fluids are transmitted by said first and last mentioned pump means, pressure responsive means connected to. said enlarged part of said conduit, electrical means operable under the control of said pressure responsive means for producing corresponding electric signals, and means operable under the control of said signals for indicating the pressure in said conduit and thereby indicating the quantity of the liberated gaseous substance.

3. Apparatus for analyzing a liquid for determining the presence therein of a substance which is capable of being liberated in gaseous form by the addition of a reagent to said liquid, comprising a conduit, a proportioning pump for eflecting a flow of the liquid and the reagent in predetermined proportions to a junction point at which reaction of said reagent with said substance occurs and which is in fluid-flow communication with said conduit and a flow of the resulting fluid through said conduit occurs, pump means connected to sad conduit at. said reaction point for providing sub-atmospheric pressure at said reaction point, said conduit having an enlarged part through which the fluids are transmitted by said proportioning pump, a manometer having one arm thereof connected to said enlarged part of said conduit, an electrically conductive liquid in said manometer, a resistance member extending longitudinally of the other arm of said manometer in contact with said'manometer liquid, a terminal in contact with said manometer liquid and spaced from said resistance, a terminal connected to said resistance member at a point remote from said first mentioned terminal member so that the resistance between said terminals varies in accordance with the level of liquid in said other arm of the manometer, and means operable in accordance with variations in said resistance for indicating change of pressure in said conduit and thereby indicating the quantity of the liberated gaseous substance.

4. A method of quantitatively analyzing a liquid for the presence therein of substance capable of being liberated therefrom in gaseous form, comprising forming a stream of said liquid in a conduit, adding a reagent thereto in a part of said conduit and providing sub-atmospheric pressure in said part of the conduit for causing said substance to be evolved from the liquid in gaseous form, and measuring the fluid pressure in said part of the conduit during the flow of said fluid therein.

5. A method of analyzing blood for the quantitative determination of carbon dioxide therein, comprising forming a stream of the plasma of said blood in a conduit, adding an acid thereto capable of liberating the carbon dioxide from the blood plasma in gaseous form in a part of said conduit and providing sub-atmospheric pressure in said part of the conduit, causing the resultant fluid comprising the blood plasma and the carbon dioxide in gaseous form to flow through said part of the conduit, and

measuring the fluid pressure in said part of the conduit. 6. A method of analyzing blood for the quantitative determination of carbon dioxide therein, comprising.

gaseous form to flow through said part of the conduit,

subjecting a fluid-pressure responsive device to the fluid pressure in said part of the conduit, and operating a recorder under the control of said fluid-pressure responsive device.

7. A method of quantitatively analyzing a liquid for the presence therein of substance capable of being liberated therefrom in gaseous form, comprising forming a stream of said liquid in a conduit, adding a reagent thereto in a part of said conduit and providing sub-atmospheric pressure in said part of the conduit for causing said substance to be evolved from the liquid in gaseous form, and disposing the resultant fluid in fluid pressure relation to a fluid pressure responsive device for measuring the fluid pressure of said resultant fluid.

8. A method of quantitatively analyzing a liquid for the presence therein of substance capable of being liberated therefrom in gaseous form, comprising forming a stream of said liquid in a conduit, adding a reagent thereto in a part of said conduit and providing sub-atmospheric pressure in said part of the conduit for causing said substance to be evolved from the liquid in gaseous form, and disposing the resultant fluid in fluid pressure relation to a fluid-pressure responsive device, and operating a sive device.

9. A method of analyzing a series of blood plasma specimens for the quantitative determination of carbon di-' oxide in said specimens, respectively, comprising flowing each specimen through a conduit, one after another in time spaced relation, adding an acid to each specimen in a part of said conduit and providing sub-atmospheric pressure in said part of the conduit while it flows so as to liberate the carbon dioxide therefrom in gaseous form without interrupting the flow of the resultant fluid in the conduit, and subject a fluid-pressure responsive means to the pressure of said resultant fluid of each specimen for measuring the latter as an indication of the carbon dioxide therein.

10. Apparatus for analyzing a liquid for determining the presence therein of a substance which is capable of being liberated in gaseous form by the addition of a reagent to said liquid, comprising a reaction conduit for said liquid and reagent, pump means for transmitting said liquid and said reagent through said conduit, said conduit having a part of enlarged cross section, pressure responsive means connected to said enlarged part of said conduit for indicating change in pressure therein inresponse to the eflect of the addition of said reagent to the liquid,

means including a plurality of wells for supplying a pluconduit having a palt of enlarged cross section, pressure responsive means connected to said enlarged part of said conduit for indicating change in pressure therein in response to the eifect of'the addition of said reagent to the liquid, means including a plurality of wells for supplying 1,731,563 Crowley Oct. 15, 1929 1,742,87 1 North Ian. 7, 1930 pp 709.715,

8 Rosecrans May 8, 1934 Douglass et a1. Sept. 10, 1935 Brown et a1. Apr. 13, 1948 Monroe May 10, 1955 Donald Aug. 14, 1956 King et a1. Dec. 11, 1956 Skeggs June 25, 1957 OTHER REFERENCES Hawk et 211.: Practical Physio. Chem, 13th ed., 1954,

Claims

1. APPARATUS FOR ANALYZING A LIQUID FOR DETERMINING THE PRESENCE THEREIN OF A SUBSTANCE WHICH IS CAPABLE OF BEING LIBERATED IN GASEOUS FORM BY THE ADDITION OF A REAGENT TO SAID LIQUID, COMPRISING A CONDUIT, PUMP MEANS FOR EFFECTING A FLOW OF THE LIQUID AND THE REAGENT IN PREDETERMINED PROPORTIONS TO A JUNCTION POINT AT WHICH REACTION OF SAID REAGENT WITH SAID SUBSTANCE OCCURS AND WHICH IS IN FLUID-FLOW COMMUNICATION WITH SAID CONDUIT AND A FLOW OF THE RESULTING FLUID THROUGH SAID CONDUIT OCCURS, PUMP MEANS CONNECTED TO SAID CONDUIT AT SAID REACTION POINT FOR PROVIDING SUB-ATMOSPHERIC PRESSURE AT SAID REACTION POINT, SAID CONDUIT HAVING AN ENLARGED PART THROUGH WHICH THE FLUIDS ARE TRANSMITTED BY SAID FIRST AND LAST MENTIONED PUMP MEANS, AND PRESSURE RESPONSIVE MEANS CONNECTED TO SAID ENLARGED PART OF SAID CONDUIT FOR INDICATING PRESSURE CHANGES THEREIN DURING THE FLOW OF SAID FLUID THROUGH SAID CONDUIT AND THEREBY INDICATING THE QUANTITY OF THE LIBERATED GASESOUS SUBSTANCE.

4. A METHOD OF QUANTITATIVELY ANALYZING A LIQUID FOR THE PRESENCE THEREIN OF SUBSTANCE CAPABLE OF BEING LIBERATED THEREFORM IN GASEOUS FORM, COMPRISING FORMING STREAM OF SAID LIQUID IN A CONDUIT, ADDING A REAGENT THERETO IN A PART OF SAID CONDUIT AND PROVIDING SUB-ATMOSPHERIC PRESSURE IN SAID PART OF THE CONDUIT FOR CAUSING SAID SUBSTANCE TO BE EVOLVED FROM THE LIQUID IN GASEOUS FORM, AND MEASURING THE FLUID PRESSURE IN SAID PART OF THE CONDUIT DURING THE FLOW OF SAID FLUID THEREIN.