CN212521772U - Device for monitoring dynamic change of blood ionized calcium in real time on line and used for CRRT (continuous room temperature recovery) device - Google Patents

Abstract

The utility model relates to the field of medical equipment, especially, relate to a device and CRRT device that can be used to CRRT's online real-time supervision blood ionized calcium dynamic change. The utility model provides a can be used to CRRT's online real-time supervision blood ionized calcium dynamic change's device, including the electrode body, be equipped with liquid channel, working electrode inner chamber, reference electrode inner chamber and temperature electrode inner chamber on the electrode body. The utility model provides a can be used to CRRT's online real-time supervision blood ion calcium dynamic change's device can the ionic calcium concentration in the flowing liquid of real-time supervision, and this electrode can be in the fluid steady operation, has shorter reaction time, has higher selectivity to calcium ion, and measuring result does not receive the velocity of flow, solution pH value to influence, compares the bias less with the clinical iSSTAT blood gas analysis appearance of using always at present, can provide online real-time blood ion calcium concentration monitoring.

Description

Device for monitoring dynamic change of blood ionized calcium in real time on line and used for CRRT (continuous room temperature recovery) device

Technical Field

The utility model relates to the field of medical equipment, especially, relate to a device and CRRT device that can be used to CRRT's online real-time supervision blood ionized calcium dynamic change.

Background

Safe and effective anticoagulation is a key and technical difficulty for blood purification, and is particularly prominent in long-term continuous renal replacement therapy. Regional Citrate Anticoagulation (RCA) has been shown to have an effective in vitro anticoagulation method that avoids prolonged exposure to heparin for continuous renal replacement therapy. RCA can reduce the incidence of bleeding associated with dialysis, increase the service life of the dialyzer, and improve the biocompatibility of the dialyzer. Although RCA has many advantages, there are still many technical limitations and difficulties in clinical practice application, which hinder its popularization. The technical key in RCA implementation is how to identify the appropriate citric acid and calcium infusion rates to maintain the circulating ionized calcium concentration in vivo and in vitro within the appropriate, narrow therapeutic target range. Currently, the most commonly used method for RCA per unit administration is the so-called "trial and error" method, in which the ionized calcium concentration in the patient's in vivo and in vitro circulation is maintained within a target range (around 1.1 and 0.3mM/L, respectively) by frequently monitoring (usually every 0.5-2 hours) the ionized calcium concentration in the patient's in vivo and in vitro circulation and adjusting the calcium supplementation and citric acid infusion rates in time. The method has the advantages that the cost of manpower (at least one experienced nurse and a doctor familiar with the RCA principle is required to be on site for 24 hours) and material resources (at least 2 ionized calcium monitoring times per hour, 80 yuan each time or 2000-3000 yuan each day) is huge, and special monitoring equipment (an iSTAT biochemical instrument, each equipment is 10-15 ten thousand yuan each time) is required, so that the CRRT process is undoubtedly more complicated, the economic burden of a patient and the burden of medical care personnel are increased, and the wide application of RCA-CRRT in clinic is limited.

Ion-selective electrodes are currently the most commonly used laboratory method for the in vitro detection of ionic calcium. The principle of the method is potential analysis, and the potential analysis consists of a working electrode, a reference electrode, a temperature electrode and a signal output device. It can sensitively and specifically respond to the change of the concentration of ionized calcium in the liquid, and the ion concentration is calculated according to the Nernst equation.

Electrodes of conventional construction currently exist: activating for 2-4 days; the zero points are inconsistent, and each electrode needs to be calibrated; the influence of the temperature on the active film is inconsistent, so that the temperature compensation curve is not uniform and the like. In order to realize the monitoring of dynamic plasma calcium without activation, calibration, quick installation, batch production, safety and reliability, the prior art is lack of and cannot realize real-time online monitoring of blood samples, thereby limiting the application of the dynamic plasma calcium in clinic.

SUMMERY OF THE UTILITY MODEL

In view of the above-mentioned shortcomings of the prior art, the present invention is directed to a device for online real-time monitoring of dynamic changes of ionized calcium in blood, which can be used in CRRT, and is used for solving the problems in the prior art.

In order to achieve the above and other related objects, one aspect of the present invention provides a device for monitoring dynamic changes of blood ionized calcium in real time on line, which can be used for CRRT, and comprises an electrode body, wherein the electrode body is provided with a liquid channel, a working electrode inner cavity, a reference electrode inner cavity and a temperature electrode inner cavity;

the working electrode inner cavity extends to the liquid channel, a membrane electrode is arranged between the working electrode inner cavity and the liquid channel, and working electrode inner liquid and a working electrode are arranged in the working electrode inner cavity;

the reference electrode inner cavity comprises a first electrode inner cavity and a second electrode inner cavity, a first separating membrane is arranged between the first electrode inner cavity and the second electrode inner cavity, the second electrode inner cavity extends to the liquid channel, a second separating membrane is arranged between the second electrode inner cavity and the liquid channel, a reference electrode stationary phase and a reference electrode are arranged in the first electrode inner cavity, liquid in the reference electrode and a microporous fiber rod are arranged in the second electrode inner cavity, and the microporous fiber rod extends to the first electrode inner cavity;

the temperature electrode inner cavity extends to the liquid channel, a heat conduction film is arranged between the temperature electrode inner cavity and the liquid channel, and a temperature monitoring device is further arranged in the temperature electrode inner cavity.

In some embodiments of the present invention, the liquid passage extends straight, and the diameter of the cross section of the liquid passage is 4.5 to 5.5 mm.

In some embodiments, the membrane electrode comprises a first gasket, an active membrane and a second gasket stacked in sequence, wherein the first gasket is located on one side of the liquid channel, and the second gasket is located on one side of the working electrode cavity.

In some embodiments of the present invention, the material of the first gasket and/or the second gasket is a silicone, the active film comprises an active substance, preferably, the active substance is selected from an organic phosphate, more preferably, the organic phosphate is selected from bis [4- (1,1,3, 3-tetramethylbutylphenyl) calcium phosphate, the thickness of the first gasket is 0.27 to 0.33mm, the thickness of the active film is 0.27 to 0.33mm, and the thickness of the second gasket is 0.27 to 0.33 mm.

In some embodiments of the present invention, the working electrode internal solution is selected from a calcium chloride aqueous solution, and the working electrode is selected from an Ag/AgCl wire.

The utility model discloses in some embodiments, the volume of working electrode inner chamber is 4.5 ~ 5.5ml, the working electrode inner chamber is the cylindricality, and preferably is cylindrical, and the diameter of cavity cross section is 7.2 ~ 8.8 mm.

In some embodiments of the present invention, the material of the first separation membrane and/or the second separation membrane is selected from silica gel, and the thickness of the first separation membrane and/or the second separation membrane is 3.6 to 4.4 mm.

In some embodiments of the present invention, the reference electrode stationary phase is selected from potassium chloride gel, the reference electrode inner solution is selected from potassium chloride aqueous solution, the length of the microporous fiber rod is 9.5-10.5 mm, the diameter of the cross section is 0.85-0.95 mm, the aperture is 0.28-0.32 mm, and the reference electrode is selected from Ag/AgCl line.

The utility model discloses in some embodiments, the volume of first electrode inner chamber is 4.5 ~ 5.5ml, first electrode inner chamber is the cylindricality, and preferably is cylindrical, and the diameter of cavity cross section is 7.2 ~ 8.8 mm.

The utility model discloses in some embodiments, the volume of second electrode inner chamber is 4.5 ~ 5.5ml, second electrode inner chamber is the cylindricality, and preferably is cylindrical, and the diameter of cavity cross section is 7.2 ~ 8.8 mm.

In some embodiments of the present invention, the material of the heat conductive film is selected from heat conductive silica gel.

In some embodiments of the invention, the temperature monitoring device is selected from a thermistor.

In some embodiments of the present invention, the volume of the inner cavity of the temperature electrode is 48-58 mm²The inner cavity of the temperature electrode is cylindrical, preferably cylindrical, and the diameter of the cross section of the cavity is 2.8-3.4 mm.

The utility model discloses in some embodiments, still include joint and wire, the wire is connected with working electrode, reference electrode and temperature monitoring device electricity respectively, the joint is located liquid channel's both ends.

The utility model discloses in some embodiments, still include signal output device, signal output device is including the collection signal circuit, amplifier circuit and the display device that connect gradually, signal output device is connected with the wire electricity.

The utility model discloses another aspect provides a CRRT device, including CRRT device body, the artery end and/or the vein of the CRRT return circuit of CRRT device body serve and are connected with foretell device that can be used to CRRT's online real-time supervision blood ionized calcium dynamic change.

Drawings

Fig. 1 is a schematic overall view of the device for on-line real-time monitoring of dynamic change of blood ionized calcium, which can be used in CRRT of the present invention.

Fig. 2 is a schematic structural diagram of an apparatus for on-line real-time monitoring of dynamic change of blood ionized calcium, which can be used in CRRT of the present invention.

Fig. 3 is a schematic diagram of an in vitro simulation cycle according to an embodiment of the present invention.

Fig. 4 is a schematic view of a partial structure of a CRRT device according to the present invention.

Description of the element reference numerals

1 electrode body

2 liquid channel

3 working electrode cavity

31 film electrode

32 working electrode internal liquid

33 working electrode

4 reference electrode inner cavity

41 first electrode lumen

411 reference electrode stationary phase

412 reference electrode

42 second electrode lumen

421 reference electrode internal liquid

422 micropore fiber rod

43 first separating Membrane

44 second separator film

5 temperature electrode inner cavity

51 temperature monitoring device

52 Heat conduction film

6 conducting wire

7 external analog circulation device

71 peristaltic pump

72 solution to be detected

73 display device

74 sampling hole

8 terminal

9 joint

10 display device

Detailed Description

In order to make the objects, technical solutions and advantageous effects of the present invention more clear, the present invention will be further described in detail with reference to the following embodiments, and those skilled in the art can easily understand other advantages and effects of the present invention from the disclosure of the present specification.

The first aspect of the present invention provides a device for monitoring dynamic changes of blood ionized calcium in real time on line, which can be used in CRRT, as shown in fig. 1 and 2, the device can include an electrode body 1, wherein the electrode body 1 is provided with a liquid channel 2, a working electrode inner cavity 3, a reference electrode inner cavity 4 and a temperature electrode inner cavity 5;

the working electrode cavity 3 extends to the liquid channel 2, a membrane electrode 31 is arranged between the working electrode cavity 3 and the liquid channel 2, and working electrode inner liquid 32 and a working electrode 33 are arranged in the working electrode cavity 3;

the reference electrode inner cavity 4 comprises a first electrode inner cavity 41 and a second electrode inner cavity 42, a first separating membrane 43 is arranged between the first electrode inner cavity 41 and the second electrode inner cavity 42, the second electrode inner cavity 42 extends to the liquid channel 2, a second separating membrane 44 is arranged between the second electrode inner cavity 42 and the liquid channel 2, a reference electrode stationary phase 411 and a reference electrode 412 are arranged in the first electrode inner cavity 41, a reference electrode inner liquid 421 and a microporous fiber rod 422 are arranged in the second electrode inner cavity 42, and the microporous fiber rod 422 extends to the first electrode inner cavity 41;

the temperature electrode inner cavity 5 extends to the liquid channel 2, a heat conducting film 52 is arranged between the temperature electrode inner cavity 5 and the liquid channel 2, and a temperature monitoring device 51 is further arranged in the temperature electrode inner cavity 5. The utility model provides an among the device that can be used to CRRT's online real-time supervision blood ion calcium dynamic change, can be in the stable work of flowing crystal liquid, blood sample, have shorter reaction time, and have higher selectivity to calcium ion, the measuring result also does not receive velocity of flow, solution pH value to influence.

The utility model provides an among the online real-time supervision blood ion calcium dynamic change's that can be used to CRRT device, can include electrode body 1, electrode body 1 can be suitable mould material usually to can form suitable cavity structures in electrode body 1, in order to hold each part in the online real-time supervision blood ion calcium dynamic change's that can be used to CRRT device. For example, the material of the electrode body 1 may be a 3D printing material or the like, and may specifically be a photosensitive resin or the like.

The utility model provides an among the online real-time supervision blood ion calcium dynamic change's that can be used to CRRT device, can be equipped with liquid channel 2 on the electrode body 1, liquid channel 2 is used for flowing the liquid that waits to detect usually. The shape and size of the liquid channel 2 is generally matched to the flow rate of the liquid to be detected flowing through. For example, in the liquid channel 2, the flow rate of the liquid may be 20ml/min to 150ml/min, 20ml/min to 30ml/min, 30ml/min to 40ml/min, 40ml/min to 60ml/min, 60ml/min to 80ml/min, 80ml/min to 100ml/min, 100ml/min to 120ml/min, or 120ml/min to 150 ml/min; for another example, the cross-section of the liquid channel 2 may have a diameter of 4.5 to 5.5mm, 4.5 to 4.8mm, 4.8 to 5.2mm, or 5.2 to 5.5 mm. The direction of extension of the liquid channel 2 in the electrode body 1 can be adjusted by the person skilled in the art, for example, the liquid channel 2 can extend generally straight.

The utility model provides an among the online real-time supervision blood ion calcium dynamic change's that can be used to CRRT device, can be equipped with working electrode inner chamber 3 on the electrode body 1, working electrode inner chamber 3 is each part that is used for holding working electrode usually. The working electrode cavity 3 can extend to the liquid channel 2, and a membrane electrode 31 can be arranged between the working electrode cavity 3 and the liquid channel 2, so that the working electrode can be in proper contact with the liquid to be detected in the liquid channel 2. The shape and size of the working electrode inner cavity 3 can be adjusted for a person skilled in the art, for example, the volume of the working electrode inner cavity 3 can be 4.5-5.5 ml, 4.5-4.8 ml, 4.8-5.2 ml, or 5.2-5.5 ml, the working electrode inner cavity 3 can be cylindrical, preferably cylindrical, and the diameter of the cavity cross section is 7.2-8.8 mm, 7.2-7.5 mm, 7.5-7.8 mm, 7.8-8.2 mm, 8.2-8.5 mm, or 8.5-8.8 mm.

In the working electrode cavity 3, the membrane electrode 31 includes a first gasket, an active membrane, and a second gasket, which are sequentially stacked. The first gasket is positioned on one side of the liquid channel 2, can be contacted with liquid to be detected, and is used for reinforcing the active membrane and reducing the impact force of the fluid on the active membrane. Suitable types and sizes of gasket materials suitable for the working electrode will be known to those skilled in the art, for example, the first gasket material may typically be silicone or the like, and for example, the first gasket may have a thickness of 0.27 to 0.33mm, 0.27 to 0.29mm, 0.29 to 0.31mm, or 0.31 to 0.33 mm. The second gasket is located on one side of the working electrode cavity 3 and can be in contact with the working electrode internal liquid 32 for sealing the electrode cavity. Suitable types and sizes of gasket materials suitable for the working electrode will be known to those skilled in the art, for example, the second gasket material may typically be silicone or the like, and for example, the second gasket may have a thickness of 0.27 to 0.33mm, 0.27 to 0.29mm, 0.29 to 0.31mm, or 0.31 to 0.33 mm. The active membrane is typically located between the first pad and the second pad for sensing the ionized calcium concentration in the fluid, the active membrane is typically selectively responsive to calcium ions, and the relationship between the potential of the active membrane and the calcium ion content should be such that the Nernst equation is satisfied. Suitable active film species will be known to those skilled in the art, for example, the active film may generally include calcium ion actives (e.g., alkyl phenyl calcium phosphate, etc.), may also include plasticizers (e.g., phenyl dioctyl phosphate, etc.), high molecular weight polymers (e.g., PVC, etc.), and the like. The thickness of the active film may be 0.27 to 0.33mm, 0.27 to 0.29mm, 0.29 to 0.31mm, or 0.31 to 0.33 mm. The active substance can generally react specifically with calcium ions. Suitable active materials suitable for use in the active membrane of the working electrode should be known to those skilled in the art, for example, the active material may be an organophosphate or the like, and further for example, the organophosphate may be bis [4- (1,1,3, 3-tetramethylbutylphenyl) calcium phosphate or the like.

In this application, among the working electrode inner chamber 3, can be equipped with working electrode inner liquid 32 and working electrode 33, working electrode 33 main function makes ionic signal change into the signal of telecommunication and transmits to can detect the liquid that awaits measuring in the liquid passage 2. Suitable working electrode internal liquids 32 and working electrodes 33 suitable for working electrodes should be known to those skilled in the art, for example, the working electrode internal liquid 32 may be selected from an aqueous solution of calcium chloride, and the concentration of the solution may be 9.5 to 10.5mmol/L, 9.5 to 9.7mmol/L, 9.7 to 9.9mmol/L, 9.9 to 10.1mmol/L, 10.1 to 10.3mmol/L, or 10.3 to 10.5 mmol/L; for another example, the working electrode 33 may be an Ag/AgCl wire, etc., the Ag/AgCl wire may have a length of 27 to 33mm, 27 to 29mm, 29 to 31mm, or 31 to 33mm, and a diameter of 0.27 to 0.33mm, 0.27 to 0.29mm, 0.29 to 0.31mm, or 0.31 to 0.33 mm. In general, working electrode 33 may be electrically connected to a suitable lead 6 and may extend out of working electrode lumen 3 to deliver a detection signal to a signal output device.

The utility model provides an among the online real-time supervision blood ion calcium dynamic change's that can be used to CRRT device, can be equipped with reference electrode inner chamber 4 on the electrode body 1, reference electrode inner chamber 4 is each part that is used for holding the reference electrode usually. The reference electrode lumen 4 can include a first electrode lumen 41 and a second electrode lumen 42, and a first separator 43 can be disposed between the first electrode lumen 41 and the second electrode lumen 42 such that the reference electrode lumen 4 can be separated into the first electrode lumen 41 and the second electrode lumen 42. The second electrode lumen 42 may extend to the fluid channel 2, and a second separator 44 is provided between the second electrode lumen 42 and the fluid channel 2, so that the reference electrode may be brought into proper contact with the fluid to be detected in the fluid channel 2. Suitable materials and dimensions for the separation membrane of the reference electrode should be known to those skilled in the art, for example, the material of the first separation membrane 43 may be selected from silica gel and the like, and the thickness of the first separation membrane 43 may be 3.6 to 4.4mm, 3.6 to 3.9mm, 3.9 to 4.1mm, or 4.1 to 4.4 mm; for another example, the material of the second separating film 44 may be selected from silica gel, etc., and the thickness of the second separating film 44 may be 3.6 to 4.4mm, 3.6 to 3.9mm, 3.9 to 4.1mm, or 4.1 to 4.4 mm; the shape and size of the reference electrode inner cavity 4 should be adjustable for those skilled in the art, for example, the volume of the first electrode inner cavity 41 may be 4.5-5.5 ml, 4.5-4.8 ml, 4.8-5.2 ml, or 5.2-5.5 ml, the first electrode inner cavity 41 may be cylindrical, preferably cylindrical, and the diameter of the cavity cross section is 7.2-8.8 mm, 7.2-7.5 mm, 7.5-7.8 mm, 7.8-8.2 mm, 8.2-8.5 mm, or 8.5-8.8 mm; for another example, the volume of the inner cavity 42 of the second electrode may be 4.5 to 5.5ml, 4.5 to 4.8ml, 4.8 to 5.2ml, or 5.2 to 5.5ml, the inner cavity 42 of the second electrode may be cylindrical, preferably cylindrical, and the diameter of the cross section of the cavity may be 7.2 to 8.8mm, 7.2 to 7.5mm, 7.5 to 7.8mm, 7.8 to 8.2mm, 8.2 to 8.5mm, or 8.5 to 8.8 mm; for another example, the first electrode lumen 41 and the second electrode lumen 42 may extend in the same direction as a whole, so that the reference electrode lumen 4 may be cylindrical as a whole, and preferably, may be cylindrical.

In this application, the first electrode cavity 41 is provided with a reference electrode stationary phase 411 and a reference electrode 412, so that the reference electrode potential is stabilized. Suitable reference electrode internal solutions and reference electrodes should be known to those skilled in the art, for example, the reference electrode stationary phase 411 can be selected from potassium chloride gel and the like, wherein the concentration of potassium chloride can be a saturation concentration; for another example, the reference electrode may be selected from Ag/AgCl wire, etc., and the Ag/AgCl wire may have a length of 27 to 33mm, 27 to 29mm, 29 to 31mm, or 31 to 33mm, and a diameter of 0.27 to 0.33mm, 0.27 to 0.29mm, 0.29 to 0.31mm, or 0.31 to 0.33 mm. In general, the reference electrode may be electrically connected to a suitable lead 6 and may extend out of the first electrode lumen 41 to deliver a detection signal to a signal output device.

In this application, the second electrode inner cavity 42 is provided with a reference electrode inner liquid 421 and a microporous fiber rod 422, and the microporous fiber rod 422 extends to the first electrode cavity 41, so as to form a stable and continuous electronic loop. Suitable reference electrode internal liquids and microporous fiber rods suitable for reference electrodes should be known to those skilled in the art, for example, the reference electrode internal liquid 421 may be selected from potassium chloride aqueous solution and the like, and the concentration of the solution may be 3.5 to 4.0 mmol/L; for another example, the microporous fiber rod may allow the potassium chloride solution to slowly permeate outwards, the length of the microporous fiber rod 422 may be 9.5 to 10.5mm, 9.5 to 9.8mm, 9.8 to 10.2mm, or 10.2 to 10.5mm, the cross-sectional diameter may be 0.85 to 0.95mm, 0.85 to 0.88mm, 0.88 to 0.92mm, or 0.92 to 0.95mm, and the pore diameter may be 0.28 to 0.32mm, 0.28 to 0.29mm, 0.29 to 0.30mm, 0.30 to 0.31mm, or 0.31 to 0.32 mm. Generally, the second electrode chamber 42 is in communication with the first electrode chamber 41 via a microporous fiber rod, allowing for a slow continuous penetration of the potassium chloride solution.

The utility model provides an among the online real-time supervision blood ion calcium dynamic change's that can be used to CRRT device, can be equipped with temperature electrode inner chamber 5 on the electrode body 1, temperature electrode inner chamber 5 is each part that is arranged in detecting liquid passage 2 to detect the temperature of the liquid that waits to detect usually. The temperature electrode cavity 5 can extend to the liquid channel 2, and a heat conducting film 52 is arranged between the temperature electrode cavity 5 and the liquid channel 2, so that the heat conducting film 52 can be in proper contact with the liquid to be detected in the liquid channel 2, and heat can be transferred to the temperature monitoring device 51. The shape and size of the temperature electrode inner cavity 5 can be adjusted by those skilled in the art, for example, the volume of the temperature electrode inner cavity 5 can be 48-58 mm²、48～50mm²、50～52mm²、52～54mm²、54～56mm²Or 56 to 58mm²The inner cavity 5 of the temperature electrode can be cylindrical, preferably cylindrical, and the diameter of the cross section of the cavity can be 2.8-3.4 mm, 2.8-3.0 mm, 3.0-3.2 mm or 3.2-3.4 mm.

Suitable heat conducting film 52 and temperature monitoring device 51 suitable for detecting the temperature of the liquid to be detected in the liquid channel 2 are known to those skilled in the art, for example, the material of the heat conducting film 52 may be selected from heat conducting silica gel and the like, and the thickness of the heat conducting film 52 may be 0.27-0.33 mm, 0.27-0.29 mm, 0.29-0.31 mm, or 0.31-0.33 mm; for another example, the temperature monitoring device 51 may be selected from a thermistor, etc. Generally, the temperature monitoring device 51 may be electrically connected to a suitable lead 6, and the lead 6 may extend into the temperature electrode lumen 5 to transmit a detection signal to a signal output device.

The utility model provides an among the online real-time supervision blood ionized calcium dynamic change's that can be used to CRRT device, as shown in fig. 4, can also include the joint, the joint can be used for installing the online real-time supervision blood ionized calcium dynamic change's that can be used to CRRT device in suitable operating position. The connectors may be generally located at both ends of the liquid channel 2, the kind of the connectors may be adjusted by those skilled in the art, for example, the connectors may be luer connectors or the like.

The utility model provides an among the online real-time supervision blood ion calcium dynamic change's that can be used to CRRT device, can also include signal output equipment, signal output equipment can be generally including the signal acquisition circuit, amplifier circuit, the display device etc. that connect gradually, signal output equipment can be generally connected with 6 electricity on the wire to can be with passing through signal acquisition circuit collection data, and with signal transmission to display device through amplifier circuit. Suitable signal collectors, amplification circuits, display devices should be known to the person skilled in the art, for example the display device may be a display or the like.

The utility model discloses the second aspect provides a CRRT device, including CRRT device body, the artery end and/or the vein of the CRRT return circuit of CRRT device body are served and are connected with foretell device that can be used to CRRT's online real-time supervision blood ionized calcium dynamic change. On the CRRT device, the fluid to be detected is typically a blood sample. After the ionic calcium concentration is measured by the device, the collected signals can be output, and the readings can be displayed by an output device. After the device is used for continuous kidney replacement therapy by adopting RCA anticoagulation, the technical difficulty of RCA implementation can be obviously reduced, and the anticoagulation mode is easier to popularize, thereby bringing clinical benefit to more hemodialysis patients.

The utility model provides a can be used to CRRT's online real-time supervision blood ionized calcium dynamic change's device can the ionic calcium concentration in the flowing liquid of real-time supervision (crystal liquid, blood), this electrode can be in the fluid steady operation, has shorter reaction time, has higher selectivity to calcium ion, the measuring result is not influenced by the velocity of flow, solution pH value, it is less to compare the bias with the present clinical iSSTAT blood gas analysis appearance of using always, can provide online real-time blood ionized calcium concentration monitoring. In addition, the device has the characteristics of no activation, no calibration, quick installation, batch production, safety, reliability and the like, and has good industrialization prospect.

The following examples further illustrate the invention of the present application, but do not limit the scope of the present application.

Example 1

(1) Calcium ion exchange membrane composition and thermal processing:

calcium ion exchange membrane composition: contains 15mg of bis [4- (1,1,3, 3-tetramethylbutylphenyl) calcium phosphate, 400mg of dioctyl phenylphosphate, and 170mg of PVC. The thickness of the film is 0.3 mm.

Hot processing: the calcium ion exchange membrane is protected and clamped in the middle by a PP thin film material, and is placed in a hot rolling machine, the temperature is kept at 75 ℃,

hot pressing for eight times to make the film thickness uniform and ensure the uniform distribution of the active ingredients in the PVC plastic. (this procedure facilitates the uniformity of the calculated curves and the quantitative production)

(2) A calcium ion sensor:

the electrode mold is made by applying 3D printing technology, the printing material is photosensitive resin, and the printing appearance is as shown in figure 1. The electrode mould includes size 50mm 15mm 45mm cuboid, is equipped with the straight line on the length direction and extends the sample through-hole, and the aperture is on one side of the body of 4.85mm cuboid, is equipped with 1# hole, 2# hole, 3# hole, and the aperture is 8.3mm, 3.2mm respectively, and the interval between each hole is that each hole of 3mm all extends to the through-hole and communicates, and the extending direction all is perpendicular with the extending direction of through-hole.

A working electrode: and sequentially adding a gasket with the thickness of 0.3mm, an active membrane and a gasket with the thickness of 0.3mm into the hole No. 1, extending the three-layer structure to the bottom of the hole No. 1, wherein the diameters of the sections of the gasket and the active membrane are basically the same as the diameter of the hole No. 1, and fixing the film pressing structure by using a screw member with the length of 10mm and M8. Adding 1ml polyurethane solid gel containing 0.01M CaCl2 and 0.1M sodium chloride, 0.3mm silver/silver chloride wire into the cavity, sealing with silica gel pad, adding epoxy resin, encapsulating, and leading out red tetrafluoro wire (in welding and connecting terminal)

Reference electrode: sequentially adding 8.1mm silica gel plugs (with the diameter of 8.1mm and the thickness of 3mm and the center penetrated by a 0.9mm microporous fiber rod), saturated potassium chloride solid gel, 8.1mm silica gel plugs (with the diameter of 8.1mm and the thickness of 3mm and the center penetrated by a 0.9mm microporous fiber rod), saturated potassium chloride gel solution, 0.3mm silver/silver chloride wires, sealing by using a silica gel pad, adding epoxy resin for encapsulation, and leading out yellow tetrafluoro wires (welded in a connecting terminal);

temperature electrode: in the No. 3 hole, NTC type thermistor is placed in 316L medical stainless steel shell and sealed by heat-conducting silica gel, and the tetrafluoro black line is led out (welding and wiring terminal is in)

The luer joint is bonded at the two ends by UV glue to obtain the complete electrode, and the luer joint has good universality with a continuous kidney replacement therapy pipeline. (the above-described sensor configuration facilitates the uniformity and quantitative production of the calculated curves)

(3) And (3) displaying data:

the electrode adopts an external instrument to receive signals and can display potential signals or calcium ion concentration. Meanwhile, the instrument has a simple programming function, and automatic multi-section curve compensation correction can be realized by inputting the slope and intercept of a standard curve and the temperature value. See the documentary for a schematic diagram of circuit transmission.

Example 2

Electrode detection

(1) In vitro simulation cycle establishment

A small peristaltic pump, PVC hose, beaker, three-way valve, etc. were used to construct an in vitro simulated closed cycle (see figure 3 for schematic). The beaker is a liquid to be tested, and the liquid to be tested can comprise crystalloid solution, blood and the like. The crystal liquid is calcium chloride solution, and the preparation method comprises the following steps: according to the concentration requirement, adding 10% calcium chloride solutions with different volumes into 0.15mmol/L sodium chloride solution to obtain calcium chloride solutions with different concentrations, wherein the concentration range of calcium ions is 0.01-3.00mmol/L, so as to meet the clinical detection requirement. The blood is whole blood from domestic pigs, common heparin is added in advance for full anticoagulation, the concentration is 5000IU/100ml whole blood, and calcium chloride solution is added according to the experiment requirement to adjust the ionized calcium concentration.

(2) Electrode detection process

The electrode was left standing overnight in 0.1mmol/L calcium chloride solution before electrode detection. After an in vitro simulation closed cycle is constructed, a small peristaltic pump is started to fill the pipeline with liquid, and whether bubbles are generated in the pipeline or not is observed. The electrode is provided with an external display screen which can display potential reading or ion concentration (automatic conversion after inputting slope and intercept). Because the temperature has great influence on the potential, the detection is carried out at room temperature, and the fluctuation of the room temperature is controlled to be less than 0.5 ℃. Data analysis was performed using SPSS 20.0 and medcalc13.5 statistical software. The continuous variable is described by adopting a mean value and a standard deviation, the standard curve is calculated by adopting a linear regression method, and the statistical methods are realized by adopting SPSS software. The Relative Standard Deviation (RSD) is equal to the standard deviation of multiple measurements of the same sample divided by the measurement mean, and is used to describe the accuracy of the electrode measurement.

When the electrode detects the crystal liquid, a standard curve is established by taking the logarithm of the concentration as the abscissa and the reading of the potential as the ordinate according to the known ionic calcium concentration of the solution. The specific results of the detection of the electrode in the crystal liquid are shown in the proved document, when the calcium ion concentration fluctuates between 0.01 and 3.00mmol/L, the electric potential shown by the electrode and the ionized calcium concentration satisfy Nernst reaction, namely, the logarithm of the electric potential and the ionized calcium concentration satisfy a linear relation (R)²0.9970) and a standard curve is established in this way. When the concentration of ionized calcium changes, the potential reading of the electrode begins to change after 1-2 seconds, and the reading is stable for about 5-6 seconds, particularly referring to a certificate, so that the electrode has short reaction time and can be monitored in real time.

In addition, tests were conducted on the characteristics of the electrodes, examining the effect of the effective working length of the electrodes, the reaction time, and the liquid flow rate, the solution pH, and the change in the concentration of magnesium and potassium ions on the potential readings.

When the effective working time of the detection electrode is long, taking calcium chloride solutions with lower concentration (0.1mmol/L) and higher concentration (1mmol/L) as liquids to be detected for detection respectively, recording potential readings every 15 minutes, and calculating the relative standard deviation between the recorded values after recording for 6 hours so as to analyze the stability of electrode detection. The effective working time of the electrode is measured, and the results are shown in the evidence document and table 1, the electrode can stably work in a lower concentration calcium chloride solution (0.1mmol/L) or a higher concentration calcium chloride solution (1.0mmol/L) for at least 6 hours, and the relative standard deviation among records is 0.29% (0.1mmol/L solution) or 0.24% (1.0mmol/L solution).

TABLE 1 differences recorded at different time points

Calcium chloride solutions of different concentrations	0.1mmol/L	1mmol/L
			Relative standard deviation of each record	0.29％	0.24％

When the influence of the flow rate on the potential reading is detected, 0.1mmol/L calcium chloride solution is used as the liquid to be detected, the flow rate is gradually increased to 110ml/min from 50ml/min according to 5ml/min, the reading is recorded, and the experiment is repeated for three times. Effect of flow rate on potential readings see in particular the evidence document that when the flow rate is gradually increased from 50ml/min to 110ml/min, the potential readings are hardly affected by the flow rate changes and the measurement results are not affected by the flow rate values.

When the influence of the pH value of the solution on potential reading is detected, 0.1mmol/L and 1mmol/L calcium chloride solutions are taken as liquids to be detected, concentrated hydrochloric acid or 1mol/L sodium hydroxide solution is respectively added to adjust the pH value of the solution, and the potential reading when the pH value of the solution fluctuates between 5 and 10 is recorded. Effect of solution pH change on potential readings see in particular the evidence document that when the solution pH is in the range of 5-10, the pH change has no significant effect on the electrode readings and the measurement results are not affected by the solution pH.

When the influence of the concentration of magnesium ions and potassium ions on potential reading is detected, a pre-prepared 1mol/L magnesium chloride solution and a pre-prepared 3.5mol/L potassium chloride solution are taken as liquid to be detected, added into a 0.1mmol/L calcium chloride solution to adjust the concentration of the magnesium ions and the potassium ions, wherein the concentration range of the magnesium ions is 0-1.25mmol/L, the concentration range of the potassium ions is 0-7mmol/L, and the potential reading is recorded. The influence of the concentration change of the magnesium ions and the potassium ions on the electrode reading is shown in a proved document, and the potential reading is not obviously influenced by adding the magnesium ions or the potassium ions into the calcium chloride solution, which shows that the selectivity of the electrode on the calcium ions is high.

After testing the characteristics of the electrode, selecting a calcium chloride solution with a known concentration as a liquid to be tested to test in an in vitro simulation cycle, repeatedly testing the solution with the same concentration for 5 times at an interval of 5 minutes every time, comparing the electrode reading with the known concentration, and analyzing the accuracy and precision of the electrode by calculating the ratio of the electrode result to the known concentration and the relative standard difference of the test result. Specific results are shown in table 2. As can be seen from Table 2, when the solution concentration is low, the relative error between different measurements is large, and as the solution concentration increases, the relative error gradually decreases; and the deviation of the measured result from the actual concentration is not more than 5%.

TABLE 2 continuous test results of different concentrations of solution electrodes

When the electrode is used for blood detection, an iSTAT blood gas analyzer (purchased from Yapei company) is used for measuring the ionized calcium concentration in whole blood, and a standard curve is established according to the ion concentration logarithm and the corresponding potential reading, and the result is shown in a certificate. Electrode potential and blood ionic calcium concentrationThe degrees also satisfy the linear relation (R)²0.9994), the slope was 20.91 ± 0.26 mV. And then, detecting ionized calcium with different concentrations in blood by using an electrode, adjusting the ionized calcium concentration by adding 10% (w/v) calcium chloride solution (0.9mol/L) into the whole blood intermittently, detecting the obtained liquid serving as liquid to be detected in an in-vitro simulation cycle, recording electrode reading, comparing the detection result of the in-vitro simulation cycle with an iSSTAT blood gas analyzer by using MedCalc software and adopting a Bland-altman method, drawing by using an iSSTAT detection result as an abscissa and using the percentage of the (iSSTAT result-electrode result)/iSSTAT result as an ordinate, and analyzing the deviation degree of the electrode detection and the iSSTAT result. See the results in the documentation. The linear regression showed that the electrode assay results were significantly linearly related to the iSTAT assay results (R²0.999); the bland-altman analysis showed that the mean bias between the electrode results and the iSTAT results was 0.9%, the maximum bias was 4.7%, and the 95% consistency margin was (-3.2%, 5.1%), indicating that the bias between the electrode results and the iSTAT results was less than 10%, which is a clinically acceptable error. Therefore, the electrode can accurately detect the concentration of ionized calcium in flowing blood, and has smaller deviation compared with the currently clinically common method for detecting ionized calcium.

To sum up, the utility model discloses various shortcomings in the prior art have effectively been overcome and high industry value has.

The above embodiments are merely illustrative of the principles and effects of the present invention, and are not to be construed as limiting the invention. Modifications and variations can be made to the above-described embodiments by those skilled in the art without departing from the spirit and scope of the present invention. Accordingly, it is intended that all equivalent modifications or changes which may be made by those skilled in the art without departing from the spirit and technical spirit of the present invention be covered by the claims of the present invention.

Claims (10)

1. A device for monitoring dynamic changes of blood ionized calcium in real time on line and capable of being used for CRRT is characterized by comprising an electrode body (1), wherein a liquid channel (2), a working electrode inner cavity (3), a reference electrode inner cavity (4) and a temperature electrode inner cavity (5) are arranged on the electrode body (1);

the working electrode inner cavity (3) extends to the liquid channel (2), a membrane electrode (31) is arranged between the working electrode inner cavity (3) and the liquid channel (2), and working electrode inner liquid (32) and a working electrode (33) are arranged in the working electrode inner cavity (3);

the reference electrode inner cavity (4) comprises a first electrode inner cavity (41) and a second electrode inner cavity (42), a first separating membrane (43) is arranged between the first electrode inner cavity (41) and the second electrode inner cavity (42), the second electrode inner cavity (42) extends to the liquid channel (2), a second separating membrane (44) is arranged between the second electrode inner cavity (42) and the liquid channel (2), a reference electrode stationary phase (411) and a reference electrode (412) are arranged in the first electrode inner cavity (41), reference electrode inner liquid (421) and a microporous fiber rod (422) are arranged in the second electrode inner cavity (42), and the microporous fiber rod (422) extends to the first electrode inner cavity (41);

the temperature electrode inner cavity (5) extends to the liquid channel (2), a heat conducting film (52) is arranged between the temperature electrode inner cavity (5) and the liquid channel (2), and a temperature monitoring device (51) is further arranged in the temperature electrode inner cavity (5).

2. The device for on-line real-time monitoring of blood ionized calcium dynamic change applicable to CRRT according to claim 1, wherein the liquid channel (2) extends straight, and the diameter of the cross section of the liquid channel (2) is 4.5-5.5 mm.

3. The device for on-line real-time monitoring of blood ionic calcium dynamics for CRRT according to claim 1, wherein the membrane electrode (31) comprises a first gasket, an active membrane and a second gasket stacked in sequence, the first gasket being located at one side of the liquid channel (2), and the second gasket being located at one side of the working electrode lumen (3).

4. The device for on-line real-time monitoring of plasma ionized calcium dynamic change of CRRT according to claim 3, wherein the thickness of the first pad is 0.27-0.33 mm, the thickness of the active membrane is 0.27-0.33 mm, and the thickness of the second pad is 0.27-0.33 mm.

5. The device for on-line real-time monitoring of blood ionic calcium dynamics for CRRT according to claim 1, wherein the working electrode is selected from Ag/AgCl wire;

the volume of the working electrode inner cavity (3) is 4.5-5.5 ml, the working electrode inner cavity (3) is cylindrical, and the diameter of the cross section of the cavity is 7.2-8.8 mm.

6. The device for on-line real-time monitoring of blood ionized calcium dynamic change applicable to CRRT according to claim 1, wherein the thickness of the first separation membrane (43) and/or the second separation membrane (44) is 3.6-4.4 mm;

the length of the microporous fiber rod is 9.5-10.5 mm, the diameter of the cross section of the microporous fiber rod is 0.85-0.95 mm, the aperture of the microporous fiber rod is 0.28-0.32 mm, and the reference electrode is selected from Ag/AgCl wires;

the volume of the first electrode inner cavity (41) is 4.5-5.5 ml, the first electrode inner cavity (41) is cylindrical, and the diameter of the cross section of the cavity is 7.2-8.8 mm;

the volume of the second electrode inner cavity (42) is 4.5-5.5 ml, the second electrode inner cavity (42) is cylindrical, and the diameter of the cross section of the cavity is 7.2-8.8 mm.

7. The device for on-line real-time monitoring of plasma calcium dynamics useful for CRRT according to claim 1, wherein the temperature monitoring device (51) is selected from the group consisting of a thermistor;

the volume of the inner cavity (5) of the temperature electrode is 48-58 mm²The inner cavity (5) of the temperature electrode is cylindrical, and the diameter of the cross section of the cavity is 2.8-3.4 mm.

8. The device for on-line real-time monitoring of blood ionized calcium dynamic change applicable to CRRT according to claim 1, further comprising a connector and a lead (6), wherein the lead (6) is electrically connected with the working electrode (33), the reference electrode (412) and the temperature monitoring device (51), respectively, and the connector is positioned at two ends of the liquid channel (2).

9. The device for on-line real-time monitoring of blood ionized calcium dynamic change applicable to CRRT according to claim 8, further comprising a signal output device, wherein the signal output device comprises a signal acquisition circuit, an amplification circuit and a display device which are connected in sequence, and the signal output device is electrically connected with the conducting wire (6).

10. A CRRT device, characterized in that, comprises a CRRT device body, the artery end and/or vein end of the CRRT loop of the CRRT device body is connected with the device for monitoring blood ionized calcium dynamic change on line and in real time of CRRT according to any claim 1 to 9.

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