The present invention relates to a pipette tip and a pipette system for collecting capillary blood, more particularly, relates to a pipette tip for collecting capillary blood and a pipette system, capable of securing a sufficient plasma amount required for immunoassay, satisfying various collection sample amounts required for immunoassay with one pipette tip, reducing errors in immunoassay by providing a sufficient reaction amount, and moving without contamination for immunoassay when necessary.
The immunoassay equipment measures the concentration of a specific biomarker protein in the plasma or serum of a person, and may use venous blood extracted from the arm of a person in case of cardiovascular disease as a measurement sample and capillary blood extracted from the tip of a person in case of diabetes and infectious virus measurement as a measurement sample.
When venous blood is used, 5 mL or more of blood for measurement should be sampled even though the amount of blood to be actually used is sufficient only in tens to hundreds of µL, and there are problems in that automatic sampling is possible only when several mL of blood are contained in a blood tube in an automated device, in the case of infants and patients who have difficulty in collecting blood due to deep blood vessels, there are psychological distress of collecting blood and difficulty in collecting blood itself, it is difficult to collect an appropriate sample amount unless they are skilled, and convenience of use decreases.
Meanwhile, when capillary blood is used, the user may collect blood using a finger tip only as much as the amount of blood actually used for measurement, but it is difficult to check whether the amount of collected blood is as much as desired, and since the user does not know how much the amount of blood collected by the finger tip is, it is difficult to accurately discharge a sample amount to a desired position of a cartridge well.
As described above, even when capillary blood is used, the finger tips should be used separately according to the amount of blood required, and there is a problem in that an appropriate amount of samples is not guaranteed when centrifuging to obtain plasma, and accordingly, there is a problem in that an accurate result value cannot be provided.
Further, in the immunoassay equipment, it is difficult to stably and simply couple the pipette tip for collecting capillary blood to the cartridge when loading/unloading the syringe quantitative tip.
In addition, in the case of the conventional pipette tip for collecting capillary blood, there is a problem in that a sample used when being mounted on a cartridge is contaminated or equipment is contaminated by the sample.
As shown in
As shown in
That is, in the case of using capillary blood, it is impossible to extract an appropriate amount of plasma required for various immunoassays, and when the desired sample amount is properly sampled and coupled to a cartridge of an immunoassay device, there are still problems of specimen contamination and surrounding contamination, and it is difficult to couple to the cartridge.
The present invention has been made in an effort to provide a pipette tip and a pipette system for collecting capillary blood capable of guaranteeing a desired collection amount of blood and accurately discharging a collected sample to remove an error of measurement.
An exemplary embodiment of the present invention provides a pipette tip and a pipette system for collecting capillary blood capable of improving the accuracy of measurement by installing a membrane filter in a pipette tip for collecting capillary blood so that, when the pipette tip is mounted on a cartridge, plasma in blood is separated by the membrane filter by a plunger in a cartridge well, and thus, the plasma may be used by a quantitative suction in an immunoassay device.
Another embodiment of the present invention provides a pipette tip and a pipette system for collecting capillary blood capable of providing convenience and simplicity of use by easily sampling capillary blood using the capillary blood even by an unskilled user.
Yet another embodiment of the present invention provides a pipette tip and a pipette system for collecting capillary blood that can be used in various tests with a single pipette tip because various sample amounts can be covered with the single capillary pipette tip even if a desired amount of blood sample is changed.
Still another embodiment of the present invention provides a pipette tip and a pipette system for collecting capillary blood, which allow easy cartridge mounting and separation, can provide a structure allowing easy storage and movement by sealing an aluminum thin film and a storage tube thermally fused to the upper end of a sample collecting unit when mounting in a storage tube, and can enable a quantitative analysis to be performed by a quantitative syringe in an immunoassay device through the aluminum thin film.
A pipette tip for collecting capillary blood according to an exemplary embodiment of the present invention includes: a sampling unit having a capillary tube with a first diameter for sampling capillary blood; a sample storage unit having a first extension end formed from the end of the capillary tube of the sampling unit so as to have a larger area than the sampling unit; a sealing unit closely adhered to a distal opening of the sample storage unit so as to be broken by a quantitative syringe introduced from the outside; and a handle unit having a shielding wall surrounding the circumference of the sealing unit so as to prevent the sample from splashing from the sample storage unit to the outside when the sealing unit is broken by the quantitative syringe, and which is held by a user so as for sampling a sample by using the sampling unit.
The pipette tip for collecting capillary blood according to a modified exemplary embodiment of the present invention may further include a filter unit accommodated in a front end of the sample storage unit, absorbing and storing the capillary blood along a first extension end of the sampling unit, separating the capillary blood into red blood cells and plasma when being pressurized through a front end opening of the sampling unit, and storing the plasma in the sample storage unit.
The sample storage unit may include: a tubular body; an air-discharge hole which is formed on the upper side of the body and from which air is discharged when the sealing unit is broken; and an insertion-fitting and coupling unit for insertion-fitting coupling with respect to a cartridge for immunoassay or a storage tube for accommodating the sampling unit and the sample storage unit along the outer circumferential part of the upper end of the body.
The filter unit may include a porous membrane for separating the red blood cells and the plasma by a pressure equal to or greater than a predetermined pressure, and an upper surface of the filter unit may be treated so that the sample stored in the sample storage chamber may not move downward by gravity.
The sample storage unit may have a second diameter larger than the first diameter of the capillary tube and a length of 50% to 80% of the length of the capillary tube, the second diameter may facilitate the movement of the quantitative syringe, and the sealing unit may be made of aluminum foil and coupled to the bottom of the sample storage chamber by thermal fusion. The storage tube may include: a tube main body having one end blocked, the tube main body accommodating the sampling unit and the sample storage unit; an inner circumferential insertion-fitting and coupling unit formed in an inner circumferential part of the tube main body in order to insertion-fitting couple the tube main body with respect to a lower part of a handle unit of the pipette tip; and a support flange supporting a second extension end of the handle unit.
According to another embodiment of the present invention, the capillary blood pipette tip system may include: a pipette tip for collecting capillary blood, including a sampling unit having a capillary tube having a first diameter so as to sample a capillary blood, a sample storage unit having a first extension end formed from a distal end of the capillary tube of the sampling unit so as to have a larger area than the sampling unit, a sealing unit closely adhered to a distal opening of the sample storage unit and broken by a quantitative syringe introduced from the outside, a shielding wall surrounding the sealing unit to prevent the sample from splashing from the sample storage unit to the outside when the sealing unit is broken by the quantitative syringe, and a handle unit which is held by a user to sample using the sampling unit; an immunoassay cartridge having at least one pipette tip mounting well having a plunger that presses a sample of a sampling unit of the pipette tip from the bottom to the top when the pipette tip is coupled to the top; and a quantitative syringe for quantitatively sampling the capillary blood collected in the upper part thereof by approaching through the upper part of the pipette tip, when the capillary blood from the sampling unit is collected in the upper part by the pressurization of the plunger during the coupling of the pipette tip to the immunoassay cartridge.
The modified capillary blood pipette tip system according to another embodiment of the present invention may further include a filter unit accommodated in a front end of the sample storage unit, absorbing and storing the capillary blood along a first extension end of the sampling unit, separating the capillary blood into red blood cells and plasma when being pressurized through a front end opening of the sampling unit, and storing the plasma in the sample storage unit.
The storage tube may include a label unit provided on an outer wall of a tube body in a form of a barcode, the plunger may integrally protrude from a bottom of the pipette tip mounting well in a form of a bar or a rod, the plunger may include a bar or a rod and a support plate formed at a lower part of the bar or the rod, the plunger may be detachably installed at the bottom of the pipette tip mounting well, and a length of the bar or the rod may be variable.
A pipette tip and a pipette system for collecting capillary blood according to an exemplary embodiment of the present invention can guarantee a desired collection amount of blood and can accurately discharge a collected sample, thereby removing an error of measurement.
Further, in the pipette tip and a pipette system for collecting capillary blood according to an exemplary embodiment of the present invention, when the pipette tip is mounted on a cartridge, even a small amount of blood in a sampling unit is pressed by a plunger in a cartridge well so that a quantitative amount of blood may be sucked in from the immunoassay device and used, thereby minimizing a sample collecting volume error, and performing a quantitative suction operation by using a syringe pump, thereby improving measurement accuracy.
In addition, a pipette tip for collecting capillary blood and a pipette system according to an exemplary embodiment of the present invention may improve the accuracy of measurement by installing a membrane filter in the pipette tip for collecting capillary blood so that, when the pipette tip is mounted in a cartridge, plasma in blood is separated by the membrane filter by a plunger in a cartridge well, and thus, the plasma may be used by a quantitative suction in an immunoassay device.
A pipette tip and a pipette system for collecting capillary blood according to an exemplary embodiment of the present invention may provide convenience and convenience of use by easily sampling capillary blood using the capillary blood even by an unskilled user.
Further, a pipette tip and a pipette system for collecting capillary blood according to an exemplary embodiment of the present invention may cover various sample amounts with one capillary blood pipette tip even if a desired blood sample amount is changed, and thus one pipette tip may be used for various tests.
A pipette tip and a pipette system for collecting capillary blood according to an exemplary embodiment of the present invention may allow a cartridge to be easily mounted and detached, may provide a structure facilitating storage and movement by sealing an aluminum thin film and a storage tube thermally fused to the upper end of a sample collecting unit when being mounted on the storage tube, and may perform quantitative analysis by a quantitative syringe in an immunoassay device through the aluminum thin film.
In the following detailed description, only certain exemplary embodiments of the present invention have been shown and described, simply by way of illustration. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. Accordingly, the drawings and description are to be regarded as illustrative in nature and not restrictive. Like reference numerals designate like elements throughout the specification.
Throughout the specification, when a part “includes” a component, this means that other components may be further included, rather than excluding other components, unless specifically stated otherwise.
Hereinafter, a pipette tip and a pipette system for collecting capillary blood according to an exemplary embodiment of the present invention will be described in detail with reference to the accompanying drawings.
As shown in
The handle unit 110, the sample storage unit 120, and the sampling unit 130 may be integrally formed with each other, may be made of glass or plastic, may be preferably made of a transparent material, and may be preferably made of a material having high rigidity so as not to cause a shape change due to an external force.
The sampling unit 130 includes a long capillary tube 131 formed in a longitudinal direction thereof to introduce a sample, and the capillary tube 131 may be made of a hydrophilic material for an effective capillary phenomenon or an inner circumferential surface of the capillary tube 131 may be coated with a hydrophilic thin film.
The capillary tube 131 is formed to penetrate the sampling unit 130 in the longitudinal direction thereof, and stores the sample, that is, the capillary blood, by a capillary phenomenon, such that it is preferably anticoagulated, and the sampling capacity may be about 5 µl to 100 µl.
The diameter P1 of the capillary tube 131 may be determined within a range in which a sample may be sampled by a capillary phenomenon, and may be preferably determined at about 0.5 mm to 1.5 mm to maximize a capillary phenomenon of the capillary tube 131.
Meanwhile, in the present invention, the cross-sectional shape of the capillary may be variously modified in consideration of the sampling capacity. For example, in order to increase the sampling capacity, the length L1 of the sampling unit 130 should be increased, but in the present invention, the size of the cross-section of the capillary tube may be increased for a large sampling capacity.
In the pipette tip 100 according to an exemplary embodiment of the present invention, a sufficient sampling capacity required may be determined by the volume of the capillary tube 131 of the sampling unit 130. That is, the volume of the capillary tube 131 is determined by the cross-sectional area and the length L1 of the capillary tube 131, and the sampled sample fills the capillary tube 131 below the extension end 121 by a capillary phenomenon. The sample storage unit 120 has a hollow tubular shape, and forms a sample storage chamber 122 which communicates with the capillary tube 111 with a first extension end 121 discontinuously extending therefrom to store a sample, and has a second diameter D2 larger than the first diameter D1 of the capillary tube 131.
Although the second diameter D2 is larger than the first diameter D1 of the capillary tube 131, the quantitative syringe 1 may be freely moved up and down and the length L2 of 50% to 80% of the length L1 of the capillary tube 131 may be preferably set to have a predetermined height with respect to a minimum sample amount of 5 µl so that the sample moved from the capillary tube 131 to the sample storage unit 120 by the quantitative syringe 1 may be easily sampled.
Although the first extension end 121 has a right angle with respect to the capillary tube 131, it can be confirmed that when the inclination angle θ is 45° or more, the capillary tube 131 is filled with a liquid sample sampled by a capillary phenomenon, and the inclination angle θ may be 90° or more.
In Table 1, it was tested whether each of the 100 pipette tips 100 according to an exemplary embodiment of the present invention is filled into the sample storage unit 120 by passing through the capillary tube 131 and the first extension end 121 by varying the inclination angle θ of the first extension end 121.
95 or more of the 100 pipette tips 100 are marked as being good when the sample storage chamber 122 is filled with the capillary blood by passing through the capillary tube 131 and the first extension end 121.
The sample storage chamber 122 is formed to penetrate the center of the sample storage unit 120, and may ensure a sufficient amount of blood collection even when the capillary tube 131 is not too long due to a capillary phenomenon along the first extension end 121. As shown in
When the sample sampled by the capillary tube 131 is capillary blood, the filter unit 150 may filter red blood cells, platelets, and the like, and store the plasma in the sample storage chamber 122.
The filter unit 150 may have a disk shape having a second diameter D2 so as to be insertedly coupled to the sample storage chamber 122, and may serve as a stopper to restrict movement of a plunger fixed to a bottom of a cartridge well, which will be described later.
The filter unit 150 may be formed of a porous membrane that absorbs and stores the capillary blood and moves only the plasma by pressure equal to or greater than a predetermined pressure, and the top surface of the filter unit 150 may be treated so as to prevent gravity movement of the plasma stored in the sample storage chamber 122.
The handle unit 110 having the second extension end 111 formed at the upper end of the sample storage chamber 122 may be luer lock assembled to one of the immunoassay cartridge wells, and the insertion-fitting and coupling unit 125 may be formed at the outer circumferential part of the sample storage unit 120 under the second extension end 111 so as to be insertion-fitting coupled to the upper end of the cartridge well.
The handle unit 110 may have a hollow shape having a predetermined volume to allow the quantitative syringe 1 to easily approach the sample storage chamber 122 up and down, and may have a shielding wall 113 along the second extension end 111 with respect to the upper opening 122a of the sample storage chamber 122 so as to prevent the sample from splashing around.
A longitudinal protrusion may be formed on an outer circumferential part of the shielding wall 113 so that a user may hold the sample with a finger without slipping and collect a sample through the sampling unit 130.
Once the handle unit 110 is insertion-fitting coupled to the cartridge well, the capillary blood in the capillary tube 131 may be pressed in a direction opposite to the direction of gravity by a plunger installed at the bottom of the cartridge well, thereby separating plasma from the capillary blood absorbed in the filter unit 150.
The insertion-fitting and coupling unit 125 formed on the outer circumferential part of the sample storage unit 120 under the second extension end 111 of the handle unit 110 may be a coupling protrusion coupled to a sealing cap to be described in detail below. The insertion-fitting and coupling protrusion 125 may be a leaf spring having an elastic restoring force capable of being compressed and protruding to an original state when a force is applied thereto, and may be integrally formed by being pressed and folded when the material of the sample storage unit 120 is a metal material.
In the outer circumferential part of the sample storage unit 120, an air-discharge hole 123 may be further formed under the insertion-fitting and coupling protrusion 125 to discharge air.
When the sample storage chamber 122 is filled with plasma, the air-discharge hole 123 may discharge air filled in the sample storage chamber 122 to the outside.
Meanwhile, a sealing unit 170 may be coupled to the upper opening 122a of the sample storage chamber 122 by thermal fusion.
Therefore, the quantitative syringe 1 may break the sealing unit 170 and then approach the sample storage chamber 122 to quantitatively dispense the sample, and in this case, since air is discharged to the outside through the air-discharge hole 123, the sample in the sample storage chamber 122 may be prevented from being severely splashed to the outside.
The sealing unit 170 may be preferably made of an aluminum foil that is thermally fused to the second extension end 111 and is crushed by the vertical movement of the quantitative syringe 1, and the aluminum foil coated with a black film may be advantageous for optical measurement and the like.
As described above, since the upper opening 122a of the sample storage chamber 122 is sealed by the sealing unit 170, it is possible to prevent the sample from being contaminated while moving to the immunoassay device, to prevent the sample from being contaminated even when the sample is installed in a cartridge well of the immunoassay device, and to prevent other cartridge wells from being contaminated.
When the quantitative syringe 1 of the immunoassay device passes through the sealing unit 170 in the gravity direction, the air-discharge hole 123 may discharge internal air to the outside to prevent the plasma from splashing to the outside, and also, air may be introduced into the sample storage chamber 122 from the outside to allow the quantitative syringe 1 to easily pass through the sealing unit 170 in the gravity direction. A pipette system for collecting capillary blood according to an exemplary embodiment of the present invention will be described with reference to
As shown in
The capillary blood may fill the sample storage chamber 121 with a sufficient amount of the capillary blood by a capillary phenomenon along the capillary tube 131 along the first extension end 121.
When the handle unit 110 of the pipette tip 100 is held according to the exemplary embodiment of the present invention in which capillary blood is filled, and is slowly lowered in the gravity direction to the pipette tip mounting well 11 among the plurality of wells of the circular cartridge 10 to be mounted on the immunoassay device, and thus the handle unit 110 is seated and coupled at the upper part of the pipette tip mounting well 11, the capillary blood is moved sufficiently upward by the plunger 15 protruding from the support plate 13 under the pipette tip mounting well 11, the capillary blood are quantitatively sucked and centrifuged using the quantitative syringe 1 of the immunoassay device, the centrifuged plasma is transferred to the pre-treatment solution of another well, the sample (plasma) and the pre-treatment solution are mixed to prepare a mixed solution, and then, the mixed solution is sucked again using the quantitative syringe 1 to be dispensed to a desired place.
Meanwhile, as shown in
As shown in
In addition, as shown in
The plunger 15 may further include a support plate 13 having a rod shape or a bar shape and having a predetermined load against the bottom of the pipette tip mounting well 11 to support the plunger 15, and the support plate 13 may be fixedly installed to the bottom of the pipette tip mounting well 11 afterwards.
As shown in
In particular, it is preferable that the sampling unit 130 and the sample storage unit 120 of the pipette tip 100 are completely accommodated in the pipette tip mounting well 11 of the immunoassay cartridge 10, and only the handle unit 110 is exposed to the inlet of the pipette tip mounting well 11 and is configured to be locked and coupled to the inlet of the pipette tip mounting well 11.
The diameter of the plunger 15 is configured to correspond to the diameter of the capillary tube 131, and it is preferable to have the elastic sheath 15a at the upper part so as to be fastened so that there is no gap between the plunger 15 and the capillary tube 131.
Now, a pipette tip and a pipette system for collecting capillary blood according to a modified exemplary embodiment of the present invention will be described with reference to
The pipette tip 100 for collecting capillary blood according to a modified exemplary embodiment of the present invention is the same as the pipette tip 100 for collecting capillary blood according to an exemplary embodiment of the present invention except for including a storage tube 160.
As shown in
The storage tube 160 may include a tube body 161 having one end closed and accommodating the sampling unit 130 and the sample storage unit 120, an inner circumferential insertion-fitting and coupling unit 163 formed at an inner circumferential part of the tube body 161 in order to insertion-fitting couple the tube body 161 to a lower part of the handle unit 110 of the pipette tip 100, and a support flange 165 supporting the second extension end 111 of the handle unit 110.
The tube body 161 has a first jaw 161a on which the first extension end 121 of the sampling unit 130 is supported, and when the first extension end 121 is installed on the first jaw 161a, the bottom of the tube body 161 may be configured to face the end of the capillary tube 131.
The insertion-fitting and coupling unit 163 may be a coupling groove 165a which is insertion-fitting-coupled to the insertion-fitting and coupling protrusion 125 formed on the outer circumference of the sample storage unit 120.
As shown in
The capillary blood may fill the sample storage chamber 121 with a sufficient amount of the capillary blood along the capillary tube 131 along the first extension end 121 by a capillary phenomenon, the sampling unit 130 and the sample storage unit 120 may be accommodated in the storage tube 160 to be locked, and the patient information may be attached to the label unit 180 in the form of a barcode so as to be transferred over a long distance by vehicle or the like.
In the pipette tip 100 for collecting capillary blood according to the modified exemplary embodiment of the present invention, since the upper part of the sample storage unit 120 is blocked by the sealing unit 170 and the lower part thereof is blocked by the storage tube 160, contamination of the surroundings may be prevented even when the sample contains coronavirus or the like.
When the handle unit 110 is seated and coupled at the upper part of the pipette tip mounting well 11 by holding the handle unit 110 of the pipette tip 100 according to the exemplary embodiment of the present invention which is filled with capillary blood after separating the storage tube 160 after being transferred remotely and slowly descending the same in the gravitational direction among the plurality of wells of the circular cartridge 10 to be mounted in the immunoassay device, the capillary blood is sufficiently moved upward by the plunger 15 protruding from the support plate 13 in the lower part of the pipette tip mounting well 11, the quantitative suction is performed using the quantitative syringe 1 of the immunoassay device to perform centrifugation, the centrifuged plasma is transferred to the pre-treatment solution of another well to mix the sample (plasma) with the pre-treatment solution to prepare a mixed solution, and the mixed solution is again sucked with the quantitative syringe 1 to perform the dispensing at the desired position.
Meanwhile, as shown in
In the pipette tip 100 for collecting capillary blood according to the modified exemplary embodiment of the present invention, the upper part of the sample storage unit 120 is blocked by the sealing unit 170 and the lower part thereof is blocked by the storage tube 160, and the storage tube 160 is immediately separated during the immunoassay without centrifugation to perform the immunoassay.
Therefore, as in the case where the sample contains coronavirus, etc. when it should not contaminate the surroundings, provide patient information immediately, and is required to be urgent, the storage tube 160 is very effectively separated, and when the handle unit 110 is coupled to be seated on the top of the pipette tip mounting well 11, the sample is quantitatively suctioned by using the quantitative syringe 1 of the immunoassay device, transferred to a pre-treatment solution of another well without separate centrifugation, mixed with the sample (plasma) and the pre-treatment solution to prepare a mixed solution, and then suctioned again by using the quantitative syringe 1 to be dispensed to a desired place.
As described above, the pipette tip and the pipette system according to an exemplary embodiment or a modified exemplary embodiment of the present invention can secure a sufficient plasma amount required for the immunoassay, can satisfy various collected sample amounts required for the immunoassay with one pipette tip, can reduce an error of the immunoassay by providing a sufficient reaction amount, and can move without contamination for the immunoassay if necessary.
Number | Date | Country | Kind |
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10-2020-0094335 | Jul 2020 | KR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/KR2021/006800 | 6/1/2021 | WO |