Source: https://patents.google.com/patent/DE102011075127B4/en
Timestamp: 2019-10-21 00:09:26
Document Index: 599653499

Matched Legal Cases: ['Application No. 10', 'art 25', 'art 25', 'art 25', 'art 25', 'art 251', 'arts 251', 'art 25', 'art 25', 'art 25', 'art 25', 'art 25', 'art 25', 'art 25']

DE102011075127B4 - Microvalve structure with a polymer actuator and Lab-on-a-chip module - Google Patents
Microvalve structure with a polymer actuator and Lab-on-a-chip module
DE102011075127B4
DE102011075127B4 DE201110075127 DE102011075127A DE102011075127B4 DE 102011075127 B4 DE102011075127 B4 DE 102011075127B4 DE 201110075127 DE201110075127 DE 201110075127 DE 102011075127 A DE102011075127 A DE 102011075127A DE 102011075127 B4 DE102011075127 B4 DE 102011075127B4
DE201110075127
DE102011075127A1 (en
Kwang Suk Yang
Ji Sun YUN
2010-05-04 Priority to KR10-2010-0042060 priority Critical
2010-05-04 Priority to KR20100042060 priority
2010-12-17 Priority to KR20100129857A priority patent/KR101465828B1/en
2010-12-17 Priority to KR10-2010-0129857 priority
2011-05-03 Application filed by Electronics and Telecommunications Research Institute filed Critical Electronics and Telecommunications Research Institute
2011-11-10 Publication of DE102011075127A1 publication Critical patent/DE102011075127A1/en
2014-10-30 Publication of DE102011075127B4 publication Critical patent/DE102011075127B4/en
Microvalve structure comprising:
a flexible structure (20) disposed on the substrate; and a polymer actuator (40) inserted in the flexible structure (20),
wherein the flexible structure comprises a portion (25) which can be spaced from the substrate (10) due to a flexing movement of the polymer actuator (40) to be formed as a valve such that only in the flexible structure (20) therebetween Valve portion (25) and the substrate (10) a micro-channel (35) is defined, and
wherein the polymer actuator (40) is separated from the microchannel (35) by the flexible structure (20) and is formed to change the width of the microchannel (35) through the flexural positioning movement.
This patent application claims the priority of Korean Patent Application No. 10-2010-0042060 , filed on May 4, 2010, and No. 10-2010-0129857 , filed on Dec. 17, 2010, the entire contents of which are incorporated herein by reference.
The present invention disclosed herein relates to a microchannel control technology, and more particularly to a microvalve structure and a lab-on-a-chip module comprising a polymer actuator.
Recently, the developments and applications of a microfluid control technology which controls the flow rate or direction of a microfluid continue to increase along with advances in biosensor and semiconductor technologies. A trace amount of a component contained in a biological fluid, such as blood, can be quantitatively or qualitatively detected by the microfluid control technology. Therefore, the microfluid control technology has become a core technology in the technical field of a biochip or a lab-on-a-chip (LOC).
A patterning technology that allows for the formation of microchannels in desired shapes and a switching technology that allows control of the opening and closing of the microchannels must be provided to control the microfluid. The microchannel structuring technology has become available due to advances in semiconductor manufacturing technology or microelectromechanical system (MEMS) technology. The switching technology of the microchannel can be realized by means of a microactuator using a piezoelectric device. Although the microactuator using the piezoelectric device has high reliability and is suitable for mass production, because of its high power consumption and miniaturization limitations, it is well within a point-of-care testing (POCT) device difficult to use on a portable device.
The publication US 7,052,594 B2 discloses a device that controls fluid flow and that includes a substrate and an elastic film on the substrate. The pamphlets US 6,960,864 B2 and WO 01/06579 A2 disclose an electroactive polymer actuator. The publication by H. F. Schlaak et al., "Novel Multilayer Electrostatic Solid State Actuators with Elastic Dielectric", Proceedings of SPIE, Vol. 5759, 2005, pp. 121-133, discloses an actuator of elastic silicone elastomers with thin graphite powder electrodes. The publication by RD Kornbluh et al., "Electroactive polymers: An emerging technology for MEMS", Proceedings of SPIE, Vol. 5344, 2004, pp. 13-27, discloses electroactive polymers for MEMS devices. The publication by Mohsen Shahinpoor et al., "Ionic Polymer-Metal Composites: IV. Industrial and Medical Applications", Smart Materials and Structures, Vol. 14, 2005, pp. 197-214, discloses ionic polymer-metal composites (IPMCs ) for various applications. The publication of F. Lefevre et al., "A Polymeric micro actuator to be integrated into on organic material based lab on chip micro system", joint 6 th Internatial IEEE Northeast Workshop on Circuits and Systems and Taisa Conference, 2008, pp 318- 322 discloses a microvalve actuated by an electroactive polymer. The publication DE 10 2007 044 889 A1 discloses a diagnostic test system having a first layer and a base. The first layer is attached to the base to form one or more chambers. The diagnostic test system includes one or more pumps. Each of the one or more pumps is configured to control the movement of a fluid within one of the one or more chambers by generating a strain that changes a volume of the one or more chambers.
The present invention is defined in independent claims 1 and 10. The dependent claims define embodiments of the invention. The present invention provides a microvalve structure capable of providing low power consumption, small volume, and increased durability.
The present invention also provides a lab-on-a-chip having a microvalve structure capable of providing low power consumption, small volume, and increased durability.
Embodiments of the present invention provide a microvalve structure in which the opening and closing of the valve are controlled directly by a polymer actuator. The microvalve structure may be a substrate; a flexible structure disposed on the substrate; and include a polymer actuator inserted in the flexible structure. At this time, the flexible structure has a valve portion defining a microchannel, and the polymer actuator may be separated from the microchannel by the flexible structure. In addition, the polymer actuator may be configured to change a width of the microchannel by mechanically and directly controlling a displacement of the valve portion.
In some embodiments, the polymer actuator may include a pair of electrodes and a polymer-metal composite disposed therebetween. The ionic polymer-metal composite may be one of sulfonated tetrafluoroethylene-based fluoropolymer copolymers.
In other embodiments, the microchannel may include first and second spaced-apart channels, wherein the valve portion of the flexible structure is disposed between the first and second channels, and the polymer actuator may include a portion inserted into the valve portion. Further, the polymer actuator may have a width greater than a sum of the widths of the first and second passages of the valve portion and may have a parallelepiped shape with rectangular top and bottom sides.
In further embodiments, the microchannel may have an inlet where fluid is supplied from the outside and an outlet where the fluid is removed. Further, the substrate has a recess forming region used as a microchannel, and the valve portion of the flexible structure can be inserted into the recess forming region, this embodiment being illustrative and not covered by the claims.
In further embodiments, a largest surface of the polymer actuator may be disposed substantially parallel to an upper surface of the substrate.
In further embodiments, the largest surface of the polymer actuator may be disposed substantially perpendicular to the top of the substrate.
In further embodiments of the present invention, a microvalve structure may comprise a substrate; a flexible structure having a valve portion between first and second channels which are spaced apart and disposed on the substrate; and a polymer actuator interposed in the flexible structure to control displacement of the valve portion.
In further embodiments, the polymer actuator may be spaced from the first and second channels by the flexible structure. The polymer actuator may comprise a pair of electrodes and an ionic polymer-metal composite disposed therebetween. At this time, the polymer actuator is surrounded by the flexible structure so that the electrodes of the polymer actuator are not exposed to an outside atmosphere or the first and second channels. The ionic polymer-metal composite may be one of sulfonated tetrafluoroethylene-based fluoropolymer copolymers.
In further embodiments of the present invention, a lab-on-a-chip module may have a flexible structure; a plurality of polymer actuators introduced into the flexible structure; and a controller that independently controls the respective polymer actuators. At this time, the flexible structure may include a first channel, a plurality of second channels, and a plurality of valve portions spatially separating the second channels from the first channel, and the polymer actuators may be configured to control displacements of the respective valve portions ,
In other embodiments, the controller may be configured to drive at least two of the polymer actuators at different times with a predetermined time interval.
In further embodiments, the first channel is configured to pass a fluid with biomolecules, and reactants that react with the biomolecules may be formed in the respective second channels. The reactants formed in the second channels may be the same and all polymer actuators may be driven at different times. In addition, at least one reaction detector may additionally be disposed on the second channels to monitor a reaction between the fluid and the reactant.
The accompanying drawings are included to provide a further understanding of the present invention and are incorporated in and constitute a part of this specification. The drawings illustrate exemplary embodiments of the present invention and, together with the description, serve to explain the principles of the present invention , In the drawings:
1 and 2 13 are drawings exemplifying a microvalve structure and an operation thereof according to an embodiment of the present invention;
3 and 4 FIG. 15 are perspective and cross-sectional views exemplarily illustrating a lab-on-a-chip according to an embodiment of the present invention; FIG.
5 to 8th 3 are perspective views exemplifying microvalve structures and FIGS Illustrate operations thereof and are not covered by the claims;
9 and 10 FIG. 15 are cross-sectional and perspective views exemplarily illustrating a microvalve structure and an operation thereof according to another embodiment of the present invention; FIG.
11 and 12 FIG. 15 is perspective views illustrating the microvalve structures and operations thereof according to other modified embodiments of the present invention; FIG.
13 and 14 15 are cross-sectional views exemplifying Lab-on-a-chips according to other embodiments of the present invention; and
15 is a drawing illustrating a use of a lab-on-a-chip according to the present invention.
The above objects, other objects, features and advantages of the present invention will become more apparent from the following description of preferred embodiments taken in conjunction with the accompanying drawings. However, the present invention may be embodied in various forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the present invention to those skilled in the art.
When the description refers to a layer (or film) that is "on top" of another layer or substrate, it is to be understood that it may be directly on the other layer or substrate, or interlayers can happen. In the drawings, the dimensions of layers and regions are exaggerated for clarity of illustration. Further, although terms such as first, second and third are used to describe various regions and layers in various embodiments of the present invention, the regions and the layers are not limited to these terms. These terms are used only to distinguish one region or layer from another region or layer. Therefore, a layer referred to as the first layer in one embodiment may be referred to as a second layer in another embodiment. An embodiment described and exemplified herein includes a supplemental embodiment thereof.
1 and 2 13 are drawings exemplifying a microvalve structure and an operation thereof according to an embodiment of the present invention.
Referring to 1 and 2 is a flexible structure 20 on a substrate 10 arranged and a polymer actuator 40 is in the flexible structure 20 inserted.
The substrate 10 and the flexible structure 20 may be arranged to at least one channel 30 define. For example, the channel 30 between a bottom of the flexible structure 20 and an upper surface of the substrate 10 be formed. In particular, as in 1 shown a side wall of the canal 30 through the flexible structure 20 be defined. That is, the bottom of the flexible structure 20 the side wall of the canal 30 can define by forming an upwardly directed recess. According to other embodiments, as in 5 to 7 shown can be the top of the substrate 10 the side wall of the canal 30 by defining a downwardly directed depression.
The substrate 10 can be glass. However, the spirit of the present invention is not limited thereto. For example, the substrate 10 be selected from at least one material that is not one in the channel 30 flowing fluid or with materials contained in the fluid reacts.
The flexible structure 20 may be a polymer compound having elasticity. In particular, the flexible structure 20 a material that does not match the one in the channel 30 flowing fluid or reacted with the materials contained in the fluid, be of polymer compounds known as elastomer. For example, the flexible structure 20 be formed from polydimethylsiloxane (PDMS).
The flexible structure 20 with the channel 30 can be made using a soft lithographic technology. For example, the channel 30 on a surface of the flexible structure 20 using technology selected from microcontact stamping (μCP), replica (REM), microtransfer (μTM), microforming in capillaries (MIMIC), and solvent-assisted microphones (SAMIM). The flexible structure 20 can be applied to the substrate by an adhesive method, such as an oxygen plasma treatment 10 to be glued.
According to embodiments of the present invention, the flexible structure 20 one between the channels 30 arranged valve portion 25 include, and the side walls of the channel 30 can through the valve part 25 be defined. A bottom of the valve part 25 Can be in substantial contact with the top of the substrate 10 However, these surfaces can not adhere to each other. As a result, the distance between the valve portion 25 and the substrate 10 , as in 2 illustrated by the polymer actuator 40 to be controlled.
The polymer actuator 40 can be an electrically separated pair of electrodes 41 and 42 and one between these electrodes 41 and 42 arranged electroactive polymer 45 include. The electrodes 41 and 42 may comprise at least one metallic material. For example, the electrodes 41 and 42 Platinum or gold on two opposing surfaces of the electroactive polymer 45 is applied. According to one embodiment, the electrodes 41 and 42 of the polymer actuator 40 not an outside atmosphere or the channels 30 be exposed. For this purpose, in addition, a thin protective layer (not shown) may be provided on a surface of the polymer actuator 40 be formed. The protective layer may have flexible properties.
The electroactive polymer 45 may be a material that exhibits a bending displacement under an applied stress. The electroactive polymer 45 may be, for example, an ionic polymer-metal composite (IPMC). When the ionic polymer-metal composite as an electroactive polymer 45 can be used, the voltage difference between the electrodes 41 and 42 the preceding bending actuator motion and the accompanying displacements of the polymer actuator 40 and the valve portion 25 by ion migration and electrostatic repulsion generated in the ionic polymer-metal composite. According to some embodiments, the ionic polymer-metal composite may be a sulfonated tetrafluoroethylene-based fluid polymer copolymer, but the technical idea of the present invention is not limited thereto. According to modified embodiments, the ionic polymer-metal composite may further comprise graphene oxide or graphene.
The polymer actuator 40 may be adjacent to the valve portion 25 in the flexible structure 20 be formed. In this case, as in 2 illustrated, the valve portion 25 when the voltage difference between the electrodes 41 and 42 is generated due to the bending actuator movement of the polymer actuator 40 from the substrate 10 be spaced. As a result, a microchannel can 35 , the channels 30 connects, between the valve part 25 and the substrate 10 be formed.
According to some embodiments of the present invention, the valve portion 25 , as in 1 and 2 illustrated, mechanically and directly with the polymer actuator 40 be connected. As a result, the valve portion 25 directly through the polymer actuator 40 be controlled. As a result, the mechanical displacement of the valve portion 25 directly through the polymer actuator 40 to be controlled. The foregoing aspect of the present invention can provide much better reaction rate and operating force characteristics as compared to the modified embodiments in which the valve portion 25 from the polymer actuator 40 is spaced. According to the foregoing embodiments, the polymer actuator 40 be formed so that it has a greater width than the sum of the widths of the channel pair 30 and the valve portion 25 having.
3 and 4 FIG. 15 are perspective and cross-sectional views exemplarily illustrating a lab-on-a-chip according to an embodiment of the present invention. FIG. 4 is a cross-sectional view along the dashed line II 'of 3 , For the sake of simplicity, no description will be given regarding the technical characteristics with reference to 1 and 2 overlap described embodiments provided.
Referring to 3 can be a flexible structure 20 that have a first channel 301 and a second channel 302 , which are spaced apart, defined, on a substrate 10 be formed. Furthermore, the flexible structure 20 be formed to a third channel 303 between the first and second channels 301 and 302 define. The third channel 303 is from the first and second channels 301 and 302 spaced. The first and second channels 301 and 302 can have an inlet 36 have, where a fluid is supplied from the outside. Furthermore, the first to third channels 301 . 302 and 303 in addition an outlet 37 have, where the supplied fluid is discharged respectively.
The flexible structure 20 can, as in 4 illustrates a first valve portion 251 that is between the first and third channels 301 and 303 is formed, and a second valve portion 252 that is between the second and third channels 302 and 303 is formed. Further, the first and second polymer actuators 401 and 402 that are above the first and second valve portions 251 and 252 are arranged in the flexible structure 20 be inserted. The valve part 25 and the polymer actuator 40 according to with reference to 1 described embodiment can be used to the first valve part 251 and the first polymer actuator 401 and the second valve portion 252 and the second polymer actuator 402 to realize.
A biomolecule fluid becomes at least one of the first and second channels 301 and 302 fed and a reagent which reacts with the biomolecules can be supplied to the other. When the first and second valve parts 251 and 252 from the substrate 10 Thus, the biomolecules and the reactant can be controlled by driving the first and second polymer actuators 401 and 402 after flowing through the third channel 303 react. According to embodiments of the present invention, the fluid with the biomolecules may be blood. However, it is not limited thereto, and the biomolecule types are also not limited.
5 to 8th FIG. 15 are perspective views exemplifying microvalve structures and operations thereof and not covered by the claims. For the sake of simplicity, no description will be given regarding the technical characteristics with reference to 1 to 4 described embodiments overlap provided.
Referring to 5 to 8th may be a recess forming region 15 having a lower top than the outer edge in a given region of the substrate 10 be formed. The deepening region 15 can be designed in various forms. For example, a width of the recess forming region may be 15 , as in 5 illustrates, can taper up or, as in 6 illustrates, be substantially the same or, as in 7 illustrated, tapering down.
The flexible structure 20 can have a valve part 25 having in the recess forming region 15 is inserted, and a polymer actuator 40 adjacent to the valve portion 25 can in the flexible structure 20 be inserted. The valve part 25 may be formed so as to form a region forming a recess 15 have indented form. For example, if the indent forming region 15 , as in 5 illustrated, has an upwardly tapering shape, the valve portion 25 also have an upwardly tapering shape. As in
6 Illustratively, the recess forming region 15 and the valve part 25 be formed to have a rectangular parallelepiped shape or the recess forming region 15 and the valve part 25 can, as in 7 illustrated, have a downwardly tapering shape.
As in 5 to 7 1, the microvalve structures according to the embodiments may have a normally open structure. That is, when no voltage is applied, a through the substrate 10 and the flexible structure 20 defined channel may be in an open state. For this purpose, the indent forming region 15 and the valve part 25 when no voltage is applied, spaced apart such that the channel may be in the open state. Furthermore, the width of the valve portion 25 be narrower than the width of the recess forming region 15 ,
Meanwhile, the polymer actuator 40 when the voltage is applied to both electrodes of the polymer actuator 40 is created by convex bending up the valve portion 25 lift upwards. In this case, the valve portion is 25 , as in 8th illustrates, with the side walls of the recess forming region 15 in contact, that the channel can be closed. According to other embodiments, the polymer actuator bends 40 when a voltage is applied, convex down, leaving the valve portion 25 a bottom of the recess forming region 15 can touch. In this case, the channels can according to the in 6 and 7 be closed embodiments illustrated.
In addition, in order for the microvalve structure to have the normally open structure, a spacer (not shown), which may be a thickness of the channel 30 determines between the flexible structure 20 and the substrate 10 be arranged. According to some embodiments, the spacer may be part of the flexible structure 20 or the substrate 10 be provided.
9 and 10 12 are cross-sectional and perspective views exemplifying a microvalve structure and an operation thereof according to another embodiment of the present invention, and FIGS 11 and 12 FIG. 15 are perspective views exemplifying the microvalve structures and operations thereof according to other modified embodiments of the present invention. FIG. For the sake of simplicity, no description will be given regarding the technical characteristics that are described with reference to FIGS 1 to 8th overlap described embodiments provided.
Referring to 9 and 10 is a flexible structure 20 , the spaced channels 30 defined on a substrate 10 arranged. The flexible structure 20 can one between the channels 30 arranged valve portion 25 and at least one in the valve portion 25 inserted polymer actuator 40 is in the flexible structure 20 arranged.
According to some embodiments, the polymer actuator 40 be arranged with a major axis MA thereof substantially perpendicular to an upper surface of the substrate 10 is positioned. For example, the polymer actuator 40 , as in 10 Fig. 10 illustrates a thin rectangular parallelepiped having rectangular shaped top and bottom surfaces and the surfaces (eg, the top and bottom surfaces) having the largest area in the polymer actuator 40 can be perpendicular to the top of the substrate 10 be. Therefore, a shift of the polymer actuator 40 take place along a direction which the channels 30 crosses, and a transverse displacement of the polymer actuator 40 causes a transverse displacement of the valve portion 25 showing the widths of the channels 30 changes.
According to some embodiments, the flexible structure 20 a gap region 29 include that in an upper part of the canal 30 is arranged. The space region 29 can be filled with a gas at atmospheric pressure. The polymer actuator 40 can in the valve part 25 the flexible structure 20 be inserted by placing this in the gap region 29 penetrates. As a counteraction or a resistance to the actuation force of the polymer actuator 40 through the gap region 29 is reduced, the operating force of the polymer actuator 40 better on the valve part 25 be transmitted. According to the preceding embodiment, the to the polymer actuator 40 applied voltage can be reduced.
Although the bottoms of the channels 30 , as in 9 illustrated by the top of the substrate 10 can be defined, the subpages, as in 10 illustrated by the flexible structure 20 be defined. That means the channels 30 according to the embodiment of the 10 inside the flexible structure 20 may be formed by these from the top of the substrate 10 are spaced.
As in 10 and 11 illustrates a variety of polymer actuators 40 in the flexible structure 20 be inserted. At this time, some of the polymer actuators are 40 adapted to the actuating force against the one channel 30 and the others may be configured to apply the actuating force to the other channel 30 to create. For example, if the channels 30 are parallel to the xy plane and the major axes thereof are substantially in the y direction, creating some polymer actuators 40 a shift in the x-direction and the other polymer actuators 40 can produce a displacement in the -x direction. In this case it is possible to use all channels 30 close as well as selectively the one channel 30 close.
The shape of the channels 30 can, as in 11 and 12 shown to be changed differently. For example, the channels 30 , as in 11 illustrated, formed in a zigzag shape, or may be formed to have at least one narrow region 30n and at least a wide region 30w have, as in 12 illustrated are arranged alternately. Furthermore, as in 12 illustrates the channel 30 have a shape in which a border region between the narrow region 30n and the wide region 30w a tapered shape similar to heart valves.
13 and 14 12 are cross-sectional views exemplifying lap-on-a-chips according to other embodiments of the present invention. 15 Figure 11 is a drawing exemplifying the use of a lap-on-a-chip according to the present invention. For the sake of simplicity, no description will be given regarding the technical characteristics with reference to 1 to 12 overlap described embodiments provided.
Referring to 13 and 14 can a lab-on-a-chip one on a substrate 10 arranged flexible structure 20 include to channels 31 and 32 define. The channels 31 and 32 can be a first channel 31 who has an inlet 36 and an outlet 37 connects, and a variety of second channels 32 coming from the first channel 31 are spaced apart.
The flexible structure 20 may include a valve portion which the second channels 32 from the first channel 31 separates. Furthermore, a variety of polymer actuators 40 in the flexible structure 20 be inserted and the polymer actuators 40 may be disposed adjacent to the respective valve portions. According to some embodiments, the shape and arrangement of the valve portion and polymer actuator 40 as referenced in the above 1 described embodiment, be the same. According to other embodiments, the shape and arrangement of the valve portion and the polymer actuator 40 however, as with reference to 5 to 12 described embodiments may be the same or may be a modification thereof.
In addition, the lab-on-a-chip can additionally control 90 which are the polymer actuators 40 drives and a tax link structure 71 which are the polymer actuators 40 electrically connects. According to some embodiments, the controller may 90 as an external component of Lab-on-a-Chip be provided. The tax link structure 71 For example, it consists of flexible connections, so that the relative position and the relative distance between the controller 90 and the substrate 10 can be changed.
The tax link structure 71 can be a first control connection 71a , usually with the polymer actuators 40 is connected and second control connections 71b , with the respective polymer actuators 40 are connected. As with reference to 1 described, the polymer actuator 40 a first electrode 41 , a second electrode 42 and the interposed electroactive polymer 45 include. In this case, the first control connection is 71a with the first electrode 41 of the polymer actuator 40 connected and the second control connections 71b can with the respective second electrodes 42 the polymer actuators 40 be connected. That is, the number of second control connections 71b may be the same as the number of polymer actuators 40 ,
The first channel 31 may have a form in which a fluid is passed through with biomolecules. The fluid may be, for example, blood and the first channel 31 may be provided as a bypass line of a blood vessel. In particular, the Lab-on-a-Chip (LOC) according to the present invention, as in 15 illustrated, attached to a human body (eg, forearm), and an inlet 36 and an outlet 37 of the first channel 31 can be linked to a blood vessel of the human body.
A reactive with the biomolecules reagent can in the second channels 32 be formed. In this case, if the fluid with the biomolecules by driving the polymer actuators 40 in the second channel 32 may flow in the second channel 32 between the biomolecules and the reagent a reaction product 99 form.
The lab-on-a-chip may also include reaction detectors 80 include that monitor whether the reaction product 99 is produced. For example, the reaction detectors 80 , as in 13 and 14 illustrated on upper parts of the respective second channels 32 be arranged. Although the technical idea of the present invention is not limited to a process involving the reaction product 99 can detect the reaction detector 80 according to some embodiments, be configured to detect the presence of the reaction product 99 by an optical or electrical method. An action control of the reaction detector 80 or a transmission of the measured data can, as in 13 can be achieved by a proof connection structure 72 which the reaction detectors 80 and the controller 90 combines. According to other embodiments, the control connection structure 71 however, act as a detection compound structure which, as in 14 illustrates the reaction detectors 80 and the controller 90 combines.
When the mutually different second control connections 71b with the polymer actuators 40 can be connected, the polymer actuators 40 be controlled independently. For example, the polymer actuators 40 in response to a control signal from the controller 90 be controlled in turn. In this case, the second channels 32 in turn with the first channel 31 be connected and a fluid F1 in the first channel 31 can in the open second channel 32 be flowed through an inflow F2 of the fluid F1. That is, the controller 90 may be formed to the polymer actuators 40 to drive at different times with a predetermined time interval. Because the sequential triggering allows periodic monitoring of a biochemical life status, critical issues such as a heart attack or stroke can be prevented. According to the embodiments, the same reactants in the second channels 32 be formed.
According to the modified embodiments, those in the second channels 32 formed reactants, however, be two types. In this case, two risk factors or diseases can be monitored using the Lab-on-a-Chip.
According to embodiments of the present invention, a polymer actuator that generates mechanical displacement in accordance with an applied voltage is used for a microvalve structure or a lab-on-a-chip. As a result, the microvalve structure or the Lab-on-a-Chip can be miniaturized and possibly low power consumption characteristics compared with a method using a piezoelectric device can be achieved. Thus, the lab-on-a-chip of the present invention may be manufactured as a product, such as a point-of-care testing device (POCT) or a portable device.
In addition, according to some embodiments of the present invention, the polymer actuator is spaced from a microchannel by means of a flexible structure. That is, the polymer actuator does not directly contact a fluid in the microchannel. Therefore, technical difficulties resulting from the direct contact between the polymer actuator and the fluid can be prevented. That is, the microvalve structure or lab-on-a-chip of the present invention may have improved durability and reliability.
According to some embodiments of the present invention, a valve portion that controls the opening and closing operation of the microvalve (eg, channel width control) is mechanically and directly connected to the polymer actuator. Therefore, an operating force of the polymer actuator for the opening and closing operation can be directly transmitted to the valve portion. The microvalve structure or the lab-on-a-chip according to the present invention can provide an increased operating speed by the direct transmission of the actuating force.
The above-disclosed subject matter is to be considered as illustrative and not restrictive, and the appended claims are intended to cover all modifications, improvements, and other embodiments that fall within the true spirit and scope of the present invention. Accordingly, to the maximum extent permitted by law, the scope of the present invention should be determined by the broadest permissible interpretation of the following claims and their equivalents and shall not be limited or limited by the foregoing detailed description.
A microvalve structure comprising: a substrate ( 10 ); a flexible structure ( 20 ) disposed on the substrate; and a polymer actuator ( 40 ), which is in the flexible structure ( 20 ), the flexible structure comprising a share ( 25 ), which due to a bending-adjusting movement of the polymer actuator ( 40 ) from the substrate ( 10 ) can be spaced so as to be designed as a valve such that only in the flexible structure ( 20 ) between the valve portion ( 25 ) and the substrate ( 10 ) a microchannel ( 35 ) and wherein the polymer actuator ( 40 ) from the microchannel ( 35 ) by the flexible structure ( 20 ) is separated and is formed such that this the width of the microchannel ( 35 ) can change by the bending-adjusting movement.
The microvalve structure of claim 1, wherein the polymer actuator comprises a pair of electrodes and an ionic polymer-metal composite disposed therebetween.
The microvalve structure of claim 2, wherein the ionic polymer-metal composite is a sulfonated tetrafluoroethylene-based fluoropolymer copolymer.
Microvalve structure according to one of claims 1 to 3, wherein the flexible structure ( 20 ) first and second channels ( 30 ), which are spaced apart, and the proportion ( 25 ) of the flexible structure ( 20 ), which is designed as a valve and the microchannel ( 35 ) between the first and second channels ( 30 ), and the microchannel ( 35 ) between the first and the second channel ( 30 ) Are defined.
Microvalve structure according to claim 4, wherein the polymer actuator ( 40 ) has a width greater than a sum of the widths of the first and second channels ( 30 ) and the proportion of the flexible structure ( 20 ), which is designed as a valve and the microchannel ( 35 ) defined.
The microvalve structure of claim 4, wherein the polymer actuator has a parallelepiped shape with rectangular top and bottom sides.
A microvalve structure according to any one of claims 1 to 6, wherein the microchannel has an inlet where a fluid is supplied from the outside and an outlet where the fluid is discharged.
Microvalve structure according to one of claims 1 to 7, wherein the largest surface of the polymer actuator is arranged substantially parallel to an upper surface of the substrate.
Microvalve structure according to one of claims 1 to 7, wherein the largest surface of the polymer actuator is arranged substantially perpendicular to the top of the substrate.
A microvalve structure comprising: a substrate ( 10 ); a flexible structure ( 20 ) with a share ( 25 ), which is designed as a valve, between first and second channels ( 30 ), which are spaced apart from each other and are constantly without fluid communication and on the substrate ( 10 ) are arranged; and a polymer actuator ( 40 ), which is in the flexible structure ( 20 ) in order to postpone the share ( 25 ) of the flexible structure ( 20 ), which is designed as a valve to control such that the widths of the two channels ( 30 ), where the polymer actuator ( 40 ) of the first and second channels ( 30 ) by the flexible structure ( 20 ) is spaced.
The microvalve structure of claim 10, wherein the polymer actuator comprises a pair of electrodes and an ionic polymer-metal composite disposed therebetween.
The microvalve structure of claim 11, wherein the polymer actuator is surrounded by the flexible structure so that the electrodes of the polymer actuator are not an external atmosphere or the first and second channels is exposed.
A microvalve structure according to claim 11 or 12, wherein the ionic polymer-metal composite is a sulfonated tetrafluoroethylene-based fluoropolymer copolymer.
A lab-on-a-chip module comprising: a microvalve structure according to claim 1; the flexible structure ( 20 ) is formed with a first channel, a plurality of second channels and a plurality of portions, which are formed as a valve and spatially separate the second channels from the first channel, wherein a plurality of polymer actuators ( 40 ), which are in the flexible structure ( 20 ) and adjacent to their respective shares ( 25 ), which are formed as a valve, in the flexible structure ( 20 ) are arranged by the bending-adjusting movements of the respective polymer actuators ( 40 ) Relocations of the respective shares ( 25 ) of the flexible structure ( 20 ), which are designed as a valve to control; and a controller ( 90 ), which the respective polymer actuators ( 40 ) controls independently.
The lab-on-a-chip module of claim 14, wherein the controller is configured to drive at least two of the polymer actuators at different times with a predetermined time interval.
The lab-on-a-chip module of claim 14 or 15, wherein the first channel is configured to pass a fluid with biomolecules, and reactants that react with the biomolecules are formed in the respective second channels.
The lab-on-a-chip module of claim 16, wherein the reactants formed in the second channels are the same and all polymer actuators are driven at different times.
The lab-on-a-chip module of any one of claims 14 to 16, further comprising at least one reaction detector disposed on the second channels for monitoring a reaction between the fluid and the reagent.
DE201110075127 2010-05-04 2011-05-03 Microvalve structure with a polymer actuator and Lab-on-a-chip module Expired - Fee Related DE102011075127B4 (en)
KR10-2010-0042060 2010-05-04
KR20100042060 2010-05-04
KR20100129857A KR101465828B1 (en) 2010-05-04 2010-12-17 Micro-Valve Structure Including Polymer Actuator And Lab-On-A-Chip Module
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DE102011075127A1 DE102011075127A1 (en) 2011-11-10
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DE201110075127 Expired - Fee Related DE102011075127B4 (en) 2010-05-04 2011-05-03 Microvalve structure with a polymer actuator and Lab-on-a-chip module
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