DE102022125010A1 - Microfluidic component - Google Patents

Abstract

The invention relates to the field of microsystem technology and relates to a microfluidic component, such as can be used for actuator or sensory lab-on-a-chip systems. The object of the present invention is to provide a microfluidic component that can be used in microfluidic systems Disturbances are compensated for, suppressed and/or terminated and thus at least the main function of the microfluidic system is guaranteed to be essentially trouble-free. The task is solved by a microfluidic component in a microfluidic system, containing at least one channel-shaped component which has at least one opening with the microfluidic system is connected, wherein the channel-shaped component is split into at least two sub-channels, and wherein at least two sub-channels are directly connected by at least one connecting channel, and wherein the one or more connecting channels can have inlets and / or outlets, and wherein in the interior of the connecting channels a smaller Flow resistance is realized in the respective sub-channels, and the sub-channels have inlets and/or outlets.

Description

The invention relates to the fields of microsystem technology and microfluidics and relates to a microfluidic component, such as for actuator or sensory lab-on-a-chip systems, for portable microfluidic systems for field use in agriculture, bioanalytics, medical technology, can be used for impedance spectroscopy, surface plasmon resonance or electromagnetic separation in medical technology or in analytical chemistry and biochemistry.

Microfluidics deals with the behavior of liquids and gases in very small spaces (Wikipedia, search term “microfluidics”). Microfluidics is increasingly being used for the analysis or manipulation of fluids, for example for the synthesis of particles and medically effective biological molecules/particles/cells. For this purpose, so-called lab-on-chip systems (also referred to as micro total analysis systems, µTAS) are now used as microfluidic systems that combine the functionality of a macroscopic laboratory on a chip substrate. To achieve this, the necessary tasks that are implemented on a macroscopic scale must also be able to be carried out in all lab-on-a-chip systems. These include, for example, mixing, measuring, reacting, transporting, filtering, analyzing (e.g. optically, electrically or acoustically), etc.

Various devices are known from the prior art for applications in microfluidics.

From the EN 10 2012 206 042 A1 is a microfluidic microchemomechanical system with at least one structural carrier with at least one first channel, a cover which at least partially covers the structural carrier and at least one second channel, wherein the second channel is arranged on the structural carrier or the cover. The channels each form reservoirs delimited by active elements which are arranged such that they have at least one overlapping area with one another and together form a reaction chamber.

Also known from the DE 10 2011 112 638 A1 is a microfluidic chip that includes at least one microfluidic channel system, which includes at least one horizontal channel and at least one horizontal chamber, wherein the at least one channel and the at least one chamber are separated by a membrane and the at least one channel is flowed through by a cell-containing liquid and has a width of at least 10 µm and a maximum of 300 µm and a depth of at least 10 µm and a maximum of 100 µm.

Also known from the DE 10 2006 020 716 A1 is a microfluidic processor that has at least one fluidic mixing unit, which has hydrogel actuator-based pumps connected on the output side and produces mixing ratios for various process media that can be structurally specified by the respective volumes of the pump chambers of the pumps and the resulting mixture in reaction or analysis units transport.

Furthermore, from the DE 10 2012 201 714 A1 a method for producing microfluid systems is known. At least one polymer layer is applied to a substrate at least at the positions of connecting elements and the connecting element is subsequently brought into position on the polymer layer. Subsequently, at least one further polymer layer is applied at least partially over the connecting element at least with a thickness that is at least greater than the height of the connecting element, and then structuring and curing of the at least second polymer layer is realized.

According to P. Abgrall et al: J. Micromech. Microeng. 16 (2006) 113-121 a new manufacturing process for flexible and monolithically integrated 3D microfluidic structures by lamination of SU-8 films is known. Uncrosslinked dry SU-8 films are then applied to a polyester substrate and laminated to existing SU-8 structures. Lithographic networking then takes place to form closed microstructures.

It is known that in microfluidic components and systems, liquids with different fluid or solid phases are transported at low flow rates. The small channel dimensions typically lead to a dominance of wall effects (fluid adhesion) and thus to a laminar flow with a low Reynolds number (Re _type <1). This laminar flow and constant flow conditions are either mandatory or advantageous for many basic microfluidic operations.

Therefore, studies have already been carried out on the importance of flow resistance in microfluidic systems, both external to the chip in peripheral components of the microfluidic systems, such as hose lines and cartridges, and internal to the chip within the microfluidic structures, for example in microfluidic channels in a chip.
This has led to various solutions for adjusting the on-chip flow resistances being commercially available, such as pressure-driven pumps, hoses, dampers or flow restrictors.
To adjust the internal flow resistances, the flow resistance in the microfluidic channel can be calculated taking into account the channel dimensions and the cross-sectional shape and then adjusted by changing the geometry (e.g. walls, floors, lids) and surfaces (e.g. roughness, surface chemistry).

A disadvantage of the solutions of the prior art is that in the known solutions for microfluidic systems, in particular through external events that act on the microfluidic system, or through internal events, for example in a sub-area of the microfluidic system, which affect other sub-areas of the microfluidic system have an effect (“crosstalk”), disruptions to at least the main function of the microfluidic system are caused, which affect and/or prevent the desired result that is to be achieved by the microfluidic system, and thus the functionality of the microfluidic system as a whole cannot be reliably guaranteed can.

The object of the present invention is to provide a microfluidic component that compensates for, suppresses and/or terminates disturbances in microfluidic systems and thus at least the main function of the microfluidic system is guaranteed to be essentially trouble-free.

The task is solved by the invention specified in the claims. Advantageous refinements are the subject of the subclaims, with the invention also including combinations of the individual dependent claims in the sense of an AND connection, as long as they are not mutually exclusive.

The microfluidic component according to the invention in a microfluidic system contains at least one channel-shaped component which is connected to the microfluidic system at least with an opening, the channel-shaped component being split into at least two sub-channels, and at least two sub-channels being directly connected by at least one connecting channel, and wherein the connecting channel(s) may have inlets and/or outlets, and wherein a lower flow resistance is realized in the interior of the connecting channels than in the respective sub-channels, and wherein the sub-channels have inlets and/or outlets.

Advantageously, the channel-shaped component(s) and/or the partial channels and/or the connecting channel(s) have dimensions in the micrometer and/or nanometer range, more advantageously dimensions between 0.1 and 1000 μm.

Further advantageously, due to the geometry and/or the surface properties of the surfaces in contact with the fluid, the channel-shaped components have a flow resistance to form a continuous and/or laminar flow of the fluid.

Also advantageously, the at least one channel-shaped component is split into 3 to 5 sub-channels.

And also advantageously, in the case of different fluids in the microfluidic system, depending on the respective function of the microfluidic system, only partial channels which have fluids of the same composition are connected to one another via at least one connecting channel.

It is also advantageous if a flow resistance that is 10 to 100 times lower is realized inside a connecting channel than in the sub-channels that the connecting channel connects.

It is also advantageous if the microfluidic components are integrated into microfluidic systems, which are actuator or sensory lab-on-a-chip systems or microfluidic systems.

It is also advantageous if the at least one channel-shaped component and/or the at least two partial channels and/or the at least one connecting channel and/or the inlets and/or outlets are at least partially made of elastomers, such as polydimethylsiloxane (PDMS), glass-based microfluid systems, such as Silicon, glass, (amorphous) SiO2, polymers such as cycloolefin copolymers (COC), epoxy resins, acrylic resins, PTFE, PMMA, PC, PS and/or PEEK, piezoelectric materials, TOPAS, ceramics, ultra-thin and/or thin vitreous or polymers Plates or films and/or dry photoresists.

With the solution according to the invention, it is possible for the first time to provide a microfluidic component that compensates for, suppresses and/or terminates disturbances in microfluidic systems and thus ensures at least the main function of the microfluidic system essentially trouble-free.

This is achieved by a microfluidic component in a microfluidic system that has at least one channel-shaped component, which is connected to the microfluidic system at least with an opening.

The channel-shaped component is further split into at least two sub-channels. Furthermore, the at least two sub-channels are connected by at least one connecting channel, which directly connects the at least two sub-channels to one another. The connecting channel can have inlets and/or outlets.
According to the invention, it is important that a lower flow resistance is realized inside the connecting channels than in the respective sub-channels that are connected by the connecting channel(s).
It is also according to the invention that the sub-channels have inlets and/or outlets.

In a microfluidic system, functional microfluidic components must generally be connected to channel-shaped microfluidic components and channel-shaped microfluidic components must also be present from the inlet and to the outlet of the fluid and other components from and into the microfluidic system. These are also generally referred to as microfluidic channels.

Furthermore, within a microfluidic system there are fluids in gaseous and/or liquid form. By definition, the fluids can also contain gas bubbles, fluid drops and/or solids that can be moved in the microfluidic system, or can be mixtures of gaseous or liquid components with solids, such as suspensions, dispersions or emulsions.

Advantageously, the channel-shaped components, the partial channels and/or the connecting channels have dimensions in the micrometer and/or nanometer range, more advantageously dimensions between 0.1 and 1000 μm.

Channel-shaped components also advantageously have geometries and/or surface properties of the surfaces in contact with the fluid, as a result of which they have a flow resistance to form a continuous and/or a laminar flow of the fluid.

Furthermore advantageously, the at least one channel-shaped component is split into 3 to 5 sub-channels.

It is also advantageous if, in the case of different fluids in the microfluidic system, only partial channels which have fluids of the same composition are connected to one another via a connecting channel, depending on the respective function of the microfluidic system.

It is furthermore advantageous if the at least one connecting channel has dimensions in the micrometer and/or nanometer range, but partially has smaller dimensions of its length and/or larger dimensions of its cross-sectional area than the channel-shaped component before separation.

Due to the dimensions of the at least one connecting channel and/or the lower flow resistance inside, the flow velocity and the associated friction losses on the connecting channel walls are lower and the momentum compensation is significantly smaller.

A further advantageous embodiment of the solution according to the invention is that a flow resistance that is 10 - 100 times lower is realized inside a connecting channel than in the sub-channels that the connecting channel connects.

And further advantageously, the microfluidic components are integrated into microfluidic systems, which are actuator or sensory lab-on-a-chip systems or microfluidic systems.

The desired function of the microfluidic systems requires that inlets and outlets be present on the microfluidic systems, which in turn are usually connected via connectors, cannulas and hoses to peripheral devices for fluid supply, to reservoirs or upstream and/or downstream passive or active (microfluidic elements, or connected to sampling facilities.

All of these upstream and downstream components in the microfluidic system and in particular the formation of drops at fluid outlets and/or the presence of more than two inlets and outlets of the microfluidic component can disrupt at least the main function of the microfluidic system due to external events, such as movements and/or vibrations. For example, movements and vibrations can cause pressure fluctuations in the microfluidic system, which are passed on directly to the fluid in the microfluidic systems due to the low compressibility of fluids. Such disturbances can be bubbles, blockages, temperature fluctuations, pressure fluctuations, the effects of which can be balanced out, suppressed and/or stopped by the solution according to the invention.

Such disturbances caused by external events also arrive via the inlets and/or outlets the channel-like microfluidic components spread there over the fluid and interact with the components through friction on the component walls, through friction in the flow of the fluid, through geometric scattering, through the momentum transfer to the flow of the fluid and/or through momentum transfer to the Component walls and, if present, particles in the fluid. The compensation, suppression and/or termination of these disturbances in the microfluidic component takes place proportionally according to the respective fluid mechanical resistances. The disruptions are often not predictable or externally controllable.

All external events that lead to such disturbances can have a negative impact on the flow conditions in the microfluidic system and in the channel-shaped components, and can lead to impairment of the function and even to malfunction and failure of the microfluidic systems.

With the solution according to the invention, it is now possible for the first time to use the microfluidic component according to the invention to compensate for, suppress and suppress such disturbances in the microfluidic systems that are triggered by external events or by internal events in the microfluidic system, such as in downstream microfluidic components / or can be terminated and thus at least the main function of the microfluidic system can be guaranteed essentially trouble-free.
The solution according to the invention enables a secure, stable operation of the microfluidic systems, in particular independently of downstream microfluidic components.

The microfluidic component according to the invention can also ensure that disturbances caused by external and/or internal events do not reach the areas of the microfluidic systems that are present for the desired function of the microfluidic systems, but rather they are compensated for in the microfluidic components according to the invention , suppressed and/or terminated.

For this purpose, according to the invention, the channel-shaped component of the microfluidic component is split into at least two partial channels after an inlet and/or before an outlet. Then the at least two sub-channels are directly connected to one another via at least one connecting channel after and/or in front of the inlets and/or outlets of the microfluidic system. For example, in the connecting channel there is a fluid of the same composition as in the at least two sub-channels that the connecting channel connects to one another.
Furthermore, the connecting channel itself can have inlets and/or outlets.

Furthermore, the connecting channel can also be filled with a gas or gas mixture, such as air, which prevents fluid from penetrating the sub-channels into the connecting channel and further compensates for disturbances, for example in the form of pressure fluctuations, due to the compressibility of the gas or gas mixture. suppressed or terminated.

For example, if particles are to be separated from a liquid in a microfluidic system, at least one partial channel is required for the discharge of the particles after the particles have been separated from the liquid. For the liquid, two sub-channels can be continued from the separation point of particle-free liquid and concentrated dispersion and subsequently connected to a connecting channel in front of the outlets. In this case, there are liquids of the same composition in the sub-channels with the particle-free liquid and the connecting channel.
This means that the negative effects of pressure fluctuations, which arise, for example, from liquid dripping from one or both of the sub-channels, do not reach the point in the microfluidic system where the particles are separated from the liquid.

With the solution according to the invention, the structure of the microfluidic systems, for example on chips, can be essentially preserved by splitting them into partial channels and integrating connecting channels, since only a small amount of space is required for production and/or integration into existing systems and no other space is required Manufacturing processes are required. The adjustment of peripheral components and/or the use of additional components, such as flow limiters, is not necessary.

The solution according to the invention compensates for, suppresses or ends the coupling of interference from external or internal influences into microfluidic systems and improves the functionality of the microfluidic components of the microfluidic systems. This also makes it possible to change media or flush the system without deactivating one or more inlets and/or outlets due to excessive flow resistance. This is also the case if air bubbles appear in the system. Larger fluid volumes can also be introduced and/or discharged from or into different reservoirs via more than two inlets and/or outlets. Contamination of various fluids in the microfluidic system is also avoided by avoiding effects of disturbances to the function of the microfluidic system.

The solution according to the invention requires only minor conceptual changes in the structure of microfluidic systems, can be implemented without additional effort in chip production and is compatible with conventional microfluidic systems, such as polymer fluidic chips, microfluidic systems based on elastomers such as PDMS, or glass-based microfluidic systems.

Likewise, the components according to the invention can also be installed as a module in microfluidic systems.
The at least one channel-shaped component and/or the at least two partial channels and/or the at least one connecting channel and/or the inlets and/or outlets can be made of elastomers, such as polydimethylsiloxane (PDMS), glass-based microfluid systems, such as silicon, glass, (amorphous ) SiO ₂ , polymers such as cycloolefin copolymers (COC), epoxy resins, acrylic resins, PTFE, PMMA, PC, PS and/or PEEK, piezoelectric materials, TOPAS, ceramics, ultra-thin and/or thin glass-like or polymeric plates or films and/ or dry photoresist at least partially.

The microfluidic component according to the invention can be produced using known methods such as laminating, hot pressing, hot stamping, deep drawing, injection molding, additive manufacturing processes such as inkjet, piezojet, aerosol jet printing, stereolithography, aerosol printing, 3D printing, lithography, (nano) imprint -Lithography, microtechnology, microcontact printing, wafer bonding, dispensing technologies, CNC machining, laser application processes, milling and/or grinding.

The invention is explained in more detail below using an exemplary embodiment.

• 1 eine Prinzipskizze eines erfindungsgemäßen mikrofluidischen Bauteils und
• 2 die Prinzipdarstellung der Strömungswiderstände R und Volumenströme Q im erfindungsgemäßen mikrofluidischen Bauteil gemäß 1

It shows:

• 1 a schematic diagram of a microfluidic component according to the invention and
• 2 the principle representation of the flow resistances R and volume flows Q in the microfluidic component according to the invention according to 1

example 1

A microfluidic component for separating ceramic particles 600 from water as a fluid consists of a substrate 100 on which the microfluidic component is arranged in a microfluidic system. At the inlet 400 of the microfluidic system, the water-particle mixture is introduced as a fluid into the channel-shaped component 300. In an area of influence 200, in which mechanical forces act on the ceramic particles 600, a separation of water and ceramic particles 600 takes place. Then the channel-shaped component 300 is split into three sub-channels 301, 302, 303 at the location of splitting 401. The ceramic particles 600 are discharged from the microfluidic system from a partial channel 301 with an outlet 501. The particle-free water is discharged from the microfluidic system via the outlets 502 and 503 via the two sub-channels 302/304 and 303/305. Before the water is discharged, the water-filled sub-channels 302 and 303 are directly connected to a connecting channel 504.

For the channel-shaped component 300, the cross-sectional dimensions are 300 µm × 50 µm × 1000 µm (width × height × length) and it has a flow resistance R300 = 3.575419e15 Pa s/m ³ .

After the separation point of water and ceramic particles, the channel-shaped component 300 is split at the split 401 into three sub-channels 301 with the dimensions 100 µm × 50 µm × 75 µm (W × H × L) and 302, 303 with the dimensions 100 µm × 50 µm × 100 µm (W × H × L). The flow resistances are R301 = 1.05e15 Pa s/m ³ , R302 = 1.40e15 Pa s/m ³ and R303 = 1.40e15 Pa s/m ³ .

The connecting channel 504 has the dimensions 2000 µm × 50 µm × 30 µm (W × H × L) and a flow resistance R504 = 1.40e13 Pa s/m ³ . The connecting channel 504 has a significantly lower flow resistance inside in relation to R302 and R303.

After the connecting channel 504 there are the sub-channels 304 and 305, each with the dimensions 250 µm × 50 µm × 100 µm (W × H × L), which lead to the outlets 502 and 503 and the flow resistances R304 = R305 = 4.39e14 Pa s /m ³ have. The sub-channels 304 and 305 each have a lower flow resistance in relation to R302 and R303 and a higher flow resistance in relation to R504.

The dripping of water from the two outlets 502 and 503 of the two partial channels 304 and 305 triggers a movement which, as an external disturbance, causes a pressure fluctuation in the microfluidic component.

If R504 = 1/100 * R302 = 1.40e13 Pa s/m ³ , then the volume flows Q302 = 2.95e-10 m ³ /s and Q303 = 2.95e-10 m ³ /s are equal and pressure differences between the outlets 502 and 503 cause only small differences in the volume flows, ie the ratio of Q302 to Q303 is 1. The pressure fluctuations are directed into the connecting channel 504 and brought there to the same pressure level, so that the pressure difference is zero goes back.

As a result, the pressure fluctuations do not reach the separation 401 of water and ceramic particles 600, so that the flow conditions are not changed there and the separation function and thus the main function of the microfluidic component is fully realized.

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102012206042 A1 [0004]
• DE 102011112638 A1 [0005]
• DE 102006020716 A1 [0006]
• DE 102012201714 A1 [0007]

Claims (8)

Microfluidic component in a microfluidic system, containing at least one channel-shaped component which is connected to the microfluidic system at least with one opening, the channel-shaped component being split into at least two sub-channels, and wherein at least two sub-channels are directly connected by at least one connecting channel, and wherein the connecting channel(s) may have inlets and/or outlets, and wherein a lower flow resistance is realized in the interior of the connecting channels than in the respective sub-channels, and wherein the sub-channels have inlets and/or outlets. Microfluidic component Claim 1 , in which the channel-shaped component(s) and/or the partial channels and/or the connecting channel(s) have dimensions in the micrometer and/or nanometer range, advantageously having dimensions between 0.1 and 1000 μm. Microfluidic component according to Claim 1 , in which, due to the geometry and/or the surface properties of the surfaces in contact with the fluid, the channel-shaped components have a flow resistance to form a continuous and/or laminar flow of the fluid. Microfluidic component Claim 1 , in which the at least one channel-shaped component is split into 3 to 5 partial channels. Microfluidic component Claim 1 , in which in the case of different fluids in the microfluidic system, depending on the respective function of the microfluidic system, only partial channels are connected to one another via at least one connecting channel, which have fluids of the same composition. Microfluidic component Claim 1 , in which a flow resistance that is 10 to 100 times lower is realized inside a connecting channel than in the sub-channels that the connecting channel connects. Microfluidic component Claim 1 , in which the microfluidic components are integrated into microfluidic systems, which are actuator or sensory lab-on-a-chip systems or microfluidic systems. Microfluidic component Claim 1 , in which the at least one channel-shaped component and / or the at least two partial channels and / or the at least one connecting channel and / or the inlets and / or outlets are at least partially made of elastomers, such as polydimethylsiloxane (PDMS), glass-based microfluid systems, such as silicon, glass , (amorphous) SiO2, polymers such as cycloolefin copolymers (COC), epoxy resins, acrylic resins, PTFE, PMMA, PC, PS and/or PEEK, piezoelectric materials, TOPAS, ceramics, ultra-thin and/or thin glass-like or polymeric plates or films and/or dry photoresists.

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