Patent Description:
A variety of microfluidic devices and sensors are known. Sensors such as disclosed by <CIT> and <CIT> are provided in the dry state and a liquid test sample applied to the device is transported to the sensor region within the device by capillary flow. Other types of sensors are known, such as ion selective sensors comprising an ion selective membrane.

Another example is provided by <CIT> which discloses an apparatus for creating layers of amphiphilic molecules, and is now briefly discussed with reference to <FIG>.

<FIG> shows an apparatus <NUM> which may be used to form a layer of amphiphilic molecules. The apparatus <NUM> includes a body <NUM> having layered construction comprising a substrate <NUM> of non-conductive material supporting a further layer <NUM> also of non-conductive material. A recess <NUM> is formed in the further layer <NUM>, in particular as an aperture which extends through the further layer <NUM> to the substrate <NUM>. The apparatus <NUM> further includes a cover <NUM> which extends over the body <NUM>. The cover <NUM> is hollow and defines a chamber <NUM> which is closed except for an inlet <NUM> and an outlet <NUM> each formed by openings through the cover <NUM>. The lowermost wall of the chamber <NUM> is formed by the further layer <NUM>.

In use aqueous solution <NUM> is introduced into the chamber <NUM> and a layer <NUM> of amphiphilic molecules is formed across the recess <NUM> separating aqueous solution <NUM> in the recess <NUM> from the remaining volume of aqueous solution in the chamber <NUM>. Use of a chamber <NUM> which is closed makes it very easy to flow aqueous solution <NUM> into and out of the chamber <NUM>. This is done simply by flowing the aqueous solution <NUM> through the inlet <NUM> as shown in <FIG> until the chamber <NUM> is full. During this process, gas (typically air) in the chamber <NUM> is displaced by the aqueous solution <NUM> and vented through the outlet <NUM>.

The apparatus includes an electrode arrangement to allow measurement of electrical signals across the layer <NUM> of amphiphilic molecules, which allows the device to function as a sensor. The substrate <NUM> has a first conductive layer <NUM> deposited on the upper surface of the substrate <NUM> and extending under the further layer <NUM> to the recess <NUM>. The portion of the first conductive layer <NUM> underneath the recess <NUM> constitutes an electrode <NUM> which also forms the lowermost surface of the recess <NUM>. The first conductive layer <NUM> extends outside the further layer <NUM> so that a portion of the first conductive layer <NUM> is exposed and constitutes a contact <NUM>.

The further layer <NUM> has a second conductive layer <NUM> deposited thereon and extending under the cover <NUM> into the chamber <NUM>, the portion of the second conductive layer <NUM> inside the chamber <NUM> constituting an electrode <NUM>. The second conductive layer <NUM> extends outside the cover <NUM> so that a portion of the second conductive layer <NUM> is exposed and constitutes a contact <NUM>. The electrodes <NUM> and <NUM> make electrical contact with aqueous solution in the recess <NUM> and chamber <NUM>. This allows measurement of electrical signals across the layer <NUM> of amphiphilic molecules by connection of an electrical circuit to the contacts <NUM> and <NUM>.

In practice, the device of <FIG> can have an array of many such recesses <NUM>. Each recess is provided with the layer <NUM> of amphiphilic molecules. Further, each layer can be provided with a nanopore, to allow other molecules to pass through the layer (which affects the electrical signal measured). For example, one nanopore is provided per membrane. The extent to which this occurs is determined in part upon the concentration of the nanopores in the medium applied to the membranes.

An analysis apparatus incorporating means to provide amphiphilic membranes and nanopores to the sensor is disclosed by <CIT>. The step of providing the amphiphilic membranes and nanopores is carried out prior to use of the device, typically by the end user. However this provides drawbacks in that additional steps are required on the part of the consumer and also requires the provision of an apparatus with a complex fluidic arrangement including valves and supply reservoirs. Furthermore setting up such a sensor for use by the user can be prone to error. There is a risk that, even if the system is set up correctly, it will dry out, which could potentially damage the sensor. There is also a risk that excessive flowrates in the sample chamber could cause damage to the sensor. This risk increases for more compact devices, which bring the sample input port into closer proximity to the sensor (and so there is less opportunity for system losses to reduce the flowrates through the device).

It is therefore desirable to provide a device to the user in a 'ready to use' state wherein the amphiphilic membranes and nanopores are pre-inserted and are maintained under wet conditions. More generally it is also desirable to provide a device wherein the sensor is provided in a wet condition, for example provided in a wet condition to or by the user prior to detection of an analyte.

A typical nanopore device provided in a 'ready to use' state comprises an array of amphiphilic membranes, each membrane comprising a nanopore and being provided across a well containing a liquid. Such a device and method of making is disclosed by <CIT>. Test liquid to be analysed is applied to the upper surface of the amphiphilic membranes. Providing a device in a 'ready to use' state however has additional considerations in that care needs to be taken that the sensor does not dry out, namely that liquid is not lost from the well by passage through the amphiphilic membrane, which may result in a loss of performance or damage the sensor. One solution to address the problem of drying out of the sensor is to provide the device with a buffer liquid over the surface of the amphiphilic membrane such that any evaporation through the surface of the membrane is minimised and the liquids provided on either side of the membrane may have the same ionic strength so as to reduce any osmotic effects. In use the buffer liquid may be removed from the surface of the amphiphilic membrane and a test liquid to be analysed is introduced to contact the surface. When the device contains a buffer liquid, the questions of how to remove it and how to introduce the test liquid become an issue. Due to the presence of the buffer liquid, namely that the sensor is provided in a 'wet state', the capillary force provided by a dry capillary channel cannot be utilised to draw test liquid into the sensor. A pump may be used to displace the buffer liquid and to introduce a test liquid, however this results in a device with added complexity and cost.

An ion selective electrode device comprising one or more ion selective membranes is typically calibrated prior to use with a solution having a known ionic concentration. The ion selective membranes may be provided in a capillary flow path connecting a fluid entry port through which a calibrant solution may be introduced and caused to flow over the ion selective electrodes by capillary action. Thereafter the calibrant solution may be displaced and the analyte solution caused to flow over the electrodes in order to perform the measurement. In large benchtop devices for the measurement of ions, a peristaltic pump may for example be employed to displace the liquid. However for simple disposable devices, a less complex solution is more desirable.

In other devices, a pair of electrodes may be provided in a capillary channel into which a first test liquid is drawn by capillary action in order to make an electrochemical analysis. Following measurement of the first test liquid, it may be desirable to measure a second test liquid. However an additional force intervention is needed in order to remove the first test liquid prior to introduction of the second test liquid as capillary force is longer available.

The present invention aims to at least partly reduce or overcome the problems discussed above.

<CIT> discloses an analysis apparatus for performing biochemical analysis of a sample using nanopores comprises: a sensor device that supports plural nanopores, reservoirs holding material for performing the analysis; a fluidics system; and plural containers for receiving respective samples, all arranged in a cartridge that is removably attachable to an electronics unit arranged to generate drive signals to perform signal processing circuit to generate output data representing the results of the analysis. The fluidics system supplies samples selectively from the containers to the sensor device using a rotary valve.

According to a first aspect of the invention there is provided a microfluidic device microfluidic device for analysing a test liquid comprising: a sensor provided in a sensing chamber, the sensor comprising a membrane; a sensing chamber inlet and a sensing chamber outlet connecting to the sensing chamber for respectively passing liquid into and out of the sensing chamber, and a sample input port in fluid communication with the inlet, for introducing a test liquid into the microfluidic device; a liquid collection channel downstream of the outlet; a flow path comprising the sample input port, the sensing chamber inlet, the sensing chamber, the sensing chamber outlet and the liquid collection channel, and wherein the sensing chamber inlet, sensing chamber and liquid collection channel are arranged such that displacing liquid from the liquid collection channel into the sensing chamber in tum displaces liquid from the sensing chamber into the sensing chamber inlet; a flow path interruption between the sensing chamber outlet and the liquid collection channel, wherein the microfluidic device is configured to be changeable from an inactive state, in which liquid is prevented by the flow path interruption from flowing into the liquid collection channel from upstream, to an active state in which the flow path between the sample input port and the liquid collection channel is completed; and a buffer liquid, filling from the sample input port to the flow path interruption such that the sensor is covered by liquid and unexposed to a gas or gas/liquid interface. The device is configured such that following a change of the device into the active state, the capillary pressure at the liquid collection channel and the capillary pressure at the sample input port are balanced such that the buffer liquid does not freely drain out of the sensing chamber and one or more volumes of test liquid may be introduced, via a wet surface of the input port, such that the capillary pressure at the input port is less than the capillary pressure at the liquid collection channel so as to draw the test liquid into the device and displace the buffer liquid into the liquid collection channel.

In some embodiments, the device is an electrochemical device for the detection of an analyte and the sensor comprises electrodes.

In some embodiments the electrodes may be ion selective.

In some embodiments, a sample input port, a sensing chamber inlet and a liquid collection channel are configured to avoid free draining of a sensing chamber when a flow path is completed and further wherein a input port is configured such that it presents a wet surface to a test liquid to be applied to the device.

In some embodiments, a sample input port, a sensing chamber inlet and a liquid collection channel are configured such that, when an activation system has been operated to complete the flow path, a sensor remains unexposed to gas or a gas/liquid interface whilst the device is tilted.

In some embodiments, a device provided herein further comprises a weir past which fluid may be displaced by provision of a liquid to a sample input port, but which prevents draining of a sample chamber.

In some embodiments, a device provided herein further comprises a priming reservoir filled with fluid. A fluid may be introduced into a flow path, for example for making fine adjustments to a volume of liquid in the flow path. An activation system may be operable to introduce fluid from the priming reservoir to complete the flow path between a liquid outlet and a liquid collection channel.

In some embodiments, a device provided herein further comprises a removable seal for a sample input port.

In some embodiments, a sample input port and a seal are configured such that the removal of the seal provides a priming action to maintain a buffer liquid in the input port and present a wet surface to a test liquid to be applied.

In some embodiments, a priming action draws fluid from the liquid collection channel or a priming reservoir.

In some embodiments, a flow path interruption comprises a closed valve; and an activation system comprises a mechanism for opening the valve. The valve may be a hydrophobic valve.

In some embodiments, a flow path interruption comprises a flow obstacle; and an activation system comprises a mechanism for removing the flow obstacle or forcing liquid past the flow obstacle.

In some embodiments, a sensor can contain a single well. Alternatively, a sensor can comprise an array of wells, wherein each well comprises a well liquid and wherein the membrane is provided across the surface of each well separating the well liquid contained in the well from the buffer liquid.

In some embodiments, each membrane further comprises a nanopore.

In some embodiments, a membrane is ion selective.

In some embodiments, a membrane is amphiphilic.

In some embodiments, a nanopore is a biological nanopore.

According to another aspect of the invention there is provided a method of filling the microfluidic device according to any one of the preceding embodiments, with test liquid, the method comprising one or more of the following steps: operating the activation system to complete the flow path; introducing test liquid into the device via the sample input port so as to displace buffer liquid from the sensing chamber into the liquid collection channel whilst; ceasing to introduce test liquid such that the sensor remains unexposed to gas or a gas/liquid interface.

In some embodiments, a device further comprises a removable seal for a sample input port and the method further comprises: removing the removable seal and priming the sample input port so that the input port is filled with buffer liquid before the step of introducing the test liquid.

In some embodiments, a step of priming comprises flushing a device by providing additional buffer liquid to the device through a sample input port.

In some embodiments, a step of priming comprises drawing fluid from inside a device into a sample input port.

In some embodiments, a plurality of discrete volumes of test liquid are successively applied to a sample input port in order to successively displace buffer liquid into the liquid collection channel.

The invention is described below with reference to exemplary Figures, in which:.

The present disclosure allows for a microfluidic device, using a "wet-sensor" (i.e. a sensor that functions in a wet environment) to be produced and stored in a state in which the sensor is kept wet, until it is needed. This is effectively achieved by providing a device that has an "inactive" state in which the sensor is kept wet, but in which the device cannot be used, and an "active" state in which the device can be used. In other words, an "inactive" state can be a state in which a flow path between a sample input port and a liquid collection channel is not complete, as discussed below. In contrast an "active" state, can be a state in which the flow path between a sample input port and a liquid collection channel is complete. A particular benefit of keeping the sensor wet when considering nanopore sensors (see more detail below) is to ensure that well liquid does not escape through the membrane. The membrane is very thin and the sensor is very sensitive to moisture loss. Moisture loss can create for example a resistive air gap between the well liquid and the membrane thus breaking the electrical circuit between an electrode provided in the well and in the sample. Moisture loss can also serve to increase the ionic strength of the well liquid, which could affect the potential difference across the nanopore. The potential difference has an effect on the measured signal and thus any change would have an effect on the measurement values.

In any case the device of the invention can be maintained in the "inactive" state for a long period of time until it is required. During that time, for example, the device could be transported (e.g. shipped from a supplier to an end user), as the "inactive" state is robust and capable of maintaining the sensor in a wet condition, even when the device is in a non-standard orientation (i.e. orientations in which the device is not used to perform its normal function). This is possible because the inactive states seals an internal volume of the device, containing the sensor, from the surroundings. That internal volume (referred to as a 'saturated volume' below) is filled with liquid. The absence of any air gaps and/or bubbles means the sensor isolated from the possibility of a gas/air interface intersecting with the sensor (which could damage the functionality of the sensor) even if the device is moved around. Further, even in the active state, the device is able to maintain the sensor in a wet condition, for a long period of time, even if the device is activated and then not used.

<FIG> shows a top cross-sectional view of an example of a microfluidic device <NUM> with an inset showing a side cross-sectional view of a portion of the microfluidic device comprising a sample input port <NUM>. The microfluidic device <NUM> comprises a sensing chamber <NUM>, for housing a sensor.

The sensing chamber <NUM> is provided with a sensor, which is not shown in <FIG>. The sensor may be a component or device for analyzing a liquid sample. For example, a sensor may be a component or device for detecting single molecules (e.g., biological and/or chemical analytes such as ions, glucose) present in a liquid sample. Different types of sensors for detecting biological and/or chemical analytes such as proteins, peptides, nucleic acids (e.g., RNA and DNA), and/or chemical molecules are known in the art and can be used in the sensing chamber. In some embodiments, a sensor comprises a membrane that is configured to permit ion flow from one side of the membrane to another side of the membrane. For example, the membrane can comprise a nanopore, e.g., a protein nanopore or solid-state nanopore. In some embodiments, the sensor may be of the type discussed with reference to <FIG>, above, which is described in <CIT>. The sensor is connected to an electrical circuit, in use. The sensor may be an ion selective membrane provide directly over an electrode surface or over a ionic solution provided in contact with an underlying electrode.

The sensor may comprise an electrode pair. One of more of the electrodes may be functionalised in order to detect an analyte. One or more of the electrodes may be coated with a selectively permeable membrane such as NafionTM.

An example design of such an electrical circuit <NUM> is shown in <FIG>. The primary function of the electrical circuit <NUM> is to measure the electrical signal (e.g., current signal) developed between the common electrode first body and an electrode of the electrode array. This may be simply an output of the measured signal, but in principle could also involve further analysis of the signal. The electrical circuit <NUM> needs to be sufficiently sensitive to detect and analyse currents which are typically very low. By way of example, an open membrane protein nanopore might typically pass current of 100pA to 200pA with a <NUM> salt solution. The chosen ionic concentration may vary and may be between for example <NUM> and <NUM>. Generally speaking the higher the ionic concentration the higher the current flow under a potential or chemical gradient. The magnitude of the potential difference applied across the membrane will also effect the current flow across the membrane and may be typically chosen to be a value between 50mV and 2V, more typically between 100mV and 1V.

In this implementation, the electrode <NUM> is used as the array electrode and the electrode <NUM> is used as the common electrode. Thus the electrical circuit <NUM> provides the electrode <NUM> with a bias voltage potential relative to the electrode <NUM> which is itself at virtual ground potential and supplies the current signal to the electrical circuit <NUM>.

The electrical circuit <NUM> has a bias circuit <NUM> connected to the electrode <NUM> and arranged to apply a bias voltage which effectively appears across the two electrodes <NUM> and <NUM>.

The electrical circuit <NUM> also has an amplifier circuit <NUM> connected to the electrode <NUM> for amplifying the electrical current signal appearing across the two electrodes <NUM> and <NUM>. Typically, the amplifier circuit <NUM> consists of a two amplifier stages <NUM> and <NUM>.

The input amplifier stage <NUM> connected to the electrode <NUM> converts the current signal into a voltage signal.

The input amplifier stage <NUM> may comprise a trans-impedance amplifier, such as an electrometer operational amplifier configured as an inverting amplifier with a high impedance feedback resistor, of for example 500MΩ, to provide the gain necessary to amplify the current signal which typically has a magnitude of the order of tens to hundreds of pA.

Alternatively, the input amplifier stage <NUM> may comprise a switched integrator amplifier. This is preferred for very small signals as the feedback element is a capacitor and virtually noiseless. In addition, a switched integrator amplifier has wider bandwidth capability. However, the integrator does have a dead time due to the necessity to reset the integrator before output saturation occurs. This dead time may be reduced to around a microsecond so is not of much consequence if the sampling rate required is much higher. A transimpedance amplifier is simpler if the bandwidth required is smaller. Generally, the switched integrator amplifier output is sampled at the end of each sampling period followed by a reset pulse. Additional techniques can be used to sample the start of integration eliminating small errors in the system.

The second amplifier stage <NUM> amplifies and filters the voltage signal output by the first amplifier stage <NUM>. The second amplifier stage <NUM> provides sufficient gain to raise the signal to a sufficient level for processing in a data acquisition unit <NUM>. For example with a 500MΩ feedback resistance in the first amplifier stage <NUM>, the input voltage to the second amplifier stage <NUM>, given a typical current signal of the order of 100pA, will be of the order of 50mV, and in this case the second amplifier stage <NUM> must provide a gain of <NUM> to raise the 50mV signal range to <NUM>.

The electrical circuit <NUM> includes a data acquisition unit <NUM> which may be a microprocessor running an appropriate program or may include dedicated hardware. In this case, the bias circuit <NUM> is simply formed by an inverting amplifier supplied with a signal from a digital-to-analog converter <NUM> which may be either a dedicated device or a part of the data acquisition unit <NUM> and which provides a voltage output dependent on the code loaded into the data acquisition unit <NUM> from software. Similarly, the signals from the amplifier circuit <NUM> are supplied to the data acquisition card <NUM> through an analog-to-digital converter <NUM>.

The various components of the electrical circuit <NUM> may be formed by separate components or any of the components may be integrated into a common semiconductor chip. The components of the electrical circuit <NUM> may be formed by components arranged on a printed circuit board. In order to process multiple signals from the array of electrodes the electrical circuit <NUM> is modified essentially by replicating the amplifier circuit <NUM> and A/D converter <NUM> for each electrode <NUM> to allow acquisition of signals from each recess <NUM> in parallel. In the case that the input amplifier stage <NUM> comprises switched integrators then those would require a digital control system to handle the sample-and-hold signal and reset integrator signals. The digital control system is most conveniently configured on a field-programmable-gate-array device (FPGA). In addition the FPGA can incorporate processor-like functions and logic required to interface with standard communication protocols i.e. USB and Ethernet. Due to the fact that the electrode <NUM> is held at ground, it is practical to provide it as common to the array of electrodes.

In such a system, polymers such as polynucleotides or nucleic acids, polypeptides such as a protein, polysaccharides or any other polymers (natural or synthetic) may be passed through a suitably sized nanopore. In the case of a polynucleotide or nucleic acid, the polymer unit may be nucleotides. As such, molecules pass through a nanopore, whilst the electrical properties across the nanopore are monitored and a signal, characteristic of the particular polymer units passing through the nanopore, is obtained. The signal can thus be used to identify the sequence of polymer units in the polymer molecule or determine a sequence characteristic. A variety of different types of measurements may be made. This includes without limitation: electrical measurements and optical measurements. A suitable optical method involving the measurement of fluorescence is disclosed by <NPL>. Possible electrical measurements include: current measurements, impedance measurements, tunnelling measurements (<NPL>), and FET measurements (<CIT>). Optical measurements may be combined with electrical measurements (<NPL>). The measurement may be a transmembrane current measurement such as measurement of ionic current flowing through the pore.

The polymer may be a polynucleotide (or nucleic acid), a polypeptide such as a protein, a polysaccharide, or any other polymer. The polymer may be natural or synthetic. The polymer units may be nucleotides. The nucleotides may be of different types that include different nucleobases.

The nanopore may be a transmembrane protein pore, selected for example from MspA, lysenin, alpha-hemolysin, CsgG or variants or mutations thereof.

The polynucleotide may be deoxyribonucleic acid (DNA), ribonucleic acid (RNA), cDNA or a synthetic nucleic acid known in the art, such as peptide nucleic acid (PNA), glycerol nucleic acid (GNA), threose nucleic acid (TNA), locked nucleic acid (LNA) or other synthetic polymers with nucleotide side chains. The polynucleotide may be single-stranded, be double-stranded or comprise both single-stranded and double-stranded regions. Typically cDNA, RNA, GNA, TNA or LNA are single stranded.

In some embodiments, the devices and/or methods described herein may be used to identify any nucleotide. The nucleotide can be naturally occurring or artificial. A nucleotide typically contains a nucleobase (which may be shortened herein to "base"), a sugar and at least one phosphate group. The nucleobase is typically heterocyclic. Suitable nucleobases include purines and pyrimidines and more specifically adenine, guanine, thymine, uracil and cytosine. The sugar is typically a pentose sugar. Suitable sugars include, but are not limited to, ribose and deoxyribose. The nucleotide is typically a ribonucleotide or deoxyribonucleotide. The nucleotide typically contains a monophosphate, diphosphate or triphosphate.

The nucleotide can include a damaged or epigenetic base. The nucleotide can be labelled or modified to act as a marker with a distinct signal. This technique can be used to identify the absence of a base, for example, an abasic unit or spacer in the polynucleotide. Of particular use when considering measurements of modified or damaged DNA (or similar systems) are the methods where complementary data are considered. The additional information provided allows distinction between a larger number of underlying states.

The polymer may also be a type of polymer other than a polynucleotide, some non-limitative examples of which are as follows.

The polymer may be a polypeptide, in which case the polymer units may be amino acids that are naturally occurring or synthetic.

The polymer may be a polysaccharide, in which case the polymer units may be monosaccharides.

A conditioning liquid provided in the device to maintain the sensor in a wet state may be any liquid that is compatible with the device (e.g., a liquid that does not adversely affect the performance of the sensor) By way of example only, when the sensor comprise a protein nanopore, it would be apparent to one of ordinary skill in the art that the conditioning liquid should be free of an agent that denatures or inactivates proteins. The conditioning liquid is a buffer liquid, e.g., an ionic liquid or ionic solution. The conditioning liquid may contain a buffering agent to maintain the pH of the solution.

The sensor is one that needs to be maintained in a 'wet condition', namely one which is covered by a liquid. The sensor comprises a membrane, such as for example an ion selective membrane or amphiphilic membrane. The membrane, which may be amphiphilic, may comprise an ion channel such as a nanopore.

The membrane, which may be amphiphilic, may be a lipid bilayer or a synthetic layer. The synthetic layer may be a diblock or triblock copolymer.

The membrane may comprise an ion channel, such an ion selective channel, for the detection of anions and cations. The ion channel may be selected from known ionophores such as valinomycin, gramicidin and <NUM> crown <NUM> derivatives.

Returning to <FIG>, the sensing chamber has a liquid inlet <NUM>, and a liquid outlet <NUM>, for respectively passing liquid into and out of the sensing chamber <NUM>. In the inset of <FIG>, it is shown, in cross section through the device <NUM>, that the inlet <NUM> is in fluid communication with a sample input port <NUM>. The sample input port <NUM> is configured for introducing, e. g delivering, a sample to the microfluidic device <NUM>, e.g. for testing or sensing. A seal 33A, such as a plug, may be provided to seal or close the sample input port <NUM>, when the device <NUM> is in its inactive state, to avoid any fluid ingress or egress through the sample input port <NUM>. As such, the seal 33A may be provided within the sample input port <NUM> in the inactive state. Preferably the seal 33A is removable and replaceable. The sample input port may be desirably situated close to the sensing chamber, such as shown in <FIG>, wherein the port is provided directly at the sensing chamber. This reduces the volume of sample liquid that needs to be applied to the device by reducing the volume of the flow path.

Downstream from the outlet <NUM> of the sensing chamber <NUM> is a liquid collection channel <NUM>. The liquid collection channel can be a waste collection reservoir, and is for receiving fluid that has been expelled from the sensing chamber <NUM>. At the most downstream end, e.g. the end portion, of the collection channel <NUM> is a breather port <NUM>, for allowing gas to be expelled as the collection channel <NUM> receives liquid from the sensing chamber and fills with the liquid.

In the example shown in <FIG>, upstream of the sensing chamber <NUM>, is a liquid supply port <NUM>, which is optional. This port provides the opportunity to supply liquid, for example a buffer, into the device, once the device <NUM> is in its active state. It can also be used for delivering larger volume samples, if desired, and for high volume flushing/perfusion of previous samples from the sensing chamber <NUM> before a new sample is delivered.

As described below in more, the device is configured to accept a sample at the sample input port, which is subsequently drawn into the sensing chamber of its own accord, without the aid of an external force or pressure, e.g. by capillary pressure as described below. This removes the need for the user to introduce a test liquid into the device under an applied positive pressure.

In <FIG>, the device <NUM> is in an inactive state. This is achieved by the provision of a valve <NUM> which is configured in a close state, which is a state that does not permit fluid flow between the liquid collection channel <NUM> and the sensing chamber <NUM>, as well as the provision of the seal 33A on the sample input port <NUM>, which seals or closes the sample input port <NUM>. In the inactive state, as shown in <FIG>, flow through the sensing chamber <NUM> is not possible. The valve <NUM> in a closed state is a structure that serves as a flow path interruption between the liquid outlet <NUM> of the sensing chamber <NUM> and the liquid collection channel <NUM>, preventing upstream liquid (e.g., liquid from the sensing chamber <NUM>) from flowing into the liquid collection channel <NUM>. Similarly, the valve <NUM> in a closed state is a structure that serves as a flow path interruption between the supply port <NUM> and the sensing chamber <NUM>, preventing upstream liquid (e.g., liquid introduced through the supply port) from flowing into the sensing chamber <NUM>. As such, the sensing chamber <NUM> is isolated from the supply port <NUM> and the waste collection reservoir, in the form of liquid collection channel <NUM> (which may be open to the atmosphere). Further, the provision of the plug 33A sealing the sample input port <NUM> ensures that the sensing chamber <NUM> is entirely isolated. The plug 33A can also serve an additional purpose: when it is removed it can created a 'suction' in the inlet <NUM>, ensuring that the port <NUM> becomes wetted (and hence ready to receive sample fluid) as the plug 33A is removed. As such, the plug 33A provides a priming action. The priming action can draw fluid from the liquid collection channel (e.g., indirectly, displacing fluid into the sensing chamber <NUM>, which in turn is displaced into the inlet <NUM> and the port <NUM>) or a separate priming reservoir (see examples below).

In some embodiments, the valve 31serves a dual function. For example, as shown in <FIG>, the valve <NUM> can be configured in a state such that it acts an activation system. An activation system can complete the flow path between the liquid outlet <NUM> and the liquid collection channel <NUM> (and also the flow path between the supply port <NUM> and the sensing chamber <NUM>). Further, as discussed in more detail below, such activation occurs without draining the sensor chamber <NUM> of liquid. That is, the sensor <NUM> remains unexposed to gas or a gas/liquid interface after activation. In the example of <FIG>, this is achieved by rotation of the valve <NUM> by <NUM>° (from the depicted orientation) within the valve seat 31A. This leads to channels 31B of the valve completing flow path interruptions <NUM> between the liquid outlet <NUM> and the liquid collection channel <NUM>, as well as between the buffer liquid input port <NUM> and the sensing chamber <NUM>. In that active state, it is possible for liquid to flow from the buffer supply port <NUM> (also referred to herein as a 'purge port') through the sensing chamber <NUM> and into the liquid collection channel <NUM>. However such flow does not occur freely, as discussed in more detail in connections with <FIG>, below.

As a result, the sensing chamber <NUM> can be pre-filled with a conditioning liquid, such as a buffer, before turning the valve <NUM> into the position shown in <FIG>. It should be noted that the type of the conditioning liquid is not particularly limited according to the invention, but should be suitable according to the nature of the sensor <NUM>. Assuming the plug 33A has been inserted and that the sensor chamber <NUM> is appropriately filled so that there are no air bubbles, there is then no opportunity for the sensor to come into contact with a gas/liquid interface which would potentially be damaging to the sensor. As such, the device <NUM> can be robustly handled, without fear of damaging the sensor itself.

<FIG> shows a schematic of a device <NUM> corresponding to that of <FIG>. In <FIG>, the fluid channels are simply shown as lines. Further, the valve <NUM> is shown as two separate valves <NUM> upstream and downstream of the sensing chamber <NUM>. This is for the sake of clarity, but in some embodiments it may be desirable to have two separate valves <NUM> as shown.

<FIG> shows a schematic cross-section along the flow path through the device of <FIG>. This may not be a 'real' cross-section, in the sense that the flow path may not be linear in the way depicted in <FIG>. Nonetheless, the schematic is useful in understanding the flow paths available to the liquid in the device <NUM>. In particular, the upstream buffer supply/purge port <NUM> can be seen to be separated from the sensing chamber by upstream valve <NUM>. Further downstream breather port <NUM> can be seen to be separated from the sensing chamber <NUM> by downstream valve <NUM>. As such, it becomes readily apparent that the sensing chamber <NUM> may be filled with fluid and isolated from the upstream and downstream ports <NUM> and <NUM>. Further, by providing a seal over sample input port <NUM>, the sensing chamber can be entirely isolated.

It is also instructive to consider the scale of the features presented in <FIG>.

The purge port <NUM> and the sample input port <NUM> may be of similar design, as both are configured to receive a fluid to be delivered to the device <NUM>. In some embodiments, the ports <NUM> and/or <NUM> may be designed to accommodate the use of a liquid delivery device, e.g., a pipette tip, to introduce liquid into the ports. In preferred embodiments, both ports have a diameter of around <NUM> to <NUM>, which allows for wicking of fluid into the ports whilst also limiting the possibility of the device <NUM> free-draining of liquid (discussed in more detail below). In contrast the size of the downstream breather port <NUM> is less important, as it is not intended, in routine use, for accepting liquid delivery devices (e.g., pipettes) or delivering liquid.

The size of the sensor any vary and depend upon the type and the number of sensing elements, for example nanopores or ion selective electrodes, provided in the sensor. The size of the sensor <NUM> may be around <NUM> x <NUM>. As discussed above, it can be an array of sensing channels, with a microscopic surface geometry that contains membranes with nanopores.

The 'saturated volume' of the device <NUM> is the volume, e.g. the flow path volume, connecting between the valves <NUM> (one valve controls flow between the liquid outlet <NUM> and the liquid collection channel <NUM>, and another valve controls flow between the buffer liquid input port <NUM> and the sensing chamber <NUM>)that can be filled with liquid and sealed and isolated from the surroundings when the plug 33a is present, i.e. to seal the simple input port <NUM>, and valves <NUM> are configured in a closed state. In one embodiment, the saturated volume can be around <NUM>µl, which can vary depending on the design of the flow path in the devices described herein. However, smaller volumes are more preferable (to reduce the size of sample required, for example) and preferably the saturated volume is <NUM>µl or less. In other configurations, the provision of the purge port <NUM> (and connecting fluid path to the sensing chamber <NUM>) may not be necessary, in which case the saturated volume will extend from the sealed sample input port <NUM> to the sensing chamber 37and past the liquid outlet <NUM> to the flow path interruption <NUM>.

In contrast it is desirable for the liquid collection channel <NUM> to have a much larger volume, e.g., a volume that is at least <NUM>-fold larger, e.g., at least <NUM>-fold larger, at least <NUM>-fold larger, at least <NUM>-fold larger, or at least <NUM>-fold larger, than the saturated volume, so it can collect liquid expelled from the saturated volume over several cycles of testing and flushing. In one embodiment, the liquid collection channel <NUM> may have a volume of <NUM>µl, The hydraulic radius of the liquid collection channel is typically <NUM> or less.

The sizes of the valves <NUM> are not particularly important (and, as discussed below, alternative flow channel interruptions can be provided). They serve the function of isolating the saturated volume in connection with the plug 33a.

Further, even in the active state, the device is resistant to the sensing chamber <NUM> drying out. This is discussed below, with reference to <FIG>, which is a schematic cross-section of the sensing chamber <NUM> according to one embodiment and surrounding connections of the device <NUM> of <FIG> or <FIG>, for example.

In <FIG>, the sensor <NUM> is provided in a sensing chamber <NUM>. The sensing chamber liquid inlet <NUM> is connected upstream of the sensing chamber <NUM>, for simplicity of presentation (i.e. although the liquid inlet <NUM> is shown as entering sensing chamber <NUM> from above in <FIG> and <FIG>, the change in location in <FIG> does not affect the outcome of the analysis below). <FIG> shows a further restriction 38a in the diameter of the liquid inlet before it reaches the sensing chamber <NUM>. This could be for example, due to a widening of the input <NUM> to ease sample collection/provision. Downstream of the sensing chamber <NUM> is the liquid outlet <NUM> to the liquid collection channel <NUM>.

In the diagram, several parameters and dimensions are indicated. Heights (measured in metres) are indicated by the symbol h. Radii of curvature (measured in metres) are indicated by the symbol R. Radii of the tubular parts (measured in metres) are indicated by the symbol r. Surface tension (measured in N/m) is indicated by the symbol γ. Liquid density (measured in kg/m<NUM>) is indicated by the symbol ρ. Flow rates (measured in m<NUM>/s) is indicated by the symbol Q. Contact angles (measured in degrees) of liquid/gas meniscii with the device <NUM> walls, are indicated by the symbol θ. The subscripts "i" are used to refer to conditions at the inlet, the subscript "c" is used to indicate conditions at the constriction, and the subscript "o" is used to indicate conditions at the outlet.

The behaviour of fluid in the depicted system is controlled by capillary and/or Laplace bubble pressures and Poiseuille pressure drops to limit flow rates. As is generally known, capillary pressure at a meniscus can be calculated using the equation:
<MAT>
where R<NUM> and R<NUM> are radii of curvature in perpendicular directions. In the case of a tube, such as a capillary, the radius of curvature R<NUM> is the same as the radius of curvature R<NUM> and the radius of curvature is related to the radius of the tube by the following equation:
<MAT>.

Further, in a rectangular channel, where R<NUM> is not the same as R<NUM>, the radii of curvature are given by the following equations:
<MAT>
where a is e.g. the width of the rectangular section, and b is the height of the rectangular section.

For incompressible Newtonian fluids, assuming un-accelerated lamina flow in a pipe of constant circular cross-section that is substantially longer than its diameter, the pressure losses can be calculated from the Hagen-Poiseuille equation:
<MAT>
where µ is the viscosity (measured in N. s/m<NUM>) of the liquid, l is the length of the tube through which flow occurs (in metres) and r is the radius of the tube (in metres).

Finally, static pressure is calculated according to the following equation:
<MAT>
in which g is the acceleration due to gravity (<NUM>/s<NUM>), and h is the height of the fluid column.

<FIG> illustrates a scenario in which an activated device <NUM> is tilted to encourage fluid in the device <NUM> to drain into the liquid collection channel <NUM>. When considering whether fluid will remain at the opening to the inlet <NUM> (i.e. the sample input port <NUM>), it can be understood that the capillary pressure at the inlet (Pci) must be equal to or greater than the capillary pressure at the outlet plus any difference in hydrostatic pressure brought about by the inlet not being at the same height as the outlet (that difference in height being denoted as δh in <FIG> and the equations below) to avoid free draining. This is set out in the following equation:
<MAT>
From this equation, in combination with equations <NUM> and <NUM>, the maximum height difference δh before free draining occurs can be deduced (assuming the same contact angle θ at the inlet and the outlet):
<MAT>
<MAT>
<MAT>.

Substituting typical values of the relevant variables (e.g. ri=<NUM>, r<NUM>=<NUM>, θ=<NUM>°, ρ=<NUM>/m<NUM>, y=<NUM> N/m), indicates that a difference in height of about <NUM> can be achieved before the inlet de-wets.

Considering this further, and as shown in <FIG>, if the difference in height exceeds this critical value, the meniscus at the input port <NUM> will retreat to the inlet to the sensing chamber. In the limit before the meniscus detaches from that inlet (i.e. allowing gas into the sensing chamber <NUM>), the meniscus will have the maximum radius of curvature, being equal to the radius of the inlet (ignoring any constriction 38a). In that case, the contact angle θ will be zero and so the non-draining scenario is described by:
<MAT>
and in the limit:
<MAT>
<MAT>
<MAT>.

Again, using the typical values mentioned above, this indicates that the allowable difference in height between the inlet to the sensing chamber and the downstream meniscus and the waste outlet can be of the order of <NUM>. As a result, even if the inlet port <NUM> itself does not remain wetted, it is unlikely that the sensing chamber <NUM> will de-wet in normal use, as this is quite a substantial height difference, which would indicate an unusual amount of tilting.

Further, it is unlikely that the sensing chamber will de-wet by dripping out of the inlet. As shown in <FIG>, the other extreme to the scenario previously considered is the limit before the liquid starts to drip from the inlet. Again, in this case, the radius of curvature of the meniscus (this time in the other direction) to equal the radius of curvature of the inlet capillary itself. In this case, assuming that δh is the difference in height between the inlet meniscus and the outlet meniscus, and that the outlet is raised to encourage flow out of the inlet, the non-drip scenario is described by:
<MAT>
and in the limit:
<MAT>
<MAT>
<MAT>.

Once again, substituting typical values indicates that the maximum allowable δh is of the order of <NUM>. Once again, this is well within a tolerable range for normal handling in use.

Therefore, from the above analysis, it can be seen that once the device <NUM> is switched from an inactive state to an active state, the liquid sensor <NUM> will remain wetted, in normal conditions. Further, even if the input port <NUM> becomes de-wetted, this will not necessarily result in the sensor being exposed to a gas/liquid interface, because the interface is likely to be pinned at the entrance to the sensing chamber <NUM>.

It is also possible to consider how this stability affects the ability to deliver sample to the sensing chamber <NUM>. In <FIG> a first extreme of wicking a fluid from a 'puddle' into the input port <NUM> is considered. In that case, the capillary pressure acting to drawn the fluid in is balanced by the laminar flow losses in the inlet (having length l):
<MAT>
<MAT>.

Applying the typical values (including µ = <NUM>. 9x10-<NUM> N. s/m<NUM> and l = <NUM>), a flowrate of <NUM>µl/s can be derived. This is more than sufficient when sample volumes are low, such as in microfluidic devices having a total volume of around <NUM>µl for example.

In another extreme, shown in <FIG>, the sample may be supplied to the input port <NUM> as droplet (e.g. a drop of blood from a finger or a droplet from a pipette). In that case, the driving force is the Laplace bubble pressure for the droplet:
<MAT>.

For a <NUM> droplet, the pressure is around <NUM> Pa (using the typical values). A 2D approximation, in comparison to the puddle wicking scenario, indicates that this around <NUM> times greater, and so a flowrate of around <NUM>µl/s can be expected for the same viscous drag.

As a result, it can be seen that the device <NUM>, e.g., the dimensions of the inlet <NUM> and outlet <NUM> as well as the liquid collection channel <NUM>, can be configured not only to robustly maintain a wetted state in the sensing chamber <NUM>, but may also to operate easily to draw fluid into the sensing chamber <NUM>. When the sample has been supplied, the device <NUM> returns to a new equilibrium, in which the device will not de-wet/drain dry. That is, the device <NUM> is configured to avoid free draining of the sensing chamber <NUM>. In particular, the sample input port <NUM>, the sensing chamber inlet <NUM> and the liquid collection channel <NUM> are configured to avoid such draining, such that when the activation system has been operated to complete the flow path downstream of the sensing chamber <NUM>, the sensor <NUM> remains unexposed to gas or a gas/liquid interface even whilst the device <NUM> is tilted. Put another way, the sensing chamber inlet <NUM> and the liquid collection channel <NUM> are thus configured to balance capillary pressures and flow resistances to avoid free draining of the sensing chamber <NUM> when the flow path is completed.

In considering how the sensing chamber inlet and liquid collection channel are configured to balance capillary pressures and flow resistances, it is helpful to consider the how the device practically functions. Priming of the device into its 'active state' is achieved by completing the flow path between the liquid outlet and the liquid collection channel <NUM>. The capillary pressures at the downstream collection channel and the sample input port are balanced such that following activation of the device, gas is not drawn into the sample inlet port, and the sample input port presents a wet surface to a test liquid. If it were the case that the capillary pressure at the liquid collection channel was greater than at the sample input port, the device would drain following activation, with buffer liquid being drawn into the collection channel.

Following activation of the device and prior to addition of a test liquid, the device may be considered to be at equilibrium, namely wherein the pressure at the input port is equal to the pressure at the downstream collection channel. In this equilibrium state, liquid remains in the sensing chamber and gas is not drawn into the input port such that the input port presents a wet surface to a test liquid to be introduced into the device. The device is configured to ensure that balance of forces are such that the sensing chamber remains filled with liquid and that liquid remains (at least partially) in the inlet, in the outlet and the liquid collection channel. If the equilibrium is disturbed by shifting the position of the liquid (without adding or removing liquid to the system) there is an impetus to return to that equilibrium. When the liquid is moved, it will create new gas/liquid interfaces. Thus this balance of force and restoring of the equilibrium will effectively be controlled by the capillary forces at those interfaces.

Ideally, the balance of force is such that following activation or addition of a volume of liquid, the liquid fills the sample input port and presents a wet surface. However, some adjustment may be necessary following activation/perfusion in order to provide a wet surface at the sample input port. In any case, the inlet port is configured such that following addition of a test liquid to the port, the capillary pressure at the input port is less than the capillary pressure at the downstream collection channel. This provides the driving force to draw test liquid into the device thereby displacing liquid from the sensing chamber into the liquid collection channel. This continues until the pressures at the sample input port and the liquid collection channel once more reach equilibrium. This driving force may be provided by the change in shape of a volume of liquid applied to the input port, as outlined by equation <NUM>, wherein a volume of fluid applied to the port, such as shown in <FIG> having a particular radius of curvature, 'collapses' into the port, thus reducing the effective rate of curvature and supplying a Laplace pressure (there may also be other components of the overall driving pressure, e.g. due to the head of pressure of the volume of the test liquid, which will reduce in time as that volume is introduced into the device). The liquid inlet diameter is advantageously less than the diameter of the liquid collection channel such that fluid is located at the input port and over the sensor and that the liquid is present in the device as a continuous phase as opposed to discrete phases separated by gas.

A further volume of sample may be subsequently applied to the device in order to further displace buffer liquid from the sensing chamber. This may be repeated a number of times such that the buffer liquid is removed from the sensor in sensing chamber and replaced by the test liquid. The number of times required to completely displace buffer liquid from the sensor will be determined by the internal volume of the device, the volume of test sample applied as well as the degree of driving force that may be achieved.

Thus in this particular embodiment, a test liquid may be drawn into the device and displace the buffer liquid without the need for the user to apply additional positive pressure, for example by use of a pipette. This has the advantage of simplifying the application of a test liquid to the device. Surprisingly and advantageously, the invention provides a device that may be provided in a 'wet state' wherein liquid may be displaced from the device by the mere application of another liquid to the device.

Further, the above analysis considers only a linear configuration. <FIG> is a schematic plan of an example microfluidic device <NUM> in an alternative configuration. In this configuration, the waste collection channel <NUM>, downstream of the outlet <NUM> from the chamber <NUM> is provided in a twisting or tortuous path, to maintain the channel <NUM> within a defined maximum radius from the sample input port <NUM>. Such a configuration allows for a large length (and hence volume) of the waste collection channel <NUM>, whilst keeping the maximum distance of the downstream meniscus within the maximum radius. That maximum allowable radius is dictated by the allowable difference in height, between the input port <NUM> and the downstream meniscus, that does not result in the sensor chamber <NUM> draining. Put another way, a purely linear arrangement would result in the meniscus reaching the maximum allowable height difference after a certain amount of use, but in the tortuous arrangement the meniscus is diverted back to be closer to the input port <NUM> and so the critical condition is not reached. That is because the tortuous arrangement maintains the downstream meniscus closer to the input port, a larger angle of tilt is required to obtain the same difference in height (for any given amount of liquid in the downstream channel assuming the dimensions of the channel do not change, only the path of the channel).

Further, even if the sample input port <NUM> does de-wet, device <NUM> may be operable so as to re-prime the system in the active state. In the <FIG> and <FIG> example, additional liquid can be supplied to the inlet <NUM> directly via the sample input port <NUM>. Alternatively, re-wetting could be encouraged by drawing liquid back through from the outlet <NUM> and sensing chamber <NUM> into the inlet <NUM> and sample input port <NUM>. Another alternative is for additional fluid to be provided via buffer supply port <NUM>.

However, in other embodiments at least the downstream part of valve <NUM> of the <FIG> embodiment might be omitted, and replaced by another form flow path interruption. For example, the downstream waste channel <NUM> could be isolated from the saturated volume by a surface treatment (e.g. something hydrophobic), which would effectively form a barrier to upstream liquid until the interruption was removed by forced flow initiated by a priming or flushing action. Such a surface treatment would effectively be a hydrophobic valve. In effect, the interruption <NUM> may be any flow obstacle that may be removed or overcome by an activation system.

<FIG> are example embodiments of the devices described herein.

<FIG> shows a device <NUM>, in which a pipette <NUM> is being used to provide sample to the input port <NUM>. The port <NUM> is provided centrally above the sensor in the sensing chamber <NUM>, in this example. In this example, and the example of <FIG>, a valve <NUM> of the type illustrated in <FIG> (i.e. a single valve which opens and closes both the upstream and downstream channels to the sample chamber <NUM>) is provided.

In <FIG>, the main image of the device <NUM> shows the presence of the plug or seal 33A on the sample input port. The expanded image shows the plug 33A removed, revealing the sample input port <NUM> below. In this example the sample input port <NUM> is provided at the most upstream end of the chamber <NUM> containing the sensor <NUM>. This is advantageous because, in the activated state with the upstream purge port <NUM> closed, the sample chamber <NUM> can be filled quickly by forcing sample through port <NUM>, so as to displace buffer liquid already in the sample chamber downstream (i.e. no upstream displacement is possible, due to the closed purge port <NUM>).

Some operating scenarios of the microfluidic device <NUM> of the present invention (i.e. as exemplified by <FIG>) are now discussed.

In a first configuration, valve <NUM> is open, as is sample port <NUM> (i.e. plug 33A is not present). Purge port/buffer supply port <NUM> is closed. In this configuration, a pipette may be used at breather port <NUM> to withdraw all liquid, including from the sample cell. Alternatively, if liquid is supplied to this port, it will displace fluid through the waste reservoir <NUM> into the sensor chamber <NUM> and out of the sample port <NUM>.

In another configuration, valve <NUM> and sample input port <NUM> are open and breather port <NUM> is sealed. In this scenario, a pipette can provide fluid into the purge port <NUM>, which will force fluid through the cell, into the sample chamber <NUM> (i.e. through the saturated volume) and downstream into the reservoir <NUM>. This will also cause the sample input port <NUM> to wet if it has de-wetted. Alternatively, if the pipette is used to drain liquid, it is possible to drain the sensor chamber and the upstream portion of the device.

In another configuration, the valve <NUM>, the purge port <NUM> and the breather port <NUM> are all open. In this configuration, a pipette may be supplied to the sample input port <NUM> to provide sample into the sensor chamber. Alternatively, if the pipette is applied to drain liquid from the sample input port <NUM>, the sensor chamber <NUM> can be drained. If this is done slowly, it is also possible to draw liquid back from the waste reservoir <NUM>.

In another scenario, the valve <NUM> and the purge port <NUM> are open, whilst the breather port <NUM> is closed. In this scenario, it is possible to apply fluid via the sample input port <NUM> to force fluid out of the purge port <NUM>, if required. Alternatively, extracting liquid from the sample input port <NUM> will draw air into the cell via the purge port.

In another configuration, the valve <NUM> and the breather port <NUM> are open, whilst the purge port <NUM> is closed. In this scenario, a fluid supplied to the sample input port <NUM> can be pushed into the cell more quickly, without fluid spilling from the purge port. Alternatively, extracting fluid from the sample input port <NUM> in this scenario will drain the cell and the downstream waste, if done quickly.

In a further two configurations, the valve <NUM> is closed. In some configurations, closing valve <NUM> may connect the upstream purge port <NUM> to the downstream waste reservoir <NUM>, at the same time as isolating the sensing chamber (i.e. in the arrangement of <FIG>, the upstream purge port <NUM> is not so connected to the downstream waste <NUM>, but increasing the length of the valve channel 31B could result in such a connection). When such a connection is made, it is possible to either fill the waste from the breather port <NUM> (i.e. so that any liquid spills from the purge port <NUM>) or to fill the waste from the purge port <NUM> (i.e. so that any liquid spills from the breather port <NUM>). Further, the waste may be emptied by withdrawing liquid from either of the purge port <NUM> or the breather port <NUM> (assuming the other one is open).

<FIG> shows an example design of a guide channel <NUM> extending from the sample input port <NUM> of a portion of the device <NUM>. The guide channel tapers outwardly from the port and serves to guide a pipette tip <NUM> applied to the channel to the sample input port. The guide channel also slopes downwardly towards the sample input port which aids travel of the pipette tip to the port. Once the pipette tip has been guided to the sample input port the user is able to apply liquid sample to the port from the pipette tip. Collar <NUM> serves to delimit the area of the channel and act as a support for a pipette tip applied directly to the sample input port. Due to the dimensions of the port, which may be for example be <NUM> or less in diameter, it may be challenging for the user to locate the pipette tip directly at the sample input port itself. The outwardly tapering channel area provides a larger target area for the user to locate and guide a pipette tip to the sample input port, should this be required.

Claim 1:
A microfluidic device (<NUM>) for analysing a test liquid comprising:
a sensor (<NUM>) provided in a sensing chamber (<NUM>), the sensor (<NUM>) comprising a membrane;
a sensing chamber inlet (<NUM>) and a sensing chamber outlet (<NUM>) connecting to the sensing chamber (<NUM>) for respectively passing liquid into and out of the sensing chamber (<NUM>),
a sample input port (<NUM>, <NUM>) in fluid communication with the inlet (<NUM>), for introducing a test liquid into the microfluidic device;
a liquid collection channel (<NUM>) downstream of the outlet (<NUM>);
a flow path comprising the sample input port (<NUM>,<NUM>), the sensing chamber inlet (<NUM>), the sensing chamber (<NUM>), the sensing chamber outlet (<NUM>) and the liquid collection channel (<NUM>), and wherein the sensing chamber inlet (<NUM>), sensing chamber (<NUM>) and liquid collection channel (<NUM>) are arranged such that displacing liquid from the liquid collection channel (<NUM>) into the sensing chamber (<NUM>) in turn displaces liquid from the sensing chamber (<NUM>) into the sensing chamber inlet (<NUM>);
a flow path interruption (<NUM>) between the sensing chamber outlet (<NUM>) and the liquid collection channel (<NUM>), wherein the microfluidic device is configured to be changeable from an inactive state, in which liquid is prevented by the flow path interruption (<NUM>) from flowing into the liquid collection channel (<NUM>) from upstream, to an active state in which the flow path between the sample input port (<NUM>, <NUM>) and the liquid collection channel (<NUM>) is completed; and
a buffer liquid, filling from the sample input port (<NUM>, <NUM>) to the flow path interruption (<NUM>) such that the sensor (<NUM>) is covered by liquid and unexposed to a gas or gas/liquid interface;
wherein the device is configured such that following a change of the device into the active state, the capillary pressure at the liquid collection channel (<NUM>) and the capillary pressure at the sample input port (<NUM>, <NUM>) are balanced such that the buffer liquid does not freely drain out of the sensing chamber (<NUM>) and one or more volumes of test liquid may be introduced, via a wet surface of the input port (<NUM>, <NUM>), such that the capillary pressure at the input port (<NUM>, <NUM>) is less than the capillary pressure at the liquid collection channel (<NUM>) so as to draw the test liquid into the device and displace the buffer liquid into the liquid collection channel (<NUM>).