Recent Advances of Fluid Manipulation Technologies in Microfluidic Paper-Based Analytical Devices (μPADs) toward Multi-Step Assays

Microfluidic paper-based analytical devices (μPADs) have been suggested as alternatives for developing countries with suboptimal medical conditions because of their low diagnostic cost, high portability, and disposable characteristics. Recently, paper-based diagnostic devices enabling multi-step assays have been drawing attention, as they allow complicated tests, such as enzyme-linked immunosorbent assay (ELISA) and polymerase chain reaction (PCR), which were previously only conducted in the laboratory, to be performed on-site. In addition, user convenience and price of paper-based diagnostic devices are other competitive points over other point-of-care testing (POCT) devices, which are more critical in developing countries. Fluid manipulation technologies in paper play a key role in realizing multi-step assays via μPADs, and the expansion of biochemical applications will provide developing countries with more medical benefits. Therefore, we herein aimed to investigate recent fluid manipulation technologies utilized in paper-based devices and to introduce various approaches adopting several principles to control fluids on papers. Fluid manipulation technologies are classified into passive and active methods. While passive valves are structurally simple and easy to fabricate, they are difficult to control in terms of flow at a specific spatiotemporal condition. On the contrary, active valves are more complicated and mostly require external systems, but they provide much freedom of fluid manipulation and programmable operation. Both technologies have been revolutionized in the way to compensate for their limitations, and their advances will lead to improved performance of μPADs, increasing the level of healthcare around the world.


Introduction
Paper-based diagnostic devices have been widely used for the past decades because of their capability to enable cost-effective point-of-care testing (POCT). In addition, their simple operation and capillary action without the need for external equipment for fluid transport have accelerated the spread of such technology. Besides these characteristics, POCT has been highlighted as an appropriate technology for developing countries with suboptimal medical conditions, as it enables cheap and quick diagnosis. Many diagnostic products, such as the dipstick test and lateral flow assay (LFA), have already been commercialized, which are of single-test type and do not require the injection of additional paper-based diagnostic platforms, simplicity, and cost-effectiveness. In this paper, we analyzed the research trends for paper-based diagnostic devices being researched and developed in terms of the fluid manipulation of paper microfluidics. Furthermore, we discussed the benefits and limitations of these technologies, as well as future perspectives, by introducing the application areas in which multi-step assay technologies are applied.

Fluid Manipulation Technologies in Microfluidic Paper-based Analytical Devices (µPADs)
A fluid manipulation technology, which can control the flow of reagents and samples, is the most important element in paper-based diagnostic devices with multi-step assays. This is because it allows the required reagents to flow selectively as needed, and fluid control is essential for multi-step tests using various reagents, such as antibody solutions, washing buffers, and substrate solutions. In order to implement multi-step tests in a paper microfluidic device, it is very important to understand the fluid's behavior on paper. In paper microfluidic devices, the flow based on the capillary tube is governed by the capillary pressure: where P c is the capillary pressure, R is the radius of the capillary tube, γ is the fluid surface tension, and θ is the solid-liquid contact angle. Based on combination with Hagen-Poiseuille's law, based on the assumptions of the fluid-laminar, incompressible, and Newtonian-the fluid in this paper follows the Lucas-Washburn equation [42,43] for a one-dimensional model in cylindrical tubes, which can be derived from where L is the fluid column length, and µ is the fluid dynamic viscosity. The capillary is the driving force for fluid to move into the tube, and the velocity of the fluid is reduced as the fluid penetrates into the capillary. More detailed discussions can be found in other reports [11,12,44,45]. Fluid manipulation technology can be divided into passive and active methods according to the operation modes. In general, passive valves control fluids by changing the structure of the paper or by chemically treating the paper, while active valves use external inputs, including mechanical or electrical operation (Figure 1). A passive valve usually controls fluid flow by restructuring or chemical treatment of the device itself. In general, geometry and chemical-based fluid manipulation technologies are applied to passive valves. Passive valves are structurally simple and easy to fabricate but have a disadvantage of difficulty in terms of control fluid flow. A typical geometry-based fluid manipulation technology is to control the flow velocity by changing the position of the sudden expansion structure on the strip with the same width [46]. When the sudden expansion structure is close to the inlet, it shows a relatively short transport length compared to the far distance ( Figure 1A, left). Such a valve is structurally simple, which is advantageous for mass production and cost-effectiveness; however, it presents difficulties in response speed control of the fluid because the fluid movement is controlled by the structure of a predetermined paper strip. Another passive valve technology is chemical-based fluid manipulation that works on the principle of fluid diodes using surfactants ( Figure 1A, right). This method also simplifies the manufacturing process because it uses properties that can flow into the hydrophobic region as the surfactant dissolves [47].
In contrast, active valves primarily control the flow of fluid through geometry transformation and electrical or mechanical actuation. Mechanical-actuation-based fluid manipulation is one of the main active valve categories. For instance, solenoid-driven pressure valves delay or stop the flow of fluid depending on the pressure applied to the paper [48]. Applying voltage to the solenoid actuator causes the plunger head to pressurize the paper strip and stop the flow of fluid ( Figure 1B). The active valve has the advantages of fast response, reproducibility, and compatibility with biological samples by no use of surfactants and chemicals. In addition, it does not require complicated and long paper channels frequently shown in passive valves. Since the pressure-driven valve system utilizes an Arduino microprocessor, it enables programmable fluidic control and repeatable valve operations. Despite its unique and versatile performance, a critical disadvantage is that the additional instruments, the solenoid valves, and the microprocessor make the device larger and increase the cost. and θ is the solid-liquid contact angle. Based on combination with Hagen-Poiseuille's law, based on the assumptions of the fluid-laminar, incompressible, and Newtonian-the fluid in this paper follows the Lucas-Washburn equation [42,43] for a one-dimensional model in cylindrical tubes, which can be derived from where L is the fluid column length, and μ is the fluid dynamic viscosity. The capillary is the driving force for fluid to move into the tube, and the velocity of the fluid is reduced as the fluid penetrates into the capillary. More detailed discussions can be found in other reports [11,12,44,45].   [46]. Chemical-based fluid control: Principle of fluidic diodes using a surfactant. Figure reprinted with permission from [47]. (B) Active method: Solenoid-driven pressure valve pressurizes the paper, resulting in the disconnection of the fluid channels. Figure reprinted with permission from [48].
A number of fluid control technologies based on the function of passive and active valves have been developed. Among other technologies, flow rate controlling and switching technologies have made a lot of progress. The controlling flow rate is a method of changing the velocity of a fluid on paper through structural, chemical, and mechanical ways. A representative method is to induce a programmable flow delay using dissolvable sugar ( Figure 2A) [49]. This device uses various strips coated with 10%-70% dried sucrose to control the flow rate as intended. When the dried sucrose meets the fluid and dissolves, it increases the viscosity of the fluid and thus causes a fluid delay. Using this delay effect, multi-step testing is possible by adjusting the fluid velocity of each reagent on the paper. Unlike the flow rate controlling way, a switching method allows fluid to flow or not. A typical case is a way that allows fluid to flow by pressing a folded switch on a cut piece of paper to connect a separate fluid path ( Figure 2B) [18]. This switching method enables multi-step assays through sequential reagent flow by turning each reagent flow on/off. The following sections examine in detail the functions and applications of passive and active fluid manipulation technologies.

Passive Fluid Manipulation
Paper-based analytical devices fundamentally exploit capillary action to transport the fluid. Although the control of fluid by relying solely on capillary action in µPADs is so passive that it limits the flexibility of fluid manipulation, it is still the most widely used method due to its simplicity, affordability, and expandability. The chemical treatment and geometry transformation of papers can be critical parameters in terms of fluid control in µPADs. A number of methods have been used to manipulate fluid delivery, including adjustment of the paper dimensions, control of the paper permeability, switching strategies, and change of the surface chemistry of the fluidic path on the paper. paper through structural, chemical, and mechanical ways. A representative method is to induce a programmable flow delay using dissolvable sugar (Figure 2A) [49]. This device uses various strips coated with 10%-70% dried sucrose to control the flow rate as intended. When the dried sucrose meets the fluid and dissolves, it increases the viscosity of the fluid and thus causes a fluid delay. Using this delay effect, multi-step testing is possible by adjusting the fluid velocity of each reagent on the paper. Unlike the flow rate controlling way, a switching method allows fluid to flow or not. A typical case is a way that allows fluid to flow by pressing a folded switch on a cut piece of paper to connect a separate fluid path ( Figure 2B) [18]. This switching method enables multi-step assays through sequential reagent flow by turning each reagent flow on/off. The following sections examine in detail the functions and applications of passive and active fluid manipulation technologies.  [49]. (B) Switching method using cut paper, which enables fluid flow by pressing the cut paper and connecting the passage of fluid. Figure reprinted with permission from [18].

Chemical-Based Fluid Manipulation
Chemical-based fluid manipulation is a method of changing the wicking properties of paper by chemical treatment and can be divided into the fluid velocity control technique and the switching technique. Table 1 summarizes various chemical treatment-based fluid manipulation technologies for µPADs. Table 1. Chemical-based fluid manipulation techniques for microfluidic paper-based analytical devices (µPADs).

Function Application
Ref.
Above all, in the aspects of fluid control techniques, a great deal of research, including a method to delay the flow rate using dissoluble material (sucrose [49], trehalose [50]), has been conducted. A fluid delay channel is fabricated by injecting a diluted trehalose or sucrose solution into the strip and drying it. Then, when the injected sample reaches the dried dissolvable material, the dried material dissolves, and a fluid delay effect occurs by the dissolving time and the viscosity change. As shown in Figure 3A, trehalose is thickly dried on the right fork of the Y-shaped device and thinly dried on the left one. Subsequent injection of red dye into the inlet has resulted in a longer fluid delay time on the right fork. In addition, research on increasing the fluid velocity by patterning the toner several times on a paper strip through laser printing has been conducted [51]. On patterning the toner with hydrophobic properties above and below the channel, the flow rate increases by preventing the evaporation of a fluid, and it is also increased with the number of times of toner patterning. As Figure 3B shows, the flow rates have increased in the order of channels printed 6, 4, and 0 times under a 53% humidity environment after 25 min. Besides these technologies, methods of adding paraffin wax-coated layers on three-dimensional (3D) fluidic channels have been developed [52,53]. Coating hydrophobic paraffin on the channel can control the delay of fluid depending on the concentration. In Figure 3C, a fluid delay effect is achieved by stacking each micropatterned layer and interposing paraffin wax-patterned layers between them. In a similar way, Weng et al. studied the effect of fluid delay on the paper channel according to the color and saturation degree of colored wax [54]. Cyan-and yellow-colored waxes have a fine, porous-type structure when patterned on paper and have higher permeability than their black and magenta counterparts. Based on these characteristics, this group confirmed that adjusting the concentrations of colored wax controlled the flow rate delay effects ( Figure 4A). As another approach using the patterning technique, a method of controlling the flow of fluid by forming a barrier pattern through inkjet printing on nitrocellulose paper has been studied [55]. Through various patterns, these devices can control the activation time by dissolving the dried reagents. In the case of Figure 4B, the sample flows to both the delaying and non-delaying channels, and the enzyme-linked detection antibody located in the non-delaying channel reacts with the analyte of the sample. Afterward, the enzyme-detection antibody complexes bind specifically to the capture antibody in the control and detection zones. On the contrary, the substrate on the delaying channel is rehydrated and switched from the sample fluid containing the previous complexes to the sample fluid, including the substrate (y+s), which allows the substrate to react with the enzyme-detection antibody complexes. This principle of operation enables sequential multi-step ELISA in a single step.
Micromachines 2020, 11, 269 6 of 29 times on a paper strip through laser printing has been conducted [51]. On patterning the toner with hydrophobic properties above and below the channel, the flow rate increases by preventing the evaporation of a fluid, and it is also increased with the number of times of toner patterning. As Figure  3B shows, the flow rates have increased in the order of channels printed 6, 4, and 0 times under a 53% humidity environment after 25 min. Besides these technologies, methods of adding paraffin waxcoated layers on three-dimensional (3D) fluidic channels have been developed [52,53]. Coating hydrophobic paraffin on the channel can control the delay of fluid depending on the concentration. In Figure 3C, a fluid delay effect is achieved by stacking each micropatterned layer and interposing paraffin wax-patterned layers between them. In a similar way, Weng et al. studied the effect of fluid delay on the paper channel according to the color and saturation degree of colored wax [54]. Cyanand yellow-colored waxes have a fine, porous-type structure when patterned on paper and have higher permeability than their black and magenta counterparts. Based on these characteristics, this group confirmed that adjusting the concentrations of colored wax controlled the flow rate delay effects ( Figure 4A). As another approach using the patterning technique, a method of controlling the flow of fluid by forming a barrier pattern through inkjet printing on nitrocellulose paper has been studied [55]. Through various patterns, these devices can control the activation time by dissolving the dried reagents. In the case of Figure 4B, the sample flows to both the delaying and non-delaying channels, and the enzyme-linked detection antibody located in the non-delaying channel reacts with the analyte of the sample. Afterward, the enzyme-detection antibody complexes bind specifically to the capture antibody in the control and detection zones. On the contrary, the substrate on the delaying channel is rehydrated and switched from the sample fluid containing the previous complexes to the sample fluid, including the substrate (y+s), which allows the substrate to react with the enzymedetection antibody complexes. This principle of operation enables sequential multi-step ELISA in a single step.    [55].
In addition to fluid velocity control technology, switching methods using the principle of linking disconnected parts or blocking channels are also widely used in passive fluid manipulation technology. Research on a soluble bridge using the dissolving property of pullulan film and dried sugar has been carried out [32,56]. The soluble bridge is located between channels and acts as a temporal channel. After application of the sample, the bridge begins to dissolve slowly and functions as an on/off switch, when the volume of injected fluid reaches a certain amount ( Figure 5A). However, this method has difficulty in precisely controlling the time when the bridge dissolves and breaks off. As another switching technique, a method to control the flow of fluids by alkyl ketene dimer (AKD), which is a hydrophobic material, has been developed [57]. The channel is patterned with high-load AKD, and the valve part that prevents the flow of fluid is patterned by low-load AKD. While highload AKD retains its hydrophobic properties even with ethanol injection, low-load AKD loses its hydrophobic properties, allowing fluid to flow. Using this principle, it is possible to control the stepwise flow by opening the valve with an eluent (55% ethanol) after the application of the sample ( Figure 5B). However, it is not guaranteed how the ethanol as an eluent will affect the sample.
Studies on fluid manipulation technology using surfactants have been conducted [47,58]. A fluid diode technology based on surfactant uses hydrophilic channels with dried surfactant made by the patterning of hydrophobic materials. When the sample is injected, the surfactant in the hydrophilic region dissolves. Consequently, the surface tension of the fluid decreases, and thus, the fluid flows into the hydrophobic region. The fluid diode has a specific structure in which the flow is blocked when the sample is introduced from the cathode side, whereas the fluid flows when the sample comes from the anode side ( Figure 5C). The fluid control method with surfactants and dissolving materials, such as sucrose, has the advantage of being simple in structure, but using materials, such as ethanol, as mentioned in previous studies, may affect samples or downstream reactions. However, if verified materials, such as tween, which is often utilized in immunoassay using various antibodies, or sucrose, which is widely applied to dry and preserve antibody conjugates used in multi-step reactions, such as ELISA, are used, accurate assays can be performed without any significant impact on downstream action [49,61]. In addition, optimizing the deposition concentration of the surfactant or sugar has little effect on valve opening, on the solubility of each reagent, or on delivery capability, thus showing In addition to fluid velocity control technology, switching methods using the principle of linking disconnected parts or blocking channels are also widely used in passive fluid manipulation technology. Research on a soluble bridge using the dissolving property of pullulan film and dried sugar has been carried out [32,56]. The soluble bridge is located between channels and acts as a temporal channel. After application of the sample, the bridge begins to dissolve slowly and functions as an on/off switch, when the volume of injected fluid reaches a certain amount ( Figure 5A). However, this method has difficulty in precisely controlling the time when the bridge dissolves and breaks off. As another switching technique, a method to control the flow of fluids by alkyl ketene dimer (AKD), which is a hydrophobic material, has been developed [57]. The channel is patterned with high-load AKD, and the valve part that prevents the flow of fluid is patterned by low-load AKD. While high-load AKD retains its hydrophobic properties even with ethanol injection, low-load AKD loses its hydrophobic properties, allowing fluid to flow. Using this principle, it is possible to control the stepwise flow by opening the valve with an eluent (55% ethanol) after the application of the sample ( Figure 5B). However, it is not guaranteed how the ethanol as an eluent will affect the sample.
Studies on fluid manipulation technology using surfactants have been conducted [47,58]. A fluid diode technology based on surfactant uses hydrophilic channels with dried surfactant made by the patterning of hydrophobic materials. When the sample is injected, the surfactant in the hydrophilic region dissolves. Consequently, the surface tension of the fluid decreases, and thus, the fluid flows into the hydrophobic region. The fluid diode has a specific structure in which the flow is blocked when the sample is introduced from the cathode side, whereas the fluid flows when the sample comes from the anode side ( Figure 5C). The fluid control method with surfactants and dissolving materials, such as sucrose, has the advantage of being simple in structure, but using materials, such as ethanol, as mentioned in previous studies, may affect samples or downstream reactions. However, if verified materials, such as tween, which is often utilized in immunoassay using various antibodies, or sucrose, which is widely applied to dry and preserve antibody conjugates used in multi-step reactions, such as ELISA, are used, accurate assays can be performed without any significant impact on downstream action [49,61]. In addition, optimizing the deposition concentration of the surfactant or sugar has little effect on valve opening, on the solubility of each reagent, or on delivery capability, thus showing sensitivity that is equivalent to the existing methods [58]. In addition, several attempts have been made to control the flow of fluid through target-responsive hydrogels [59,60]. When aptamer cross-linked hydrogels encounter a target sample, they undergo the gel-sol phase transformation and flow. However, in the case of a fluid without the target sample, this phenomenon does not occur; thus, the hydrogel interferes with the flow of fluid in gel form. Based on this principle, hydrogels can be used as a switch to control fluid flow.
Micromachines 2020, 11, 269 8 of 29 sensitivity that is equivalent to the existing methods [58]. In addition, several attempts have been made to control the flow of fluid through target-responsive hydrogels [59,60]. When aptamer crosslinked hydrogels encounter a target sample, they undergo the gel-sol phase transformation and flow. However, in the case of a fluid without the target sample, this phenomenon does not occur; thus, the hydrogel interferes with the flow of fluid in gel form. Based on this principle, hydrogels can be used as a switch to control fluid flow.

Geometry-based Fluid Manipulation
Geometry-based fluid manipulation technology is a method of adjusting the flow of fluid by altering the structural shape of the paper itself or by adding additional structures. There are representative methods of cutting, structural change, and attaching additional materials in this manipulation technology. Table 2 summarizes the studies on geometry-based fluid manipulation techniques for μPADs.
Cutting the paper strip is a typical method in geometry-based fluid manipulation. A lot of studies have been conducted regarding how to control the flow rate by adjusting the width and length of the paper channel [44,46,50,62]. Figure 6A shows that the flow rate decreases as the width of the paper becomes wider. This is because the longer the width and length of the paper, the greater the resistance and the slower the fluid velocity. Other researches have attempted to increase the flow rate by adding a layer with hollow regions cut out in the form of a channel to a layer with an existing hydrophilic channel [34,35,38,[64][65][66]. As shown in Figure 6B, the flow rate of the single drop of liquid injected into the hollow channel is about 7 times higher than that on a normal paper channel by forming a rapid, pressure-driven flow of about ~0.2 mbar [34].
Cutting the paper strip is a typical method in geometry-based fluid manipulation. A lot of studies have been conducted regarding how to control the flow rate by adjusting the width and length of the paper channel [44,46,50,62]. Figure 6A shows that the flow rate decreases as the width of the paper becomes wider. This is because the longer the width and length of the paper, the greater the resistance and the slower the fluid velocity. Other researches have attempted to increase the flow rate by adding a layer with hollow regions cut out in the form of a channel to a layer with an existing hydrophilic channel [34,35,38,[64][65][66]. As shown in Figure 6B, the flow rate of the single drop of liquid injected into the hollow channel is about 7 times higher than that on a normal paper channel by forming a rapid, pressure-driven flow of about~0.2 mbar [34].  [76].
The methods using the structural change of paper or a combination of various kinds of papers and attaching additional materials have been frequently applied in μPADs. These methods have a principle that adjusts the flow rate by reducing the pore size and cross-sectional area on the paper by applying pressure to the paper [67][68][69]. If the pore size and cross-sectional area are reduced, the fluid resistance increases and, consequently, the flow rate decreases. As shown in Figure 7A, it is confirmed that the fluid transports differently depending on the pressure applied to the paper strips. The advantage of this approach is that a permanent fluid delay effect can be obtained by simply applying pressure to the paper. In another way, the use of a shunt, a method for controlling the flow rate by distributing the flow of fluid, has been studied [63]. This technique can distribute the flow of fluid by placing absorbent pads in the position where the fluid is to be delayed in the porous channel. In this study, it has been shown that the fluid delay time could be varied from 3 to 20 min by varying the thickness and length of the shunt ( Figure 7B). Although this has a simple fabrication process, it has a limitation in terms of requiring a large quantity of sample due to the absorbent pads. In addition, a study has been conducted on how to control the flow rate by adding flexible films on the paper channel [33]. By sandwiching paper channels between two additional films, it prevents evaporation of the sample and thus accelerates the flow rate in comparison with channels without films. The advantage of this method is that the increased velocity of the fluid can reduce the diagnostic time.  The advantage of this approach is that the fast flow rate can reduce assay time and increase the size of the fluid network. In Figure 6C of the study, two-dimensional paper networks (2DPNs) have been applied to control the flow of fluid by varying the length of the leg in charge of each inlet [76]. When paper strips with different lengths are inserted into the fluid source wells, the fluid source of the wells is continuously reduced, and the shorter paper strips have briefer contact time with the fluid than the longer ones. This method has an advantage in that it is possible to make stepwise assays by making legs easily using cut paper and placing each leg into different reagent pads.
The methods using the structural change of paper or a combination of various kinds of papers and attaching additional materials have been frequently applied in µPADs. These methods have a principle that adjusts the flow rate by reducing the pore size and cross-sectional area on the paper by applying pressure to the paper [67][68][69]. If the pore size and cross-sectional area are reduced, the fluid resistance increases and, consequently, the flow rate decreases. As shown in Figure 7A, it is confirmed that the fluid transports differently depending on the pressure applied to the paper strips. The advantage of this approach is that a permanent fluid delay effect can be obtained by simply applying pressure to the paper. In another way, the use of a shunt, a method for controlling the flow rate by distributing the flow of fluid, has been studied [63]. This technique can distribute the flow of fluid by placing absorbent pads in the position where the fluid is to be delayed in the porous channel. In this study, it has been shown that the fluid delay time could be varied from 3 to 20 min by varying the thickness and length of the shunt ( Figure 7B). Although this has a simple fabrication process, it has a limitation in terms of requiring a large quantity of sample due to the absorbent pads. In addition, a study has been conducted on how to control the flow rate by adding flexible films on the paper channel [33]. By sandwiching paper channels between two additional films, it prevents evaporation of the sample and thus accelerates the flow rate in comparison with channels without films. The advantage of this method is that the increased velocity of the fluid can reduce the diagnostic time. Research has been conducted on technology that can control the maximum flow rate according to the source pad size [20,70,71]. Larger source pads can accommodate larger amounts of liquid and, therefore, have longer fluid transport distances and times ( Figure 7C). Through this technology, stepwise assays can be applied to two-dimensional (2D) paper network chips, and reagent flow can be controlled by adjusting the size of the source pad. In contrast, methods of controlling the flow of fluid by stacking paper layers in a three-dimensional structure have been studied [72][73][74][75]77]. These methods use the principle of controlling the direction of fluid movement in the three dimensions by vertically connecting layers with hydrophobic regions ( Figure 7D). This shows the characteristic of being able to assay target biomolecules by distributing the sample from one inlet to several outlets [72].

Active Fluid Manipulation
A lot of studies have also focused on active fluid manipulation, which is different from the passive fluid manipulation approach described in Section 2.1. While passive fluid manipulation is primarily utilized for uncomplicated assays, active fluid manipulation technology, which allows the fluid or sample to flow freely to the desired point at the desired time [78], can be applied to sequential multi-step assays. This active fluid manipulation approach makes simultaneous multiplex assays and multiple detection zones more affordable in μPADs. This technology can be classified into wettability-, geometry transformation-, and mechanical actuation-based methods.

Wettability-based Active Valves
Fluid control methods that use the chemical transformation of materials coated on the paper, for example, using the characteristics of corona discharge and electrowetting, have been developed and are summarized in Table 3.  Research has been conducted on technology that can control the maximum flow rate according to the source pad size [20,70,71]. Larger source pads can accommodate larger amounts of liquid and, therefore, have longer fluid transport distances and times ( Figure 7C). Through this technology, stepwise assays can be applied to two-dimensional (2D) paper network chips, and reagent flow can be controlled by adjusting the size of the source pad. In contrast, methods of controlling the flow of fluid by stacking paper layers in a three-dimensional structure have been studied [72][73][74][75]77]. These methods use the principle of controlling the direction of fluid movement in the three dimensions by vertically connecting layers with hydrophobic regions ( Figure 7D). This shows the characteristic of being able to assay target biomolecules by distributing the sample from one inlet to several outlets [72].

Active Fluid Manipulation
A lot of studies have also focused on active fluid manipulation, which is different from the passive fluid manipulation approach described in Section 2.1. While passive fluid manipulation is primarily utilized for uncomplicated assays, active fluid manipulation technology, which allows the fluid or sample to flow freely to the desired point at the desired time [78], can be applied to sequential multi-step assays. This active fluid manipulation approach makes simultaneous multiplex assays and multiple detection zones more affordable in µPADs. This technology can be classified into wettability-, geometry transformation-, and mechanical actuation-based methods.

Wettability-Based Active Valves
Fluid control methods that use the chemical transformation of materials coated on the paper, for example, using the characteristics of corona discharge and electrowetting, have been developed and are summarized in Table 3. Some studies have been conducted on how to control fluids by converting the hydrophobic region into a hydrophilic property through corona discharge [79]. This method forms fluidic channels by coating octadecyltrichlorosilane (OTS) on all parts except the valving region and channel. Subsequent corona discharge treatments in the valving region allow this area to regain its original hydrophilic properties, enabling the flow of fluid ( Figure 8A). A fast valve activation rate of about 1 s is an advantage, but the limitation is that it can be difficult to find the correct valve position and apply corona discharge. In addition to the corona discharge application, studies on valves using electrowetting, a phenomenon that can control the surface tension of a liquid by electricity, have been conducted [80,81]. The reason why surface tension of water changes on the application of electrical force is that the polarity of the water molecules creates a more attractive force for the conductive material flowing with electricity, which increases the surface tension. Koo et al. printed hydrophobic conductive electrodes (valves) on paper, together with hydrophilic conductive electrodes. The sample flows through a paper strip, passes the hydrophilic electrodes, and stops at the hydrophobic electrode. Then, applying a voltage across the electrode destroys the fluorinated monolayer of the hydrophobic electrode, causing the fluid to flow ( Figure 8B).
Recently, a study on a fluid control method using electro-osmotic pumping has been conducted [82]. Applying a direct current voltage to electrodes on both sides of the wet paper causes the liquid to move toward one pole. This highlights the principle that the charge of the electric double layer at the solid-liquid interface is accompanied by the liquid when it is moved by the electric field ( Figure 8C). This technology has advantages in that flow rate control, automatic control, and reversible (ON-OFF) actuation are possible. As another approach from the aforementioned method, research has been carried out on temperature control-operated valve systems [83][84][85], which is a method in which the flow of fluid is controlled according to the temperature change by using the characteristic that wax melts with temperature. In Figure 8D, the injected sample (blue liquid) flows to the outlet through the open valve over the wax patterned line ( 1 , 2 ). Heating the wax causes it to penetrate the channel and close the valve ( 3 ). At this time, the injected red liquid only flows to the closed valve and stops ( 4 , 5 ). When the heat is applied again, the wax melts, and the red liquid flows downwards ( 6 ) ( Figure 8D). The characteristics of these valves are repeatable and can be automatically operated.
force is that the polarity of the water molecules creates a more attractive force for the conductive material flowing with electricity, which increases the surface tension. Koo et al. printed hydrophobic conductive electrodes (valves) on paper, together with hydrophilic conductive electrodes. The sample flows through a paper strip, passes the hydrophilic electrodes, and stops at the hydrophobic electrode. Then, applying a voltage across the electrode destroys the fluorinated monolayer of the hydrophobic electrode, causing the fluid to flow ( Figure 8B).

Geometry Transformation-based Active Valves
A variety of techniques, including rotational valve, folding, push-button, sliding action, and paper switch, have been studied, and examples are shown in Table 4.  Rotational valve (circular disk) Switching (ON) Fluorescence-based molecular-imprinting detection (4-nitrophenol and 2,4,6-trinitrophenol) [39] Rotational valves on paper-based analytical devices have been implemented using rotatable disk-type packaging [101], hollow rivets [102], comb binding [103], and rotational paper-based microfluidic chips [39] as ways to bridge separated paper channels. As a representative case using rotational valves, a rotatable disk-type device has a bottom piece with a test strip and a top piece with a pad on which the reagent is dried. After dropping the sample on the test strip, it performs the assays by turning the bottom piece in the directions of S1, S2, S3, and S4, in that order, for stepwise reagent flow ( Figure 10A). This rotational valve has the advantage of being relatively simple to operate but has a limitation in that each step must be manually operated. Researches on the technique of transferring one fluid flow to another channel by paper folding have been also conducted [29,37,[86][87][88][89][90][91][92]. The "pop-up" device shown in Figure 10B has a structure wherein the sample zone touches the detection zone and performs electrochemical detection when the popped up paper is folded. This method has an advantage now that the working time of the valve is relatively simple to operate.
In a manner similar to the paper folding method, Martinez et al. have developed a device with a push button and a 3D device structure that intersects paper layers with fluidic channels and tapes layers with holes [93]. When the hole is pressed by the button, the gap between the paper and the tape layers is reduced, and the fluid starts to flow ( Figure 9A). This principle allows the switching of fluids to be a programmable operation but can be used only once. There have been many studies on sliding action valves [36,[94][95][96][97][98][99][100], which is a method of flowing fluid in a way contacting the paper channels of two layers each other by sliding one of the different layers with paper channels. Han et al. flowed the sample and buffer, simultaneously, with the sliding of the top layer using 3D slip-PAD (paper-based analytical device) ( Figure 9B), which allows starting the flow at the desired time with the sample and reagents prepared. Finally, the paper switch technique has already been discussed in the fluid manipulation chapter, explaining the switching function [18]. Manually pressing the cut and folded paper switch connects the disconnected passage of the fluid ( Figure 2B).

Mechanical Actuation-based Active Valves
Fluid manipulation methods using mechanical movement include expandable materials, magnetic valves, pressure valves, and reconfigurable flow switches, and their examples are given in Table 5. Colorimetric-enzymatic assay (glucose, protein, and nitrite) [107] Research has been conducted to control the flow of fluid using expandable material (sponge) [104]. When the sponge gets wet with the fluid flowing through the actuation channel, it expands so that the channel associated with the sponge transfers the flow of fluid to another channel or stops the flow. The advantage of this approach is that it can perform various functions (Off to On, On to Off, and diversion switch) ( Figure 11A). An electromagnetic valve on paper-based analytical devices has also been studied [105,106]. The cantilever valve is made by applying ferromagnetic nanoparticles. In the case of a normally open valve, the cantilever valve remains folded, and when the electromagnet is operated, it is pulled toward the electromagnet to connect the separate channels. In this way, the flow of fluid can be automatically controlled ( Figure 11B). This valve can be operated several times and is programmable [106]. Rotational valve (hollow rivet) Switching (ON) ELISA (carcino-embryonic antigen; CEA) [102] Rotational valve (comb binding) Switching (ON) Colorimetric-enzymatic assay (Fe 2+ and nitrite) [103] Rotational valve (circular disk) Switching (ON) Fluorescence-based molecular-imprinting detection (4-nitrophenol and 2,4,6-trinitrophenol) [39] Rotational valves on paper-based analytical devices have been implemented using rotatable disk-type packaging [101], hollow rivets [102], comb binding [103], and rotational paper-based microfluidic chips [39] as ways to bridge separated paper channels. As a representative case using rotational valves, a rotatable disk-type device has a bottom piece with a test strip and a top piece with a pad on which the reagent is dried. After dropping the sample on the test strip, it performs the assays by turning the bottom piece in the directions of S1, S2, S3, and S4, in that order, for stepwise reagent flow ( Figure 9A). This rotational valve has the advantage of being relatively simple to operate but has a limitation in that each step must be manually operated. Researches on the technique of transferring one fluid flow to another channel by paper folding have been also conducted [29,37,[86][87][88][89][90][91][92]. The "pop-up" device shown in Figure 9B has a structure wherein the sample zone touches the detection zone and performs electrochemical detection when the popped up paper is folded. This method has an advantage now that the working time of the valve is relatively simple to operate.  In a manner similar to the paper folding method, Martinez et al. have developed a device with a push button and a 3D device structure that intersects paper layers with fluidic channels and tapes layers with holes [93]. When the hole is pressed by the button, the gap between the paper and the tape layers is reduced, and the fluid starts to flow ( Figure 10A). This principle allows the switching of fluids to be a programmable operation but can be used only once. There have been many studies on sliding action valves [36,[94][95][96][97][98][99][100], which is a method of flowing fluid in a way contacting the paper channels of two layers each other by sliding one of the different layers with paper channels. Han et al. flowed the sample and buffer, simultaneously, with the sliding of the top layer using 3D slip-PAD (paper-based analytical device) ( Figure 10B), which allows starting the flow at the desired time with the sample and reagents prepared. Finally, the paper switch technique has already been discussed in the fluid manipulation chapter, explaining the switching function [18]. Manually pressing the cut and folded paper switch connects the disconnected passage of the fluid ( Figure 2B).

Mechanical Actuation-Based Active Valves
Fluid manipulation methods using mechanical movement include expandable materials, magnetic valves, pressure valves, and reconfigurable flow switches, and their examples are given in Table 5. Colorimetric-enzymatic assay (glucose, protein, and nitrite) [107] Research has been conducted to control the flow of fluid using expandable material (sponge) [104]. When the sponge gets wet with the fluid flowing through the actuation channel, it expands so that the channel associated with the sponge transfers the flow of fluid to another channel or stops the flow. The advantage of this approach is that it can perform various functions (Off to On, On to Off, and diversion switch) ( Figure 11A). An electromagnetic valve on paper-based analytical devices has also been studied [105,106]. The cantilever valve is made by applying ferromagnetic nanoparticles. In the case of a normally open valve, the cantilever valve remains folded, and when the electromagnet is operated, it is pulled toward the electromagnet to connect the separate channels. In this way, the flow of fluid can be automatically controlled ( Figure 11B). This valve can be operated several times and is programmable [106].
A novel technique based on the pressure valve has been introduced as an example of an active valve in the fluid manipulation section [48]. Like a pressure valve using a solenoid actuator that can press the paper directly, it has the ability to decrease the flow velocity or blocking the flow according to the strength of the pressure ( Figure 1B). The feature of this technology is that the valve can be operated repeatedly, and it is programmable and reversible. In addition to the above-mentioned techniques, research on the flow switch using the reconfigurable property of paper has been conducted [107]. The reconfigurable flow switch is a valve that uses the property of unfolding when liquid is injected into the folded part of the paper. When the liquid is injected into the actuator (folded paper) with the input and output channels structurally separated from each other, the tip pushes the input channel up and makes contact with the output channel ( Figure 11C). This method is called single-pole single-throw (SPST) and can also be applied as single-pole double-throw (SPDT). The valve has the advantage of being able to operate only with paper and liquids, but it might have limitations in terms of mass production and complexity of the device.  [105]. (C) Operation of a reconfigurable flow switch. When the liquid is injected into the crest of the actuator made by folding the paper, it spreads out as it was before. It connects the input and output channels initially separated from each other. Figure reprinted with permission from [107].
A novel technique based on the pressure valve has been introduced as an example of an active valve in the fluid manipulation section [48]. Like a pressure valve using a solenoid actuator that can press the paper directly, it has the ability to decrease the flow velocity or blocking the flow according to the strength of the pressure ( Figure 1B). The feature of this technology is that the valve can be operated repeatedly, and it is programmable and reversible. In addition to the above-mentioned techniques, research on the flow switch using the reconfigurable property of paper has been conducted [107]. The reconfigurable flow switch is a valve that uses the property of unfolding when liquid is injected into the folded part of the paper. When the liquid is injected into the actuator (folded paper) with the input and output channels structurally separated from each other, the tip pushes the input channel up and makes contact with the output channel ( Figure 11C). This method is called single-pole single-throw (SPST) and can also be applied as single-pole double-throw (SPDT). The valve has the advantage of being able to operate only with paper and liquids, but it might have limitations in terms of mass production and complexity of the device.

Nucleic Acid Amplification Testing (NAAT)
Molecular diagnostics is a technique used to analyze biological markers in the genome using gene amplification techniques, such as polymerase chain reaction (PCR). This method identifies a disease infection by extracting DNAs and RNAs containing the pathogen's genetic information from the saliva and blood of the infected person and then amplifying them. The most popular method for molecular diagnostics is PCR, but it is limited because it requires expensive equipment with thermal cycling. However, with the development of isothermal amplification technology, DNA strands can be amplified without the thermal cycling process. The isothermal amplification method includes loop-mediated isothermal amplification (LAMP) [108], helicase-dependent amplification (HDA) [109], recombinase protein amplification (RPA) [110], and rolling circle amplification (RCA) [40]. Recently, several attempts have been made to transfer isothermal amplification of nucleic acid technology to the paper microfluidics platform for POCT [4,84,96,[111][112][113]. These µPAD studies are summarized in Table 6 by comparing them with conventional methods.  [115] Sliding action Escherichia coli malB gene 500 cells mL −1 [96] LAMP, 1.02 copies [116] Sliding action Salmonella typhimurium 10 2 CFU mL −1 [111] #3 QCM, 10 0 CFU mL −1 [117] Folding Influenza A (H1N1) 10 6 copies mL −1 [113] RT-PCR, 384 copies mL −1 [118] Folding Human papillomavirus (HPV) 16  Isothermal amplification comprises three steps: sample preparation, nucleic acid amplification, and detection. Tang et al. implemented the whole operation process of HDA within an integrated paper-based platform [111]. After sample injection, the DNA extraction process starts by manually pressing the button. The strip is then moved over the thermal pad by a sliding action to carry out the amplification process. Finally, colorimetric detection is performed by moving the amplified sample to the test strip with another sliding action of the strip ( Figure 12A). Connelly et al. implemented the LAMP amplification method on the sliding strip. After the sample injection into the reaction disc, the strip is placed in the wash port [96]. Then, the wash buffer is introduced, and the strip is moved again to the port for injecting the amplification master mix. As a final process, signals are obtained by exposing the strip to UV after injecting SYBR green I ( Figure 12B).

Enzyme-linked Immunosorbent Assay (ELISA)
ELISA is a method of detecting and quantifying specific antigens or antibodies in biological samples, such as blood, urine, tissues, and cells. ELISA can be divided into direct ELISA, indirect ELISA, and sandwich ELISA according to the detection method. Sandwich ELISA is widely used

Enzyme-Linked Immunosorbent Assay (ELISA)
ELISA is a method of detecting and quantifying specific antigens or antibodies in biological samples, such as blood, urine, tissues, and cells. ELISA can be divided into direct ELISA, indirect ELISA, and sandwich ELISA according to the detection method. Sandwich ELISA is widely used because it shows higher specificity than the other methods. The processes of sandwich ELISA include stepwise reactions with several materials, such as the analyte, the enzyme-coupled detection antibody, and the substrate. The intermediate washing steps are also essential. Several studies have been conducted to implement ELISA in paper-based devices [36,55,58,[120][121][122], as shown in Table 7. Our group recently developed a paper-based ELISA system using pressure valves [48]. The pressure valves of the system operate by a linear push-pull solenoid, which enables active control of the fluid flow on the paper strips. Based on this solenoid valve, ELISA with complicated multi-step procedures is successfully conducted. In the first step, when a sample is injected into the sample pad, the analyte of the sample reacts with the pre-dried detection antibody behind the sample pad ( Figure 13A). The bound analyte-detection antibody then binds to the pre-dried capture antibody in the test zone. The next step is to wash off the unbound antibodies in the test zone by opening Valve 1 (shown as V 1 in Figure 13A) to flow the washing buffer. Finally, colorimetric detection, depending on the concentration of analytes, is carried out by opening Valve 2 so that the color reaction of the enzyme in the test zone is induced. Verna et al. detected C-reactive protein (CRP) with ELISA using a paper-based 3D sliding strip [36]. This platform first injects the sample into the inlet and then moves the sliding strip to the inlet for alkaline phosphatase (ALP)-conjugated antibody injection. After the introduction of the ALP-conjugated antibody, the sliding strip moves to the inlet where 5-bromo-4-chloro-3-indolyl phosphate (BCIP)/nitro blue tetrazolium (NBT) is injected. BCIP/NBT is introduced, and the results are finally analyzed by removing the sliding strip from the device ( Figure 13B). in the test zone is induced. Verna et al. detected C-reactive protein (CRP) with ELISA using a paperbased 3D sliding strip [36]. This platform first injects the sample into the inlet and then moves the sliding strip to the inlet for alkaline phosphatase (ALP)-conjugated antibody injection. After the introduction of the ALP-conjugated antibody, the sliding strip moves to the inlet where 5-bromo-4chloro-3-indolyl phosphate (BCIP)/nitro blue tetrazolium (NBT) is injected. BCIP/NBT is introduced, and the results are finally analyzed by removing the sliding strip from the device ( Figure 13B).

Signal Enhancement Assay
A signal enhancement assay is a method to improve the detection signal and sensitivity. Because it requires several amplification steps (e.g., reagent injection and washing), it should be accompanied by fluid manipulation techniques for application in paper-based diagnostic devices. Thus far, several studies have been done on paper-based signal enhancement assays (Table 8).

Signal Enhancement Assay
A signal enhancement assay is a method to improve the detection signal and sensitivity. Because it requires several amplification steps (e.g., reagent injection and washing), it should be accompanied by fluid manipulation techniques for application in paper-based diagnostic devices. Thus far, several studies have been done on paper-based signal enhancement assays (Table 8). Lutz et al. performed stepwise signal enhancement through paper strips using dissolvable materials (sucrose) [49]. As shown in Figure 14A, four strands of strips are dried with 0%, 30%, 54%, and 65% sucrose, respectively. When the sample pad filled with sample, washing buffer, and gold enhancement reagent is folded and contacted with the strip, the velocity of the fluid is controlled according to the concentration of sucrose, and fluids reach the detection zone in the following order: sample, washing buffer, and gold enhancement reagent. Using this principle, they performed the PfHRP2 malaria assay. Park et al. enabled salmonella diagnosis through a step-by-step reaction using a pressed paper [68]. When the device is dipped into the sample, the analytes react with the antibody-conjugated gold nanoparticles ( Figure 14B). Immuno-complexes are then captured by antibodies in the test line and give a colored reaction. The sample passing through the pressed region reacts with the pre-dried gold enhancer solutions i, ii, and iii and binds with the gold nanoparticles in the test line, resulting in an amplified signal. Through this method, amplified signals can be obtained from a mixture of E. coli O157:H7 and Salmonella typhimurium.

Expandable material
Malaria protein PfHRP2 Not marked [104] Lutz et al. performed stepwise signal enhancement through paper strips using dissolvable materials (sucrose) [49]. As shown in Figure 14A, four strands of strips are dried with 0%, 30%, 54%, and 65% sucrose, respectively. When the sample pad filled with sample, washing buffer, and gold enhancement reagent is folded and contacted with the strip, the velocity of the fluid is controlled according to the concentration of sucrose, and fluids reach the detection zone in the following order: sample, washing buffer, and gold enhancement reagent. Using this principle, they performed the PfHRP2 malaria assay. Park et al. enabled salmonella diagnosis through a step-by-step reaction using a pressed paper [68]. When the device is dipped into the sample, the analytes react with the antibodyconjugated gold nanoparticles ( Figure 14B). Immuno-complexes are then captured by antibodies in the test line and give a colored reaction. The sample passing through the pressed region reacts with the pre-dried gold enhancer solutions i, ii, and iii and binds with the gold nanoparticles in the test line, resulting in an amplified signal. Through this method, amplified signals can be obtained from a mixture of E. coli O157:H7 and Salmonella typhimurium.   Another approach to enhance sensitivity is to integrate an online sample stacking, enabling the use of a less sensitive detection modality [132]. Li et al. demonstrated a low-voltage paper isotachophoresis device for focusing on DNA samples [133]. By the 2-mm-long, 2-mm-wide circular paper channel formed by concertina folding a paper strip and aligning the circular paper zones on each layer, they could concentrate DNA with more than two orders of magnitude within 4 min. This electrophoretic approach makes possible the precise separation of mixed samples by adjusting the potentials applied at separation channels, not to mention the improvement of the limit of detection. While these studies usually utilize a relatively simple structure [134][135][136], they have the potential to realize in situ multiplex separation and detection among mixed samples with low cost, low-power requirements, and hand-held testing manners.

Colorimetric Enzymatic Assay
Colorimetric detection is the most widely used technology for paper-based analytical devices, which involves visual observation of the color change owing to the reaction of various reagents. This method enables either qualitative or quantitative analysis by taking advantage of the fact that it can be measured with the naked eye or with the help of simple visual readers. In particular, a colorimetric enzymatic assay using reactions depending on the concentration of analytes and enzyme, such as a glucose colorimetric assay, is a representative method in µPADs [34,60]. Glucose oxidase (GOx) and horseradish peroxidase (HRP) are commonly used to catalyze the reaction for glucose detection. The glucose catalytic reaction at the presence of glucose oxidase generates hydrogen peroxide (H 2 O 2 ) and gluconic acid. Peroxidase then catalyzes the reaction of H 2 O 2 with a color indicator, resulting in a color change. In this process, potassium iodide (KI) is the most commonly applied color indicator, resulting in a reaction showing brown coloration as KI is oxidized. In addition to the application based on glucose assay, colorimetric enzymatic assay in µPADs is widely used in various fields, such as pesticide assay [32,33], ion detection [79,103], and protein analysis [94]. These µPAD studies are summarized in Table 9 by comparing them with conventional methods. Renault et al. developed hollow channel paper devices for glucose and protein assays ( Figure 15A). When the hydrophilic channel and the hollow channel are overlapped in a three-dimension, and the sample is injected into the inlet, the analyte reacts with the enzyme (KI, HRP) at the outlet, resulting in a color-producing reaction [34]. This combined structure increases the velocity of the fluid by about 7 times as much as that of regular paper channels. Han et al. tested the color reaction of Fe 2+ and nitrite using plastic comb binding spine (PCBS)-based valves [103]. Although the inlet and detection zones have a gap distance between them, the analyte reacts with the reagents in the detection zone by connecting the strip between the inlet and the detection zone using a PCBS-based valve ( Figure 15B).

Challenges and Perspectives
In recent years, many advances have been made in fluid handling in the field of paper microfluidics. Advances of fluid manipulation technology have led to improved performance and diverse applications of microfluidic paper-based analytical devices. In this paper, the fluid handling technologies were classified into passive and active methods according to the operation principle, which has advantages and disadvantages, respectively. Passive valves have the advantages of being able to reduce the cost and being more portable because the valve is configured in the device itself without any additional equipment. Based on the benefits, the approach is expected to evolve toward a way that can support faster response and higher integration with compact fashion. Active valves are advantageous for more accurate and programmable fluid manipulation because of the excellent responsiveness of the valves. However, since active valve methods are accompanied by additional equipment, cost-effective and straightforward modules will be desirable. In terms of practical utility and commercialization, the delicate calculation will be required between the cost increase by additional active valve modules and the expected values by reduction of reagents and performance enhancement. What is clear is that if the value of lateral flow assays-a simple, convenient, and cheap diagnosis-itself is fading away, it will face practical limitations no matter how sophisticated the active valve technology is. As such, it would be desirable to conduct technical development within the scope of the original value of paper-based platforms.
The potential requirements of fluid manipulation technologies for multi-step assays in paperbased analytical devices can be summarized as follows: (1) compact form, (2) instant response, (3) repeatable use, and (4) automated operation. The development of paper-based multi-step assay technologies through fluid handling techniques can bridge the current disparity in medical advancements globally. For instance, complicated assays for many viral and infectious diseases can be performed on-site in undeveloped countries if the assays currently being performed in the laboratory are implemented in paper-based technology. Therefore, it can accelerate the time to commercialization if it (1) meets the ASSURED (Affordable, Sensitive, Specific, User-friendly, Rapid

Challenges and Perspectives
In recent years, many advances have been made in fluid handling in the field of paper microfluidics. Advances of fluid manipulation technology have led to improved performance and diverse applications of microfluidic paper-based analytical devices. In this paper, the fluid handling technologies were classified into passive and active methods according to the operation principle, which has advantages and disadvantages, respectively. Passive valves have the advantages of being able to reduce the cost and being more portable because the valve is configured in the device itself without any additional equipment. Based on the benefits, the approach is expected to evolve toward a way that can support faster response and higher integration with compact fashion. Active valves are advantageous for more accurate and programmable fluid manipulation because of the excellent responsiveness of the valves. However, since active valve methods are accompanied by additional equipment, cost-effective and straightforward modules will be desirable. In terms of practical utility and commercialization, the delicate calculation will be required between the cost increase by additional active valve modules and the expected values by reduction of reagents and performance enhancement. What is clear is that if the value of lateral flow assays-a simple, convenient, and cheap diagnosis-itself is fading away, it will face practical limitations no matter how sophisticated the active valve technology is. As such, it would be desirable to conduct technical development within the scope of the original value of paper-based platforms.
The potential requirements of fluid manipulation technologies for multi-step assays in paper-based analytical devices can be summarized as follows: (1) compact form, (2) instant response, (3) repeatable use, and (4) automated operation. The development of paper-based multi-step assay technologies through fluid handling techniques can bridge the current disparity in medical advancements globally. For instance, complicated assays for many viral and infectious diseases can be performed on-site in undeveloped countries if the assays currently being performed in the laboratory are implemented in paper-based technology. Therefore, it can accelerate the time to commercialization if it (1) meets the ASSURED (Affordable, Sensitive, Specific, User-friendly, Rapid and Robust, Equipment-free, and Deliverable) criteria of the World Health Organization (WHO), which is the standard of point-of-care testing and, at the same time, (2) solves the challenges with full automation and obtains high sensitivity of paper-based diagnostic technology capable of multi-step assays. In addition, providing medical benefits to developing countries can greatly contribute to the diagnosis of diseases caused by super bacteria or viruses and can help prevent disease spread.