Abstract
Microfluidic chip technology is an emerging tool in the field of biomedical application. Microfluidic chip includes a set of groves or microchannels that are engraved on different materials (glass, silicon, or polymers such as polydimethylsiloxane or PDMS, polymethylmethacrylate or PMMA). The microchannels forming the microfluidic chip are interconnected with each other for desired results. This organization of microchannels trapped into the microfluidic chip is associated with the outside by inputs and outputs penetrating through the chip, as an interface between the macro- and miniature world. With the help of a pump and a chip, microfluidic chip helps to determine the behavioral change of the microfluids. Inside the chip, there are microfluidic channels that permit the processing of the fluid, for example, blending and physicochemical responses. Microfluidic chip has numerous points of interest including lesser time and reagent utilization and alongside this, it can execute numerous activities simultaneously. The miniatured size of the chip fastens the reaction as the surface area increases. It is utilized in different biomedical applications such as food safety sensing, peptide analysis, tissue engineering, medical diagnosis, DNA purification, PCR activity, pregnancy, and glucose estimation. In the present study, the design of various microfluidic chips has been discussed along with their biomedical applications.
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1 Introduction
Microfluidic technology is a rapidly emerging field of science characterized by a range of micro-domain effects. The technology has found its place in various application-based streams ranging from micro-arrays to cellular biophysics. These systems essentially have a size range of 10–100 µm. It is also known as ‘lab-on-a-chip’ technology (Tabeling 2005). Microfluidic technology is accustomed to configuring miniaturized devices, which precisely controls physicochemical reactions of the fluid contained. These chips have a compact size, which in turn, increase the surface area, resulting in high mass transfer and high analytical throughput (Cui and Wang 2019; Tabeling 2005). The technology further reduces the requirement of samples and reagents, to achieve multiplexing (Cui and Wang 2019) and high-throughput screening. The grooves or microchannels that are characteristically engraved on silicon or polymer layers are specifically designed to enable efficient mixing. The common fabrication materials that are employed to prepare chips are polydimethylsiloxane (PDMS), silicon, glass, quartz, polycarbonate, and polymethylmethacrylate (PMMA) (Focaroli et al. 2014). The basic design of the microchips with their components, various types and applications are illustrated in Fig. 1. The chip contains a reagent inlet, sample inlet, valves, grooves or microchannels, the drainage system, and the sensor part. From the inlets, the reagent and sample are injected for evaluation. The flow of fluids inside the microchannels is regulated by the valves. The fluid flows through different microfluidic flows, namely open microfluidics (Berthier et al. 2016), continuous-flow (Dendukuri et al. 2006; Jahn et al. 2008), droplet-based (Seemann et al. 2011), digital-based (Choi et al. 2012), paper-based (Lin et al. 2016), particle detection microfluidics (Xuan et al. 2010) and microfluidic-assisted magnetophoresis (Yan et al. 2016). From the drainage system, the waste material is emptied out and the sensor assists with assessing the outcomes.
2 Types of microfluidic chips based on device configuration
There are different types of microfluidic chips are designed, namely droplet microfluidic chip (Mashaghi et al. 2016; Seemann et al. 2011), organ-on-chip (OOC) (Wu et al. 2020), microfluidic hydrogel chip (Cuchiara et al. 2010; Nie et al. 2018), microfluidic chip integrated with 3D culture technology (Carvalho et al. 2015; Van Duinen et al. 2015; Xu et al. 2013), microfluidic chip merged with detection instruments (Gao et al. 2013; Killeen et al. 2003; Vollmer et al. 2006), microfluidic chip for single-cell analysis (Wheeler et al. 2003; Yin and Marshall 2012; Yue and Xue-Feng 2006) and microfluidic model organism (Rohde et al. 2007). These are schematically illustrated in Fig. 1B.
2.1 Droplet-based microfluidics (DBM) chips
A droplet-based microfluidics (DBM) system is primarily accustomed to exploit the distinct volume of fluids that are immiscible in nature (Seemann et al. 2011; Teh et al. 2008). It is among the most successful domains of microfluidic technology that deals with the manipulation of uniformly arranged microdroplets, especially at higher rates. The distinctive quality of this technique is its high production rate (Teh et al. 2008). It typically enables the formation of thousand droplets each second. In comparison with conventional techniques, it helps in producing larger number of assays and also gives a higher analysis (Zhao et al. 2017). With this technique, the sizes of microdroplets are adjustable according to their requirements. Trapping of individual cells within the droplets enables high throughput (Mashaghi et al. 2016; Teh et al. 2008).
DBM may further remove the probability of cross-contamination. The miniaturized droplets are actually micro-reactors that could trap anything that we intend to observe in, namely cosmetics (Opalski et al. 2019; Tan and Lee 2005), diagnostic tests and assays (Kaler and Prakash 2014; Kang et al. 2014; Srinivasan et al. 2003), low-fat food with air-filled fat particles (Chung et al. 2013; Nguyen et al. 2019), and controlled delivery of drugs with biodegradable microparticles (Liu et al. 2017a; b; Xu et al. 2009). Figure 2A shows a basic design of a droplet-based microfluidics system.
2.1.1 Formation of droplets
Droplet formation constitutes the significant part in DBM to achieve any desired analysis. For this, two phases are necessary, one being the continuous phase and the other being the dispersed phase. There are two different types of methods for the formation of droplets. These include active flow method and passive flow method (Teh et al. 2008). Passive flow method is widely used for the droplet formation as it does not depend upon an external energy and could produce results with a simplified device (Mashaghi et al. 2016; Seemann et al. 2011; Teh et al. 2008). The active method may include electric, magnetic and centrifugal factors, whereas a passive method would include cross-flowing (T-junction) (Garstecki et al. 2006), flow focusing (Fu et al. 2012; Xu et al. 2009) and co-flowing droplet formation (Zhu et al. 2016) as illustrated in Fig. 2B–D. Droplet formation operates under a low Reynolds number to ensure laminar flow of the liquid. Surfactants are often used to stabilize such microdroplets by decreasing the interfacial tension among the two distinct phases (Baret 2012).
2.2 Microfluidic chip integrated with 3D culture technique
Most of the conventional cell array techniques are of a 2D cell culture system that failed to replicate the in vivo microenvironment of any cell or tissue. To accurately study the proper growth of cells, their migration, and pattern, a 3D cell culture technique is mostly preferred (Matsusaki et al. 2014; Van Duinen et al. 2015). To provide accurate information on the in vivo study parameters, microfluidic chips are integrated with the 3D cell culture technique. This may provide a 3D tissue model for drug-screening purposes (Matsusaki et al. 2014). Currently, microfluidic devices are used in in vitro studies to test anticancer drugs as these devices enable the formation of tumor spheroids. They may also control the uniformity of the size of the tumor spheroids (Jeong et al. 2016). Xu et al., introduced a design of microfluidic chip integrated with 3D co-culture for drug sensitivity testing of anticancer drugs. They had cultured lung cancer tissues in a 3D culture which accurately replicated the tumor microenvironment system. Anticancer medicaments were later introduced according to gradient concentration generator (CGG). The system is also enabled to screen the sensitivities of various anticancer medicaments that were tested (Xu et al. 2013). The microfluidic 3D co-culture chip is designed and fabricated with polydimethylsiloxane (PDMS) polymer. Microchannels are engraved by a photolithography process. The chip is connected to the injection pump to manipulate the progression of the liquid inside the chip. The chip consists of a reservoir, a concentration-gradient generator, and three chambers of cell culture. The CGG comprises an upstream drug input arrangement from where the drug is inserted and a downstream medium input from where the medium is injected, which is further attached to the cell culture chamber. Both the inputs are mixed at the mixing microchannel (light blue, as shown in Fig. 3) to maintain an equal flow rate. With the assistance of this design, dissimilar cells and drugs could be cultured and tested for any disease condition (Bruzewicz et al. 2008; Xu et al. 2013).
2.3 Microfluidic hydrogel chip
For the planning of microfluidic chips, PDMS polymer is usually utilized, in light of the fact that it is biocompatible, transparent, profoundly precise, and creates a high throughput. Apart from these qualities, one challenge with the PDMS is that they seldom facilitate cell adhesion or attachment (McDonald et al. 2000). It is known that in cell-biomaterial studies, cell attachment is the initial step. It plays a crucial role in the cellular processes such as cell proliferation and cell differentiation (Leclerc et al. 2003). To overcome this challenge, microfluidic channels could be coated with a cell-compatible hydrogel layer inside a PDMS-layered device (Rosser et al. 2015). Hydrogels are usually composed of a 3D network made up of natural or synthetic polymers that mimic the microenvironment of the extracellular matrix. Natural polymers include agarose, alginate, collagen, dextran, fibrin, and laminin, whereas synthetic polymers include polyethylene glycol (PEG) and PEG diacrylate (PEG-DA). Among these, PEG and its by-products are frequently used for microfluidic hydrogel devices. Hydrogels are mainly used for the encapsulation of cells/drugs and also for cellular barrier establishment (Beebe et al. 2000).
These 3D hydrogel-based microfluidic chips have been found very helpful in angiogenesis and cell migration. For instance, Shin et al., developed microfluidic systems that was fabricated in polydimethylsiloxane (PDMS) using standard soft lithographic methods. It was comprised of hydrogel-incorporating chambers between surface-accessible microchannels to study angiogenesis using cell culture assay. The platform was composed of four gel regions and three channels, each of which is individually accessible. The cells were cultured in the center channel, and the other two side channels acted as control channel and condition channel, respectively. The interior of the channels was coated with extracellular matrix (ECM) proteins to promote cell adhesion. Further, the coating with poly-d-lysine (PDL) hydrobromide was done to promote 3D capillary morphogenesis into the hydrogel. This platform has allowed application of biochemical and biophysical stimuli to multiple cell types interacting over distances of less than one millimeter, thereby replicating many aspects of the in vivo microenvironment. Further, it provided the possibilities for time-dependent manipulation of flow and concentration gradients as well as generation of high-resolution real-time images for observing spatial–temporal single-cell behavior, cell–cell communication, cell–matrix interactions and cell population dynamics. This platform has provided a scope for performing heterotypic cell type assays that can be used to study cell survival, proliferation, migration, morphogenesis and differentiation under controlled conditions (Shin et al. 2012).
In another study, Annabi et al., developed hydrogel-coated microfluidic channels for cardiomyocytes culture where they had synthesized photo-crosslinkable gelatin plus tropoelastin-based hydrogel mixture for the purpose of coating (Annabi et al. 2013). Tropoelastin is a soluble precursor to elastin which helps to retrieve the original shape of any tissue (Vrhovski and Weiss 1998). The primary cardiomyocytes cultured on tropoelastin hydrogel layers showed better cell attachment and high voluntary beating rates in contrast with photo-crosslinkable gelatin. This shows that tropoelastin hydrogels may be suitable for the fabrication of OoC, as it provides better elasticity and better exposure for the production of elastic tissues like blood vessels (Annabi et al. 2013; Bakooshli et al. 2013). The microfluidic hydrogel device included an inlet, an outlet and an inside layer of the microchannels where the hydrogels were coated. The microchannels were engraved on the PDMS layer. There are different types of hydrogels, namely linear, T-shaped and branched. The green-shaded area has transport properties in a penetrable hydrogel (Koo and Velev 2017).
Nie et al. developed Vessel-on-a-chip with hydrogel-based microfluidics that was equipped with internal microchannels to offer more in vivo-relevant models for construction of tissues and organs in vitro. The chips were designed by combining the casting and bonding processes with twice cross-linking strategy to obtain a bonding interface that had the same strength with the hydrogel bulk, which was applied to arbitrary combinations of hydrogels. The developed chips show that combination of gelatin and gelatin methacrylate (GelMA) were biocompatible and promoted cell functionalization. The chip offered a promising model for studying vascularization, vascular inflammation, tissue engineering, and drug development (Nie et al. 2018).
It has been observed that hydrogel-based microfluidics chips are more biologically relevant than the PDMS chips. However, the inherited swelling of hydrogels leads to the decrease in mechanical performance and deformation of the structure of chips, which causes difficulty in application processing. To address these issues, Shen et al., non-swelling hydrogel-based microchips by fabricating by covalently cross-linking of the biocompatible copolymer of di-acrylated Pluronic F127 (F127-DA). The non-swelling property of this chip helped in maintaining the as-prepared mechanical strength and channel morphology when equilibrated in aqueous solution at 37 °C. In addition, these chips showed slow degradation rate (within 21 days of incubation) upon conducting the stability studies. Furthermore, using this technology, a vessel-on-a-chip is established that was designed via seeding human umbilical vein endothelial cells (HUVECs) on the microchannel surfaces inside the microfluidic that showed resistance to fluid shear stress and expressed higher endothelial functions than the corresponding static culture (Shen et al. 2019). The diagrammatic representation of swellable and non-swellable hydrogel-based microfluidic chips are shown in Fig. 4.
2.4 Microfluidic chip merged with detection instruments
Microfluidic chips could be integrated with location-based instruments to improve effectiveness, speed of the test, and throughput as well as to minimize the expenses and test utilization of the examination (Cui and Wang 2019; Gao et al. 2013). In recent years, there has been an increased interest in the miniaturization of instruments in analytical chemistry. Microfluidic devices are being tested by coupling with different analytical instrumentation techniques, namely mass spectrometry (Wang et al. 2015), polymerase chain reaction-based instrumentation (Ottesen et al. 2006), gas chromatography–mass spectrometry (Pang et al. 2015) and liquid chromatography (Grinias and Kennedy 2016).
2.4.1 Microfluidics combined with electrospray ionization and mass spectroscopy technique
Recently, there has been an increased utilization of microfluidic chips coupled with electrospray ionizers and mass spectrometers (ESI–MS) for high sensitivity and throughput. These systems are equipped to measure samples to picogram range. Apart from the advantages, one significant challenge in the coupling of microfluidics to electrospray ionizer is to improve steady and successful interfaces (Lee et al. 2009a; b). Coupling a microfluidic device to an electrospray ionizer is carried out through several methods that have been employed currently. The primary strategy was to utilize monolithic technique, where electrospray would be executed in a straightforward manner from the microfluidic channels that are opened at the edge of a chip. Disregarding that such kind of technique is straightforward, the major hurdle associated with it includes difficulty to control electrospray ionizer along the chip edge (Lee et al. 2009a; b; Wang et al. 2015). To overcome this challenge, intertwined silica capillaries are embedded toward the ends of the channels to fill in as the electrospray tip. However, such a methodology being troublesome, a third approach was explored where integrated emitters were being used in the designing process monolithically (Gao et al. 2013; Lee et al. 2009a, b).
As per the requirements, single or multiple electrospray emitters are fabricated with different materials, namely PDMS, glass, silicon, quartz, PMMA and polycarbonate (Feng et al. 2015). Different fabrication technologies used include: (a) cleanroom intensive approaches that include X-ray photolithography, HF etching, UV exposure/SU-8; (b) non-cleanroom approaches, namely hot embossing, plasma etching, injection molding and embossing (Feng et al. 2015; Sung et al. 2005). In electrospray ionization mass spectrometry, the sample solution is sprayed through a high-voltage potential capillary by nebulization gas. The sprayed droplets are ionized due to the high-voltage potential in the capillary. Heat desolvation gas evaporates the solvent and its resultant molecular ions are formed (Xue et al. 1997). Electrospray ionization process is primarily employed in the ionization of proteins, peptides, lipids and oligosaccharides (Koster and Verpoorte 2007). The design of the microchip comprises nine microchannels and each of them has two inlet wells. One well is for the sample inlet which can be associated with the syringe siphon. The subsequent well contains a support that can be associated with a high-voltage source. The leave ports of the chip are lined up with the orifice of the mass spectrometer utilizing a 3D translational stage as shown in Fig. 5 (Gao et al. 2013; Koster and Verpoorte 2007; Lee et al. 2009a, b; Xue et al. 1997).
2.4.2 Microfluidics coupled with matrix-assisted laser desorption ionization (MALDI)
MALDI is one of the common ionization techniques in mass spectrometry, which could be coupled with microfluidic technology for better sensitivity, speed, throughput and cost reduction (DeVoe and Lee 2006). This is because microfluidics has the ability to manipulate small sample quantities with minimal sample consumption, minimal cross-contamination, and high accuracy. MALDI is essentially employed for bigger particles such as proteins, peptides, and different biomolecules (DeVoe and Lee 2006; Wheeler et al. 2005). In this technique, a pulsed laser beam is guided to collide with the sample–matrix mixture. This would result in the conversion of the sample into ions due to translational energy (Kussmann and Roepstorff 2000). Coupling of the MALDI technique with microfluidics may be performed in two ways: on-line or off-line formats (Lee et al. 2009a; b). In the on-line design, the analyte is conveyed into the mass spectrometer basically by three methodologies, for example, vaporized particles, vessels, or by mechanical methods. However, a major challenge in on-line coupling is that MALDI requires vacuum, whereas the microfluidic operations are done at atmospheric pressure (Chatterjee et al. 2010). Therefore, the off-line coupling is widely used because samples can be directly deposited on the target for subsequent analysis. Sample deposition is accomplished with a robotic target spotter. Both, the matrix as well as sample are mixed on-line before being spotted on a matrix-coated target (Chatterjee et al. 2010; Gao et al. 2013). A plan of the microfluidic chip integrated with the MALDI procedure comprises a T-junction droplet microfluidic type where the drops are framed after the connection between the oil and fluid stage. At that point, the droplets are coordinated from a microfluidic T-junction onto the MALDI plate mounted on a motorized x–y stage by a capillary. For capturing the aqueous droplets, MALDI plate is precoated with teflon and hydrophilic spot regions. The solvents are then permitted to dissipate. 2,5-Dihydroxybenzoic acid (DHB), which is a MALDI matrix, is applied to the dried droplets as shown in Fig. 6 (Feng et al. 2019; Kussmann and Roepstorff 2000; Küster et al. 2013; Wang et al. 2015). This technique is mainly used for bioanalysis reactions such as enzymatic reaction, proteins and peptide analysis.
2.4.3 Microfluidics combined with PCR technique
PCR technique is widely utilized in molecular biology for the amplification of DNA strands (Zhang et al. 2006). The amplification process consists of three steps such as, denaturation, annealing, and extension. In the denaturation cycle, the double-stranded DNA loosens up into two single strands at 95 °C. The temperature is then lowered to 55 °C, so that the primers could be attached to the DNA strands for annealing. After this step, a polymerase enzyme is attached to the complex. At that particular point, the temperature is elevated to 72 °C for the extension cycle (Ottesen et al. 2006; Zhang et al. 2006). In the PCR procedure, there are several warming and cooling steps which relatively consume time. However, the absolute analysis time can be reduced by microfabricating the device. Furthermore, the decrease in size prompts a higher surface region where mass and heat transport could be expanded (Ahrberg et al. 2016). In a microfluidic device, flow of the sample is regulated and controlled by syringe pumps. However, employing these pumps would make the operation complex. Therefore, to avoid the use of external pumps, self-propelled continuous-flow PCR is combined with a capillary-driven microfluidic chip for the amplification of DNA strands. In this, after pouring the PCR solution, it is simply transferred autonomously via capillary forces and amplification of DNA strands takes place as shown in Fig. 7 (Park et al. 2011; Tachibana et al. 2015).
2.4.4 Microfluidics integrated with liquid chromatography (LC)
Liquid chromatography is a separation technique which is utilized to isolate particles or ions that break down in a dissolvable solvent. It is preferred for the separation of complex mixtures of proteins, peptides and drug metabolites (Snyder et al. 2011). In the usual analysis of macromolecules such as proteins or peptides, there may be some challenges such as complexity, wide range of concentration, differently expressed proteins during cell development, low-level expression for certain components, sample preparation at microlevel and availability (Akshatha and Gurupadayya 2018; Snyder et al. 2011). To overcome these difficulties, multiplexed diagnostic stages are being built up which allow high throughput and precise outcomes. Miniaturization of a device enables small sample manipulations (0.1–1 nL) which results in short analysis time and simultaneously reduces the cost (Grinias and Kennedy 2016). Completion of various stages, namely sample infusion, division, labeling, and detection should be possible in fewer minutes. It can also perform exact and precise sample dealing operations. Due to these advantages, microfluidic technology is combined with LC for the biomolecule analysis (Akshatha and Gurupadayya 2018; Huft et al. 2013). Microfluidic LC devices are fabricated by photolithography and wet-chemical etching. The device typically consists of pumping channels, eluent inlet, outlet reservoirs, separation channels, double T-junction containing sample plug, sample reservoir, sample inlet and outlet, sample waste reservoir, electrospray capillary emitter, and waste reservoir as shown in Fig. 8 (Lazar et al. 2006).
2.4.5 Microfluidics coupled with gas chromatography–mass spectrometry (GC–MS)
GC–MS is a separation technique that assists in the investigation of modest and unstable compounds such as hydrocarbons, essential oils, and basic molecules such as steroids, hormones, and unsaturated fats. It can likewise be utilized for the investigation of fluid, solid, and gas samples (Adams 2007). It could also recognize complex combinations, to evaluate analytes, and trace level chemicals in organic contamination. In GC–MS, the sample is usually rendered volatile because of which it effectively disintegrates, and different segments are isolated with the support of a capillary segment packed with the stationary stage (Stein 1999). A carrier gas such as helium, argon, or nitrogen propels the components of the sample, and after getting separated, they elute from the column at different retention times. After elution, the segments get ionized by mass spectrometer utilizing an ionization procedure, and the particles get isolated through the mass analyzer depending on the respective mass-to-charge (m/z) proportions (Adams 2007; Willard et al. 1988). A GC–MS microfluidic chip is designed for the determination of ambient gaseous molecules. The device comprises a micro-reactor, gas, fluid splitting and combining channels, mixing junctions and microchannels as shown in Fig. 9. The micro-reactor is used for three purposes: as a mixer and reactor, as a heater, and as a pre-concentrator. The microchannels are engraved by hydrofluoric acid etching (HF etching) which is a form of wet etching and thermal bonding process on the glass microfluidic chip (Pang and Lewis 2012; Pang et al. 2013).
3 Biomedical applications of microfluidic technology
Microfluidic technology has various applications in disciplines of drug discovery (Dittrich and Manz 2006), proteomics (Mouradian 2002), drug screening (Damiati et al. 2018), medical diagnostics, biosensors (Lee et al. 2010; Rivet et al. 2011) and tissue engineering (Andersson and Van Den Berg 2004). Moreover, in the field of pharmaceutical analysis, microfluidic chip technology plays a significant role in drug development (Weigl et al. 2003), analysis, detection of pesticide residue and in food safety sensing, where the chip is integrated with various other equipment’s, namely colorimeter, fluorimeter and spectrophotometer (Gao et al. 2020). It further assists in the monitoring of hormone secretion (Roper et al. 2003), peptide analysis integrated with HPLC (Yin et al. 2005), analysis of tumor cell metabolism (Chen et al. 2012), and several other applications.
At a drug discovery level, it mainly emphasizes on identification, characterization, purification and structure elucidation of chemical moieties (Pihl et al. 2005). It is well reported that, during the process of analysis, there are several significant challenges that may hamper the results, namely low throughput, the need for a larger quantity of sample or reagent, reduced accuracy and tediousness in the process. In such cases, microfluidics chip technology is employed to minimize these challenges. Multiple microchannels permit high throughput which further demonstrates cost-effectiveness and rapid increase in the rate of how drugs are screened (Kang et al. 2008; Warkiani et al. 2014; .
We attempt here to establish the recent advances in the designing of different types of microfluidic chips along with their roles and applications in the field of biomedical sciences. Microfluidic chip technology is primarily applied for therapeutic and diagnostic purposes. It is basically classified on the basis of device configuration/setup and device application. In biomedical field, various types of microfluidic chips are currently being used for different purposes such as lung-on-chip, kidney-on-chip, skin-on-chip, brain-on-chip, and gut-on-chip. ‘Organ-on-chip’ technology helps to simulate the physiology of organs, namely lung, kidney, heart, gut, and brain to name a few. Moreover, it further extends its scope in targeted drug delivery systems using ‘droplet microfluidics’. In the analysis of a single cell, droplet microfluidics is extensively used because of its ability to isolate the cells. Microfluidic technology is also integrated with detection instruments and equipment’s for better sensitivity, speed, and throughput.
3.1 Droplet-based microfluidics chips
Maher et al., reported use of microfluidic chip in treatment of colorectal cancer where multifunctional microspherical magnetic and pH-responsive transporters were utilized. These were designed by droplet-based microfluidics. For colorectal cancer therapy, pH stimuli-responsive drug delivery platform played an important role here. The microfluidic chip was engineered with pH-sensitive magnetic microspherical carriers constituting a synergistic treatment for colorectal cancer. Anticancer drugs such as 5-fluorouracil and curcumin were selected because their combination had shown a synergistic effect on colorectal cancer treatment. In this study, the chemotherapeutics were stacked on permeable silicon nanoparticles and magnetic bacterial iron oxide nanowires. After the stacking, the medications were exemplified into polymeric microspheres utilizing a droplet-based microfluidic. For the controlled drug delivery, the microspheres were prepared with hypromellose acetic acid derived from a succinate polymer. This particular polymer has a unique property whereby it was insoluble in the acidic pH of the stomach and got solubilized at the pH of colon and rectum thereby releasing the drugs. The polymeric microspheres showed a thin size distribution. The synergistic activity of chemotherapeutics-stacked microspheres couple microchips were found very effective in treating cancer (Maher et al. 2017).
3.2 Organ-on-chip (OoC)
OoC is a micro-engineered 3D in vitro tissue model where micro-compartments are connected by several microfluidic channels. It helps in replicating the physiological environment of any organ (Cui and Wang 2019; Wu et al. 2020). Moreover, it may also be used for biochemical analysis. In the drug discovery process, it is important to predict the effects of any drug before it could be subjected to clinical trials. This step is usually time consuming and expensive. In contrast, OoC mimics the whole physiological part of any organ in a simplified way using the microfabrication technique (Zhang et al. 2018a; b). It reduces cost and increases throughput by reducing the gap between preclinical testing and human trials. Franzen et al. dealt with this and estimated that a decrease of 10–26% in R&D costs per new drug, and thus, it shows a positive cost impact (Franzen et al. 2019). This type of chip has several advantages, namely the compartments inside the microfluidic device enhance the control of microenvironment, precise control of the physical conditions and effective manipulation of the communication between the distinct tissues. It can also produce nutrients and oxygen for providing supply to the organs along with the elimination of catabolic metabolites (Kimura et al. 2018). The application of OoC may be limited to purely surface effects, namely the drug product being adsorbed on to the inner lining, and second, the laminar flow that may exhibit relatively a lesser degree of mixing (Probst et al. 2018). OoC may be of different types, namely brain-on-chip, heart-on-chip, liver-on-chip, kidney-on-chip, and lung-on-chip. The different types of OoC are illustrated schematically in Fig. 10.
3.2.1 Brain-on-chip (BoC)
It is well known that factors directly related to neurons and cell–cell interactions play an important role in case of brain tissue functioning. The study of the brain and its tissues are largely complex, which renders 2D models such as Petri dish or culture flasks ineffective, as these systems fail to simulate the actual physiological environment of the brain (Bang et al. 2019). To overcome this limitation, researchers currently are working on the possible development of brain-on-a-chip platform where the physiological factors of the brain could be studied under an advanced miniaturized-engineered platform that can be prepared by multistep lithography technique (Fig. 10A). It has further enabled the study of brain tissues by fabricating different dimensions of microchannels (Jahromi et al. 2019). Another study which employed an in vitro cell culture technique was previously reported, where the axons and soma were physically separated, thereby allowing only the axons to transit through the microchannels. With the help of this technique, neuroscientists could study the features of the axon itself, or may determine the mechanistic action of drugs on the axonal part, and could analyze axonal regeneration after axotomy. It is note-worthy to mention that microchannels may cause shear stress on the tissues or cells resulting in cellular damage. Air bubbles trapped under the microchannels may disrupt the flow properties and may cause cellular damage (Harrison et al. 1907). A sandwich design is usually preferred in the designing of such 3D devices, where the endothelial cells are grown in the upper layer and the brain cells are grown in the lower layer, bifurcated by a porous membrane which acts as blood–brain barrier (BBB).
3.2.2 Lung-on-chip (LoC)
Lung-on-chip (Fig. 10B) is another 3D engineered complex model of a living human lung on a microminiaturized device. It essentially constitutes a human lung and blood vessels. This system may assist largely in the physiological study of the lungs. Moreover, it also helps in studying the features of the nanoparticles absorbed in the alveoli sacs and further mimics the inflammatory response triggered by pathogens. Furthermore, it can be used to test the effects that are caused by environmental toxins, and aerosol products (Shrestha et al. 2020). LoC enables researchers to study the in vitro physiological actions of the organs or human body, and hence, it is being employed in the strategic implementation of therapeutic modalities in different pulmonary diseases. In tissue designing, microfluidic innovation assumes an essential function in noticing the development of complex tissues by providing oxygen, sustenance, and blood. It develops a microenvironment for the lung cells to study the physiological activities (Huh 2015). Wyss Institute has designed various pulmonary microchips that demonstrate the working of a typical LoC. These microchips further are capable of mimicking pulmonary edema (Ingber 2011). The design of the LoC device includes two layers: the upper layer which contains the pulmonary cells and the lower layer that consists of capillary cells. Furthermore, the two layers are bifurcated by a thin porous membrane.
3.2.3 Heart-on-chip (HoC)
Heart-on-chip is an advanced type of OoC which mimics the overall physiology of the human heart after the administration of dosage forms or, a specific drug molecule (Grosberg et al. 2011). Some of the adverse reactions have been observed using this chip. Mathur et al., in 2015 had explained the inadequacy of animal trials to estimate the exact pharmacokinetics and pharmacodynamics of a test drug molecule with respect to the human body. For that, microfluidic chip technology plays a crucial role in the study of cardiovascular diseases, cardio-vascular-related drug development, cardiotoxicity analysis, and also to study cardiac tissue regeneration (Mathur et al. 2015). Sidorov et al., in 2016 had created a I-wired HoC. They detected contractions of the cardiac muscle, which were measured by an inverted optical microscope. Furthermore, engineered 3D cardiac-tissue constructs (ECTCs) now have the ability to replicate the complex physiology of the cardiac tissues under normal and diseased conditions (Sidorov et al. 2017). Figure 10C shows the schematic representation of heart-on-chip in which the upper layer consists of heart epithelial cells and lower layer consists of heart endothelial cells. Both the layers are separated by a porous membrane. It also consists of vacuum chamber which helps in pumping of the blood.
3.2.4 Kidney-on-chip (KoC)
Limitations of traditional approaches or conventional methods, such as varying or inappropriate cellular functions and physiology rendered pathophysiological study of nephrons inaccurate and error prone. In contrast, integration with microfluidic technology has proven to produce better and precise results. KoC is essentially prepared by integrating the renal tubular cells with microfluidic chip technology (Kim and Takayama 2015). It is majorly used in assessment of kidney toxicity. Only 2% of the drug failures are screened during the preclinical stage and around 20% after the clinical stage. This justifies the use of KoC to study human nephrons on a single micro-sized chip (Wilmer et al. 2016). Lee et al., had previously explained that the pharmacodynamic and pathophysiologic reactions of the nephrons were more pragmatic in microfluidic 3D technology as compared to the 2D models. KoC has been developed and demonstrated to show better in vivo consequences of drug nephrotoxicity and the system has been employed further in the determination of various drug-induced biological responses (Lee and Kim 2018). In addition, it also assists in the culture of proximal tubules which are used for the observation of biomarkers that predicts drug-induced kidney injury (DIKI) and drug interactions (Kim and Takayama 2015; Wilmer et al. 2016). A simple design of a kidney-on-chip model basically consists of two layers. An upper layer contains the proximal tubule epithelial cells and a lower layer contains the endothelial cells. A porous membrane situated in the middle separates both the layers as illustrated in Fig. 10D.
3.2.5 Gut-on-chip (GoC)
A GoC system mimics the physiology of the human gut. It explains about the major functions of the gut, namely digestion, absorption of nutrients, regulation of enteric nerves, excretion of waste materials from the body, and the pathophysiology of the human gut accompanied by the microbial symbionts. The GoC model is primarily used for the precise reproduction of the in vivo environment of the gut with desired microfluidics parameters (Ashammakhi et al. 2020). Kim et al., studied the peristaltic movements of the intestines when a human GoC was inhabited by the gut microflora (Kim et al. 2012). The microminiaturized device was designed by aligning two microchannels: an upper and a lower, engraved on a PDMS layer which was partitioned by a porous pliable membrane coated with ECM. The setup was enveloped by human intestinal epithelial cells that imitate the physiology of the human gut as shown in Fig. 10E. Such a system could mimic the peristaltic movement of a human gut under certain specific factors, namely flow rate of fluid, minimal shear stress over the microchannels, and cyclic strain (Ashammakhi et al. 2020; Grandfils et al. 2020; Kim et al. 2012).
3.2.6 Skin-on-chip (SoC)
SoC is a bioengineered model where the skin tissues are cultured within a microfluidic system, that is sufficiently capable to mimic the 3D microenvironment of the natural human skin (Wufuer et al. 2016). To fabricate the microminiaturized SoC model, human skin tissues are integrated onto the microfluidic platform, so that it may mimic the in vivo conditions of the human skin (Zhang et al. 2018a; b). The conventional 2D model fails to recreate the multiplex 3D cell to cell, and cell to matrix interactions found in the body. However, this could be studied with the help of the 3D SoC model. To represent the epidermal and dermal layer, Lee et al. (2009a; b) used 3D-bioprinted keratinocytes and fibroblasts to create human skin tissues. The system typically has predominantly three layers: a lower layer, a middle layer, and an upper layer. The lower layer contains the microvascular channel. The porous membrane is situated in the middle/intermediate layer which separates the upper and lower layers, whereas the upper layer comprises the culture chamber and the lateral pneumatic channels. The basic setup of a SoC is illustrated in Fig. 10F. A microvascular channel provides mechanical support for the formation of the endothelial monolayer. Capillary walls formed by the endothelium layer regulate the transport, hemostasis, and inflammatory responses. Pneumatic channels are primarily designed for mechanical stimulation (Lee et al. 2014).
3.3 Microfluidic chip for single-cell analysis
Single-cell examination primarily involves the investigation of cell-to-cell associations in their microenvironment at a single-cell level. It incorporates the investigation of genomics and transcriptomics of a single cell (Yin and Marshall 2012; Yue and Xue-Feng 2006). In living tissues, each cell type has a definite lineage and function. Based on this assumption, in any case, smidgens of proof from various investigations of single cell unveil the fact that cells inside a cell populace are heterogeneous, and are comprised of individual cells that contrast incredibly (Hodzic 2016). Single-cell analysis is employed to study diseases, assists in drug development, and understand physiological functions of individuals. In the field of cell science, DNA sequencing, gene cloning and monoclonal antibody production, the employed PCR techniques have resulted in an increase in the number of samples, reagents, and assays. To beat these challenges, microfluidics has been presented which can play out an assortment of bioassays with negligible amount of samples and limited reagent utilization (Wheeler et al. 2003). A microfluidic network isolates the single cell from the cell suspension. Valves and pumps precisely deliver the volume of the reagents in nanoliters to the cells. The design of a microfluidic chip for single-cell investigation is made on the PDMS layer by multilayer soft lithography method (Unger et al. 2000). In Fig. 11, the dark and light color shows the fluidic and control channels. Reactant inlets are denoted by ‘R’ shield buffer (SB) and focusing buffer (FB). Inlets are included to reduce the fluctuation and centering of the fluid. V1–V8 are the valves that operate by applying pressure to manage the inlets. Pumps are activated by the actuation of P1 to P6 in series. After the activation of the pump, the flow rate fluctuations are regulated by the crisscross region of reagent and shield buffer medium. By utilizing hydrostatic weight, the cells are pushed from the cell channel to squander and made to zero at midway by centering support (Hodzic 2016; Kang et al. 2014; Wheeler et al. 2003).
3.4 Model organism
Model organisms are species that may be easily manipulated and bred in a typical laboratory setting. They are easy to maintain and assist to understand various biological processes. Some of the widely used model organisms are Mus musculus, Drosophila melanogaster, Caenorhabditis elegans, Saccharomyces cerevisiae, and Danio rerio (Leonelli and Ankeny 2013). C. elegans is a well-reputed model organism for the investigation of neuronal and olfactory responses (Chronis et al. 2007). They are mainly used in genetic research because they can breed on a large scale. In addition, they boast a very short generation time and their genes are similar to humans. Apart from these advantages, there are few challenges such as treatment of multicellular living beings, efficient control of the microenvironment, regulating the controls during phenotype testing, screening, and imaging of model creatures (Crane et al. 2010). Microfluidics may play an important role in overcoming these challenges, especially in the study of model organisms. Microfluidic tools have been employed in the study of the model organisms where they are immobilized by passive immobilization using microchannels. By multilayer soft lithography, the microchannels could be engraved on the PDMS membrane. Droplet-based microfluidic (DBM) technique could be adopted where the eggs/larvae of the model organisms are encapsulated into the droplets and further used for the study purpose (Hwang and Lu 2013). The DBM strategy comprises two locales: a T-junction droplet generator and a droplet trap exhibit. Arrangement of droplets occurs in the droplet generator by shearing a scattered fluid stage with a consistent oil stage. The droplets are then captured in the droplet trap array. Syringe pumps direct and control the pace of the streams in both the stages (Shi et al. 2011). Figure 12 shows a design of a model organism microfluidic chip (Ge et al. 2018).
Choudhary et al. designed multi-channel microfluidic perfusion platform for culturing zebrafish embryos and capturing live images of various tissues and organs inside the embryo. They micro-fabricated fish and chips in silicon and glass that was containing three different parts. These include a microfluidic gradient generator, a row of eight fish tanks, and eight output channels. In the fish tank, the fish embryos were individually placed. The fluidic gradient generator platform supported the analysis of drugs and chemicals in a dose-dependent manner with high reproducibility and accuracy. It provided a unique perfusion system that ensured a uniform and constant flow of media to the fish tank with a possibility of efficient waste removal. Embryonic movements were restricted in the fish tank, except for live imaging of internal tissues and organs. To validate the reproducibility of develop chip, valproic acid was taken as model drug and embryonic development of fishes were tested with/without induction of valproic acid. The results showed that embryos treated with valproic acid showed abnormalities in their development (Choudhury et al. 2012).
Similarly, Li et al. developed zebrafish on a chip for real-time monitoring of drug-induced developmental toxicity. The microfluidic system has been developed for evaluation of phenotype-based toxic and teratogenic effects of drugs on embryonic development of zebrafish. It was developed using zebrafish (Danio rerio) embryos and larvae as the model organism. The chip consisted of two independent functional units, enabling the assessment of zebrafish embryos and larvae. Each unit was consisting of a fluidic concentration-gradient generator and a row of seven culture chambers to accommodate zebrafish. The accuracy and reproducibility of results obtained using this platform was examined through evaluation of aminophylline induced toxicity and teratogenicity on 210 embryos and 210 larvae (10 individuals per chamber) as model experiment. The quantitative evaluation of effect of aminophylline on zebrafish embryonic development was done by recording a series of physiological indicators such as heart rate, survival rate, body length, and hatch rate. The toxic effect of aminophylline on zebrafish larvae was measured by assessment of clonic convulsion rate in combination with mortality. The results indicated that aminophylline could be able to induce deformity and cardiovascular toxicity in zebrafish embryos as well as their larvae. Hence, this device can be used as tool for the examination of indexes beyond toxicity and teratogenicity at the sub-organ and cellular levels and could also provide a potentially cost-effective and rapid pharmaceutical safety assessment tool (Li et al. 2014).
In another research, Chen et al., developed acoustofluidic rotational tweezing platform that enabled contactless, high-speed, 3D multispectral imaging and digital reconstruction of zebrafish larvae for quantitative phenotypic analysis. This platform was reported to achieve contactless and rapid (~ 1 s/rotation) rotation of zebrafish larvae, which further enabled multispectral imaging of the zebrafish body and internal organs. The authors also claimed that the developed acoustofluidic rotational tweezing system was very helpful for the researchers working in the area of developmental biology, small molecule screening in biochemistry, and preclinical drug development in pharmacology (Chen et al. 2021).
4 Role of microfluidic chip in therapy and diagnosis
Microfluidic technology holds a vast range of applications in most fields, namely drug discovery, food technology, electrophoresis, PCR, chemical synthesis, proteomics, tissue engineering, medical diagnosis, single-cell studies, and microarray systems (Cui and Wang 2019; Li and Zhou 2013). Microfluidic devices are miniaturized devices that can control a modest quantity of test sample (like biomolecules, cells, or particles). These microminiaturized devices have the potential for biomedical analysis and diagnosis as they only consume a small volume of samples and reagents which simultaneously reduces the cost of the experiment (Li and Zhou 2013). Furthermore, they also have the capacity to produce high throughput and accurate results (Cheong et al. 2010; Cui and Wang 2019; Upadhyaya and Selvaganapathy 2010). In the field of biomedical sciences, these chips are mainly used for diagnostic purposes such as in the diagnosis of pathogens, cancer screening, monitoring cardiovascular events, detection of deadly blood infections, genetic analysis, and several other low-cost bioassays (Li and Zhou 2013; Webster et al. 2011). There are various case studies based on therapy and diagnosis where microfluidic technology is employed.
4.1 Microfluidic technology used in therapy
In last 30 years, microfluidic chip has emerged out as great tool in the field of cancer therapy for its diagnosis and treatment. Various types of cell and tissue cultures, including 2D cell culture, 3D cell culture and tissue organoid culture could be performed on microfluidic chips. Patient-derived cancer cells and tissues can be cultured on microfluidic chips in a visible, controllable, and high-throughput manner, which greatly advances the process of personalized medicine. Moreover, the functionality of microfluidic chip is greatly expanding due to the customizable nature (Guo et al. 2021). In addition, it has been found economical as it enables the processing of trace amount of samples such as cells from patient biopsies, provides a high level of automation, and allows the setup of complex models for cancer studies (Mathur et al. 2020). There are various endeavors made in the development of microfluidic chips for their theranostic use. For instance, the microchips have been designed to investigate cancer cascade, which include tumor growth and expansion (Fig. 13), angiogenesis (Fig. 14), progression from early to late stage lesions involving epithelial–mesenchymal transition (EMT), tumor cell invasion (Fig. 15) and metastasis (Fig. 16) (Sontheimer-Phelps et al. 2019).
The tumor growth on-chip models have been designed for identification of neighboring normal parenchymal cells and ECM in the local tissue microenvironment that can influence the growth of various types of cancer. As an example, the co-culture of T47D human breast carcinoma cells with immortalized human mammary fibroblasts (HMFs) and different combinations of various ECM components in a microfluidic device revealed that HMFs promote increased growth of breast cancer cell clusters, especially in fibronectin-rich ECM compared with monocultures (Montanez-Sauri et al. 2013). Furthermore, it also facilitated the analysis of the morphology and growth of T47D cell clusters in response to broad-spectrum inhibitors of matrix metalloproteinases when cultured alone or with HMFs under different ECM conditions.
These microfluidic devices have the ability to model interactions between breast cancer cells and relevant stromal microenvironments of both primary and metastatic breast cancer sites. Based on this property, recently a microfluidic model has been designed that utilizes a heterotypic co-culture approach including up to three different cell types (breast cancer cells, stromal cells and monocytes) in combination with gene expression analysis to understand the mechanism of interaction of different cell types through paracrine signaling via production of transforming growth factor-β (TGFβ) by breast cancer cells and expression of corresponding receptors by stromal cells (Regier et al. 2016).
The microfluidic chips are also reported to investigate with high resolution of the complex interactions between multiple cancer-associated cell types and ECM molecules that are found in the local tissue microenvironment. For example, Hassell et al. developed a human lung cancer chip that recapitulated tumor growth, invasion patterns and responses to therapy observed in patients. The chip was based on principle that the rapid growth of human non-small cell lung cancer (NSCLC) cells were entirely dependent on local microenvironmental factors produced by normal lung alveolar epithelial cells and lung endothelial cells that were interfaced across a porous ECM-coated membrane and cultured under an air–liquid interface within a lung alveolus chip (Fig. 15). In this lung cancer chip, conditioned medium from the healthy alveolar epithelium was reported as efficient medium to promote cancer cell proliferation even though secreted factors from the endothelial cells partially suppressed tumor growth. Interestingly, when cyclic strain was exerted on the alveolar–capillary interface of the lung alveolus chip by applying cyclic suction to hollow side chambers of the flexible device to mimic physiological breathing motions, cancer growth was inhibited by 50%. This was found to be mediated by mechanical strain-induced changes in epithelial growth factor receptor (EGFR) phosphorylation, which also resulted in increased resistance to the third-generation tyrosine kinase inhibitor rociletinib (Hassell et al. 2017).
Lanz et al., reported a malignant growth treatment of a breast tissue directed on a 3D high-throughput perfused microfluidic stage. Among the different disease conditions, breast malignancy is the most widely recognized intrusive malignancy in women. There are a couple of models that are usually utilized in the treatment. However, restorative reactions were neglected. In this particular trial, they have presented a microfluidic organoplate stage as the choice of treatment where the extracellular matrix was embedded with tumor culture under perfusion. They utilized triple-negative breast malignancy cell lines. In addition, they had also assessed the cultivating densities, ECM composition, and biomechanical (perfusion/static) conditions. After that, the cells were exposed to anticancer medicaments (paclitaxel, olaparib, and cisplatin) and they found that 3D high-throughput culture showed a better response than the 2D culture technique (Lanz et al. 2017).
Microfluidic chips have also been reported to study neovascularization (angiogenesis) among cancer cells. For instance, Nguyen et al., developed a multiple parallel endothelium-lined microvessels within microfluidic channels by depositing sacrificial materials using a form of 3D printing during gel formation. The endothelial cells were plated on the internal walls of these channels and perfused with culture medium to form the microvessels. When tumor angiogenic factors were perfused through one set of these engineered microvessels, capillary sprouts were observed to extend from neighboring vessels, eventually linking to establish new functional capillary tubes. This model was also used to investigate the mechanisms of action of angiogenesis inhibitors, including the vascular endothelial growth factor (VEGF) receptor 2 (VEGFR2) inhibitor semaxanib and the sphingosine-1-phosphate receptor (S1PR) inhibitor fingolimod as well as angiogenesis stimulators, such as VEGF, monocyte chemotactic protein 1 (MCP1; also known as CCL2), hepatocyte growth factor (HGF) and basic fibroblast growth factor (bFGF) (Nguyen et al. 2013). Such microfluidic platforms have also been used to study brain tumor cell–endothelial cell interactions for investigating glioblastoma (Hsu et al. 2013).
Microfluidic cancer organ chip models have also been used to study steps during cancer progression that are accompanied by an EMT. These were developed by co-culturing multiple human pancreatic cancer cell lines (Lee et al. 2018) and human HT-29 colon cancer cells (Jeong et al. 2016) with their corresponding cancer-specific fibroblasts. A microfluidic device was designed with multiple parallel channels and the tumor spheroids were loaded in the central channel. The medium was flowed through the surrounding channels and fibroblasts were cultured in the outer channels. This setup allowed close proximity co-culture without direct cell contact to investigate the role of soluble factors. Induction of EMT occurred only when the fibroblasts were cultured in close proximity to the cancer cells (Jeong et al. 2016; Lee et al. 2018). The induction of this mesenchymal phenotype diminished the response of the cancer cells to chemotherapy upon treatment using paclitaxel (Jeong et al. 2016).
The use of microfluidic culture technologies has also been used to study tumor cell migration and invasiveness. For example, a microfluidic chip equipped with pneumatic micro-valves was used to analyze the paracrine loop between human CL1-0 lung adenocarcinoma cells and MRC-5 lung fibroblasts. Similarly, the primary human macrophages were co-cultured with human MDA-MB-231 breast or PC3 prostate tumor cells or MDA-MB-435S melanoma cells in a microfluidic device to understand cancer cell migration speed and persistence (Li et al. 2017).
Tumor cell invasion was studied on-chip by measuring invadopodia formation and ECM degradation by human lung cancer A549 cells growing within an ECM gel-filled microfluidic channel (Wang et al. 2013). In addition, the microfluidic device has been used to evaluate the metastasis of breast cancer cells using metastatic human MDA-MB-231 breast cancer cells and mouse RAW 264.1 macrophages. These cells were placed within neighboring ECM gels which were composed of collagen type I and Matrigel, respectively, within a microfluidic device. The invasion of macrophages was reported into the gels in the presence of breast cancer cells. Whereas, no invasion of macrophages was observed in the absence of breast cancer cells (Huang et al. 2009).
Recently, microfluidic paper-based analytical devices (µPADs) have got popularity as potential alternative tools for various analytical tasks due to certain advantages such as use of paper as the substrate material, which is economical, disposable, easy to fabricate and possibility of external power-free sample transport driven by capillary forces (Xia et al. 2016). Owing to these advantages, Tenda et al., designed µPADs for the colorimetric analysis of sub-microliter sample volumes of human serum albumin (HSA). In this study, calibration curves for HAS were recorded from sub-microliter samples (0.8 µL), with tolerance against ± 0.1 µL variations in the applied liquid volume (Tenda et al. 2016). The obtained results showed that the µPADs are specific and sensitive for trace volume (sub-micron) of sample.
4.2 Microfluidic technology used for diagnostic purpose
Liu et al., worked on establishing a novel electrochemical identification stage by microscopically integrating with a microfluidic chip. They used this novel platform for tracing three therapeutic drugs: warfarin sodium (WFS), cyclophosphamide, and carbamazepine. Warfarin sodium is an oral anticoagulant drug, whereas cyclophosphamide and carbamazepine are used as an immunosuppressant and as an anticonvulsant, respectively. Two methods, namely electrochemical catalysis and gate effect were used for the measurement of WFS. In light of the molecular imprinted technique, the novel electrochemical detection stage was installed with a counter and a reference electrode which employed a platinum wire. For the working anode, nanoporous Au–Ag alloy microwire joined with molecularly imprinted polymer was employed. The electrochemical catalysis method is a direct detection method where the electrode is used. The sample mixture which had the WFS was siphoned into the microfluidic chip and estimated by differential pulse voltammetry. On the other hand, the gate effect is an indirect method that works based on the peak current change towards the probe ions before and after adsorbing WFS. The outcome of the study was that they successfully developed the detection platform for all the three drugs (Liu et al. 2017a, b).
Fan et al., studied the microfluidic digital PCR strategy which enabled a fast pre-birth conclusion of fetal aneuploidy. Aneuploidy is an unstable genomic condition where the chromosome numbers become abnormal. It might be caused because of the solid relationship with fetal premature delivery and stillbirth. For the evaluation of fetal karyotype, traditional cytogenesis is utilized where the fetal cells were collected from amniotic fluid or chorionic villi which are then cultured. Although it provides accurate results, it requires approximately 1–2 weeks. Moreover, with conventional real-time PCR, one threshold cycle corresponds to a twofold change in copy number, which makes it more challenging to measure the smaller changes. This might be the reason for microfluidic digital PCR to be utilized for the quantification of the number of nucleic acids. They utilized 24 amniocentesis and 16 chorionic villus tests for microfluidic digital PCR. For each target chromosome, 360 PCR responses were performed, and further, the quantity of single-molecule amplification was compared with a reference. The outcome indicated that digital PCR precisely distinguished all the instances of fetal trisomy (Fan et al. 2009).
Basiri et al., studied RNA virus detection using microfluidic devices. The technology was an ideal platform to test its applicability in the detection of coronavirus (CoV). The virus is reported to cause severe acute respiratory syndrome. As of now, quantitative reverse transcription (qRT-PCR) is favored for the detection of the corona virus. However, the disadvantages related to qRT-PCR are: it is expensive, time consuming, and insensitive. To control the pandemic scenario, there needs to be an alternate way that can show rapid detection, ease of use, at the same time being affordable. Microfluidic chip-based innovation may be employed which would offer the stage to apply for numerous demonstrative tests such as RT-PCR, nested-PCR, nucleic acid hybridization, enzyme-linked immunosorbent assay (ELISA), fluorescence-based measures, and many more. Microfluidics chips ensure faster reactions (approximately 25–60 min) resulting in accurate and precise outcomes. Moreover, it makes the analysis modest and simple to deal with higher affectability. Thus, microfluidic devices end up being a superior elective technique for the detection of RNA infections. Previously, these devices have been used for the detection of many RNA viruses such as subtype of influenza virus A(H1N1), Zika, hepatitis A virus (HAV), human immunodeficiency virus (HIV), and norovirus (Basiri et al. 2020).
Moarefian et al., demonstrated iontophoretic drug conveyance in a microfluidic device. Iontophoresis is a process that deals with drug conveyance by electrophoresis and electroosmosis. It can likewise build the penetrability of the skin with the assistance of an electric flow. It uses low-power electrical voltage and a continuous consistent flow to coordinate a charged medication to the tissue. As of date, the iontophoresis strategy is utilized as a novel methodology in the therapy of malignancy (in vivo). It is ideal to show the low-power electrical fields in all culture frameworks for the streamlining of iontophoretic drug conveyance to the malignancy cells. They planned an iontophoresis-on-chip stage to evaluate carboplatin drug conveyance and to compare the anticancer viability under various voltages and flows. The authors had further utilized an in vitro heparin-based hydrogel microfluidic device to display the development of a charged medication across extracellular matrix and in breast malignancy cell lines. The concentration of the anticancer medication, for example, carboplatin in the tumor extracellular matrix was determined utilizing a small amount of sample. The study concluded that the medication conveyance and the tumor cell demise were expanded when 50 mV DC electrical field and 3 mA electrical flow were added (Moarefian et al. 2020).
Maria et al., used cross-connected hyaluronic acid nanoparticles (cHANPs) by utilizing a microfluidic stage integrated with magnetic resonance imaging (MRI). As of date, nanostructures are utilized to capture MRI-contrast agents, without the need to synthetically alter the clinically affirmed segments. In this study, the authors developed a microfluidic stage that was used to incorporate cHANPs in which a clinically pertinent gadolinium diethylenetriamine penta-acidic corrosive (Gd-DTPA) was captured. The microfluidic cycle empowered the creation of monodisperse particles of around 35 nm. Fine-tuning of the process parameters were performed to achieve the impedance of Gd-DTPA, which influenced the utilization of hydrophilic–lipophilic balance of surfactants and pH conditions during polymer precipitation. Microfluidic approaches have several favorable outcomes where it can improve the relaxometric properties of Gd-DTPA stacked in cHANPs with any synthetic alteration. It was discovered that Gd-DTPA stacked cHANPs supported the unwinding rate and this system could be utilized for both, analytical and restorative applications (Russo et al. 2016).
Herr et al., employed microfluidic immunoassays for the quick determination of components in human saliva. They had also adopted the clinical point-of-care (POC) indicative, which allowed fast quantitation of an oral infection biomarker in the human saliva. In POC diagnostic, usually a monolithic disposable cartridge is employed which is intended to function in a conservative analytical instrument. Microfluidic innovation technology was employed which encouraged investigation of hands-free salivation by consolidating test pretreatment (filtering, advancement, blending) with electrophoretic immunoassays. This method empowered the quick estimation of analyte concentration in an insignificant quantity of saliva. Utilizing this strategy, they estimated collagen-dividing enzyme matrix metalloproteinase-8 (MMP-8) in salivation from a healthy as well as a periodontally infected individual. Microfluidics incorporated with POC indicative is equipped for rapid finding of proteinaceous sickness biomarkers in biological liquids (Herr et al. 2007).
Liu et al., studied cancer diagnostics by single-exosome counting immunoassays. Exosomes are usually used as a biomarker in cancer diagnostics. The tumor cells shed the exosomes which indicate the presence of cancer. An immunosorbent assay was designed and combined with droplet microfluidics which enabled the digital diagnostics of exosomes. The exosomes were immobilized on magnetic microbeads with the assistance of a sandwich ELISA. The constructed beads were then isolated and encapsulated into a droplet so that each bead should get encapsulated in a droplet. The droplet-based single-exosome counting ELISA model enabled the counting of specific cancer exosomes in cancer diagnostic purposes. In addition, a limit of detection down to 10 enzymes labeled exosomes complex per microliter was achieved. This approach ensured an early diagnosis of cancer (Liu et al. 2018).
Ziober et al., studied a lab-on-chip system for the screening and diagnosis of oral cancer. Oral squamous cell carcinoma (OSCC) is a deadly cancer which is usually diagnosed only at an advanced stage. Around 40% of all oral cancer cases represents malignant growth in the head and neck region. Furthermore, they also contain squamous cell carcinoma of the oral cavity, for example, the tongue, mouth floor, buccal mucosa, gums and lips. There is no precise, moderate, and reproducible methodology that can recognize the OSCC at an earlier phase. A rapid oral cancer test is needed for mass screening. In addition, the analysis of OSCC requires present-day lab facilities, refined sorts of equipment, and skilled staff. Ziober et al., employed a lab-on-chip device for biomarker-based identification of oral malignancy using a ‘spit test’. Magnetic bead cell arrangement and multiplex identification of mRNAs utilizing bio-scanner tags were utilized for this purpose. The spit test showed the presence of ordinary cells along with cancer cells, and lymphocytes. The lymphocytes were then encapsulated into magnetic beads with anti-CD-45. After incubation, the lymphocytes were captured by the magnet. Furthermore, incubation was carried out after the addition of antibody-coated magnetic beads and quantum dots (Q-dots). The cancer cell-based Q-dot complexes were isolated from the solution, with the help of an external magnetic field. Expulsion of unbound Q-dots was accomplished by washing and malignant growth cell limited Q-dots were assessed. Magnetic beads with captured mRNAs were segregated using an external magnetic field and beads with DNA bio-barcodes were added. During incubation, complexes of barcode-magnetic bead sandwiches were formed and captured by a magnetic field. Eventually, the barcode-DNAs were dehybridized and detected by fluorescence using a fiber-optic array (Ziober et al. 2008).
Xie et al., employed a novel methodology where they combined electrochemical microfluidic chips with different biomarkers for the early detection of malignant growth in the stomach. Presently, gastric cancers are the second most reported malignancy in the world. It is difficult to detect the cancer in the earlier phases. To improve the therapeutic outcomes and viability, a multidisciplinary treatment approach is to be employed. It is critical to monitor the condition from an early phase, which may significantly improve the therapeutic outcomes. A disposable electrochemical microfluidic chip joined with numerous biomarkers was constructed by Xie and co-workers. Six types of biomarkers were employed in the detection of gastric malignant growth. These were carcinoembryonic Ag(CEA), carbohydrate Ag 19-9(CA 19-9), Helicobacter pylori CagA protein (H.P.), P53 oncoprotein (P53), and pepsinogen I and II (PG-I and II). Three specially designed gold electrodes were used to avoid cross-contamination in each of the detection areas. The device consisted of 6 different kinds of biomarkers targeting 6 detection areas. Differential pulse voltammetry (DPV) was employed to compare the electron transfer ability between working electrodes and bare electrodes after antibody immobilization. The biomarker solutions were injected into the microchannel and were then incubated at 37℃ for 30 min. This methodology has proven to possess an extraordinary potential in early detection of gastric malignancy (Xie et al. 2015).
Fu et al., studied and analyzed a swine virus sample using an incorporated microfluidic stage. The microfluidic stage incorporated a microfluidic chip combined with a semi-automated immunoassay system. Currently, the ELISA technique is the most commonly employed technique for the detection of swine virus. Samples such as a serum or oral fluid are usually collected and tested through an ELISA. However, the main disadvantage with this technique is that it is tedious and time consuming. To confirm the presence of the virus, a rapid, inexpensive, and reproducible technique is needed. Microfluidic chips based platforms provide accurate and early detection of the viral particles. These are rapid and have a high analytical effectiveness. A single chip could be employed for the analysis of several samples. These chips were used to detect several types of viruses from porcine origin, respiratory syndrome virus, CSF virus, and porcine circovirus type 2. The procedure includes sample and reagent injection, well washing, waste collection, and finally colorimetric detection. The findings revealed that the microfluidic technique took just 12 min and 4 µL of sample for the detection process. The accuracy rate was high with high effectiveness and high explicitness (Fu et al. 2020).
In recent years, numerical approaches have been designed for developing efficient microfluidic technologies for cell analysis (Sheidaei et al. 2020). The numerical based evaluation are powerful tools to rapidly analyze the problems at a lower cost. In addition, these are able to study multiphysics problems that help in understanding biological processes that involve physical phenomena such as fluid flow, solid mechanics, mass and heat transfer. The numerical simulation can assist researchers in studying complex device functions. Moreover, numerical simulations are capable of determining critical operating parameters such as velocity, pressure, concentration, shear rate, and temperature that are cumbersome to be measured experimentally. Looking at various advantages of microfluidic chips, Zahorodny-Burke et al., simulated the stationary convection diffusion mass transfer phenomena in a 2D cell culture device to explore the effect of chip thickness and channel height on oxygen transport (Zahorodny-Burke et al. 2011). A decrease in the oxygen concentration in the cell layer was located at the bottom of the culture channel was noted with increase in heights of the channel and the chip (Fig. 17A). Huang and Nguyen used a 2D computational model to optimize key dimensional parameters of a cyclic cell-stretching device (Huang and Nguyen 2013). The cells were cultured on a thin membrane and a mechanical strain was induced to these cells. The effect of geometrical parameters on membrane displacement was studied (Fig. 17B). Liu et al. (2017c) numerically simulated a 2D gel injection process in a microfluidic chip with different pillar spaces (Fig. 17C). In another numerical study, Chen et al. (2019) investigated a 2D fluid flow in a microfluidic device with various micropillar designs. Pillars with circular, elliptical and square cross-section were arranged in both aligned and staggered styles. It was observed that in the staggered arrangement, the fluid flew through the center of the array as well as around the pillars. For distribution of fluids, the staggered arrangement was found better than the aligned pillars (Fig. 17D).
5 Conclusion
The microfluidic chip technology employs advanced innovative strategies and is an emerging science in the field of life sciences and biomedical sciences. It is predominantly utilized for the estimation of behavioral changes in miniature fluids (micro- or nano-level) through miniature channels that are engraved on the polymer layer. The technology enables effective control over the physicochemical responses of the liquid. Due to its miniature scaled down methodology, it brings about high mass exchange and high throughput. It is primarily employed in drug discovery, proteomics, drug screening, clinical analysis and food innovation. Various types of microfluidic chips are currently employed for various purposes. Compared to the conventional methods, microfluidic chip technology offers much advantage and better outcomes in terms of time consumed and amount of samples and reagents required. In pharmaceutical investigation, microfluidic innovation could be integrated with various other detection equipment, namely PCR, ESI–MS, MALDI-MS and GC–MS to name a few. Much of the current applications of microfluidic innovation are reported in the detection and treatment of malignancies. Organ-on-chips are reportedly utilized for the investigation of the physiological processes in specific body organs such as brain, lungs, heart, kidney, gut and skin. Significantly, microfluidic innovation is playing a major role in the current COVID-19 pandemic situation, especially in the treatment strategies and analysis of coronavirus particles by integrating with a qRT-PCR strategy. Thus, microfluidic innovation technology has demonstrated that it is a superior cutting-edge technology which could be adopted in the screening and treatment for various infective conditions. Despite enormous advantages, microfluidic chips suffer from some limitations. For example, paper-based microfluidic devices are very complex to pattern the channels on the chip. The organ-on-a-chip systems have replaced animal testing and improved patient safety and considered as a great advancement in medical research because they facilitate testing of active ingredients on cell cultures in the chambers of a plastic chip. However, they are not a true-to-life replication of the human body and can only simulate a few functions and activities because the human body is a complex system where different kinds of organs and cells interact. Its complexity cannot be built into organ-on-a-chip systems. Moreover, their designs are complex. When coupling organs on chips, whether it is to measure the efficiency of a treatment or to study the interactions between organs, the relative size of the models matters. In case of organ-on-chip, sometimes it becomes difficult to determine right scale (organ mass/organ volume/fluid flow) for analysis. Determination of quantity of fluid inside the organ-on-chip is another limitation. It has been reported that human body contains 5 L blood, hence, in can be imagined that a microhuman would have 5 µL of blood. This total volume of 5 µL implies many challenges because excessive volume could dilute the treatment, or hormones secreted by the different organs, and skew the results of the tests. Hence, it is important to create microfluidic pumps and valves of the right size for such small volumes (Wikswo et al. 2013). Hence, there is a need for standardization of microfluidic chips to compare and interpret their findings. Since this is a process starts with the cells that are being used, some researchers use primary cell cultures and other cell lines, while others try to differentiate stem cells into specialized cells for specific organs. Other issues include the formulation of cell culture media, the cell life cycle on the chips or the materials used in bioprinting for example. These are all variables that could impact results. Based on these facts, it can be concluded that microfluidic chips still have a long way to go before they can replicate the complexity of living organisms.
Availability of data and materials
Not applicable.
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Acknowledgements
I would like to express my deep gratitude towards Chancellor of LPU, Shree Ashok Mittal for providing necessary support.
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PP: methodology, data curation, and writing—original draft. SKS: conceptualization, validation, supervision, and writing—review and editing. MG: supervision and writing—review and editing. SV: methodology. BK: methodology. DKC: data curation and writing—original draft. KA: methodology. GG: methodology. NKJ: methodology. PKG: methodology. PP: methodology. KD: methodology. HD: methodology. DK: methodology. VK: methodology.
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Pattanayak, P., Singh, S.K., Gulati, M. et al. Microfluidic chips: recent advances, critical strategies in design, applications and future perspectives. Microfluid Nanofluid 25, 99 (2021). https://doi.org/10.1007/s10404-021-02502-2
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DOI: https://doi.org/10.1007/s10404-021-02502-2