Emerging Trends in Microfluidic Biomaterials: From Functional Design to Applications

Microfluidic biomaterials can be formed by micro-molding of the material against a pre-patterned template. Microfluidic chip preparation technology utilizes microfabrication technology to construct microchannel networks on chips, achieving high-throughput preparation and screening of biomaterials. This method can precisely control the cellular microenvironment for studying cell behavior, drug screening, and tissue construction. The first, and most commonly applied, strategy is based on the micro-molding of hydrogels. The hydrogels used as microfluidic biomaterials have unique advantages. They are composed of hydrophilic polymer networks, naturally porous, and have a high moisture content, which can be used as a simulation of an extracellular matrix [132,133,134]. Therefore, the microfluidic gel obtained is very suitable for use as scaffolds for engineered living tissues. At the same time, the surface of hydrogel materials is soft, which can reduce cell damage and immune rejection. This approach is amenable to the formation of gels that contain single channels or planar networks.

Micro-mold is also a key technology for manufacturing polymer microfluidic devices. For microfluidic devices based on thermoplastic materials, micro-mold is used to replicate microchannels through hot pressing or injection molding. For PDMS-based microfluidics, micro-mold in soft lithography is an important step in casting PDMS microchannels from molds. Currently, SU-8 micro-mold is the most commonly used method for manufacturing thermoplastic or PDMS microfluidic devices, as it is easy to operate and has lower facility costs compared to other micro-mold manufacturing methods [135]. For example, alginate micro-forming is performed using PDMS micro-molds through soft lithography. The operation steps are as follows: pour PDMS onto a silicon wafer with a positive pattern formed by SU-8 photoresist lithography and cure it at 60 °C using the RTV615B catalyst kit in a mixing ratio of 10:1 [136] (Figure 6a). To demonstrate the feasibility of using cell-friendly micro-forming technology to generate alginate-based particles, Fabien Nativel et al. employed this micro-forming method, which can produce calibrated microparticles that can be easily adjusted by changing their shape and size, thus facilitating the selection of appropriate mold sizes in their research [137]. However, there are potential issues with the adhesion between SU-8 resin and silicon substrate, and the SU-8 layer may peel off during the demolding process, which limits the lifespan of the micro-mold. An effective alternative to address this drawback is the use of polymer-based micro-forming, which has already been applied in the field of microfluidic chip manufacturing [138].

As one of the traditional techniques used for the preparation of microfluidic biomaterials, although the technology of the micro-molding method is more mature, the shortcomings exposed in terms of scalability and reproducibility still cannot be ignored. Since the micro-molding method relies heavily on pre-fabricated molds, the design flexibility is limited by the need to recreate the molds if preparing microfluidic organisms with different structures. In addition, the molds used will inevitably produce wear and tear, such as channel size deviation due to elastic deformation in PDMS molds, which largely affects the number of times the molds can be used. Effective solutions regarding these issues in micro-molding methods are still a serious challenge.

Light-based methods are a research approach that combines optical and microfluidic technologies for manipulating and analyzing biological samples at the microscale. The main advantage of light-based methods is high degrees of freedom, and even the ability to create complex microfluidic geometries such as branching structures or 3D networks. Traditional light-based methods can be divided into two categories: photodegradation and photopolymerization [16,139].

Photodegradation is a subtractive method used for manufacturing microfluidic biomaterials, in which light is used to remove the material to form channels. Therefore, the function of this material is similar to that of a positive photoresist. In most cases, photodegradation requires irradiation of blocky transparent hydrogels at a wavelength suitable for a specific photosensitive part of the hydrogel skeleton [140,141,142]. The main application of in vivo methods is to construct dynamic microscale concentration gradients through spatial control to provide a more realistic research environment. This method is particularly suitable for synthesizing gel, and gel made of polyethylene glycol (PEG) and its derivatives are widely used. However, because PEG itself lacks the adhesive part that allows cells to grow well on the block gel or channel surface, the use of photosensitive PEG gel is doomed to be very limited. Shinya Yamahira et al. reported a new method to construct dynamic microscale concentration gradients around cells in a step-by-step manner in micropatterned hydrogels. They innovatively used DBCO-PC-4armPEG (dibenzocyclooctyl terminated photosoluble four-arm polyethylene glycol) to prepare photodegradable hydrogel, which is a clickable cross-linking and photosoluble PEG. As shown in Figure 6b, in the microfluidic perfusion culture device, cells are encapsulated in photodegradation hydrogel, and then the perfusion microchannels are produced in the hydrogel through the photodegradation of micro patterns [143].

Compared to photodegradation, photopolymerization is significantly different. Photodegradation is applied to initially crosslinked rigid gel, and the broken bond is limited to the area that has absorbed enough light. However, photopolymerization is applied to liquid precursors and then selectively crosslinked. Currently, light-based methods are often combined with 3D bioprinting. With the development of various light-based 3D bioprinting technologies and the emergence of innovative strategies, this method is widely used in vascular tissue engineering. Light-based 3D bioprinting utilizes the unique advantages of light, including high resolution, rapid solidification, multi-material adaptability, and tunable photochemistry, to provide revolutionary solutions to the challenges faced by vascular tissue engineering [144,145,146,147]. In the process of photopolymerization, biomaterials act as negative photoresists and are constructed layer by layer to form channels. In this method, when the liquid is vertically translated, a 3D structure is generated by scanning a laser on the surface of the photosensitive liquid resin. Due to the appropriate wavelength sensitivity of photosensitive groups, photopolymerization has also been used in biodegradable elastomers to form microfluidic channels (Figure 7a). The current bioprinting technology used for manufacturing live tissue models includes VAT photopolymerization [148]. Vat photopolymerization is a 3D printing technology based on photopolymerization resin. Compared to soft lithography, VAT photopolymerization has many advantages in manufacturing microfluidic devices. It not only has high precision and is suitable for manufacturing complex microfluidic channels and fine structures, but also has good compatibility and can be combined with other technologies such as soft lithography. However, material performance limitations and post-processing requirements still pose challenges for VAT photopolymerization [149].

Three-dimensional printing microfluidic technology is an advanced technology that utilizes additive manufacturing methods to manufacture microfluidic devices. It has the advantages of rapid prototyping, flexible design, and low cost, allowing for a high degree of freedom in the engineering design of biomedical devices [150,151,152,153,154]. Nowadays, 3D printing technology provides higher flexibility, faster prototype development speed, and lower cost for the design and manufacturing of microfluidics. Three-dimensional-printed microfluidics have received widespread attention due to their various advantages [155]. The 3D printing method for specific types of applications depends on the selected material type, material compatibility, material availability, size, resolution, yield, speed, and the way the final object is sliced [156,157,158].

Three-dimensional printing is also superior to traditional PDMS micro-molding in the manufacturing of microfluidic chips, especially in terms of design flexibility, manufacturing speed, and cost-effectiveness. Three-dimensional printing increases structural complexity by bypassing mold manufacturing and labor-intensive processes, greatly reducing manufacturing time and costs [159,160,161]. Moreover, with the maturity of digital light technology (DLP), water-soluble thermoplastic materials (such as ACMO) can be used as sacrificial molds that can rapidly manufacture complex structural molds and reduce post-processing steps, which not only greatly improves productivity, but also supports the repeated printing of multiple materials [162,163]. Therefore, 3D-printed microfluidic chips can be easily designed and fabricated, and a personalized custom design can produce nanomedicines at low cost. However, due to their complex geometric shape, the application of 3D-printed microfluidic chips is still immature in the manufacturing of nanomedicines [164]. To fill this gap, Aytug Kara et al. demonstrated that the encapsulation of nifedipine within polymer nanoparticles can ensure critical quality manufacturing properties using FDM and SLA 3D-printed microfluidic chips [165] (Figure 7b). They demonstrated that microfluidic chips pave the way for a simple, cost-effective, and scalable continuous process for manufacturing nanomedicine. Overall, the micro-molding method is suitable for small-scale high-precision needs in academic labs, but 3D bioprinting is more advantageous in terms of complex structural design, large-scale production, and dynamic functional integration. In the future, the preparation process of microfluidic chips can be optimized by combining the advantages of both of these through a hybrid strategy, for example, using PDMS molds to fabricate the basic channels and then adding vascularized structures through bioprinting.

As mentioned above, 3D bioprinting has been widely used to fabricate vascularized tissue constructs for disease modeling and tissue regeneration [155,166]. Specifically, light-based 3D bioprinting technology has attracted close attention and has become a breakthrough technology in this field. Due to its advantages of being digitally processable, cell-friendly, and having the ability to enhance other 3D printing technologies, various light-based 3D bioprinting methods have been developed to manufacture in vitro vascular disease models, tissue-engineered blood vessels, and vascularized tissue/organ transplants to meet the higher demands of clinical medicine [146].

The three most common methods mentioned above often face more limitations in terms of suitable material types and/or microfluidic geometries, thus providing ease of use and the ability to quickly and conveniently generate microfluidic channels. Table 1 compares the above three methods in terms of variable restrictions, advantages, and disadvantages.

The discharge method has been used to create fractal vascular networks in degradable polymers. This method is excellent for generating large 3D branch networks in one step, although the cost is the variability of network geometry. In addition, as a better alternative method in non-photolithography, viscous fingering is the one that has seen the most application. The biggest advantage of this method is its unparalleled simplicity, but the problem it is currently facing is the lack of geometric generality.

Each of the above methods has its own unique advantages, but the range of applications is very limited. In order to compensate for, or even eliminate, the inherent shortcomings of each method, we believe that future trends in methods for preparing microfluidic biomaterials will undoubtedly require the incorporation of artificial intelligence. Currently, the combination of microfluidics in deep learning (DL) is a very innovative approach with broad prospects in the field of smart healthcare. Deep learning is particularly good at dealing with the field of big data and high-dimensional data; in addition, through its powerful pattern recognition, prediction optimization, and real-time analysis capabilities, it can significantly improve microfluidic system design, manipulation, and data processing efficiency [167,168]. For example, the combination of microfluidics with advanced technologies such as artificial intelligence has facilitated the development of wearable microfluidics, an extraordinary combination that permits high-throughput analysis of small sample sizes and advanced data processing, leading to potential breakthroughs in cell sorting, biomolecular analysis, and more [169].

Natural biomaterials mainly come from animals or plants in nature, with unique physical and chemical properties and high biocompatibility, suitable for various biomedical applications [197]. Due to their high moisture content and viscoelasticity, these natural biomaterials are widely used in 3D bioprinting as cell encapsulated bioinks for manufacturing on-chip organic matter. Common examples include ensuring that cells are protected from external hazards such as contaminants in the printing space or mechanical stress when passing through printing nozzles.

Well suited to build structures for tissue engineering, collagen is a biomaterial often used in biomedical applications based on its biocompatible, biodegradable, and noncytotoxic properties [198,199,200]. Due to these favorable characteristics, collagen serves as a prominent biomaterial in various in vitro models, including organ-on-a-chip devices. Recently, in the field of collagen-engineered glomerulonephritis (GOC), Petrosyan et al. described a GOC model using COL-IV and laminin as matrix materials (the main components of the glomerular basement membrane). For the first time, human podocytes and human glomerular endothelial cells were seeded onto microfluidics to better simulate the process of the glomerular filtration barrier through selective permeation and response to nephrotoxic drugs [198]. In summary, collagen can open up new pathways to establish microstructures. Due to its strength, it can replicate the biological barrier of the entire organ, and its non-absorbable properties make it a powerful tool for drug analysis, disease modeling, and precision medicine applications [201,202]. However, collagen does come with limitations, such as poor physical properties, that may lead to the deformation of the fabricated structure and a reduction in printing resolution. To address these limitations, a recent development involves a hybrid collagen-derived hydrogel, in which the physical properties are enhanced by the incorporation of UV-curable materials. This innovative method has been actively applied in the manufacturing of organ-on-a-chip devices [176].

Gelatin is a natural polymer derived from the hydrolysis of collagen, which is a biocompatible, biodegradable, non-toxic, and easily processed material. The functional modification and new applications of gelatin are constantly emerging. In the field of tissue engineering, gelatin is usually used in a variety of systems, such as drug delivery systems to achieve sustained and targeted delivery, the injection of hydrogels, scaffolds, or wound dressing films for cell culture and tissue regeneration [203,204,205]. It has the advantage of strong water absorption, which can be used for tissue regeneration, such as nanocomposite hydrogel for wound treatment or injectable hydrogel for bone regeneration, but its thermal stability is not stable enough, and it can easily change from solid to gel according to the change in temperature [206,207,208]. In addition, due to its hydrophilic nature, gelatin is sensitive to moisture and becomes fluid above a certain temperature. This sensitivity can pose challenges to the structural stability of organs-on-a-chip manufactured using gelatin. To solve this problem, gelatin-methacryloyl (GelMA) is commonly used [209]. GelMA has the characteristics of both natural and synthetic biomaterials and has a three-dimensional structure suitable for cell growth and differentiation, which can replace the artificial basement membrane or other natural collagen hydrogels. The gelatin part of GelMA hydrogel provides an ideal biological adhesion environment for cells. Adding GelMA helps to crosslink and solidify gelatin through UV and visible light under the action of photoinitiators, while maintaining shape fidelity and stability at physiological temperatures, without affecting the biocompatibility and degradation performance of gelatin [210]. There is no doubt that GelMA has been widely used in tissue engineering as a hydrogel.

In the medical field, silk can be combined with hydrogels, films or coatings, nanoparticles, fibers, and other particles to obtain functional biomaterials in the form of 3D-printed structures, and mixtures of different materials are used to improve their biodegradability, biocompatibility, and mechanical properties [211,212,213,214,215]. Silk fibroin (SF) is widely used in the manufacturing of organ-on-a-chip devices using 3D bioprinting methods. It is primarily used in 3D bioprinting through physicochemical transformations of pure SF or by mixing it with a high-viscosity hydrogel or supplement to create an advanced SF-based hydrogel.

However, due to the different types of natural sources, the quality of natural polymers varies greatly and requires careful sterilization and purification processes, which are quite cumbersome [216]. To compensate for the shortcomings of natural polymers in certain aspects, researchers have developed synthetic polymers to finely control the physical and chemical properties of materials and produce materials that can surpass the boundaries of naturally derived materials with minimal batch-to-batch variations. Synthetic biomaterials have the characteristics of customizable mechanical and biodegradable properties, excellent printing performance, and consistent quality [217,218,219]. Despite lacking bioactivity, synthetic biomaterials typically possess superior physical properties and rigidity compared to natural biomaterials. Consequently, they find application as a robust cell support framework in organs-on-a-chip. The combination of synthetic biomaterials with 3D bioprinting technology enables the realization of various organs in organs-on-a-chip [220]. The following will introduce several synthetic biomaterials widely used in organ-on-a-chip fabrication through 3D bioprinting.

Polylactic acid (PLA) is a novel biodegradable material widely used in biomedical applications, particularly in cardiac, dental, or orthopedic fixation devices, due to its biocompatibility. Its biodegradable properties can also be used for other implantable devices, such as surgical sutures that do not require removal. It is also used in regenerative medicine because it can stimulate hard tissue regeneration during bone transplantation and has extraordinary biological absorption capacity [221,222,223,224].

Polycarbonate (PCL) is also a very useful biodegradable biomaterial, with good compatibility with biological cells in vivo. Cells can grow normally on its scaffold and degrade into water and carbon dioxide. Under physiological conditions, it can slowly degrade within a few years, making it suitable for long-term implants such as treating bone defects, drug delivery systems, and delivery platforms for various extracellular matrix proteins or 3D scaffolds [225,226,227]. PCL has a lower melting point than other synthetic biomaterials and quickly solidifies after being sprayed from the nozzle [228]. This feature makes it suitable for constructing frameworks that directly interact with cells and support cellular structures. Therefore, PCL is commonly used for organ-on-a-chip tissue manufacturing through 3D bioprinting.

PDMS is an elastic and nondegradable material prepared by blending a curing agent and an elastomer base. PDMS has a wide range of applications in various fields, but it is mainly used in the production of various medical devices, such as particle blood analogs that stimulate red blood cells and microvalves or vascular analogs with excellent elasticity [229]. The PDMS-covered platform is highly suitable for cell cultures that require oxygen enrichment due to its excellent oxygen permeability. After curing, PDMS exhibits low shrinkage, high tensile modulus, and high thermal conductivity. PDMS also has optical transparency and the ability to easily track target particles, making it valuable for tissue applications on organ-on-a-chip devices that require these characteristics. The vascular model on the chip is based on the inherent advantage of precise control of fluid pathways using microfluidic technology. Through microfluidic channels and stress-induced rolling membrane technology, a series of tubular structures loaded with cells is used to simulate natural blood vessels. A unique strategy has emerged to generate simulated tubular structures with different types of cells deposited in different layers. As shown in Figure 8c, microfluidic channels are used to pattern different types of cells at fixed positions. After stretching, the PDMS film is covered with a semi-cured PDMS film to introduce mismatched tension. After releasing two layers of PDMS, a self-curling 3D tubular structure will be constructed.

Three-dimensional bioprinting is generally divided into the following three stages: pre-processing, processing, and post-processing [188,230,231]. Pre-processing serves as the initial stage, where bioinks, cells, and CAD designs are prepared [230]. Different biological chains are selected according to the intended application, usually including hydrogels, extracellular matrix components, or other cell-specific materials. The cells are harvested, cultured, and mixed with bioink. The CAD schematic generated from specific imaging data or predefined structures provides a blueprint for bioprinters in specific aspects.

During the processing stage, various parameters such as nozzle diameter, extrusion speed, and layer height can be adjusted as needed through material deposition and organization for printing to optimize structural integrity and cell viability. Post-processing is the final step. Based on its expected functions (such as transplantation, drug testing, and even understanding pathophysiology), cells have the opportunity to fully integrate into their expected environment, differentiate, and interact harmoniously with natural tissues.

Microfluidic chip design achieves precise manipulation of fluids through microchannel structures, generating uniform droplets or fibers. Suitable materials need to be selected for functional design based on biocompatibility, controllability, responsiveness, scalability, and multifunctionality [232]. PCL is usually used as a platform material for an organ-on-a-chip device to prepare hydrogel, and the printing conditions need to be adjusted according to the properties of each hydrogel. The 3D bioprinting code is generated in the printing system, and the organ platform on the chip is printed. This is a simple method of manufacturing organ platforms on chips with complex designs through 3D bioprinting. The microfluidic channels are designed with appropriate internal dimensions according to different applications [233].

All printing structures are dried in a vacuum at room temperature, the position of the hydrogel in the printing platform is checked, and the printing microfluidic channel of the organic platform on the chip is analyzed to achieve the purpose of scanning electron microscopy. The required cells are prepared, labeled, and encapsulated in the hydrogel, and then printed on various platforms of organ-on-a-chip devices.

Figure 9 specifically illustrates the steps of 3D bioprinting for preparing biochips. Firstly, the 3D model of the cavity is designed and prepared using CAD, and the cell types and hydrogels for the microenvironment are printed in the prepared cavity. Secondly, the sidewalls of the fluid channel are printed using a multi-layer process. By printing the shell material and crossing it above the pre-printed side walls of the fluid channel to avoid fluid leakage, the fluid channel is covered and sealed. Finally, the tube connection part for dynamic stimulation is printed. During the process of connecting the printing tube, the optimal design is chosen to ensure fluid transfer efficiency while avoiding leakage.