1. Introduction
Microfluidics has a wide variety of applications, from fluid pumping to flow properties measurement to biological sensing and detection [
1,
2]. In order to fabricate a microfluidic system, there are two main steps, namely microchannel fabrication and bonding.
There are different techniques for microchannel fabrication, namely etching in a glass or silicon and soft lithography for polymer-based substrates. Similarly, microchannel substrates are bonded with different methods such as fusion bonding, anodic bonding, solder bonding, thermo compression bonding for glass and silicon, adhesive bonding, and oxygen plasma bonding for polymer-based microchannel substrates.
Microfluidic channels were fabricated by etching in silicon and glass materials in standard microfabrication techniques [
3,
4]. Then, this was followed by bonding techniques with high bonding temperature, such as fusion bonding [
5] and solder bonding [
6], which require heat and pressure between substrates, and anodic bonding [
7], which requires high voltage and temperature. However, the etching technique is expensive and uses hazardous chemicals.
Thus, microchannels made of polymeric materials using soft lithography techniques replaced former methods [
8,
9,
10]. This technique does not require aggressive chemicals during fabrication and high temperature or pressure or excessive cleaning during bonding, which makes it less expensive compared to the previous methods. There are two main bonding techniques for polymer-based microchannels, namely adhesive [
11] and plasma bonding [
12].
Due to several advantages of PDMS, such as biocompatibility, optical transparency, and excellent mechanical properties, PDMS has been widely utilized for microfluidic devices [
13,
14]. Fabricating multi-layer microfluidic systems made with PDMS is still a challenge. Three-dimensional printing techniques as alternative approaches were proposed for one-step 3D fabrications with PDMS [
15,
16,
17,
18,
19]. However, this method requires a substrate for printing microfluidic systems; thus, the fabrication process has to be optimized for printing PDMS-suspended microfluidics, such as microcantilevers.
Moreover, there was a problem in soft lithography, specifically when electronic elements are required to be embedded in microchannels. In order to fabricate this kind of microfluidics, a thin layer of the polymer such as PDMS has been used as an adhesive [
20], which needs an exact control of the PDMS layer’s thickness for device performance or the channel may be blocked or deformed. Using uncured or partially cured PDMS as an adhesive has almost doubled the bonding strength compared to bonding strengths with the plasma technique [
21].
Another issue with multiple layer microfluidics is trapped air bubbles between substrates during bonding. However, since PDMS is a gas-permeable polymer, air bubbles can escape if at least one substrate is not of a hard material such as glass. The trapped air bubbles can degrade the bonding strength, which causes leakage and dysfunction during microfluidic testing. In order to avoid trapped air bubbles, placing a grid of empty channels to suck the air bubbles out of microfluidics to free air was suggested by [
20]. The grid of air channels is fabricated during the molding step, while microchannel mold is fabricated by using soft lithography.
In this study, we have proposed and tested an optimum number of air-vent channels between PDMS layers to remove trapped air bubbles. This allows using inexpensive plasma bonding method, which provides the required bonding strength for our experiments. Moreover, the PDMS curing temperature has been optimized to possess some stickiness during the bonding step. Since the thickness of the thin layer is around 200 µm in our fabrication procedure, using uncured or semi-cured PDMS may damage our thin substrates.
2. 3D Suspended Polymeric Microfluidic Resonator Fabrication (SPMF3)
A 3D suspended polymeric microfluidic resonator (SPMF
3) [
22,
23] comprises three different layers, as shown in
Figure 1. Two layers have microchannels, and the other one has a nozzle through which these two layers with microchannels are connected. Flow direction changes when it passes through the suspended microfluidics and applies flow forces onto the microcantilever. Monitoring the applied flow forces against flow properties can be used to measure different fluids properties using SPMF
3 [
22]. The detection and study of microparticles are among other applications of the SPMF
3 platform that have been examined and published by current authors [
24].
In order to obtain and optimize the suspended microfluidics’ dimensions, a finite element simulation with rough dimensions has been performed as the first iteration [
25]. Then, an optimization analysis for sensitivity improvement is performed to obtain the optimum dimensions. Finally, the microsystem dimensions that have the highest sensitivity and deflection are chosen for sample fabrication: a microcantilever with the size of 6000 × 2000 × 600 µm
3 with an embedded microchannel of 200 × 100 µm
2. Detailed finite element analysis and sensitivity studies of the suspended microfluidics have been performed and published by the current author [
25,
26].
Table 1 summarizes the SPMF
3 dimensions that have been used for simulations and the resulting deflection.
2.1. Fabrication Method
Soft lithography [
27] is one of the main techniques for fabricating a PDMS microfluidic chip that starts with microchannel mold fabrication on a clean silicon wafer. The silicon wafer is coated with a photoresist material, SU8-2075, up to the desired microchannel depth by a spin-coating machine. After a pre-exposure baking step at 95 °C for 10–15 min, the silicon wafer is patterned using a mask with ultra-violet light (UV). Then, post-exposure baking is required to cure the patterned microchannel. Finally, the patterned photoresist material on the silicon wafer is submerged in a developer solution, which removes the unpatterned regions on the silicon wafer. Then, the mold is employed to fabricate the microchannel using a polymeric material such as PDMS. After having the microchannel substrate cured in an oven, the microchannel is bonded to a glass slide to form the microfluidic system and closed microchannels, as shown in
Figure 2.
2.2. Fabrication Steps
2.2.1. Mold Fabrication
In order to make each of the abovementioned layers, a proper mask and mold should be designed and fabricated. Three different masks are designed and fabricated, as shown in
Figure 3; in this study, SU8-2075 has been used to make a mold for microsystem fabrication. This fabrication requires two different molds: one for microchannel layers and one for nozzle layers.
Lastly, the silicon wafer, including patterned and cured SU8, will be developed in a photoresistant developer solution to remove unpatterned areas from the mold, as shown in
Figure 4. At the end, it is better to hard bake the mold at high temperatures to produce mold features that are hard and resistant.
2.2.2. PDMS Layers Fabrication Procedure
PDMS with a 10:1 ratio to curing agent is used in this fabrication process. After preparing liquid PDMS, it may be poured on the mold prepared earlier, as shown in
Figure 4. By applying enough pressure on the mold, one makes sure that the final PDMS layer will be exactly made as designed. Applying pressure will be performed by using microscope glass slips, which are shown in
Figure 5a. Finally, the mold should be heated at 65 °C for 2 h for curing. A gripper was also used to keep some pressure on the mold during curing to maintain the desired layer thickness.
The PDMS layer is ready to be bonded when it is detached from the mold after curing process, as shown in
Figure 5d.
2.2.3. Bonding Procedure
In this step, each layer will be exposed to a 40 s plasma treatment and bonded carefully under the microscope for proper alignment using cantilever features. As observed in
Figure 6, these two PDMS layers are placed on the glass slips used during the fabrication process. Thus, when bonding is completed, one of these glass slips (the nozzle one) has to be removed. This glass slip removal process has to be performed carefully. Otherwise, the entire delicate microstructure might become damaged. Now, two layers are bonded to each other (MLT + NL), and the third layer, which is the second microchannel layer (MLB), has to be bonded to these two layers. This will be performed in the same manner as the earlier bonding process for the first microchannel later to the nozzle layer. At the end, both glass slips at two sides of the 3-layer microfluidics will be removed, and proper supporting layers are bonded to hold the microsystem. Finally, the microcantilever in which a 3D microchannel is embedded is ready for fluid detection experiments and microparticle injection tests.
2.3. Fabrication Issues
During the fabrication process and after performing experiments with the suspended microfluidic system, some issues occurred that were related to the fabrication process. These issues and their solutions are listed as follows. Trapped air bubble between layers, bonding strength, and particles stickiness were fundamental points that needed attention to make microfluidics functional. There were some other issues that were minor but needed to be addressed, such as nozzle alignment and the quality of the nozzle hole.
2.3.1. Air-Vent PDMS Fabrication Method
As mentioned during the fabrication process, microchannel (MLU, MLB) and nozzle layers (NL) are placed on a glass slide during bonding, as shown in
Figure 6a. Therefore, air bubbles may be trapped between layers during the bonding step, resulting in microfluidics dysfunction. In order to avoid this issue, two air-vent channels were designed and fabricated during the molding step, as shown in
Figure 7. These channels help vent the trapped air bubbles out and consequently increases the bonding strength.
In order to optimize the air-vent channel’s dimensions, three suspended microfluidic systems with and without air-vent channels were fabricated and bonded. In this experiment, air-vent channels of 300 µm and 500 µm were integrated into the microchannel layer. As shown in the results, the air bubble is highly trapped in the fabrication without air-vent channels, which causes complete fabrication failure and unusable microfluidics, as shown in
Figure 8.
However, when an air-vent channel of 300 µm was fabricated within the microchannel layer, the trapped air bubble transformed into multiple smaller bubble where there were no bubbles near the air-vent channels, which means that trapped air near these channels was taken out. Increasing the air-vent channel size to 500 µm removed most of the air bubbles and cleared all critical regions around the microchannel where the bonding strength was required. There is still a tiny portion of the trapped air left that is not in a critical region and can be removed with an extra air-vent channel in that zone.
2.3.2. Particle Stickiness
One of the main experiments performed in this research study was the detection and study of microparticles flow inside SPMF
3 [
24]. One of the main issues in dealing with microparticles in a PDMS microfluidics is the particles stickiness inside the channel (
Figure 9). This is due to the presence of active ions on the microchannel walls [
28]. In order to avoid this issue, which will block the microchannel, three solutions exist in the literature: diluting microparticle solution with anti-ion liquids such as TWEEN20 [
29], covering microchannel walls with lubricants such as Teflon AF [
30], and reducing the microparticle concentration in the solution [
31].
Here, we tried a combination of diluting the microparticle solution with TWEEN20 and reducing their concentration in the solution, which worked perfectly during the experiments.
2.3.3. Bonding Strength
After fabricating several SPMF
3 samples and conducting a simple flow test, it was observed that fluid leaks out of the microchannel and moves between microsystem layers. This is considered as a failure due to the low bonding strengths with respect to the desired tested flow rates. Therefore, one of the main parameters or issues that has to be monitored during the multi-layer fabrication process is bonding strength. The experimental results are unreliable if the layers are not bonded properly and fluid leaks between layers. In order to avoid this issue and based on best practices in the literature [
21], the PDMS curing temperature was lowered from 90 °C to 65 °C in order to produce more sticky surfaces after curing. Moreover, the air-vent microchannels will also improve bonding strength by removing trapped air, which is required during fluid experiments with high flow rates.
2.3.4. Alignment between PDMS Layers
The 3D-suspended microfluidics comprised five PDMS layers in which there are three main layers, namely one nozzle layer and two microchannel layers, and two supporting or sandwich layers on the top and bottom. The misalignment of the three main layers results in different designs and load sensitivity in the final suspended microfluidics. However, there are some situations in which bonding happens while the desired alignment is not reached. Since layer alignment was performed by hand and under a microscope, it is inevitable that sometimes the required alignment does not happen as it was planned, which is shown in
Figure 10. Further attention under the microscope during the bonding process would resolve unwanted misalignments. Moreover, each SPMF
3 should be tested after production for its baseline load sensitivity in order to remove variation error between different SPMF
3 samples.
3. Experimental Validation of the SPMF3
An experiment of injecting water with different flow rates has been performed to validate the sensitivity of fabricated 3D suspended microchannel to flow forces. The microcantilever deflections were measured by an optical laser-based deflection measurement system shown in
Figure 11.
In this measurement system, reflected laser light from the shiny cantilever tip was detected with PSD, and its displacement history was recorded in a data logger. Since the laser, microcantilever, and PSD are on the same plane, the displacements of the reflected laser light can be transformed into microcantilever deflections using a geometrical formula [
32].
In order to study the microchannel’s dimensions impact on the sensitivity of the fabricated microsystem, two SPMF
3 with different microchannel dimensions were fabricated for this experiment. The first SPMF
3 sample has a channel size of 400 × 100 µm
2, respectively, and the second one has a channel size of 200 × 100 µm
2. A syringe pump was employed to inject DI water with different flow rates from 0 to 20 µL/min into SPMF
3 samples. As shown below,
Figure 12 and
Figure 13, both SPMF
3 samples had high sensitivity to flow forces when a fluid passed through the suspended microchannel and nozzle.
In the next experiment, a peristaltic pump was used to investigate the sensitivity of fabricated SPMF
3 under dynamic loads such as a pulsating flow. The peristaltic pump speed is fixed at 2 rpm, and it is connected to the both fabricated SPMF
3 systems with different microchannel dimensions of 200 × 100 µm
2 and 400 × 100 µm
2 (width by depth). According to measured cantilever deflections shown in
Figure 14, the SPMF
3 systems are sensitive to dynamic loads of pulsating flows generated by rollers of the peristaltic pump. Here, the microfluidic system was tested at 2 rpm pump speed that generated flow pulses of 0.33 Hz due to 10 rotating rollers of the pump.
In the next experiment, DI water with different concentrations of salt varying from 0–15% of weight was injected into the two SPMF
3 samples with different microchannel dimensions. The intention was to verify the sensitivity of SPMF
3 relative to various fluid properties such as density and viscosity. Varying salt concentration in water results in different fluid density and viscosity, as shown in
Table 2According to the experimental results shown in
Figure 15, variation in fluid properties through the addition of salt can be detected using this microsystem. This experiment has been repeated for both SPMF
3 samples with 400 × 100 µm
2 and 200 × 100 µm
2 (width by depth) microchannel dimensions. As confirmed in this figure, SPMF
3 can be employed for different bio-fluid detection applications. Further results of such experiments in fluid detection have been examined and published by the current authors [
22].
4. Conclusions
Polydimethylsiloxane (PDMS) has shown promising results in 3D microfluidics fabrication due to its capability for multi-layer fabrication. Each layer may have microchannels, valves, pumps, and holes and can be aligned and bonded to a single microfluidic system. In this paper, the fabrication process details of a 3D-suspended microfluidics with issues and solutions were presented. SPMF3 works based on the flow forces created along the microchannel when the flow direction is modified. These forces can be optimized through the design and dimensional modification of microchannels and nozzle.
During this fabrication, some fundamental issues were observed, such as bonding adhesion, trapped air-bubble between PDMS layers, and microparticles clogging, as well as some minor issues such as microchannel and nozzle misalignment and nozzle-finishing quality. These major issues of bonding strength, trapped air, and particles clogging were addressed using optimized PDMS curing temperature from 90 °C to 65 °C, adding an optimum number of air-vent microchannels to PDMS layers and reducing microparticle flow rates by using a diluted microparticle solution with TWEEN20, respectively.
Finally, the sensitivity of the SPMF3 was examined in different conditions such as step-flow rate variation and dynamic flow (Peristaltic pump) and detecting variations in fluid properties (salt addition). Based on the experimental results, SPMF3 can be employed as a bio-fluid detection platform, which is able to differentiate fluid properties as well as its flow rate in either steady or transient flows.