Design, Fabrication, and Testing of a 3D Printer Based Microfluidic System

A pneumatically actuated PDMS based microfluidic devices were designed and fabricated by soft-lithography. Two types of molds were fabricated out of different material for this experiment. The first mold, (device 1), was fabricated from a sheet of Polymethyl methacrylate (PMMA) material, similar to Plexiglas. The device features were micro-engraved onto the face of the material. The second mold, (device 2), was fabricated from the use of fused deposition modeling (FDM) 3D printing. The pumping efficiency of the PDMS devices was analyzed through the characterization of the micro-pumps flowrate with respect to the pumps driving pressure and the actuation frequency. Tested at a driving pressure of 10psi, the flowrate for device 1 peaked at 75µL/min with a 7Hz actuation frequency before failing, while device 2 peaked at 498µL/min with a 15Hz actuation frequency. Using the techniques of rapid prototyping and fused deposition modelling a pneumatically actuated 3D printer based micro-pump and micro-mixer are fabricated. The devices were fabricated using a thermoplastic elastomer (TPE) material as an alternative material to the present polydimethylsiloxane (PDMS). The micro-pump’s fluid flow output was analyzed through the characterization of the micro-pumps flowrate with respect to the pumps driving pressure and the actuation frequency. Testing showed that a maximum flowrate of 1120µL/min was achieved at an actuation frequency of 10Hz with an applied driving pressure of 40psi. A qualitative mixing performance was conducted with the micro-mixer. The diffusion of two dyes was tested under an active mix and non-active mix condition. Testing showed that the active mixing condition resulted in a complete diffusion as opposed to the non-mixing condition which partially diffused. As a proof of concept for biological testing, E. coli and E.coli anti-bodies were mixes to measure the capturing efficiency. The results showed that the active mixing resulted in about 50% capturing efficiency as opposed to the non-mixing which resulted in 33% capturing efficiency

3D-printed peristaltic microfluidic systems fabricated from thermoplastic elastomer

Recent advancements in 3D printing technology have provided a potential low-cost and time-saving alternative to conventional PDMS (polydimethylsiloxane)-based microfabrication for microfluidic systems. In addition to reducing the complexity of the fabrication procedure by eliminating such intermediate steps as molding and bonding, 3D printing also offers more flexibility in terms of structural design than the PDMS micromolding process. At present, 3D-printed microfluidic systems typically utilize a relatively ‘stiff’ printing material such as ABS (acrylonitrile butadiene styrene copolymers), which limits the implementation of large mechanical actuation for active pumping and mixing as routinely carried out in a PDMS system. In this paper, we report the development of an active 3D-printed microfluidic system with moving parts fabricated from a flexible thermoplastic elastomer (TPE). The 3D-printed microfluidic system consists of two pneumatically actuated micropumps and one micromixer. The completed system was successfully applied to the detection of low-level insulin concentration using a chemiluminescence immunoassay, and the test result compares favorably with a similarly designed PDMS microfluidic system. Prior to system fabrication and testing, the material properties of TPE were extensively evaluated. The result indicated that TPE is compatible with biological materials and its 3D-printed surface is hydrophilic as opposed to hydrophobic for a molded PDMS surface. The Young’s modulus of TPE is measured to be 16 MPa, which is approximately eight times higher than that of PDMS, but over one hundred times lower than that of ABS

3D-printed peristaltic microfluidic systems fabricated from thermoplastic elastomer

Recent advancements in 3D printing technology have provided a potential low-cost and time-saving alternative to conventional PDMS (polydimethylsiloxane)-based microfabrication for microfluidic systems. In addition to reducing the complexity of the fabrication procedure by eliminating such intermediate steps as molding and bonding, 3D printing also offers more flexibility in terms of structural design than the PDMS micromolding process. At present, 3D-printed microfluidic systems typically utilize a relatively ‘stiff’ printing material such as ABS (acrylonitrile butadiene styrene copolymers), which limits the implementation of large mechanical actuation for active pumping and mixing as routinely carried out in a PDMS system. In this paper, we report the development of an active 3D-printed microfluidic system with moving parts fabricated from a flexible thermoplastic elastomer (TPE). The 3D-printed microfluidic system consists of two pneumatically actuated micropumps and one micromixer. The completed system was successfully applied to the detection of low-level insulin concentration using a chemiluminescence immunoassay, and the test result compares favorably with a similarly designed PDMS microfluidic system. Prior to system fabrication and testing, the material properties of TPE were extensively evaluated. The result indicated that TPE is compatible with biological materials and its 3D-printed surface is hydrophilic as opposed to hydrophobic for a molded PDMS surface. The Young’s modulus of TPE is measured to be 16 MPa, which is approximately eight times higher than that of PDMS, but over one hundred times lower than that of ABS