We present a novel benchtop-based microfabrication technology: 3D printing, ink casting, micromachined lamination (3D PICLμM) for rapid prototyping of lab-on-a-chip (LOC) and biological devices. The technology uses cost-effective, makerspace-type microfabrication processes, all of which are ideally suited for low resource settings, and utilizing a combination of these processes, we have demonstrated the following devices: (i) 2D microelectrode array (MEA) targeted at in vitro neural and cardiac electrophysiology, (ii) microneedle array targeted at drug delivery through a transdermal route and (iii) multi-layer microfluidic chip targeted at multiplexed assays for in vitro applications. The 3D printing process has been optimized for printing angle, temperature of the curing process and solvent polishing to address various biofunctional considerations of the three demonstrated devices. We have depicted that the 3D PICLμM process has the capability to fabricate 30 μm sized MEAs (average 1 kHz impedance of 140 kΩ with a double layer capacitance of 3 μF), robust and reliable microneedles having 30 μm radius of curvature and ~40 N mechanical fracture strength and microfluidic devices having 150 μm wide channels and 400 μm fluidic vias capable of fluid mixing and transmitted light microparticle visualization. We believe our 3D PICLμM is ideally suited for applications in areas such as electrophysiology, drug delivery, disease in a dish, organ on a chip, environmental monitoring, agricultural therapeutic delivery and genomic testing.
“Makerspace microfabrication” with the use of simple tools and materials is used to demonstrate the realization of 2D microelectrode arrays (MEAs) having a density of up to 8 × 8 MEAs in under four days which are comparable to conventional MEAs.
We present a nontraditional fabrication
technique for the realization
of three-dimensional (3D) microelectrode arrays (MEAs) capable of
interfacing with 3D cellular networks in vitro. The
technology uses cost-effective makerspace microfabrication
techniques to fabricate the 3D MEAs with 3D printed base
structures with the metallization of the microtowers and conductive
traces being performed by stencil mask evaporation techniques. A biocompatible
lamination layer insulates the traces for realization of 3D microtower
MEAs (250 μm base diameter, 400 μm height). The process
has additionally been extended to realize smaller electrodes (30 μm
× 30 μm) at a height of 400 μm atop the 3D microtower
using laser micromachining of an additional silicon dioxide (SiO2) insulation layer. A 3D microengineered, nerve-on-a-chip in vitro model for recording and stimulating electrical
activity of dorsal root ganglion (DRG) cells has further been integrated
with the 3D MEA. We have characterized the 3D electrodes for electrical,
chemical, electrochemical, biological, and chip hydration stability
performance metrics. A decrease in impedance from 1.8 kΩ to
670 Ω for the microtower electrodes and 55 to 39 kΩ for
the 30 μm × 30 μm microelectrodes can be observed
for an electrophysiologically relevant frequency of 1 kHz upon platinum
electroless plating. Biocompatibility assays on the components of
the system resulted in a large range (∼3%–70% live cells),
depending on the components. Fourier-transform infrared (FTIR) spectra
of the resin material start to reveal possible compositional clues
for the resin, and the hydration stability is demonstrated in in-vitro-like conditions for 30 days. The fabricated 3D
MEAs are rapidly produced with minimal usage of a cleanroom and are
fully functional for electrical interrogation of the 3D organ-on-a-chip
models for high-throughput of pharmaceutical screening and toxicity
testing of compounds in vitro.
We demonstrate a new fabrication technology for 3D Microelectrode Arrays (MEAs) to stimulate and record electrophysiological activity from cellular networks in-vitro. Electrospun Polyethylene Terephthalate (PET) 3D scaffolds are coupled to the fabricated MEAs which make them fully functional for "disease in a dish" and "organ on a chip" models to promote cell/tissue growth and regeneration. The microfabrication technology involves 3D towers realized by 3D printing and a metallization layer, defined by stencil mask evaporation techniques. Multiple insulation strategies are reported: a drop-casted/spincoated 3D layer of Polystyrene (PS) and an evaporated layer of SiO2, both of which are laser micromachined to realize the 3D microelectrodes.
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