Multiscale fabrication of scalable biomimetic 3-D, integrated micro-nanochannels network in PDMS for solute exchange
Prasoon Kumar, Prasanna S Gandhi, Mainak Majumder

TL;DR
This paper presents a scalable hybrid microfabrication method combining 3D printing and electrospinning to create biomimetic 3D micro-nanochannel networks in PDMS for efficient solute exchange, mimicking natural vasculature.
Contribution
It introduces a novel, scalable fabrication process integrating micro and nanotechnologies to produce complex micro-nanochannel networks in PDMS, overcoming limitations of traditional methods.
Findings
Successfully fabricated biomimetic micro-nanochannel networks in PDMS.
Demonstrated efficient fluid flow and solute exchange in the device.
Potential applications in biomedical and diagnostic microfluidic devices.
Abstract
Integrated micro-nanochannel networks in fluidic devices are desirable in a number of applications ranging from self-healing/cooling materials to bioengineering. The conventional micro-manufacturing techniques are capable of either producing microchannel or nanochannel networks for a fluidic application but lack proficiency in the production of an integrated micro-nanochannel network with a smooth transition from micro-to-nano scale dimension. In addition, these techniques possess limitations such as heavy initial investment, sophistication in operation and scale-up capabilities. Therefore, the current paper demonstrates the combination of micro/nanotechnologies to design and develop a biomimetic 3-D integrated micro-nanochannel network in PDMS device for solute exchange. We have used 3-D printer, a scalable technology, to design and manufacture micro-mold having fractal-shaped…
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Taxonomy
Topics3D Printing in Biomedical Research · Microfluidic and Capillary Electrophoresis Applications · Microfluidic and Bio-sensing Technologies
