Paper-based microfluidics

Summary

Paper-based microfluidics are microfluidic devices that consist of a series of hydrophilic cellulose or nitrocellulose fibers that transport fluid from an inlet through the porous medium to a desired outlet or region of the device, by means of capillary action. This technology builds on the conventional lateral flow test which is capable of detecting many infectious agents and chemical contaminants. The main advantage of this is that it is largely a passively controlled device unlike more complex microfluidic devices. Development of paper-based microfluidic devices began in the early 21st century to meet a need for inexpensive and portable medical diagnostic systems. Architecture Paper-based microfluidic devices feature the following regions:

Inlet: a substrate (typically cellulose) where liquids are dispensed manually.
Channels: hydrophilic sub-millimeter networks that guide liquid throughout a device.
Flow amplifiers: regions of varying geometry where the flow veloc

Official source

https://en.wikipedia.org/wiki/Paper-based_microfluidics

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A Microfluidic Device to Study Axon Growth and Guidance

Sarra de Valence

[...] Studying axon guidance by diffusible or substrate bound gradients is challenging with current techniques. In this study, we present two microfluidic devices to study axon guidance. [... click on "Download fulltext" for full abstract]

2008

In the domain of regenerative medicine research there are many fronts aimed at increasing our understanding of induced pluripotent, embryonic and adult stem cells. Recently a new front has appeared, stem cell niches, the microenvironment that is a crucial component in the regulation of stem cells. New in vitro platforms are continually being created to answer the multitude of biological questions that surround stem cell niches. The transition from in vitro to in vivo is a heavy setback in cellular research due to a huge gap between the two conditions, which can only be reduced if the in vitro conditions better mimic those found in vivo. This project has reduced the gap and has the potential to continue minimizing the differences between the two conditions in the field of muscle stem cell research. Through a combination of the forefront techniques in biological research, we were able to create a new innovative bioengineered platform, a bipolar hydrogel microenvironment. First, we took advantage of polyethylene glycol (PEG) hydrogels, which are highly hydrophilic polymer networks that have properties that mimic physiologic tissue, including high water content and low Young's Modulus. Microfabrication techniques allowed us to topographically pattern the hydrogel at micro-dimensions resembling the native cell environment. Utilizing microfluidics and micro-printing techniques, the three-dimensional hydrogel surface was also patterned with tethered niche proteins found in the in vivo muscle stem cell niche. The swelling properties of the PEG hydrogel were considered as an advantage and controlled to form niche gaps with physical properties that were tuned to correspond to those found in vivo. This new complex and controlled surface for cells to be cultured on is a tool, which will allow biologists to probe new questions and gain insight into the regulatory networks that control cell fate

2009

Research on microfluidic devices for biological analysis has progressed sufficiently to be developed into point-of-care diagnostics products. The goal of this thesis is to improve multiple aspects of capillary-driven microfluidic devices. In particular, the objective is to provide devices with a fast time to result, that are simple to use (one-step), that can be portable, that accept a variety of samples, that operate reliably, that provide a range of detection signals, that are mass manufacturable at lost cost, and that are able to detect medically relevant biological molecules. First, we survey the evolution of microfluidic research into portable medical diagnostic devices. By looking at several gaps and opportunities in current medical diagnostics, we provide an overview of research topics that have the potential to shape the next generation of point-of-care diagnostics. Specifically we explain technologies in the order of sample interacting with different components of a device. We investigate the materials, surface treatments, sample processing, microfluidic elements (such as valves, pumps and mixers), receptors and analytes and the integration of these components into a device that might conceivably leave the laboratory for the hands of consumers. The knowledge of what is important in a point-of-care diagnostics device was used to develop a proof of concept. One of the main challenges is to make microfluidics easy to use by incorporating reagents and microfluidic elements. We integrated a number of functional elements on a chip such as a sample collector, delay valves, flow resistors, a deposition zone for detection antibodies (dAbs), a reaction chamber sealed with a polydimethylsiloxane (PDMS) substrate, and a capillary pump and vents. We further incorporated capture antibodies (cAbs), detection antibodies (dAbs) and analyte molecules for making one-step immunoassays. The integrated microfluidic chip requires only the addition of sample to trigger a sequence of events controlled by capillary forces to detect C-reactive protein (CRP), a general inflammation and cardiac marker, at a concentration of 1 ng mL-1 within 14 min using only 5 µL of human serum. The proof-of-concept is extended to easily modify several assay parameters such as the flow rates and the volumes of samples for tests, and the type of reagents and receptors for analytes. The multiparametric microfluidic chip is capable of analyzing 20 µL of human serum in 6 parallel flow paths in a range of flow rates with filling times from 10 minutes to 72 minutes. The asymmetric release of dAbs in a stream of human serum is compensated by a Dean flow mixer. Sample is equally split into 6 reaction chambers connected to flow resistances that vary flow rates, and the kinetics of capture of analyte-dAb complexes. The increased incubation time leads to a fourfold increase in detection signal in the reaction chamber with the longer incubation time. Furthermore, integrating reagents and controlling their release is essential for simple and accurate point-of-care diagnostic devices. We developed reagent integrators (RIs) to release small amounts of dried reagents (ng quantities and less) into microliters of sample. Typical RIs are composed of an inlet splitting into a central reagent channel, with a high hydraulic resistance, and two diluter channels. Reagents spotted in the central channel reconstitute in sample during filling and merge at the end of the RI with a dilution factor corresponding to the relative hydraulic resistance of the channels forming the RI. RIs are simple to integrate in lateral flow assays and provide a great degree of control over reagent integration and dissolution. Finally, the one-step capillary-driven microfluidic chips have the ability to not only detect a variety of proteins, but also to detect nucleic acids for molecular diagnostics. These devices, especially if manufactured in low cost plastic and used with portable fluorescence readers, have the potential to identify a wide variety of health conditions and to enable truly decentralized medical diagnostics.

EPFL2011