3 research outputs found
Reduced Graphene Oxide-Based Solid-Phase Extraction for the Enrichment and Detection of microRNA
MicroRNAs
(miRNAs) are endogenous molecules with regulatory functions.
The purification and enrichment of miRNA are essential for its precise
and sensitive detection. miRNA isolated using commercial kits contains
abundant interfering RNAs, and the concentration of miRNA may not
be adequate for detection. Herein, we prepared a reduced graphene
oxide (rGO)-based magnetic solid-phase extraction material for the
enrichment and ultrasensitive detection of miRNA from intricate nucleic
acid solutions. <i>In situ</i> reverse transcription (RT)
was developed as the most efficient approach to desorb miRNA from
rGO among the methods that are compatible for the subsequent amplification
reported thus far. Additionally, rolling circle amplification and
qPCR were used to detect let-7a with a decrease of the limit of detection
by 24.7- and 31.3-fold, respectively. This material was also successfully
used to extract and detect miRNA from total RNA isolated from human
plasma. Our results show that the material prepared in this study
has the potential for cancer biopsy in clinics and the discovery of
new miRNAs in scientific research
Comprehensive Study of the Flow Control Strategy in a Wirelessly Charged Centrifugal Microfluidic Platform with Two Rotation Axes
Centrifugal microfluidics
has been widely applied in the sample-in–answer-out
systems for the analyses of nucleic acids, proteins, and small molecules.
However, the inherent characteristic of unidirectional fluid propulsion
limits the flexibility of these fluidic chips. Providing an extra
degree of freedom to allow the unconstrained and reversible pumping
of liquid is an effective strategy to address this limitation. In
this study, a wirelessly charged centrifugal microfluidic platform
with two rotation axes has been constructed and the flow control strategy
in such platform with two degrees of freedom was comprehensively studied
for the first time. Inductively coupled coils are installed on the
platform to achieve wireless power transfer to the spinning stage.
A micro servo motor is mounted on both sides of the stage to alter
the orientation of the device around a secondary rotation axis on
demand during stage rotation. The basic liquid operations on this
platform, including directional transport of liquid, valving, metering,
and mixing, are comprehensively studied and realized. Finally, a chip
for the simultaneous determination of hexavalent chromium [CrÂ(VI)]
and methanal in water samples is designed and tested based on the
strategy presented in this paper, demonstrating the potential use
of this platform for on-site environmental monitoring, food safety
testing, and other life science applications
Comprehensive Study of the Flow Control Strategy in a Wirelessly Charged Centrifugal Microfluidic Platform with Two Rotation Axes
Centrifugal microfluidics
has been widely applied in the sample-in–answer-out
systems for the analyses of nucleic acids, proteins, and small molecules.
However, the inherent characteristic of unidirectional fluid propulsion
limits the flexibility of these fluidic chips. Providing an extra
degree of freedom to allow the unconstrained and reversible pumping
of liquid is an effective strategy to address this limitation. In
this study, a wirelessly charged centrifugal microfluidic platform
with two rotation axes has been constructed and the flow control strategy
in such platform with two degrees of freedom was comprehensively studied
for the first time. Inductively coupled coils are installed on the
platform to achieve wireless power transfer to the spinning stage.
A micro servo motor is mounted on both sides of the stage to alter
the orientation of the device around a secondary rotation axis on
demand during stage rotation. The basic liquid operations on this
platform, including directional transport of liquid, valving, metering,
and mixing, are comprehensively studied and realized. Finally, a chip
for the simultaneous determination of hexavalent chromium [CrÂ(VI)]
and methanal in water samples is designed and tested based on the
strategy presented in this paper, demonstrating the potential use
of this platform for on-site environmental monitoring, food safety
testing, and other life science applications