27 research outputs found
Engineering 1‑Alkene Biosynthesis and Secretion by Dynamic Regulation in Yeast
Microbial
production of fatty acid-derived hydrocarbons offers
a great opportunity to sustainably supply biofuels and oleochemicals.
One challenge is to achieve a high production rate. Besides, low efficiency
in secretion will cause high separation costs, and it is therefore
desirable to have product secretion. Here, we engineered the budding
yeast <i>Saccharomyces cerevisiae</i> to produce and secrete
1-alkenes by manipulation of the fatty acid metabolism, enzyme selection,
engineering the electron transfer system and expressing a transporter.
Furthermore, we implemented a dynamic regulation strategy to control
the expression of membrane enzyme and transporter, which improved
1-alkene production and cell growth by relieving the possible toxicity
of overexpressed membrane proteins. With these efforts, the engineered
yeast cell factory produced 35.3 mg/L 1-alkenes with more than 80%
being secreted. This represents a 10-fold improvement compared with
earlier reported hydrocarbon production by <i>S. cerevisiae</i>
Direct Detection of DNA below ppb Level Based on Thionin-Functionalized Layered MoS<sub>2</sub> Electrochemical Sensors
A layered
MoS<sub>2</sub>–thionin composite was prepared
by sonicating their mixture in an ionic liquid and gradient centrifugation.
Because DNA is rarely present in single-stranded form, either naturally
or after PCR amplification, the composite was used for fabrication
of a double-stranded DNA (dsDNA) electrochemical biosensor due to
stable electrochemical response, intercalation, and electrostatic
interaction of thionin with DNA. The linear range over dsDNA concentration
from 0.09 ng mL<sup>–1</sup> to 1.9 ng mL<sup>–1</sup> is obtained, and moreover, it is suitable for the detection of single-stranded
DNA (ssDNA). The biosensor has been applied to the detection of circulating
DNA from healthy human serum, and satisfactory results have been obtained.
The constructed DNA electrochemical biosensor shows potential application
in the fields of bioanalysis and clinic diagnosis. Furthermore, this
work proposes a new method to construct electrochemical biosensors
based on MoS<sub>2</sub> sheets
Determination of Apparent Amylose Content in Rice by Using Paper-Based Microfluidic Chips
Determination
of apparent amylose content in rice is a key function
for rice research and the rice industry. In this paper, a novel approach
with paper-based microfluidic chip is reported to determine apparent
amylose content in rice. The conventional color reaction between amylose
and iodine was employed. Blue color of amylose–iodine complex
generated on-chip was converted to gray and measured with Photoshop
after the colored chip was scanned. The method for preparation of
the paper chip is described. In situ generation of iodine for on-chip
color reaction was designed, and factors influencing color reaction
were investigated in detail. Elimination of yellow color interference
of excess iodine by exploiting color removal function of Photoshop
was presented. Under the optimized conditions, apparent amylose content
in rice ranging from 1.5 to 26.4% can be determined, and precision
was 6.3%. The analytical results obtained with the developed approach
were in good agreement with those with the continuous flow analyzer
method
Combined Effects of Radiative and Evaporative Cooling on Fruit Preservation under Solar Radiation: Sunburn Resistance and Temperature Stabilization
Excessive solar radiation
and high temperature often cause considerable
loss and waste of fruits during transportation, retail, and storage.
In the current study, a natural deep eutectic solvent-based polyacrylamide/poly(vinyl
alcohol) hydrogel with nanoparticles (NPs/NADES@PAAm/PVA) is developed
for fruit quality protection from solar radiation and high-temperature
stress by achieving the combined effect of radiative and evaporative
cooling. NPs/NADES@PAAm/PVA presents an average solar reflectance
of ∼0.89 and an average emittance at the atmospheric window
of ∼0.90. Besides, NPs/NADES@PAAm/PVA possesses excellent flexibility,
robust mechanical strength, and good swelling behavior. The fruit
preservation experiments under sunlight demonstrate that the pear
(Pyrus sinkiangensis) treated with
NPs/NADES@PAAm/PVA can achieve an average temperature decrease of
∼15.3 °C after sun exposure compared with the blank, and
its quality-related attributes, including color, total soluble solid,
relative conductivity, and respiration rate, are similar to the fresh
one. Multivariate data analyses, including principal component analysis
and cluster analysis, further verify that the pear treated with NPs/NADES@PAAm/PVA
possesses similar quality to the fresh one after sun exposure. Thus,
NPs/NADES@PAAm/PVA has promising prospects for fruit transportation,
retail, and storage under solar radiation in a low-operation-cost
and sustainable manner
Biomimetic Microadhesion Guided Instant Spinning
Animals create high-performance fibers at natural ambient
conditions
via a unique spinning process. In contrast, the spinning technologies
developed by human beings are usually clumsy and require sophisticated
skills. Here, inspired by adhesion-based silkworm spinning, we report
a microadhesion guided (MAG) spinning technology for instant and on-demand
fabrication of micro/nanofibers. Enabled by the adhesion between the
spinning fluids and the microneedles, the MAG spinning can generate
micro/nanofibers with programmable morphology. By further mimicking
the head movement of the silkworm spinning, the MAG technology is
extended with three different modes: straight, vibratory, and twisted
spinning, which generate oriented fibers, hierarchical cross-linked
fibers, and all-in-one fibers, respectively. Due to the prevalence
of microadhesion and its unprecedented flexibility in operation, equipment-free
MAG spinning is finally realized for instant fiber fabrication by
only polymeric foams. Finally, the MAG spinning is demonstrated as
a promising instant technology for emergent applications, such as
wound dressing
Biomimetic Microadhesion Guided Instant Spinning
Animals create high-performance fibers at natural ambient
conditions
via a unique spinning process. In contrast, the spinning technologies
developed by human beings are usually clumsy and require sophisticated
skills. Here, inspired by adhesion-based silkworm spinning, we report
a microadhesion guided (MAG) spinning technology for instant and on-demand
fabrication of micro/nanofibers. Enabled by the adhesion between the
spinning fluids and the microneedles, the MAG spinning can generate
micro/nanofibers with programmable morphology. By further mimicking
the head movement of the silkworm spinning, the MAG technology is
extended with three different modes: straight, vibratory, and twisted
spinning, which generate oriented fibers, hierarchical cross-linked
fibers, and all-in-one fibers, respectively. Due to the prevalence
of microadhesion and its unprecedented flexibility in operation, equipment-free
MAG spinning is finally realized for instant fiber fabrication by
only polymeric foams. Finally, the MAG spinning is demonstrated as
a promising instant technology for emergent applications, such as
wound dressing
Biomimetic Microadhesion Guided Instant Spinning
Animals create high-performance fibers at natural ambient
conditions
via a unique spinning process. In contrast, the spinning technologies
developed by human beings are usually clumsy and require sophisticated
skills. Here, inspired by adhesion-based silkworm spinning, we report
a microadhesion guided (MAG) spinning technology for instant and on-demand
fabrication of micro/nanofibers. Enabled by the adhesion between the
spinning fluids and the microneedles, the MAG spinning can generate
micro/nanofibers with programmable morphology. By further mimicking
the head movement of the silkworm spinning, the MAG technology is
extended with three different modes: straight, vibratory, and twisted
spinning, which generate oriented fibers, hierarchical cross-linked
fibers, and all-in-one fibers, respectively. Due to the prevalence
of microadhesion and its unprecedented flexibility in operation, equipment-free
MAG spinning is finally realized for instant fiber fabrication by
only polymeric foams. Finally, the MAG spinning is demonstrated as
a promising instant technology for emergent applications, such as
wound dressing
Biomimetic Microadhesion Guided Instant Spinning
Animals create high-performance fibers at natural ambient
conditions
via a unique spinning process. In contrast, the spinning technologies
developed by human beings are usually clumsy and require sophisticated
skills. Here, inspired by adhesion-based silkworm spinning, we report
a microadhesion guided (MAG) spinning technology for instant and on-demand
fabrication of micro/nanofibers. Enabled by the adhesion between the
spinning fluids and the microneedles, the MAG spinning can generate
micro/nanofibers with programmable morphology. By further mimicking
the head movement of the silkworm spinning, the MAG technology is
extended with three different modes: straight, vibratory, and twisted
spinning, which generate oriented fibers, hierarchical cross-linked
fibers, and all-in-one fibers, respectively. Due to the prevalence
of microadhesion and its unprecedented flexibility in operation, equipment-free
MAG spinning is finally realized for instant fiber fabrication by
only polymeric foams. Finally, the MAG spinning is demonstrated as
a promising instant technology for emergent applications, such as
wound dressing
Biomimetic Microadhesion Guided Instant Spinning
Animals create high-performance fibers at natural ambient
conditions
via a unique spinning process. In contrast, the spinning technologies
developed by human beings are usually clumsy and require sophisticated
skills. Here, inspired by adhesion-based silkworm spinning, we report
a microadhesion guided (MAG) spinning technology for instant and on-demand
fabrication of micro/nanofibers. Enabled by the adhesion between the
spinning fluids and the microneedles, the MAG spinning can generate
micro/nanofibers with programmable morphology. By further mimicking
the head movement of the silkworm spinning, the MAG technology is
extended with three different modes: straight, vibratory, and twisted
spinning, which generate oriented fibers, hierarchical cross-linked
fibers, and all-in-one fibers, respectively. Due to the prevalence
of microadhesion and its unprecedented flexibility in operation, equipment-free
MAG spinning is finally realized for instant fiber fabrication by
only polymeric foams. Finally, the MAG spinning is demonstrated as
a promising instant technology for emergent applications, such as
wound dressing
Biomimetic Microadhesion Guided Instant Spinning
Animals create high-performance fibers at natural ambient
conditions
via a unique spinning process. In contrast, the spinning technologies
developed by human beings are usually clumsy and require sophisticated
skills. Here, inspired by adhesion-based silkworm spinning, we report
a microadhesion guided (MAG) spinning technology for instant and on-demand
fabrication of micro/nanofibers. Enabled by the adhesion between the
spinning fluids and the microneedles, the MAG spinning can generate
micro/nanofibers with programmable morphology. By further mimicking
the head movement of the silkworm spinning, the MAG technology is
extended with three different modes: straight, vibratory, and twisted
spinning, which generate oriented fibers, hierarchical cross-linked
fibers, and all-in-one fibers, respectively. Due to the prevalence
of microadhesion and its unprecedented flexibility in operation, equipment-free
MAG spinning is finally realized for instant fiber fabrication by
only polymeric foams. Finally, the MAG spinning is demonstrated as
a promising instant technology for emergent applications, such as
wound dressing