13 research outputs found
Kaplan–Meier analysis of DFS and OS as a function of TET3 and TDG expression.
<p>The levels of TET3 and TDG mRNAs correlated inversely with DFS in patients treated with anthracyclines. Higher levels of TET3 and TDG mRNAs correlated with better DFS (P = 0.026 and 0.030, respectively).</p
Kaplan–Meier analysis of DFS and OS as a function of TET1 mRNA levels.
<p>A. The DFS and OS of all patients were 0.521 and 0.745, respectively. B. Correlation between TET1-3 and TDG mRNAs with DFS and OS in 162 EBC patients. Higher level of TET1 mRNA was related to better OS (P = 0.022) (log-rank test).</p
Clinicopathological characteristics of patients.
<p>Clinicopathological characteristics of patients.</p
Additional file 1: Table S1. of MicroRNA-200a confers chemoresistance by antagonizing TP53INP1 and YAP1 in human breast cancer
List of primer and siRNA sequences. Table S2: Intersection between predict target of miR-200a and p53 family binding partner. (DOCX 17 kb
Additional file 2: Fig. S1. of MicroRNA-200a confers chemoresistance by antagonizing TP53INP1 and YAP1 in human breast cancer
Expression of p73 in MDA-MB-231 and MDA-MB-231 GR cells. (EPS 588 kb
Additional file 1: of Effectiveness and safety of ShenXiong glucose injection for acute ischemic stroke: a systematic review and GRADE approach
The PRISMA checklist. (DOC 62 kb
Bamboo-Inspired, Environmental Friendly PDMS/Plant Fiber Composites-Based Capacitive Flexible Pressure Sensors by Origami for Human–Machine Interaction
With
the widespread adoption of green and sustainable
development
concepts, enhancing the sensing performance of flexible pressure sensors
while reducing manufacturing costs and environmental pollution has
emerged as a pressing research issue. Drawing inspiration from bamboo,
a naturally occurring green plant, we utilized virgin bamboo pulp
as the raw material for producing draw paper. The resulting bamboo
cylinder structure serves as the dielectric layer. We propose an extremely
low-cost, user-friendly, and sustainable origami method for fabricating
paper-based sensors. The structural parameters of the sensor were
thoroughly investigated and optimized through finite element simulations
and practical experiments. Notable features of the sensor include
high sensitivity (1.96 kPa–1 within 0–50
kPa), a low detection limit (2 Pa), a wide pressure detection range
(0–500 kPa), rapid response and recovery times (40 and 45 ms,
respectively), and reliable durability and stability (∼5000
cycles). Experimental results demonstrate the successful application
of these sensors in areas such as human motion, health monitoring,
and human–computer interaction. The potential applications
of sensors extend to flexible wearables, smart healthcare, human–machine
collaboration, and electronic skin (e-skin)
Flexible Capacitive Pressure Sensor with High Sensitivity and Wide Range Based on a Cheetah Leg Structure via 3D Printing
Flexible pressure sensors can be used in human–computer
interaction and wearable electronic devices, but one main challenge
is to fabricate capacitive sensors with a wide pressure range and
high sensitivity. Here, we designed a capacitive pressure sensor based
on a bionic cheetah leg microstructure, validated the benefits of
the bionic microstructure design, and optimized the structural feature
parameters using 3D printing technology. The pressure sensor inspired
by the cheetah leg shape has a high sensitivity (0.75 kPa–1), a wide linear sensing range (0–280 kPa), a fast response
time of roughly 80 ms, and outstanding durability (24,000 cycles).
Furthermore, the sensor can recognize a finger-operated mouse, monitor
human motion, and transmit Morse code information. This work demonstrates
that bionic capacitive pressure sensors hold considerable promise
for use in wearable devices