4 research outputs found
Strategies of immobilizing BMP-2 with 3D-printed scaffolds to improve osteogenesis. Supplementary tables
Supplementary tables 1-3</p
Full Spectrum Visible LED Light Activated Antibacterial System Realized by Optimized Cu<sub>2</sub>O Crystals
Assisted
by three-dimensional printing technology, we proposed and demonstrated
a full spectrum visible light activated antibacterial system by using
a combination of 500 nm sized Cu<sub>2</sub>O crystals and light-emitting
diode (LED) lamps. Further improved antibacterial ratios were achieved,
for the first time, with pure Cu<sub>2</sub>O for both Gram-positive
bacteria and Gram-negative bacteria among all of the six different
color LED lamps. For practical antibacterial applications,
we revealed that the nonwoven fabric could act as excellent carrier
for Cu<sub>2</sub>O crystals and provide impressive antibacterial
performance. Furthermore, integrated with our self-developed app,
the polyÂ(ethylene terephthalate) film loaded with Cu<sub>2</sub>O
crystals also showed significant antibacterial property, thus making
it possible to be applied in field of touch screen. The present research
not only provided a healthier alternative to traditional ultraviolet-based
sterilization but also opened an auto-response manner to decrease
the rate of microbial contamination on billions of touch screen devices
The “Pure Marriage” between 3D Printing and Well-Ordered Nanoarrays by Using PEALD Assisted Hydrothermal Surface Engineering
For the first time, homogeneous and
well-ordered functional nanoarrays were grown densely on the complex
structured three-dimensional (3D) printing frameworks through a general
plasma enhanced atomic layer deposition (PEALD) assisted hydrothermal
surface engineering process. The entire process was free from toxic
additives or harmful residues and, therefore, can meet the critical
requirements of high-purity products. As a practical example, 3D customized
earplugs were precisely manufactured according to the model of ear
canals at the 0.1 mm level. Meanwhile, well-ordered ZnO nanoarrays,
formed on the surfaces of these 3D printed earplugs, could effectively
prevent the growth of five main pathogens derived from the patients
with otitis media and exhibited excellent wear resistance as well.
On the basis of both animal experiments and volunteers’ investigations,
the 3D customized earplugs showed sound insulation capabilities superior
to those of traditional earplugs. Further animal experiments demonstrated
the potential of as-modified implant scaffolds in practical clinical
applications. This work, exemplified with earplugs and implant scaffolds,
oriented the development direction of 3D printing in biomedical devices,
which precisely integrated customized architecture and tailored surface
performance
The “Pure Marriage” between 3D Printing and Well-Ordered Nanoarrays by Using PEALD Assisted Hydrothermal Surface Engineering
For the first time, homogeneous and
well-ordered functional nanoarrays were grown densely on the complex
structured three-dimensional (3D) printing frameworks through a general
plasma enhanced atomic layer deposition (PEALD) assisted hydrothermal
surface engineering process. The entire process was free from toxic
additives or harmful residues and, therefore, can meet the critical
requirements of high-purity products. As a practical example, 3D customized
earplugs were precisely manufactured according to the model of ear
canals at the 0.1 mm level. Meanwhile, well-ordered ZnO nanoarrays,
formed on the surfaces of these 3D printed earplugs, could effectively
prevent the growth of five main pathogens derived from the patients
with otitis media and exhibited excellent wear resistance as well.
On the basis of both animal experiments and volunteers’ investigations,
the 3D customized earplugs showed sound insulation capabilities superior
to those of traditional earplugs. Further animal experiments demonstrated
the potential of as-modified implant scaffolds in practical clinical
applications. This work, exemplified with earplugs and implant scaffolds,
oriented the development direction of 3D printing in biomedical devices,
which precisely integrated customized architecture and tailored surface
performance