... Enzymatic formation of modular cell-instructive fibrin analogs for tissue
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Halstenberg, S. ... of polymer (hydrogel) in the medium.
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Anseth and Bowman 2001) The authors investigated two divinyl crosslinki...
... tissue
interactions due to their mobility and solubility in body chemicals. Therefore, polymers that
518
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Biomedical Engineering, Trends in Materials ... Biofilm Associated Infections and
Degradation of Polymeric Materials used in Biomedical Applications
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...
Australia
free online editions of InTech
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Part 1
Materials in Biomedical Engineering
Biomedical Engineering, Trends in Materials Science
4 ... work involving materials science in biomedical engi-
neering, including developments in metallic biomaterials, nanomaterials, polymers
and other material techn...
... self-hardening paste. Biomaterials, 13, 759–763, pISSN 0142-9 612
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Fig. 17. A dental implant in a jaw bone
Fig. 18. Slicing an STL ... areas
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Z
Y
X
slicing
STL Acetabular cup model
A contour-based model
A feature layer
Fig. 11. Slicin...
... characterize
these modes individually to learn the differences in plasma conditions between the modes
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024681 0121 4
Dissolution time / ... hydroxylalkyl radicals on their reactivities in
crystalline state. J. Am. Chem. Soc., 114(16) 6505-6 512
Biomedical Engineering, Trends in Materials Science
1...
... plasma sintered Ti, Mn and TiMn alloys showing the TiMn
alloys are α+β phase alloy (a) and SEM micrograph of the fracture surface of a Ti8Mn alloy.
Biomedical Engineering, Trends in Materials Science ... sintered pure Ti at different temperatures and the TiMn alloys
with various Mn amounts were also investigated. With a temperature increase from 550°C
Biomedical Engineer...
... vitro
μ
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−
·
−
5nm
k
T
k
(a)
(b)
μ
s
7. In vivo Tests and clinical trials
in vivo
8. Concluding remarks
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the glass matrix for the samples after annealing at 693 ... crystallization, results in the formation of nano-
particles of Ti
3
Cu
4
with sizes smaller that 5 nm in the glassy matrix.
Biomedical Engineer...
... Electrolytic etching can induce highly porous NiTi surfaces that
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[4] Stoeckel, "Nitinol Medical Devices and Implants," Min Invas Ther ... Lichtenberg, Principles of plasma discharges and materials
processing, 2nd ed. Newark, NJ: Wiley, 2005.
Biomedical Engineering, Trends in Materials Science...
... surface of these nanoparticles
can overwhelm, causing reduced photoluminescence.
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vivo biomedical applications, LSMO nanoparticles can also ...
Hybrid gadolinium oxide nanoparticles: multimodal contrast agent for in vivo
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surface area, and encap...
... nanoporous alumina surfaces. Journal of Biomedical Materials
Research Part A 80, 4, (955-964).
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of having a surface enriched in silica ... direction of the sample resulting
in half-pipe or hemispherical shapes in the substrate. Such etching is typical for wet etching.
Biomedical Engineering, Trends in...