Skip to search form
Skip to main content
Skip to account menu
Semantic Scholar
Semantic Scholar's Logo
Search 228,397,761 papers from all fields of science
Search
Sign In
Create Free Account
Tissue Engineering
Known as:
tissue engineer
, Engineering, Tissue
, engineered tissue
Expand
Generating tissue in vitro for clinical applications, such as replacing wounded tissues or impaired organs. The use of TISSUE SCAFFOLDING enables the…
Expand
National Institutes of Health
Create Alert
Alert
Related topics
Related topics
19 relations
Artificial skin
Bioartificial Organs
Bioprosthesis device
Bioprosthesis procedure
Expand
Broader (1)
biomedical engineering field
Papers overview
Semantic Scholar uses AI to extract papers important to this topic.
Highly Cited
2016
Highly Cited
2016
Curdlan in fibers as carriers of tetracycline hydrochloride: Controlled release and antibacterial activity.
M. El-Naggar
,
A. Abdelgawad
,
Carlos Salas
,
O. Rojas
Carbohydrate Polymers
2016
Corpus ID: 5914054
Highly Cited
2011
Highly Cited
2011
The structural and biological properties of hydroxyapatite-modified titanate nanowire scaffolds.
Haixin Zhao
,
W. Dong
,
+7 authors
Zhan Shi
Biomaterials
2011
Corpus ID: 19064920
Highly Cited
2010
Highly Cited
2010
Self assembled bi-functional peptide hydrogels with biomineralization-directing peptides.
M. Gungormus
,
M. Branco
,
H. Fong
,
J. Schneider
,
C. Tamerler
,
M. Sarikaya
Biomaterials
2010
Corpus ID: 206025666
Review
2008
Review
2008
Engineering the microcirculation.
Z. Lokmic
,
G. Mitchell
Tissue engineering. Part B, Reviews
2008
Corpus ID: 21389529
The ultimate survival of tissue-engineered constructs in vivo depends on the provision of an adequate blood supply to the…
Expand
Highly Cited
2007
Highly Cited
2007
Linear and Hyperbranched Glycopolymer-Functionalized Carbon Nanotubes: Synthesis, Kinetics, and Characterization
Chao Gao
,
Sharmila Muthukrishnan
,
Wenwen Li
,
Jiayin Yuan
,
Youyong Xu
,
A. Müller
2007
Corpus ID: 96560205
Linear and hyperbranched glycopolymers, a kind of sugar-containing polymers, were grown successfully from surfaces of multiwalled…
Expand
Highly Cited
2007
Highly Cited
2007
A route to three-dimensional structures in a microfluidic device: stop-flow interference lithography.
Ji‐Hyun Jang
,
D. Dendukuri
,
T. Hatton
,
E. Thomas
,
P. Doyle
Angewandte Chemie
2007
Corpus ID: 9378514
hasemergedasanattractivealternativetechniquethatallowstherationaldesignofcomplexanddefect-free1D,2D,and3Dpatternsoverlargeareas…
Expand
Highly Cited
2006
Highly Cited
2006
Polymer hollow fiber three-dimensional matrices with controllable cavity and shell thickness.
L. Moroni
,
Roka Schotel
,
J. Sohier
,
J. D. de Wijn
,
C. V. van Blitterswijk
Biomaterials
2006
Corpus ID: 37597956
Review
2003
Review
2003
Progress in adipose tissue construct development.
E. Beahm
,
R. Walton
,
C. Patrick
Clinics in Plastic Surgery
2003
Corpus ID: 37158912
Highly Cited
2001
Highly Cited
2001
Selective Interaction Between Proteins and the Outermost Surface of Polyelectrolyte Multilayers: Influence of the Polyanion Type, pH and Salt
M. Müller
,
T. Rieser
,
P. Dubin
,
K. Lunkwitz
2001
Corpus ID: 38728935
Protein adsorption was studied by in-situ ATR-FT-IR spectroscopy of consecutively deposited polyelectrolyte multilayer systems…
Expand
Highly Cited
2001
Highly Cited
2001
Optimal cell source for cardiovascular tissue engineering: venous vs. aortic human myofibroblasts.
A. Schnell
,
S. Hoerstrup
,
+6 authors
Marko I. Turina
The thoracic and cardiovascular surgeon
2001
Corpus ID: 22142674
Arterial vascular cells have been successfully utilized for tissue engineering in human cardiovascular structures, such as heart…
Expand
By clicking accept or continuing to use the site, you agree to the terms outlined in our
Privacy Policy
(opens in a new tab)
,
Terms of Service
(opens in a new tab)
, and
Dataset License
(opens in a new tab)
ACCEPT & CONTINUE