Biomedical Engineering Reference
In-Depth Information
70. G.H. Altman,
et al
., Silk-based biomaterials.
Biomaterials
, 24(3): p. 401-416,
2003.
71. X. Kong,
et al
., Silk fi broin regulated mineralization of hydroxyapatite nano-
crystals.
Journal of Crystal Growth
, 270(1): p. 197-202, 2004.
72. X. Kong,
et al
., Effect of solute concentration on fi broin regulated biomin-
eralization of calcium phosphate.
Materials Science and Engineering: C
, 26(4):
p. 639-643, 2006.
73. G.M. Whitesides and B. Grzybowski, Self-assembly at all scales.
Science
,
295(5564): p. 2418-2421, 2002.
74. S.I. Stupp,
et al
., Supramolecular materials: Self-organized nanostructures.
Science
, 276(5311): p. 384-389, 1997.
75. E.R. Zubarev,
et al
., Conversion of supramolecular clusters to macromolecu-
lar objects.
Science
, 283(5401): p. 523-526, 1999.
76. S. Zhang, Fabrication of novel biomaterials through molecular self-assembly.
Nature Biotechnology
, 21(10): p. 1171-1178, 2003.
77. M. Fändrich, M.A. Fletcher, and C.M. Dobson, Amyloid fi brils from muscle
myoglobin.
Nature
, 410(6825): p. 165-166, 2001.
78. U.A. Stock and J.P. Vacanti, Tissue engineering: Current state and prospects.
Annual Review of Medicine
, 52(1): p. 443-451, 2001.
79. R. Langer and J. Vacanti,
Tissue Eng. Sci.
, 260: 920-926, 1993.
80. H. Schliephake, C. Kröly, and H. Wüstenfeld, Experimental study by fl uo-
rescence microscopy and microangiography of remodeling and regeneration
of bone inside alloplastic contour augmentations.
International Journal of Oral
and Maxillofacial Surgery
, 23(5): p. 300-305, 1994.
81. D. Tancred, B. McCormack, and A. Carr, A synthetic bone implant macro-
scopically identical to cancellous bone.
Biomaterials
, 19(24): p. 2303-2311,
1998.
82. M. Kikuchi,
et al
., Self-organization mechanism in a bone-like hydroxyapa-
tite/collagen nanocomposite synthesized
in vitro
and its biological reaction
in vivo
.
Biomaterials
, 22(13): p. 1705-1711, 2001.
83. M.C. Chang,
et al
., Preparation of a porous hydroxyapatite/collagen nano-
composite using glutaraldehyde as a crosslinkage agent.
Journal of Materials
Science Letters
, 20(13): p. 1199-1201, 2001.
84. C. Du,
et al
., Formation of calcium phosphate/collagen composites through
mineralization of collagen matrix.
Journal of Biomedical Materials Research
,
50(4): p. 518-527, 2000.
85. S. Liao, F. Cui, and Y. Zhu, Osteoblasts adherence and migration through
three-dimensional porous mineralized collagen based composite: nHAC/
PLA.
Journal of Bioactive and Compatible Polymers
, 19(2): p. 117-130, 2004.
86.
S. Liao,
et al
., Hierarchically biomimetic bone scaffold materials: Nano-HA/
collagen/PLA composite.
Journal of Biomedical Materials Research Part B:
Applied Biomaterials
, 69(2): p. 158-165, 2004.
87.
X. Liu,
et al
., Osteogenesis of mineralized collagen bone graft modifi ed by
PLA and calcium sulfate hemihydrate:
In vivo
study.
Journal of Biomaterials
Applications
, 2012.
88.
M. Vlad,
et al
., Biphasic calcium sulfate dihydrate/iron-modifi ed alpha-
tricalcium phosphate bone cement for spinal applications:
In vitro
study.
Biomedical Materials
, 5(2): p. 025006, 2010.
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