Biomedical Engineering Reference
In-Depth Information
62. Kroes-Nijboer, A., Venema, P., Linden, E.V.D.: Fibrillar structures in food. Food Funct.
3
,
221-227 (2012). doi:
10.1039/c1fo10163c
63. Lee, K., Mooney, D.: Hydrogels for tissue engineering. Chem. Rev.
101
, 1869-1879 (2001).
doi:
10.1021/cr000108x
64. Bowerman, C.J., Nilsson, B.L.: Review self-assembly of amphipathic
ʲ
-sheet peptides:
Insights and applications. Pept. Sci.
98
, 169-184 (2012). doi:
10.1002/bip.22058
65. Cheng, R.P., Gellman, S.H., DeGrado, W.F.:
ʲ
-Peptides: from structure to function. Chem.
Rev.
101
, 3219-3232 (2001)
66. Totosaus, A., Montejano, J.G., Salazar, J.A., Guerrero, I.: A review of physical
and chemical protein-gel induction. Int. J. Food Sci. Technol.
37
, 589-601 (2002).
67. Hauser, C.A., Zhang, S.: Designer self-assembling peptide nanofiber biological materials.
Chem. Soc. Rev.
39
, 2780-2790 (2010). doi:
10.1039/b921448h
68. Li, Y., Rodrigues, J., Tom£s, H.: Injectable and biodegradable hydrogels: gelation, biodeg-
radation and biomedical applications. Chem. Soc. Rev.
41
, 2193-2221 (2012). doi:
10.1039/
69. Heilshorn, S.C., Liu, J.C., Tirrell, D.A.: Cell-binding domain context affects cell behavior
on engineered proteins. Biomacromolecules
6
, 318-323 (2005). doi:
10.1021/bm049627q
70. Ngo, J.T., Tirrell, D.A.: Noncanonical amino acids in the interrogation of cellular protein
synthesis. Acc. Chem. Res.
44
, 677-685 (2011). doi:
10.1021/ar200144y
71. Gauthier, M.A., Klok, H.-A.: Peptide/protein-polymer conjugates: synthetic strategies and
design concepts. Chem. Commun. 2591-2611 (2008). doi:
10.1039/b719689j
72. Yan, C., Altunbas, A., Yucel, T., et al.: Injectable solid hydrogel: mechanism of shear-
thinning and immediate recovery of injectable
ʲ
-hairpin peptide hydrogels. Soft Matter
6
,
5143-5156 (2010). doi
:
10.1039/c0sm00642d
73. Haines-Butterick, L., Rajagopal, K., Branco, M., et al.: Controlling hydrogelation kinetics
by peptide design for three-dimensional encapsulation and injectable delivery of cells. Proc.
Natl. Acad. Sci. U.S.A.
104
, 7791-7796 (2007). doi:
10.1073/pnas.0701980104
74. Moss, J.A.: Unit 18.7: Guide for resin and linker selection in solid
‐
phase peptide synthesis.
Curr. Protoc. Prot. Sci. 1-19 (2005)
75. Barany, G., Albericio, F.: Three-dimensional orthogonal protection scheme for solid-phase
peptide synthesis under mild conditions. J. Am. Chem. Soc.
107
, 4936-4942 (1985)
76. Naik, R.R., Stringer, S.J., Agarwal, G., et al.: Biomimetic synthesis and patterning of silver
nanoparticles. Nat. Mater.
1
, 169-172 (2002). doi:
10.1038/nmat758
77. Akdim, B., Pachter, R., Kim, S.S., et al.: Electronic properties of a graphene device with
peptide adsorption: insight from simulation. ACS Appl. Mater. Interfaces
5
, 7470-7477
(2013). doi:
10.1021/am401731c
78. Dickerson, M.B., Sandhage, K.H., Naik, R.R.: Protein- and peptide-directed syntheses of
inorganic materials. Chem. Rev.
108
, 4935-4978 (2008)
79. Helen, W., de Leonardis, P., Ulijn, R.V., et al.: Mechanosensitive peptide gelation: mode of
agitation controls mechanical properties and nano-scale morphology. Soft Matter
7
, 1732
(2011). doi:
10.1039/c0sm00649a
80. Morris, K.L., Chen, L., Raeburn, J., et al.: Chemically programmed self-sorting of gelator
networks. Nat. Commun.
4
, 1480 (2013)
81. Ramachandran, S., Taraban, M.B., Trewhella, J., et al.: Effect of temperature dur-
ing assembly on the structure and mechanical properties of peptide-based materials.
Biomacromolecules
11
, 1502-1506 (2010). doi:
10.1021/bm100138m
82. Feng, Y., Taraban, M., Yu, Y.B.: The effect of ionic strength on the mechanical, struc-
tural and transport properties of peptide hydrogels. Soft Matter
8
, 11723-11731 (2012).
doi:
10.1039/c2sm26572a
83. Kim, C.A., Berg, J.M.: Thermodynamic
ʲ
-sheet propensities measured using a zinc-finger
host peptide. Nature
362
, 267-270 (1993). doi:
10.1038/362267a0
84. Jung, J.P., Gasiorowski, J.Z., Collier, J.H.: Fibrillar peptide gels in biotechnology and bio-
medicine. Biopolymers
94
, 49-59 (2010). doi:
10.1002/bip.21326
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