-
4
-
-
0344628728
-
-
Knoll W., Yu F., Neumann T., Schiller S., and Naumann R. Phys Chem Chem Phys 5 (2003) 5169
-
(2003)
Phys Chem Chem Phys
, vol.5
, pp. 5169
-
-
Knoll, W.1
Yu, F.2
Neumann, T.3
Schiller, S.4
Naumann, R.5
-
5
-
-
0026878384
-
-
Bergstrom K., Holmberg K., Safranj A.S., Edgell A.S., Kozlowski A., Hovanes B.A., et al. J Biomed Mater Res 26 (1992) 779
-
(1992)
J Biomed Mater Res
, vol.26
, pp. 779
-
-
Bergstrom, K.1
Holmberg, K.2
Safranj, A.S.3
Edgell, A.S.4
Kozlowski, A.5
Hovanes, B.A.6
-
13
-
-
0033823286
-
-
Ferretti S., Paynter S., Russell D.A., Sapsford K.E., and Richardson D.J. TrAC 19 (2000) 530
-
(2000)
TrAC
, vol.19
, pp. 530
-
-
Ferretti, S.1
Paynter, S.2
Russell, D.A.3
Sapsford, K.E.4
Richardson, D.J.5
-
16
-
-
0031269226
-
-
Patel N., Davies M.C., Hartshorne M., Heaton R.J., Roberts C.J., Tendler S.J.B., et al. Langmuir 13 (1997) 6485
-
(1997)
Langmuir
, vol.13
, pp. 6485
-
-
Patel, N.1
Davies, M.C.2
Hartshorne, M.3
Heaton, R.J.4
Roberts, C.J.5
Tendler, S.J.B.6
-
17
-
-
33645503747
-
-
Li M., Cui T., Mills D.K., Lvov Y.M., and Mcshane M.J. J Nanosci Nanotech 5 (2005) 1809
-
(2005)
J Nanosci Nanotech
, vol.5
, pp. 1809
-
-
Li, M.1
Cui, T.2
Mills, D.K.3
Lvov, Y.M.4
Mcshane, M.J.5
-
20
-
-
0142023973
-
-
Zhang Z., Chen Q., Knoll W., Foerch R., Holcomb R., and Roitman D. Macromolecules 36 (2003) 7689
-
(2003)
Macromolecules
, vol.36
, pp. 7689
-
-
Zhang, Z.1
Chen, Q.2
Knoll, W.3
Foerch, R.4
Holcomb, R.5
Roitman, D.6
-
21
-
-
14644440789
-
-
Zhang Z., Knoll W., Foerch R., Holcomb R., and Roitman D. Macromolecules 38 (2005) 1271
-
(2005)
Macromolecules
, vol.38
, pp. 1271
-
-
Zhang, Z.1
Knoll, W.2
Foerch, R.3
Holcomb, R.4
Roitman, D.5
-
24
-
-
0345381783
-
-
Smith E.A., Erickson M.G., Ulijasz A.T., Weisblum B., and Corn R.M. Langmuir 19 (2003) 1486
-
(2003)
Langmuir
, vol.19
, pp. 1486
-
-
Smith, E.A.1
Erickson, M.G.2
Ulijasz, A.T.3
Weisblum, B.4
Corn, R.M.5
-
27
-
-
0037198241
-
-
Lahann J., Balcells M., Rodon T., Lee J., Choi I.S., Jensen K.F., et al. Langmuir 18 (2002) 3632
-
(2002)
Langmuir
, vol.18
, pp. 3632
-
-
Lahann, J.1
Balcells, M.2
Rodon, T.3
Lee, J.4
Choi, I.S.5
Jensen, K.F.6
-
29
-
-
0142106318
-
-
Jérôme C., Gabriel S., Voccia S., Detrembleur C., Ignatova M., Gouttebaron R., et al. Chem Commun (2003) 2500
-
(2003)
Chem Commun
, pp. 2500
-
-
Jérôme, C.1
Gabriel, S.2
Voccia, S.3
Detrembleur, C.4
Ignatova, M.5
Gouttebaron, R.6
-
30
-
-
33745503391
-
-
Wu D.P., Zhao B.X., Dai Z.P., Qin J.H., and Lin B.C. Lab On A Chip 6 (2006) 942
-
(2006)
Lab On A Chip
, vol.6
, pp. 942
-
-
Wu, D.P.1
Zhao, B.X.2
Dai, Z.P.3
Qin, J.H.4
Lin, B.C.5
-
31
-
-
3343010284
-
-
Cheng X., Wang Y., Hanein Y., Bohringer K.F., and Ratner B.D. J Biomed Mater Res A 70 (2004) 159
-
(2004)
J Biomed Mater Res A
, vol.70
, pp. 159
-
-
Cheng, X.1
Wang, Y.2
Hanein, Y.3
Bohringer, K.F.4
Ratner, B.D.5
-
32
-
-
18044399825
-
-
Kenausis G.L., Voros J., Elbert D.L., Huang N.P., Hofer R., Ruiz-Taylor L., et al. J Phys Chem B 104 (2000) 3298
-
(2000)
J Phys Chem B
, vol.104
, pp. 3298
-
-
Kenausis, G.L.1
Voros, J.2
Elbert, D.L.3
Huang, N.P.4
Hofer, R.5
Ruiz-Taylor, L.6
-
33
-
-
0038206532
-
-
Bearinger J.P., Terrettaz S., Michel R., Tirelli N., Vogel H., Textor M., et al. Nature Mater 2 (2003) 259
-
(2003)
Nature Mater
, vol.2
, pp. 259
-
-
Bearinger, J.P.1
Terrettaz, S.2
Michel, R.3
Tirelli, N.4
Vogel, H.5
Textor, M.6
-
34
-
-
29444461305
-
-
Feller L.M., Cerritelli S., Textor M., Hubbell J.A., and Tosatti S.G.P. Macromolecules 38 (2005) 10503
-
(2005)
Macromolecules
, vol.38
, pp. 10503
-
-
Feller, L.M.1
Cerritelli, S.2
Textor, M.3
Hubbell, J.A.4
Tosatti, S.G.P.5
-
37
-
-
3442884594
-
-
Benters R., Niemeyer C.M., Drutschmann D., Blohm D., and Wöhrle D. Nucleic Acid Res 30 e10 (2002) 1
-
(2002)
Nucleic Acid Res
, vol.30
, Issue.e10
, pp. 1
-
-
Benters, R.1
Niemeyer, C.M.2
Drutschmann, D.3
Blohm, D.4
Wöhrle, D.5
-
41
-
-
33846582603
-
-
Schönherr H., Degenhart G.H., Dordi B., Feng C.L., Rozkiewicz D.I., Shovsky A., et al. Adv Polym Sci 200 (2006) 169
-
(2006)
Adv Polym Sci
, vol.200
, pp. 169
-
-
Schönherr, H.1
Degenhart, G.H.2
Dordi, B.3
Feng, C.L.4
Rozkiewicz, D.I.5
Shovsky, A.6
-
43
-
-
16344387672
-
-
Groll J., Ademovic Z., Ameringer T., Klee D., and Möller M. Biomacromolecules 6 (2005) 956
-
(2005)
Biomacromolecules
, vol.6
, pp. 956
-
-
Groll, J.1
Ademovic, Z.2
Ameringer, T.3
Klee, D.4
Möller, M.5
-
44
-
-
24044464524
-
-
and references cited therein
-
Groll J., Fiedler J., Engelhard E., Ameringer T., Tugulu S., Klok H.A., et al. J Biomed Mater Res A 74 (2005) 607 and references cited therein
-
(2005)
J Biomed Mater Res A
, vol.74
, pp. 607
-
-
Groll, J.1
Fiedler, J.2
Engelhard, E.3
Ameringer, T.4
Tugulu, S.5
Klok, H.A.6
-
49
-
-
34249807651
-
-
note
-
For example, it was found that the distance between RGD [25] functionalized cell-adhesive dots on the nanometer scale may determine cell attachment and spreading on patterned surfaces. These effects have been attributed to the corresponding cellular responses to restricted integrin [26] clustering rather than insufficient number of ligand molecules in the cell-matrix interface [27].
-
-
-
-
50
-
-
0141867968
-
-
RGD (Arg-Gly-Asp) is a tripeptide recognition motif that is important in cellular adhesive properties. The tripeptide recognition sequence of arginine, glycine and aspartic acid is found in the binding domain of many extracellular matrix proteins. Interest in this sequence has increased due to its binding to specific receptors. The processes the binding controls include are hemostasis, cell proliferation, cellular transduction and tumorgenesis:
-
RGD (Arg-Gly-Asp) is a tripeptide recognition motif that is important in cellular adhesive properties. The tripeptide recognition sequence of arginine, glycine and aspartic acid is found in the binding domain of many extracellular matrix proteins. Interest in this sequence has increased due to its binding to specific receptors. The processes the binding controls include are hemostasis, cell proliferation, cellular transduction and tumorgenesis:. Muller A., Schuman F., Koksch M., and Sewald N. Lett Peptide Sci 4 (1997) 275
-
(1997)
Lett Peptide Sci
, vol.4
, pp. 275
-
-
Muller, A.1
Schuman, F.2
Koksch, M.3
Sewald, N.4
-
51
-
-
34249817308
-
-
note
-
Integrins are a large family of heterodimeric transmembrane glycoproteins that attach cells to extracellular matrix proteins of the basement membrane or to ligands on other cells. Integrins contain large (α) and small (β) subunits of sizes 120-170 kDa and 90-100 kDa, respectively.
-
-
-
-
53
-
-
4544362955
-
-
Niemeyer C.M., and Mirkin C.A. (Eds), Wiley-VCH
-
Spatz J.P. In: Niemeyer C.M., and Mirkin C.A. (Eds). Nanobiotechnology (2004), Wiley-VCH
-
(2004)
Nanobiotechnology
-
-
Spatz, J.P.1
-
56
-
-
0037117864
-
-
Michel R., Lussi J.W., Csucs G., Reviakine I., Danuser G., Ketterer B., et al. Langmuir 18 (2002) 3281
-
(2002)
Langmuir
, vol.18
, pp. 3281
-
-
Michel, R.1
Lussi, J.W.2
Csucs, G.3
Reviakine, I.4
Danuser, G.5
Ketterer, B.6
-
58
-
-
4544329399
-
-
Lussi J.W., Michel R., Reviakine I., Falconnet D., Goessl A., Csucs G., et al. Prog Surf Sci 76 (2004) 55
-
(2004)
Prog Surf Sci
, vol.76
, pp. 55
-
-
Lussi, J.W.1
Michel, R.2
Reviakine, I.3
Falconnet, D.4
Goessl, A.5
Csucs, G.6
-
64
-
-
28844435339
-
-
Feng C.L., Zhang Z., Förch R., Knoll W., Vancso G.J., and Schönherr H. Biomacromolecules 6 (2005) 3243
-
(2005)
Biomacromolecules
, vol.6
, pp. 3243
-
-
Feng, C.L.1
Zhang, Z.2
Förch, R.3
Knoll, W.4
Vancso, G.J.5
Schönherr, H.6
-
65
-
-
33748462726
-
-
Kemper B., Carl D., Schnekenburger J., Bredebusch I., Schäfer M., Domschke W., et al. J Biomed Opt 11 (2006) 34005
-
(2006)
J Biomed Opt
, vol.11
, pp. 34005
-
-
Kemper, B.1
Carl, D.2
Schnekenburger, J.3
Bredebusch, I.4
Schäfer, M.5
Domschke, W.6
-
71
-
-
34249798490
-
-
note
-
-1) is Avogadro's number.
-
-
-
-
75
-
-
33847184328
-
-
Owing to their open structure and large number of peripheral functional groups, dendrimers have been receiving increasing attention for the modification of bioreactive surfaces: and references cited therein
-
Owing to their open structure and large number of peripheral functional groups, dendrimers have been receiving increasing attention for the modification of bioreactive surfaces:. Degenhart G.H., Dordi B., Schönherr H., and Vancso G.J. Langmuir 20 (2004) 6261 and references cited therein
-
(2004)
Langmuir
, vol.20
, pp. 6261
-
-
Degenhart, G.H.1
Dordi, B.2
Schönherr, H.3
Vancso, G.J.4
-
76
-
-
25144471855
-
-
K562 cells are probably the most widely used experimental model of chronic phase of chronic myelogenous leukemia (CML):
-
K562 cells are probably the most widely used experimental model of chronic phase of chronic myelogenous leukemia (CML):. Kuželová K., Grebeńová D., Marinov I., and Hrkal Z.J. Cell Biochem 95 (2005) 268
-
(2005)
Cell Biochem
, vol.95
, pp. 268
-
-
Kuželová, K.1
Grebeńová, D.2
Marinov, I.3
Hrkal, Z.J.4
-
77
-
-
0347122962
-
-
Cambi A., de Lange F., van Maarseveen N.M., Nijhuis M., Joosten B., van Dijk E.M.H.P., et al. J Cell Biol 164 (2004) 145
-
(2004)
J Cell Biol
, vol.164
, pp. 145
-
-
Cambi, A.1
de Lange, F.2
van Maarseveen, N.M.3
Nijhuis, M.4
Joosten, B.5
van Dijk, E.M.H.P.6
-
78
-
-
11244274075
-
-
Kim M., Carman C.V., Yang W., Salas A., and Springer T.A. J Cell Biol 167 (2004) 1241
-
(2004)
J Cell Biol
, vol.167
, pp. 1241
-
-
Kim, M.1
Carman, C.V.2
Yang, W.3
Salas, A.4
Springer, T.A.5
-
80
-
-
0032191290
-
-
Deible C.R., Petrosko P., Johnson P.C., Beckman E.J., Russell A.J., and Wagner W.R. Biomaterials 19 (1998) 1885
-
(1998)
Biomaterials
, vol.19
, pp. 1885
-
-
Deible, C.R.1
Petrosko, P.2
Johnson, P.C.3
Beckman, E.J.4
Russell, A.J.5
Wagner, W.R.6
|