Biomedical Engineering Reference
In-Depth Information
topography
in vitro. J. Cell Res.
86:
9-24.
Curtis, A. S. G., and Wilkinson, C. (1997).
Topographical control of cells.
Biomaterials
18: 1573-1583.
den Braber, E. T., Ruijter, J. E., de Smits,
H. T. J., Ginsel, L. A., Recum, A. F., and
von Jansen, J. A. (1995). Effects of
parallel surface microgrooves and
surface energy on cell growth.
J. Biomed. Mat. Res.
29: 511-518.
den Braber, E. T., Ruijter, J. E., de Smits,
H. T. J., Ginsel, L. A., Recum, A. F., and
von Jansen, J. A. (1996). Quantitative
analysis of cell proliferation and
orientation on substrata with uniform
parallel surface micro grooves.
Biomaterials
17: 1093-1099.
den Braber, E. T., Ruijter, J. E., and Jansen,
J. A. (1997). The effect of
a subcutaneous silicone rubber implant
with shallow surface micro grooves on
the surrounding tissue in rabbits.
J. Biomed. Mater. Res.
37: 539-547.
den Braber, E. T., Jansen, H. V., de Boer,
M. J., Croes, H. J. E., Elwenspoek, M.,
Ginsel, L. A., and Jansen, J. A. (1998a).
Scanning electron microscopic,
transmission electron microscopic, and
confocal laser scanning microscopic
observation of fibroblasts cultured on
microgrooved surfaces of bulk titanium
substrata.
J. Biomed. Mater. Res.
40:
425-433.
den Braber, E. T., Ruijter, J. E., Ginsel,
L. A., von Recum, A. F., and Jansen, J. A.
(1998b). Orientation of ECM protein
deposition, fibroblast cytoskeleton, and
attachment complex components on
silicone microgrooved surfaces.
J. Biomed. Mater. Res.
40: 291-300.
Dunn, G. A. (1982). Contact guidance of
cultured tissue cells: a survey of
potentially relevant properties of the
substratum. in
Cell Behavior,
R.
Bellairs, A. S. G. Curtis and G. A.
Dunn, eds. Cambridge University
Press, Cambridge, UK, pp. 247-280.
Dunn, G. A., and Brown, A. F. (1986).
Alignment of fibroblasts on grooved
surfaces described by a simple
geometric transformation.
J. Cell Sci.
83: 313-340.
Elema. H., Groot, J. H., de Nijenhuis, A. J.,
Pennings, A. J., Veth, R. P. H.,
Klompmaker, J., and Jansen, H. W. B.
(1990). Biological evaluation of porous
biodegradable polymer implants in
menisci.
Colloid Polymer Sci.
268: 1082-
1088.
Erickson, H. P. (1994). Reversible
unfolding of fibronectin type III and
immunoglobulin domains provides the
structural basis for stretch and elasticity
of titin and fibronectin.
Proc. Natl.
Acad. Sci. USA
91: 10114-10118.
Folch, A., and Toner, M. (2000).
Microengineering of cellular
interactions.
Annu. Rev. Biomed. Eng.
2: 227-256.
Groot, J. H., de Nijenhuis, A. J., Bruin,
P., Pennings, A. J., Veth, R. P. H.,
Klompmaker, J., and Jansen, H. W. B.
(1990). Preparation of porous
biodegradable polyurethanes for the
reconstruction of meniscal lesions.
Colloid Polymer Sci.
268: 1073-1081.
Harrison, R. G. (1912). The cultivation of
tissues in extraneous media as a method
of morphogenetic study.
Anat. Rec.
6:
181-193.
Hoch, H. C., Jelinski, L. W., and
Craighead, H. G. (1996).
Nanofabrication and Biosystems.
Cambridge University Press,
Cambridge, UK.
Hong, H. L., and Brunette, D. M. (1987).
Effect of cell shape on proteinase
secretion.
J. Cell Sci.
87: 259-267.
Ingber, D. E. (1993). Cellular tensegrity;
defining new rules of biological design
that govern the cytoskeleton.
J. Cell Sci.
104: 613-627.
Ingber, D. E. (1994). Cellular tensegrity and
mechanochemical transduction.
in Cell
Mechanics and Cellular Engineering,
V.
C. Mow, F. Guilak, R. Tran-Son-Tay,
and R. M. Hochmuth, eds. Springer-
Verlag, New York, pp. 329-342.
Janmey, P. A., and Chaponnier, C. (1995).
Medical aspects of the actin
cytoskeleton.
Curr. Opin. Cell Biol.
7
:
111-117.
Janmey, P. A. (1998). The cytoskeleton and
cell signaling: component localization
and mechanical coupling.
Physiol. Rev.
78: 763-781.
Jansen, H. V., Gardeniers, J. G. E., de Boer,
M. J., Elwenspoek, M. E., and Fluitman,
J. H. J. (1996). A survey on the reactive
ion etching of silicon in
microtechnology.
J. Micromech.
Microeng.
6: 14-28.
Kumar, A., Biebuyck, H. A., and
Whitesides, G. M. (1994). Patterning
self-assembled monolayers: applications
in materials science.
Langmuir
10(5):
1498-1511.
Lackie, J. M. (1986).
Cell Movement and
Cell Behaviour.
Allen & Unwin,
London.
Lanza, R. P., Langer, R., and Chick, W. L.
(1997).
Principles of Tissue Engineering.
Academic Press, San Diego.
Maniotis, A. J.,Chen, C. S., and
Ingber, D. E. (1997). Demonstration of
mechanical connections between
integrins, cytoskeletal filaments, and
nucleoplasm that stablize nuclear
structure.
Proc. Natl. Acad. Sci. USA
94: 849-854.
Maroudas, N. G. (1972). Anchorage
dependence: correlation between
amount of growth and diameter of
bead, for single cells grown on
individual glass beads.
Exp. Cell Res.
74: 337-342.
Matsuzaka, K., Walboomers, X. F.,
de Ruijter, J. E., and Jansen, J. A.
(1999). The effect of poly-
L
-lactic acid
with parallel surface micro groove on
osteoblast-like cells
in vitro.
Biomaterials
20(14): 1293-1301.
Meyle, J., von Recum, A. F., and Gibbesch,
B. (1991). Fibroblast shape
conformation to surface
micromorphology.
J. Appl. Biomat.
2: 273-276.
Meyle, J., G¨ltig, K., Wolburg, H., and von
Recum, A. F. (1993). Fibroblast
anchorage to microtextured surfaces.
J. Biomed. Mater. Res.
27: 1553-1557.
Oakley, C., and Brunette, D. M. (1993).
The sequence of alignment of
microtubules, focal contacts and actin
filaments in fibroblasts spreading on
smooth and grooved titanium substrata.
J. Cell Sci.
106: 343-354.
Oakley, C., and Brunette, D. M. (1995).
Topographic compensation: guidance
and directed locomotion of fibroblasts
on grooved micromachined substrata in
the absence of microtubules.
Cell Motil.
Cytoskeleton
31: 45-58.
Oakley, C., Jaeger, N. A., and Brunette,
D. M. (1997). Sensitiv of fibroblasts
and their cytoskeletons to substratum
topographies: topographic guidance and
topographic compensation by
micromachined grooves of different
dimensions.
Exp. Cell Res.
234:
413-424.
Ohara, P. T., and Buck, R. C. (1979).
Contact guidance
in vitro.
A light,
transmission, and scanning electron
microscopic study.
Expl. Cell Res.
121:
235-249.
O'Neill, C., Jordan, P., and Riddle,
P. (1990). Narrow linear strips of
adhesive substratum are powerful
inducers of both growth and total focal
contact area.
J. Cell Sci.
95: 577-586.
Pilliar, R. M. (1987). Porous-surfaced
metallic implants for orthopaedic
applications.
J. Biomed. Mater. Res.
21:
1-33.
Pollock, H. (1992): Breast capsular
contracture: A retrospective study
of textured versus smooth silicone
