Biomedical Engineering Reference
In-Depth Information
References
[1] M. Lavine, M. Roberts, and O. Smith, Bodybuilding:
the bionic human,
Science
295
(2002), 995-1032.
[2] D.F. Williams, On the mechanisms of biocompatibility,
Biomaterials
29
(2008), 2941-2953.
[3] D.F. Williams, Definitions in biomaterials,
Proceedings
of a consensus conference of the European society for bio-
materials
, Elsevier, New York, NY, USA (1987).
[4] B.D. Ratner and A.S. Hoffman, Physicochemical
surface modification of materials used in medicine, in
Biomaterials science
(B.D. Ratner, A.S. Hoffman, F.J.
Schoen, and J.E. Lemons, eds.), Elsevier Academic
Press, San Diego, CA, USA (2004).
[5] R. Williams,
Surface modification of biomaterials. Methods
analysis and applications
, Woodhead Publishing,
Oxford, UK (2011).
[6] B.D. Ratner and D.G. Castner, Surface modification of
polymeric biomaterials,
International symposium on
surface modification of polymeric biomaterials
, Plenum
Press, Anaheim, CA, USA (1997).
[7] J.A. Burdick and R.L. Mauck,
Biomaterials for tissue
engineering applications: a review of the past and future
trends
, Springer, Vienna, Austria (2010).
[8] D.F. Williams,
The biomaterials silver jubilee compen-
dium: the best papers published in biomaterials, 1980-2004
,
Elsevier, Amsterdam, The Netherlands (2006).
[9] Y. Ikada, Surface modification of polymers for medical
applications,
Biomaterials
15
(1994), 725-736.
[10] B.D. Ratner, Surface modification of polymers: chemi-
cal, biological and surface analytical challenges,
Biosens Bioelectron
10
(1995), 797-804.
[11] I. Langmuir, The constitution of liquids with especial
reference to surface tension phenomena,
Metall Chem
Eng
15
(1916), 468-470.
[12] I. Langmuir, The constitution and fundamental prop-
erties of solids and liquids. Part I. Solids,
J Am Chem
Soc
38
(1916), 2221-2295.
[13] S.N. Vinogradov and R.H. Linnell,
Hydrogen bonding
,
Van Nostrand Reinhold, New York, NY, USA (1971).
[14] G.W. Castellan,
Physical chemistry
, Addison-Wesley,
Reading, MA, USA (1964).
[15] E.A. Vogler, Biological properties of water, in
Water in
biomaterials surface science
(M. Morra, ed.), Wiley, New
York, NY, USA (2001), 4-24.
[16] E.A. Vogler, Protein adsorption in three dimensions,
Biomaterials
33
(2012), 1201-1207.
[17] F.W. Putnam, Alpha, beta, gamma, omega—the roster
of the plasma proteins, in
The plasma proteins: structure,
function, and genetic control
(F.W. Putnam, ed.), Aca-
demic Press, New York, NY, USA (1975), 58-131.
[18] N.L. Anderson and N.G. Anderson, The human
plasma proteome: history, character, and diagnostic
prospects,
Mol Cell Proteom
1
(2002), 845-867.
[19] E.A. Vogler, How water wets biomaterials, in
Water in
biomaterials surface science
(M. Morra, ed.), Wiley, New
York, NY, USA (2001), 269-290.
[20] E.A. Vogler, Interfacial chemistry in biomaterials
science, in
Wettability
(J. Berg, ed.), Marcel Dekker,
New York, NY, USA (1993), 184-250.
[21] E.A. Vogler, Structure and reactivity of water at bio-
material surfaces,
Adv Colloid Interface Sci
74
(1998),
69-117.
[22] E.A. Vogler, Water and the acute biological response
to surfaces,
J Biomat Sci Polym Edu
10
(1999),
1015-1045.
[23] K.D. Collins, Sticky ions in biological systems,
Proc
Natl Acad Sci
92
(1995), 5553-5557.
[24] P. Kao, P. Parhi, A. Krishnan, H. Noh, W. Haider,
S. Tadigadapa, D.L. Allara, and E.A. Vogler, Volumet-
ric interpretation of protein adsorption: interfacial
packing of protein adsorbed to hydrophobic surfaces
from surface-saturating solution concentrations,
Biomaterials
32
(2010), 969-978.
[25] F. Ariola, A. Krishnan, and E.A. Vogler, Interfacial rhe-
ology of blood proteins adsorbed to the aqueous-
buffer/air interface,
Biomaterials
27
(2006), 3404-3412.
[26] P. Parhi, A. Golas, and E.A. Vogler, Role of water and
proteins in the attachment of mammalian cells to sur-
faces: a review,
J Adhes Sci Tech
24
(2010), 853-888.
[27] E.A. Vogler, The goldilocks surface,
Biomaterials
32
(2011), 6670-6675.
[28] E.A. Vogler and C.A. Siedlecki, Contact activation of
blood plasma coagulation,
Biomaterials
30
(2009),
1857-1869.
[29] E.A. Vogler, J.C. Graper, G.R. Harper, H.W. Sugg,
L.M. Lander, and W.J. Brittain, Contact activation of the
plasma coagulation cascade I. Procoagulant surface
chemistry and energy,
J Biomed Mater Res
29
(1995),
1005-1016.
[30] D.F. Williams, General concepts of biocompatibility,
Handbook of biomaterial properties
(J. Black and G. Hastings,
eds.), Chapman and Hall, London, UK (1998), 481-488.
[31] M.L. Vanderford and D.H. Smith,
The silicone breast
implant story: communication and uncertainty
, L. Erlbaum
Associates, Mahwah, NJ, USA (1996).
[32] D.E. Bernstein, The breast implant fiasco,
Calif Law Rev
87
(1999), 457-510.
[33] M. Angell,
Science on trial: the clash of medical evidence
and the law in the breast implant case
, W.W. Norton,
London, UK (1996).
[34] S. Bondurant, V.L. Ernster, and R. Herdman,
Safety of
silicone breast implants
, Institute of Medicine, Washing-
ton, DC, USA (2000).
[35] B.D. Ratner, A.S. Hoffman, F.J. Schoen, and
J.E. Lemmons,
Biomaterials science: an introduction to
materials in medicine
, Elsevier Academic Press, New
York, NY, USA (2004).