Biomedical Engineering Reference
In-Depth Information
136. Hee, M.R., Izatt, J.A., Swanson, E.A., Huang, D. et al., Optical coherence tomography of the human
retina,
Arch Ophthalmol
, 113, 325, 1995.
137. Tomlins, P.H. and Wang, R.K., Theory, developments and applications of optical coherence tomogra-
phy,
J Phys D—Appl Phys
, 2519, 2005.
138. Gladkova, N.D., Petrova, G.A., Nikulin, N.K., Radenska-Lopovok, S.G. et al., In vivo optical coherence
tomography imaging of human skin: norm and pathology,
Skin Res Technol
, 6, 6, 2000.
139. Fujimoto, J.G., Brezinski, M.E., Tearney, G.J., Boppart, S.A. et al., Optical biopsy and imaging using
optical coherence tomography,
Nat Med
, 1, 970, 1995.
140. Boppart, S.A., Bouma, B.E., Pitris, C., Southern, J.F. et al., In vivo cellular optical coherence tomography
imaging,
Nat Med
, 4, 861, 1998.
141. Drexler, W., Stamper, D., Jesser, C., Li, X. et al., Correlation of collagen organization with polarization
sensitive imaging of in vitro cartilage: implications for osteoarthritis,
J Rheumatol
, 28, 1311, 2001.
142. Yang, Y., Whiteman, S., Gey Van Pittius, D., He, Y. et al., Use of optical coherence tomography in
delineating airways microstructure: comparison of OCT images to histopathological sections,
Phys
Med Biol
, 49, 1247, 2004.
143. Fujimoto, J.G., Optical coherence tomography for ultrahigh resolution in vivo imaging,
Nat Biotechnol
,
21, 1361, 2003.
144. Mason, C., Markusen, J.F., Town, M.A., Dunnill, P. et al., The potential of optical coherence tomography
in the engineering of living tissue,
Phys Med Biol
, 49, 1097, 2004.
145. Yang, Y., Dubois, A., Qin, X.P., Li, J. et al., Investigation of optical coherence tomography as an imag-
ing modality in tissue engineering,
Phys Med Biol
, 51, 1649, 2006.
146. Aydin, H.M., Yang, Y., Piskin, E. and El Haj, A., Optimizing Degradable Scaffolds for Cranium Tissue
Repair,
Eur. Cell Mater.
, 11, 23, 2006.
147. Cunha-Reis, C., Tuzlakoglu, K., Baas, E., Yang, Y. et al., Infl uence of porosity and fi bre diameter on the
degradation of chitosan fi bre-mesh scaffolds and cell adhesion,
J Mater Sci Mater Med
, 18, 195, 2007.
148. Bagnaninchi, P.O., Dikeakos, M., Veres, T. and Tabrizian, M., Towards on-line monitoring of cell
growth in microporous scaffolds: Utilization and interpretation of complex permittivity measurements,
Biotechnol Bioeng
, 84, 343, 2003.
149. Madihally, S.V. and Matthew, H.W., Porous chitosan scaffolds for tissue engineering,
Biomaterials
, 20,
1133, 1999.
150. Wang, R.K., Xu, X.Q., Tuchin, V.V. and Elder, J.B., Concurrent enhancement of imaging depth and
contrast for optical coherence tomography by hyperosmotic agents,
J Opt Soc Am B
, 18, 948, 2001.
151. Jozsa, L., Kannus, P., Balint, J.B. and Reffy, A., Three-dimensional ultrastructure of human tendons,
Acta Anat (Basel)
, 142, 306, 1991.
152. Bagnaninchi, P.O., Yang, Y., Zghoul, N., Maffulli, N. et al., Chitosan microchannels scaffolds for tendon
tissue engineering characterized by optical coherence tomography,
Tissue Eng
, 13, 323, 2007.
153. Yang, Y., Bagnaninchi, P.O. and El Haj, A., Application of optical coherence tomography in tissue
engineering,
Eur Cell Mater
, 11, 69, 2006.
154. Yang, Y., Bagnaninchi, P.O., Wood, M.A., El Haj, A. et al., Monitoring cell profi le in tissue engineering
by optical coherence tomography,
SPIE
, 51, 5695, 2005.
