Biomedical Engineering Reference
In-Depth Information
129b. Iijima, M., Tohda, H., Suzuki H., Yanagisawa T., Moriwaki, Y.: Effect of F on apatite
octacalcium phosphate intergrowth and morphology in a model system of tooth enamel
formation. Calcif. Tiss. Int.
50
, 357-361 (1992)
130. Aoba, T., Miake, Y., Shimoda, S., Prostak, K., Moreno, E.C., Suga, S.: Dental apatites in
vertebrates species: morphology and chemical properties. In: Nakahara, H., Suga, S. (eds.)
Mechanisms and phylogeny of mineralization in biological systems, pp. 459-463. Springer-
Verlag, Tokyo (1991)
131. Miake, Y., Aoba, T., Moreno, E.C., Shimoda, S., Prostak, K., Suga, S.: Ultrastructural studies
on crystal growth of enameloid minerals in elasmobranch and teleost fish. Calcif Tissue Int
48
, 204-217 (1991)
132. Kakei, M., Sakae, T., Yoshikawa, M.: Electron microscopy of octacalcium phosphate in the
dental calculus. J Electron Microsc
58
(6), 393-398 (2010)
133. Osborn, J.W.: The mechanism of prism formation in teeth: a hypothesis. Calcif Tissue Int
5
,
115-132 (1970)
134. Moriwaki, Y., Doi, Y., Kani, T., Aoba, T., Takahashi, J., Okazaki, M.: Synthesis of enamel-
like apatite at physiological temperature and pH using ion-selective membranes. In: Suga,
S. (ed.) Mechanism of tooth enamel formation, pp. 239-256. Quintessence, Tokyo (1983)
135. Iijima, M.: Formation of octacalcium phosphate in vitro. In: Chow, L.C., Eanes, E.D. (eds.)
Octacalcium phosphate, vol. 18, pp. 17-49. Karger, Monograp. Oral Sci. (2001)
136. Hata, M., Moriwaki, Y., Doi, Y., Goto, T., Wakamatu, N., Kamemizu, H.: Oriented growth
of octacalcium phosphate on cation selective membrane (in Japanese). Jpn J Crystal Growth
12
, 91-99 (1985)
137. Aoba, T., Fejerskov, O.: Dental fluorosis: chemistry and biology. Crit Rev Oral Biol Med
13
(2), 155-170 (2002)
138. Iijima, M., Moriwaki, Y., Takgi, T., Moradian-Oldak, J.: Effects of bovine amelogenins
on the crystal morphology of octacalcium phosphae in a model system of tooth enamel
formation. J Cryst Growths
222
, 615-626 (2001)
139. Iijima, M., Moradian-Oldak, J.: Control of octacalcium phosphae and apatite growth by
amelogenin matrices. J Mater Chem
14
, 2189-2199 (2004)
140. Iijima, M., Moradian-Oldak, J.: Control of apatite crystal growth in a fluoride containing
amelogenin-rich matrix. Biomaterials
26
, 1595-1603 (2005)
141. Chapman, F.: Notes on shell-structure in the genus
Lingula
, Recent and Fossil. J R Micro
Soc
5
, 28-31 (1914)
142. Klement, R.: Die anorganshe skeletsubstantz. Ihre zusammensetzung, naturlichs unt kun-
stliche bildung. Naturewissenshaften
26
, 145-152 (1938)
143. Kelly, P. G., Oliver, P. T. P., Pautard, F. G. E.: The shell of Lingula unguis. Proc. 2nd. Eur.
Symp. Calcif. Tissue. 337-345. (1965)
144. Iijima, M., Moriwaki, Y.: Orientation of apatite and organic matrix in
Lingula unguis
shell.
Calcif Tissue Int
47
, 237-242 (1990)
145. Iijima, M., Kamemizu, H., Wakamatu, N., Goto, T., Moriwaki, Y.: Thermal decomposition
of Lingula shell apatite. Calcif Tissue Int
49
, 128-133 (1991)
146. Iwata, K.: Ultrastructure and calcification of the shells in inarticulate Brachiopods. I.
Ultrastructure of Lingula unguis (LINNAEUS). J Geol Soc Jpn
87
, 405-415 (1981)
147. Iijima, M., Moriwaki, Y., Gyotoku, T., Hayashi, K., Imura, S.: Small angle X-ray scattering
study of Lingula unguis shell. Jpn J Oral Biolt
31
, 308-316 (1989)
148. Eanes, E.D.: Thermodynamical studies on amorphous calcium phosphate. Calcif Tissue Res
5
, 133-145 (1970)
149. Ishiyama, M., Sasagawa, I., Akai, J.: The inorganic content of pleromin in tooth plates of
the living Holocephalan consists of a crystalline calcium phosphate known as ß-Ca
3
(PO
4
)
2
(whitlockite). Arch Histol Jpn
47
, 89-94 (1984)
150. Ishiyama, M., Teraki, Y.: The fine structure and formation of hypermineralized petrodentine
in tooth plate of extant Lungfish. Arch Histol Cytol
53
, 307-321 (1990)
