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Vänänen K. Osteoclast function: Biology and mechanisms. In: Bilezikian JP, Raisz LG, Rodan GA, eds. The Biology of Bone. San Diego: Academic Press, 1996; 103–13.Search in Google Scholar
Suda T, Takahashi N, Martin TJ. Modulation of osteoclast differentiation. Endocr Rev 1992; 13: 66–80.Search in Google Scholar
Greenfield EM, Bi Y, Miyauchi A. Regulation of osteoclast activity. Life Sciences 1999; 65: 1087–102.Search in Google Scholar
Chambers TJ. The pathobiology of the osteoclast. J Clin Path 1985; 38: 241–52.Search in Google Scholar
Lucht U. Osteoclasts and their relationship to bone as studied by electron microscopy. Z Zellforsch Mikrosk Anat 1972; 135: 211–28.Search in Google Scholar
Andersson GN, Marks SC Jr. Tartrate-resistant acid ATPase as a cytological marker for osteoclasts. J Histochem Cytochem 1989; 37: 115–17.Search in Google Scholar
Barnicot NA. The supravital staining of osteoclasts by neutral red: their distribution on the parietal bone of normal growing mice, and a comparison with mutants grey-lethal and hydrocephalus-3. Proc Roy Soc B 1947; 134: 467–84.Search in Google Scholar
Burstone MS. Histochemical demonstration of succinic dehydrogenase activity in osteoclasts. Nature 1960; 185: 866.Search in Google Scholar
Hattersley G, Chambers TJ. Generation of osteoclastic function in mouse bone marrow cultures: multinuclearity and tartrate-resistant acid phosphatase are unreliable markers for osteoclast differentiation. Endocrinology 1989; 124: 1689–96.Search in Google Scholar
Mighell AJ, Hume WJ, Robinson PA. An overview of the complexities and subtleties of immunohistochemistry. Oral Diseases 1998; 4: 217–33.Search in Google Scholar
Athanasou NA. Cellular biology of bone-resorbing cells. J Bone Jt Surg 1996; 78A: 1096–112.Search in Google Scholar
Suda T, Udagawa N, Takahashi N. Cells of bone: osteoclast generation. In: Bilezikian JP, Raisz LG, Rodan GA, eds. The Biology of Bone. San Diego: Academic Press, 1996; 87–102.Search in Google Scholar
Jäger A, Radlanski RJ, Götz W. Demonstration of cells of the monocyte phagocyte lineage in the periodontium following experimental tooth movement in the rat. Histochemistry 1993; 100: 161–6.Search in Google Scholar
Damoiseaux JG, Dopp EA, Calame W et al. Rat macrophage lysosomal membrane antigen recognized by monoclonal antibody ED1. Immunology 1994; 83: 140–7.Search in Google Scholar
Dreyer CW, Pierce AM, Lindskog S. Hypothermic insult to the periodontium: a model for the study of aseptic tooth resorption. Endod Dent Traumatol 2000; 16: 9–15.Search in Google Scholar
Zamboni L, De Martino C. Buffered picric acid: formaldehyde: a new, rapid fixative for electron microscopy. J Cell Biol 1967; 35:148A.Search in Google Scholar
Sherman JK. Freeze/thaw induced structural changes in cells. J Cryosurgery 1969; 2: 189–205.Search in Google Scholar
Wesselink PR, Beertsen W, Everts V. Resorption of the mouse incisor after the application of cold to the periodontal attachment apparatus. Calcif Tiss Int 1986; 39: 11–21.Search in Google Scholar
Tal H, Stahl SS. Healing following devitalization of sites within the periodontal ligament by ultra-low temperatures. J Periodontol 1986; 57: 735–41.Search in Google Scholar
McNicol AM, Richmond JA. Optimizing immunohisto-chemistry: antigen retrieval and signal amplification. Histopathology 1998; 32: 97–103.Search in Google Scholar
Dijkstra CD, Döpp EA, Joling P, Kraal G. The heterogeneity of mononuclear phagocytes in lymphoid organs: distinct macrophage subpopulations in the rat recognized by monoclonal antibodies ED1, ED2 and ED3. Immunology 1985; 54: 589–99.Search in Google Scholar
Stirling JK. Controls for immunogold labelling. J Histochem Cytochem 1993; 41:1869–70.Search in Google Scholar
Jones S, Boyde A. The resorption of dentine and cementum in vivo and in vitro. In: Z. Davidovitch, ed. The Biological Mechanisms of Tooth Eruption and Root Resorption. Birmingham: EBSCO Media, 1988; 335–54.Search in Google Scholar
Vandevska-Radunovic V, Hals Kvïnnsland I, Kvïnnsland S, Jonsson R. Immunocompetent cells in rat periodontal ligament incident to experimental tooth movement. Eur J Oral Sci 1997; 105: 36–44.Search in Google Scholar
Akamine A, Hashigushi I, Toriya Y, Maeda K. Immunohistochemical examination on the localization of macrophages and plasma cells in induced rat periapical lesions. Endod Dent Traumatol 1994; 10: 121–8.Search in Google Scholar
Sminia T, Dijkstra CD. The origin of osteoclasts: an immunohistochemical study on macrophages and osteoclasts in embryonic rat bone. Calcif Tissue Int 1986; 39: 263–6.Search in Google Scholar
Sabokbar A, Fujikawa Y, Neale S, Murray DW, Athanasou N. Human arthroplasty-derived macrophages differentiate into osteoclastic bone resorbing cells. Ann Rheum Dis 1997; 56: 414–20.Search in Google Scholar
Beelen RHJ, Walker WS. Dynamics of cytochemically distinct subpopulations of macrophages in elicited rat peritoneal exudates. Cell Immunol 1983; 82: 246–57.Search in Google Scholar
Beelen RHJ, Eestermans IL, Döpp EA, Dijkstra CD. Monoclonal antibodies ED1, ED2 and ED3 against rat macrophages: expression of recognized antigens in different stages of differentiation. Transplantation Proceedings 1987; 19: 3166–70.Search in Google Scholar
Stutzmann J, Petrovic A, Shaye R. Extrinsic origin of bone-resorbing cells in orthodontic tooth movement. J Dent Res 1980; 59: 440.Search in Google Scholar