1. |
Problem of the corrosion with fluoride of the Ti implant Proposal from fundamental researches . |
2. |
Fibroblasts Attachment to CaCl2 Hydrothermally Treated Titanium Implant. |
3. |
Effect of surface modification on initial setting time of α-tricalcium phosphate based apatite cement. |
4. |
Effect of O3 treatment on the basic properties of apatite cement. |
5. |
Mechanical strength improvement of carbonate apatite foam bone substitute by PLGA reinforcement. |
6. |
Fabrication of bioactive polyethylen terephthalate (PET) substrates by ozone-calcium treatment. |
7. |
Fabrication of interconnected porous calcium phosphate cement. |
8. |
Surface modification of polyethylene terephthalate (PET) substrates for biomedical application by ozone-calcium chloride treatment. |
9. |
Preparation of porous calcium phosphate cement from alpha-tricalcium phosphate (alpha-TCP) microspheres for bone tissue regeneration. |
10. |
Improvement of handling property of apatite cement paste by O3 treatment. |
11. |
Effect of distilled water treatment on the initial setting time of alpha tricalcium phosphate. |
12. |
Surface modification of PET substrates with ozone-calcium treatment. |
13. |
Handling property improvement of apatite cement by ozone treatment. |
14. |
Improvement of setting time on α-tricalcium phosphate-based apatite cement by immersion in distilled water. |
15. |
Preparation of porous calcium phosphate cement from α-tricalcium phosphate granular balls. |
16. |
Studies on Improving Osteoconductivity of Titanium by Hydrothermal Treatment. |
17. |
Fabrication of Calcium Phosphate Cement from C3S-Doped α-TCP. |
18. |
Thermal decomposition of carbonate apatite. |
19. |
The studies of metallic allergy in dental clibics. 2.The factor in elution of dental metals to human saliva. |
20. |
Osteointegration of titanium implant with CaCl2 hydrothermal treatment . |
21. |
Effect of fluoride on corrosion behavior of NiTi orthodontic wire. |
22. |
Osteointegration of titanium implant with CaCl2 hydrothermal treatment. |
23. |
Effect of fluoride on corrosion behavior of NiTi orthodontic wire. |
24. |
Basic studies on metallic allergy 1. Elution of dental alloys in human saliva and protein adsorption. |
25. |
Formation of carbonated apatite by treatment of calcite-addef set gypsum in ammonium phosphate. |
26. |
Preparation of carbonate apatite monolith from hardened vaterite-gypsum by hydrothermal treatment in sodium phosphate. |
27. |
Effect of fluoride on the corrosion of titanium and titanium alloys covered by pseudo-biofilm. |
28. |
Application of the photocatalyst titanium-oxide to the denture base resin. Effect of self-cleaning. |
29. |
Fabrication of Carbonate Apatite (CHA) Foam with fully interconnected porosity for bone subtitute materials. |
30. |
Formation of carbonated apatite by treatment of calcite-added set gypsum in sodium phosphate. |
31. |
Fabrication of carbonate apatite foam by hydrothermal treatment in ammonium carbonate solution. |
32. |
Initial attachment and proliferation of osteoblast-like cell on the high corrosion resistance titanium alloys hydrothermally treated with CaCl2. |
33. |
Fabrication of hydroxyapatite bone filler from gypsum block. |
34. |
Corrosion behavior of titanium and titanium alloys using pseudo-biofilm. |
35. |
Corrosion behavior of titanium and titanium alloys in simulated oral environment. |
36. |
Thermal behavior of molds prepared by a gypsum-bonded cristbalite investment in a dental furnace. (II) X-ray diffraction analysis. |
37. |
Fabrication of hydroxyapatite monolith from gypsum treated with the ammonium phosphate solutions. |
38. |
Fabrication of carbonated apatite monolith by treatment of calcium carbonate in phosphate solutions. |
39. |
Corrosion behavior of titanium and titanium alloys in simulated oral environment. |
40. |
Preparation of carbonate apatite. |
41. |
Influence of surface modifications on the bioactivity of titanium for dental implants. |
42. |
Preparation of carbonate apatite monolith by ammonium phosphate treatment of calcium carbonate. |
43. |
Development of high corrosion resisrance titanium allys in fluoride containing environment. |
44. |
Generation of hydoroxyapatite by phosphoric acid ammonium salt processing of gypsum. |
45. |
Manufacture of Open Pore Carbonate Apatite Ceramics. |
46. |
Preparation of carbonated apatite monolith by treatment of calcium carbonate in phosphate solutions. |
47. |
Surface changes of titanium by the corrosion in fluoride containing solution. |
48. |
The Influence of Povidon-iodine Oral Rinse in tha Changes of the Casting Crawn. |
49. |
Corrosion Behavior of High Vorrosion Resistance Titanium Alloys in Oral Environment. |
50. |
Development of titanium with high corrosion resistance in fluoride containing environment. |
51. |
Development of dental titanium alloys with high corrosoion resistance and bioactivity. |
52. |
Influence of surface modification on bioactivity of titanium alloys for implants. |
53. |
Hydrolysis of calcite in potassium phosphate solution. |
54. |
Effect of fluoride on the hydrolysis of calcite in potasium dihydrogen phosphate. |
55. |
Corrosion behavior and bioactivity of the high corrosion resistant titanium alloys. |
56. |
Clinical Study on Discoloration of dental Alloys: The Effect of Povidone Iodine Oral Rince. |
57. |
Effect of fluoride on the setting reaction of glass polyalkenoate cements. |
58. |
Pseudobinary phase diagrams of AuCu-Sn. |
59. |
Development of High Corrosion resistant Titanium alloys in fluoride circumstance. |
60. |
Pseudobinary phase diagrams of AuCu-X(X=In, Ga, Mn). |
61. |
Setting process of resin-modified glass ionomer cement. |
62. |
The Study of Color Change oand Corrosion of Ag-Pd-Cu-Au Alloy. |
63. |
The effect of dissolved oxygen on corrosion behavior of titanium and titanium alloys. |
64. |
Corrosion of titanium alloys in fluoride containing environment. |
65. |
Titanium alloys with high corrosion resistance in fluoride-containing solution. |
66. |
Corrosion resistance of titanium and titanium alloys in fluoride-containing solution. |
67. |
Corrosion behavior of titanium and titanium-alloys in fluoride-containing solution. |