• 검색어에 아래의 연산자를 사용하시면 더 정확한 검색결과를 얻을 수 있습니다.
  • 검색연산자
검색연산자 기능 검색시 예
() 우선순위가 가장 높은 연산자 예1) (나노 (기계 | machine))
공백 두 개의 검색어(식)을 모두 포함하고 있는 문서 검색 예1) (나노 기계)
예2) 나노 장영실
| 두 개의 검색어(식) 중 하나 이상 포함하고 있는 문서 검색 예1) (줄기세포 | 면역)
예2) 줄기세포 | 장영실
! NOT 이후에 있는 검색어가 포함된 문서는 제외 예1) (황금 !백금)
예2) !image
* 검색어의 *란에 0개 이상의 임의의 문자가 포함된 문서 검색 예) semi*
"" 따옴표 내의 구문과 완전히 일치하는 문서만 검색 예) "Transform and Quantization"
쳇봇 이모티콘
ScienceON 챗봇입니다.
궁금한 것은 저에게 물어봐주세요.

논문 상세정보

공진 주파수 분석법에 의한 임플랜트의 안정성 측정에 관한 연구



Statement of problem : Successful osseointegration of endosseous threaded implants is dependent on many factors. These may include the surface characteristics and gross geometry of implants, the quality and quantity of bone where implants are placed, and the magnitude and direction of stress in functional occlusion. Therefore clinical quantitative measurement of primary stability at placement and functional state of implant may play a role in prediction of possible clinical symptoms and the renovation of implant geometry, types and surface characteristic according to each patients conditions. Ultimately, it may increase success rate of implants. Purpose : Many available non-invasive techniques used for the clinical measurement of implant stability and osseointegration include percussion, radiography, the $Periotest^{(R)}$, Dental Fine $Tester^{(R)}$ and so on. There is, however, relatively little research undertaken to standardize quantitative measurement of stability of implant and osseointegration due to the various clinical applications performed by each individual operator. Therefore, in order to develop non-invasive experimental method to measure stability of implant quantitatively, the resonance frequency analyzer to measure the natural frequency of specific substance was developed in the procedure of this study. Material & method : To test the stability of the resonance frequency analyzer developed in this study, following methods and materials were used : 1) In-vitro study: the implant was placed in both epoxy resin of which physical properties are similar to the bone stiffness of human and fresh cow rib bone specimen. Then the resonance frequency values of them were measured and analyzed. In an attempt to test the reliability of the data gathered with the resonance frequency analyzer, comparative analysis with the data from the Periotest was conducted. 2) In-vivo study: the implants were inserted into the tibiae of 10 New Zealand rabbits and the resonance frequency value of them with connected abutments at healing time are measured immediately after insertion and gauged every 4 weeks for 16 weeks. Results : Results from these studies were such as follows : The same length implants placed in Hot Melt showed the repetitive resonance frequency values. As the length of abutment increased, the resonance frequency value changed significantly (p<0.01). As the thickness of transducer increased in order of 0.5, 1.0 and 2.0 mm, the resonance frequency value significantly increased (p<0.05). The implants placed in PL-2 and epoxy resin with different exposure degree resulted in the increase of resonance frequency value as the exposure degree of implants and the length of abutment decreased. In comparative experiment based on physical properties, as the thickness of transducer increased, the resonance frequency value increased significantly(p<0.01). As the stiffness of substances where implants were placed increased, and the effective length of implants decreased, the resonance frequencies value increased significantly (p<0.05). In the experiment with cow rib bone specimen, the increase of the length of abutment resulted in significant difference between the results from resonance frequency analyzer and the $Periotest^{(R)}$. There was no difference with significant meaning in the comparison based on the direction of measurement between the resonance frequency value and the $Periotest^{(R)}$ value (p<0.05). In-vivo experiment resulted in repetitive patternes of resonance frequency. As the time elapsed, the resonance frequency value increased significantly with the exception of 4th and 8th week (p<0.05). Conclusion : The development of resonance frequency analyzer is an attempt to standardize the quantitative measurement of stability of implant and osseointegration and compensate for the reliability of data from other non-invasive measuring devices It is considered that further research i

참고문헌 (51)

  1. Branemark PI. Osseointegration and its experimental background. J Prosthet Dent 1983;50:399 
  2. Branemark PI. A biomechanical study of osseointegration. Ph.D thesis. Department of Orthopaedics. Institute of Surgical Science and Institute of Anatomy and Cell Biology, University of Gothenburg, Gothenburg, 1996 
  3. Branemark PI. Hansson BO. Osseointegrated implants in the treatment of the edentulous jaw. Distributed by the Almquist and Wiksell periodical Co 
  4. Branemark PI, Zarb GA, Albrektsson T. Tissue integrated prosthesis : Osseointegration in clinical dentistry, Chicago, Quintenssence Co, 1985;117 
  5. Albrektsson T. Bone tissue response. In Osseointegration in clinical dentistry. Quintessence Co. Chicago 1985;129 
  6. Albrektsson T, Branemark PI, Hansson HA, Lindstrom J. Osseointegrated titanium implants. Acta Orthop Scand 1981;52:155 
  7. Albrektsson T, Jacobsson M. Bonemetal interface in osseoi- ntegration. J Prosthet Dent 1987;57:597 
  8. Albrektsson T, Sennerby L. State of the art in oral implants. J Clin Periodontol 1991;18:474 
  9. Albrektsson T, Zarb GA, Worthington P, Eriksson AR. The long term efficacy of currently used dental implants : A review and proposed criteria of success. Int J Oral Maxillofac Implants 1986;1:11 
  10. Meredith N. On the clinical measurement of implant stability and osseointegration. Ph.D. Thesis, Department of Biomaterials / Handicap Research, Institude for Surgical Sciences. Gothenburg University, Gothenburg. Sweden. 1997 
  11. Meredith N, Alleyne D, Cawley P. Quantitative determination of the stability of the implant-tissue interface using resonance frequecny analysis : Clin Oral Impl Res 1996:7:261 
  12. Meredith N, Book K, Friberg B, Jemt T, Sennerby L. Resonance frequency measurements of implant stability in vivo. Clin Oral Implant Research 1997:226 
  13. Meredith N, Rasmussen L, Sennerby L. Alleyne D. Mapping implant stability by resonance frequency analysis. Med Sci. Research 1996;24:191 
  14. Shulte W. The Periotest periodeontal status. Zahnarztl Mitt. 1986:76:1 
  15. Shulte W. A new field of application of the Periotest mathod. The occlusal-periodontal load can now be measured quantitatively. Zahnarztl Mitt. 1988:78:474 
  16. Derhami K, Wolfaardt JF. Dent M, Faulkner G. Grace M. Assessment of the periotest device in base line mobility measurements of craniofacial implants. Int J oral Maxillofac Implants 1995;10:221 
  17. Theories Practices of Vibration Samsung Institute of Technology of Electon particle. 1991:1 
  18. Measurement of Vibration & Frequency 30 analysis International Industiral Information system. 1989 
  19. Bruel and Kjaer : Model Analysis 1992 
  20. Singiresu S R. Determination of natural frequency & mode shape. Mechanical vibration 1986:322 
  21. Cawley P, Adams RD. The mechanics of the coin-tap method of non-destructive testing. J Sound Vibration 1988:122(2):299 
  22. Johansson CB, Strid KG. Assessment of bone quality from cutting resistance during implant surgery. Int J Oral Maxillofac Implants 1994:9:279 
  23. Roos J, Sennerby L, Albrektsson T. An update on the clinical documentation on currently used bone anchored endosseous oral implants. Dent Update in press 1997 
  24. Strid JG. Radiographic results. In osseointegration in clinical dentistry (Branemark PI, Zarb G, Albrektsson T. eds) Quintessence Publiahers, Chicago. 1985;187 
  25. Rice JC, Cowin SC, Bowman JA. On the dependence of the elasticity and strength and of cancellous bone on apparent density. J Biomech 1988;21:155 
  26. Ashman RB. Ultrasonic determination of the elastic properties of cortical bone : techniques and limitations 'Thesis'. New Orleans, LA : Tulane University, 1982 
  27. Tricio J, van Steenberghe D, Rosenberg D, Duchateau L. Implant stability related to insertion torque force and bone density: An in vitro study. J Prosthet Dent 1995;74:608 
  28. Brunski JB. Biomaterials and biomechanics in dental implant design. Int Oral Maxillofac Implants 1988:3:85 
  29. Brunski JB, Mocclia Jr AF, Pollack SR, Korostoff E, Trachtenberg D. Investigation of surfaces of retrieved endosseous dental implants of commercially pure titanium. American Society for Testing and Materials. 1983;189 
  30. Brunski JB, Mocclia Jr AF, Pollack SR. The influence of functional use of endosseous dental implants on the tissue-implant interface. I Histological aspects. J Dent Res 1979;10:58 
  31. Chavez H, Lance FO. Assessment of oral implant mobility. J Prosthet Dent 70 1994;421 
  32. van Steenberghe D, Tricio J, Nys A. Damping characteristics of bone to implant interfaces. Clin Oral Impl Res 1995;6:31 
  33. Carr AB, Larsen PE, Papazoglou E, McGlumphy. Reverse torque failure of screw-shaped implants in babbons : Baseline data for abutment torque application. Int J Oral Maxillofac Implants 1995;10:167 
  34. Cucchario PJ, DeLuzio A, Dario LJ, Cucchario SJ. Structural analyser in particular for medical implants. United States Patent No. 1996;5:518 
  35. Johanson CB, Albrektsson T. Integration of screw implants in the rabbits : A 1-yrfollow-up of removal torque of titanium implants. Int J Oral Maxillofac Implants 1987;2:69 
  36. Johansson CB, Albrektsson T. A removal torque and histomorphometric study of commercial pure nobium and titanium implants in rabbit bone. Clin Oral Impl Res 1991;2:24 
  37. Johansson CB, Sennerby L, Albrektsson T. A removal torque and histomorphometric study of bone tissue reactions to commercially pure titanium and vitallium implants. J Oral Maxillofac Implants B 1991;437 
  38. Friberg B. Bone quality evaluation during implant placement. MDS dissertation, University of Gothenburg, Gothenburg, Sweden, 1994 
  39. Friberg B, Sennerby L, Roos J, Lekholm U. Identification of bone quality in conjunction with insertion of titanium implants. Clinical Oral Implant Research 1995(a);13:213 
  40. Friberg B, Sennerby L, Roos J, Strid CG, Lekholm U. Evaluation of bone density using cutting resistance measurements and microradiography : an in vitro study in pig ribs. Clin Oral Impl Res 1995(b):6:164 
  41. Elias JJ. Brunski JB, Scarton HA. A dynamic modal testing technique for non-invasive assessment of bone-dental implant interface. Int J Oral Maxillofac Implants 1996:11:728 
  42. Chavez H, Lance FO. Assessment of oral implant mobility. J Prosthet Dent 1994;70:421 
  43. Lim JH, Cho IH : A study on the evaluation of Bone quality of Maxillo and Mandibule by using peroitest. 1994;32:7.520 
  44. Deutch JE, Brunski JB. Numerical analysis of load distribution among dental implants. AADR Meeting, San Francisco, Calif. 1989:Paper No. 587 
  45. Hobo S, Ichida E, Garcia LT. Osseointegration and occlusal rehabilitation. Chicago. Quintessence Publ Co. 1989;265 
  46. Lekholm U, Zarb GA. Patient selection and preparation. In Osseointegration in clinical dentistry (Branemark PI, Zarb G, Albrektsson T, eds). Quintessence Co. Chicago. 1985;199 
  47. Sennerby L., Thomsen P, Ericson LE. Early tissue response to titanium implants inserted in rabbit cortical bone. Part 1 Light microscopic observations. J Mater Sci. : Mater in Med 1993;4:240 
  48. Sennerby L. Thomsen P. Ericson LE. Early tissue response to titanium implants inserted in rabbit cortical bone. Part 2 Ultrastructural observations. J Mater Sci. : Mater in Med 1993;4:494 
  49. Tsuboi Y, Sennerby L, Mori K, Matsuhisa H. The dynamic of the osseointegrated implant. Part 1: Theoretical analysis of the osseointegrated implant and the natural tooth by the vibration theory. Personal Communication. 1996 
  50. Wennerberg A. On surface roughness and implant incorporation. Ph.D. Thesis. Department of Biomaterials/Handicap Research, Institute for Surgical Sciences, and Department of Prosthetic Dentistry. Gothenburg Universith, Gothenburg, Sweden. 1996 
  51. Handbook of Noise & Vibration : The Korean Society for Noise & Vibration Engineers. 1995;221 

이 논문을 인용한 문헌 (3)

  1. 2006. "" 대한치과보철학회지 = The journal of Korean academy of prosthodontics, 44(3): 314~324 
  2. Lee, Ju-Hyon ; Min, Hyun-Gi ; Lee, Jin-Sook ; Kim, Myung-Rae ; Kang, Na-Ra 2008. "RESONANCE FREQUENCY ANALYSIS IN NON-SUBMERGED, INTERNAL TYPE IMPLANT WITH SINUS AUGMENTATION USING DEPROTEINIZED BOVINE BONE MINERAL" 대한악안면성형재건외과학회지 = The journal of Korean association of maxillogacial plastic and reconstructive surgeons, 30(6): 554~560 
  3. Kim, Sung-Won ; Cho, In-Ho 2014. "On the osseointegration of zirconia and titanium implants installed at defect site filled with xenograft material" 대한치과보철학회지 = The journal of Korean academy of prosthodontics, 52(1): 9~17 


원문 PDF 다운로드

  • ScienceON :

원문 URL 링크

원문 PDF 파일 및 링크정보가 존재하지 않을 경우 KISTI DDS 시스템에서 제공하는 원문복사서비스를 사용할 수 있습니다. (원문복사서비스 안내 바로 가기)

상세조회 0건 원문조회 0건

DOI 인용 스타일