Article Menu

Export Article

More by Authors Links

Article Data

  • Views 690
  • Dowloads 148

Original Research

Open Access

Refining occlusion with muscle balance to enhance long-term orthodontic stability

  • Derek Mahony1

149 Botany Street, Randwick NSW 2031, Sydney, Australia

DOI: 10.17796/jcpd.29.2.lk435w70505t1668 Vol.29,Issue 2,April 2005 pp.93-98

Published: 01 April 2005

PDF (481.04 kB) View Full-text

Abstract

The primary objective of orthodontic treatment is the movement of teeth into a more ideal relationship, not only for aesthetic, but also for functional considerations. Another very important objective, often not given enough consideration, is the need to finish the case with the muscles of mastication in equilibrium. If muscle balance is not achieved, an endless procession of retainers is required for retention. In simple terms, if the occlusal forces in maximum intercuspation are unevenly distributed around the arch, tooth movement will most likely occur.Today, however, it is possible to simultaneously and precisely measure the relative force of each occlusal contact, the timing of the occlusal contacts and the specific muscle contraction levels.This tech-nological breakthrough represents a paradigm shift in thinking and may improve orthodontic stability.


Cite and Share

Derek Mahony. Refining occlusion with muscle balance to enhance long-term orthodontic stability. Journal of Clinical Pediatric Dentistry. 2005. 29(2);93-98.

URL:

https://www.jocpd.com/articles/10.17796/jcpd.29.2.lk435w70505t1668

References

1. Thompson JR. Concepts regarding the function of the stomato-gnathic system. JADA 48: 626-637, 1954.

2. Gervais RO, Fitzsimmons GW, Thomas NR. Masseter and tempo-ralis electromyographic activity in asymptomatic, subclinical, and temporomandibular joint dysfunction patients. Cranio 7: 52-7, 1989.

3. Glaros AG, McGlynn FD, Kapel L. Sensitivity, specificity, and the predictive value of facial electromyographic data in diag-nosing myofascial pain-dysfunction. Cranio 7: 189-93, 1989.

4. Glaros AG, Glass EG, Brockman D. Electromyographic data from TMD patients with myofascial pain and from matched con-trol subjects: evidence for statistical, not clinical, significance. J Orofac Pain 11: 125-9, 1997.

5. Kamyszek G, Ketcham R, Garcia R Jr, Radke J. Electromyographic evidence of reduced muscle activity when ULF-TENS is applied to the Vth and VIIth cranial nerves. Cranio 19: 162-8, 2001.

6. Belser UC, Hannam AG. The influence of altered working-side occlusal guidance on masticatory muscles and related jaw move-ment. J Prosthet Dent 53: 406-13, 1985.

7. McCarroll RS, Naeije M, Hansson TL. Balance in masticatory muscle activity during natural chewing and submaximal clench-ing. J Oral Rehabil 16: 441-6, 1989.

8. Visser A, McCarroll RS, Oosting J, Naeije M. Masticatory electromyographic activity in healthy young adults and myo-genous craniomandibular disorder patients. J Oral Rehabil 21:

67- 76, 1994.

9. Christensen LV, Rassouli NM. Experimental occlusal inter-ferences. Part I. A review. J Oral Rehabil 22: 515-20, 1995.

10. Christensen LV, Rassouli NM. Experimental occlusal inter-ferences. Part II. Masseteric EMG responses to an intercuspal interference. J Oral Rehabil 22: 521-31, 1995.

11. Borromeo GL, Suvinen TI, Reade PC. A comparison of the effects of group function and canine guidance interocclusal device on masseter muscle electromyographic activity in normal subjects. J Prosthet Dent 74: 174-80, 1995.

12. Christensen LV, Mohamed SE. Bilateral masseteric contractile activity in unilateral gum chewing: differential calculus. J Oral Rehabil 23: 638-47, 1996.

13. Saifuddin M, Miyamoto K, Ueda HM, Shikata N, Tanne K. An electromyographic evaluation of the bilateral symmetry and nature of masticatory muscle activity in jaw deformity patients during normal daily activities. J Oral Rehabil 30: 578-86, 2003.

14. McCarroll RS, Naeije M, Kim YK, Hansson TL. Short-term effect of a stabilization splint on the asymmetry of submaximal masticatory muscle activity. J Oral Rehabil 16: 171-6, 1989.

15. Naeije M, Hansson TL. Short-term effect of the stabilization appliance on masticatory muscle activity in myogenous cranio-mandibular disorder patients. J Craniomandib Disord 5: 245-50, 1991.

16. Lobbezoo F, van der Glas HW, van Kampen FM, Bosman F. The effect of an occlusal stabilization splint and the mode of visual feedback on the activity balance between jaw-elevator muscles during isometric contraction. J Dent Res 72: 876-82, 1993, Erratum in: J Dent Res 72:1264, 1993.

17. Visser A, Naeije M, Hansson TL. The temporal/masseter co-contraction: an electromyographic and clinical evaluation of short-term stabilization splint therapy in myogenous CMD patients. J Oral Rehabil 22: 387-9, 1995.

18. al-Quran FA, Lyons MF.The immediate effect of hard and soft splints on the EMG activity of the masseter and temporalis muscles. J Oral Rehabil 26: 559-63, 1999.

19. Ferrario VF, Sforza C, Tartaglia GM, Dellavia C. Immediate effect of a stabilization splint on masticatory muscle activity in temporomandibular disorder patients. J Oral Rehabil 29: 810-5, 2002.

20. Roark AL, Glaros AG, O’Mahony AM. Effects of interocclusal appliances on EMG activity during parafunctional tooth contact. J Oral Rehabil 30: 573-7, 2003.

21. Maness WL, Podoloff R. Distribution of occlusal contacts in maximum intercuspation. J Prosthet Dent 62: 238-42, 1989.

22. Maness WL. Laboratory comparison of three occlusal registra-tion methods for identification of induced interceptive contacts. J Prosthet Dent 65: 483-7, 1991.

23. Reza Moini M, Neff PA. Reproducibility of occlusal contacts utiliz-ing a computerized instrument. Quintessence Int 22: 357-60, 1991.

24. Mizui M, Nabeshima F, Tosa J, Tanaka M, Kawazoe T. Quantitative analysis of occlusal balance in intercuspal position using the T-Scan system. Int J Prosthodont 7: 62-71, 1994.

25. Gonzalez Sequeros O, Garrido Garcia VC, Garcia Cartagena A. Study of occlusal contact variability within individuals in a posi-tion of maximum intercuspation using the T-SCAN system. J Oral Rehabil 24: 287-90, 1997.

26. Garcia Cartagena A, Gonzalez Sequeros O, Garrido Garcia VC. Analysis of two methods for occlusal contact registration with the T-Scan system. J Oral Rehabil 24: 426-32, 1997.

27. Suda S, Matsugishi K, Seki Y, Sakurai K, Suzuki T, Morita S, Hanada K, Hara K. A multiparametric analysis of occlusal and periodontal jaw reflex characteristics in young adults with nor-mal occlusion. J Oral Rehabil 24: 610-3, 1997.

28. Garrido Garcia VC, Garcia Cartagena A, Gonzalez Sequeros O. Evaluation of occlusal contacts in maximum intercuspation using the T-Scan system. J Oral Rehabil 24: 899-903, 1997.

29. Kirveskari P. Assessment of occlusal stability by measuring con-tact time and centric slide. J Oral Rehabil 26: 763-6, 1999.

30. Kerstein RB. Improving the delivery of a fixed bridge. Dent Today 18: 82-4, 86-7, 1999.

31. Suda S, MacHida N, Momose M, Yamaki M, Seki Y, Yoshie H, Hanada K, Hara K. A multiparametric analysis of occlusal and periodontal jaw reflex characteristics in adult skeletal mandibu-lar protrusion before and after orthognathic surgery. J Oral Rehabil 26: 686-90, 1999.

32. Saracoglu A, Ozpinar B. In vivo and in vitro evaluation of occlusal indicator sensitivity. J Prosthet Dent. 2002 Nov; 88(5):522-6. Comment in: J Prosthet Dent 90:310; author reply 310- 1, 2003.

33. Kerstein RB, Wright NR. Electromyographic and computer analyses of patients suffering from chronic myofascial pain-dys-function syndrome: before and after treatment with immediate complete anterior guidance development. J Prosthet Dent 66: 677- 86, 1991, Comment in: J Prosthet Dent 70: 99-100,1993

34. Hidaka O, Iwasaki M, Saito M, Morimoto T. Influence of clench-ing intensity on bite force balance, occlusal contact area, and average bite pressure. J Dent Res 78: 1336-44, 1999.

35. Kerstein RB. Combining technologies: A computerized occlusal system synchronized with a computerized electromyograhic system. Cranio 22: 96-109, 2004.

Abstracted / indexed in

Science Citation Index Expanded (SciSearch) Created as SCI in 1964, Science Citation Index Expanded now indexes over 9,500 of the world’s most impactful journals across 178 scientific disciplines. More than 53 million records and 1.18 billion cited references date back from 1900 to present.

Biological Abstracts Easily discover critical journal coverage of the life sciences with Biological Abstracts, produced by the Web of Science Group, with topics ranging from botany to microbiology to pharmacology. Including BIOSIS indexing and MeSH terms, specialized indexing in Biological Abstracts helps you to discover more accurate, context-sensitive results.

Google Scholar Google Scholar is a freely accessible web search engine that indexes the full text or metadata of scholarly literature across an array of publishing formats and disciplines.

JournalSeek Genamics JournalSeek is the largest completely categorized database of freely available journal information available on the internet. The database presently contains 39226 titles. Journal information includes the description (aims and scope), journal abbreviation, journal homepage link, subject category and ISSN.

Current Contents - Clinical Medicine Current Contents - Clinical Medicine provides easy access to complete tables of contents, abstracts, bibliographic information and all other significant items in recently published issues from over 1,000 leading journals in clinical medicine.

BIOSIS Previews BIOSIS Previews is an English-language, bibliographic database service, with abstracts and citation indexing. It is part of Clarivate Analytics Web of Science suite. BIOSIS Previews indexes data from 1926 to the present.

Journal Citation Reports/Science Edition Journal Citation Reports/Science Edition aims to evaluate a journal’s value from multiple perspectives including the journal impact factor, descriptive data about a journal’s open access content as well as contributing authors, and provide readers a transparent and publisher-neutral data & statistics information about the journal.

Scopus: CiteScore 2.0 (2022) Scopus is Elsevier's abstract and citation database launched in 2004. Scopus covers nearly 36,377 titles (22,794 active titles and 13,583 Inactive titles) from approximately 11,678 publishers, of which 34,346 are peer-reviewed journals in top-level subject fields: life sciences, social sciences, physical sciences and health sciences.

Submission Turnaround Time

Conferences

Top