Rapid maxillary expansion is employed for the treatment of cross-bite and deficiency of transversal dimension of the maxilla in patients with and without cleft of palate and lip. For this procedure, generally, different orthodontic appliances and devices generating significant transversal forces are used. The aim of this study is the finite-element analysis of stresses and displacements of the skull without palate cleft and the skull with unilateral and bilateral cleft after activation of the Hyrax orthodontic device. Two different constructions of the orthodontic device Hyrax with different positions of the screw relative palate are considered. In the first case, the screw is in the occlusal horizontal plane, and in the other, the screw is located near the palate. Activation of the orthodontic device corresponds to the rotation of the screw on one-quarter turn. It is established that the screw position significantly affects the distributions of stresses in skull and displacements of the cranium without palate cleft and with unilateral or bilateral palate cleft. Stresses in the bone structures of the craniums without cleft and with cleft are transferred from the maxilla to the pterygoid plate and pharyngeal tubercle if the screw displaces from the occlusal plane to the palate. Depending on the construction of the orthodontic appliance, the maxilla halves in the transversal plane are unfolded or the whole skull is entirely rotated in the sagittal plane. The stresses patterns and displacements of the skull with bilateral palate cleft are almost unchanged after activation of the orthodontic devices with different positions of the screw, only magnitudes of stresses and displacements are changed. The obtained results can be used for design of orthodontic appliances with the Hyrax screw, as well as for planning of osteotomies during the surgical assistance of the rapid maxillary expansion.

Boryor, A., Geiger, M., Hohmann, A., Wunderlich, A., Sander, Ch., Sander, F.M., Sander, F.G., 2008, Stress distribution and displacement analysis during an intermaxillary disjunction -- A three-dimensional FEM study of a human skull, Journal of Biomechanics, 41 pp. 376-382.

Chaconas, S.J., Caputo, A.A., 1982, Observation of orthopedic force distribution produced by maxillary orthodontic appliances, American Joural of Orthodontics, 82 pp. 492-501.

Gautam, P., Valiathan, A., Adhikari, R., 2007, Stress and displacement patterns in the craniofacial skeleton with rapid maxillary expansion: a finite element method study, American Journal of Orthodontics and Dentofacial Orthopedics, 132 pp.5.e1-5.e11.

Gautam, P., Zhao, L., Patel, P., 2011, Biomechanical response of the maxillofacial skeleton to transpalatal orthopedic force in a unilateral palatal cleft, Angle Orthodontist, 81 (3) pp. 503-509.

Holberg, C., Holberg, N., Schwenzer, K., Wichelhaus, A., Rudzki-Janson, I., 2007, Biomechanical analysis of maxillary expansion in CLP patients, Angle Orthodontist, 77 pp. 280-287.

Holberg, C., Steinhäuser, S., Rudzki-Janson, I., 2007, Rapid maxillary expansion in adults: cranial stress reduction depending on the extent of surgery, European Journal of Orthodontics, 29 pp. 31-36.

Holberg C., Steinhäuser S., Rudzki, I., 2007, Surgically assisted rapid maxillary expansion: midfacial and cranial stress distribution, American Journal of Orthodontics and Dentofacial Orthopedics, 132 pp. 776-782.

Isaacson, R.J., Murphy, T.D., 1964, Some effects of rapid maxillary expansion in cleft lip and palate patients, Angle Orthodontist, 34 pp. 143-154.

Isaacson, R.J., Wood, J.L., Ingram, A.H., 1964, Forces produced by rapid maxillary expansion, Part I and II // Angle Orthodonics, 34 pp. 256-270.

Iseri, H., Tekkaya, A.E., Öztan, Ö., Bilgiç, S., 1998, Biomechanical effects of rapid maxillary expansion on the craniofacial skeleton, studied by the finite element method, European Journal of Orthodontics, 20 pp. 347-356.

Jafari, A., Shetty, K.S., Kumar, M., 2003, Study of stress distribution and displacement of various craniofacial structures following application of transverse orthopedic forces - a three dimensional FEM study, Angle Orthodontist, 73 pp. 12-20.

Lee, H., Ting, K., Nelson, M., Sun, N., Sung, S.-J., 2009, Maxillary expansion in customized finite element method models, American Journal of Orthodontics and Dentofacial Orthopedics, 136 pp. 367-374.

Ludwig, B., Baumgaertel, S., Zorkun, B., Bonitz, L., Glasl, B., Wilmes, B., Lisson, J., 2013, Application of a new viscoelastic finite element method model and analysis of miniscrew-supported hybrid hyrax treatment, American Journal Orthodontics and Dentofacial Orthopedics, 143 pp. 426-435.

McGuinness, N.J., McDonald, J.P., 2006, Changes in natural head position observed immediately and one year after rapid maxillary expansion, European Journal of Orthodontics, 28 pp. 126-134

Memikoglu, T.U.T., Iseri, H., 1999, Effects of a bonded rapid maxillary expansion appliance during orthodontic treatment, Angle Orthodontics, 69 (3) pp. 251-256.

Pan., X., Qian Yu., Yu, Q., Wang, D., Tang, Y., Shen, G., 2007, Biomechanical effects of rapid palatal expansion on the craniofacial skeleton with cleft palate: a three-dimensional finite element analysis, Cleft Palate Craniofacial Journal, 44 pp. 149-154.

Provatidis, C., Georgiopoulos, B., Kotinas, A., McDonald, J.P., 2007, On the FEM modeling of craniofacial changes during rapid maxillary expansion, Medical Engineering and Physics, 29 pp. 566-579.

Romanyk, D.L., Lagravere, M.O., Toogood, R.W., Major, P.W., Carey, J.P., 2010, Review of maxillary expansion appliance activation methods: engineering and clinical perspectives, Journal of Dental Biomechanics, DOI:10.4061/2010/496906.

Sander, C., Hüffmeier S., Sander, F.M., Sander, F.G., 2006, Initial results regarding force exertion during rapid maxillary expansion in children // Journal of Orofacial Orthopedics, 67 pp. 19-26.

Tanne, K, Hiraga, J, Kakiuchi, K, Yamagata, Y, Sakuda, M., 1989, Biomechanical effect of anteriorly directed extraoral forces on the craniofacial complex: a study using the finite elements method. American Journal of Orthodontics and Dentofacial Orthopedics, 95(3) pp. 200-207.

Wang, D., Cheng, L., Wang, Ch., Qian Yu., Pan X., 2009, Biomechanical analysis of rapid maxillary expansion in the UCLP patient, Medical Engineering and Physics, 31 pp. 409-417.

Wood, S.A., Strait, D.S., Dumont, E.R., Ross, C.F., Grosse, I.R., 2011, The effects of modeling simplifications on craniofacial finite element models: The alveoli (tooth sockets) and periodontal ligaments, Journal of Biomechanics, 44 pp. 1831-1838.

Zimring, J.F., Isaacson, R.J., 1965, Forces produced by rapid maxillary expansion III. Forces present during retention, Angle Orthodontist, 35 pp. 178-186.