Rapid maxillary expansion (RME) treatment has been used widely since the mid 1960s. It is frequently used to correct maxillary width deficiency, posterior crossbite or to expand arch perimeters to alleviate dental crowding or patients with Class III malocclusion who often are treated with RME because of an insufficient maxillary arch width. Although, the major effect of this treatment is noticed clinically in the dentition and maxilla area. RME therapy appears to involve an ample portion of the craniofacial complex, as the maxilla is associated with 10 bones in the face and head. Although, the RME force is concentrated on widening the maxilla, concomitant changes occur in circumaxillary sutures. Moreover, it has been claimed that the transverse forces generated during rapid maxillary expansion are transmitted, via the pterygomaxillary connection, to the unpaired sphenoid bone of the cranial base, where they lead to stress. The extent and effects of this have not yet been studied extensively, nor have they been well determined. In orthodontics, the cranial base has received attention because of the fact that its growth influences the maxillary-mandibular complex. Some authors in fact consider the cranial base as a guide rail for development of the maxilla, midface, and lower facial complex. This involvement has been hypothesized following investigations based on histologic methods, radiologic imaging, photoelastic models, bone scintigraphy, and finite element analysis. However, even though the above studies have been well designed, some issues may have affected their conclusions. In fact, histological findings are limited to experimental studies in animals. Moreover, accuracy of the results of the finite element model (FEM) depends on the detailed geometry, material properties, and boundary conditions of the FEM. Therefore, until now, there have been only speculations about whether RME can or cannot disarticulate these structures in humans. With advanced technology and the introduction of three-dimensional computed tomography imaging, that allow clinicians and researchers to quantitatively evaluate bone changes with minimal distortion and lower radiation dosage, Due to the high dose of x-ray of CT, high cost and the lack of study on the effect of the RME on circumaxillary sutures and spheno-occipital synchondrosis using imaging three-dimensional radiographic (CT). Because of the importance of the effect of the maxillary expansion on maxillary displacement, and the resulting significant clinical effects, especially at the level of improvement in the third class at the children. From here stems the need for this study on the effect of rapid maxillary expansion RME on the craniofacial sutures in children using cone beam computed tomography