Maxillary Obturators Clinical Trial
Official title:
Bland-Altman Analysis of Maxillary Obturator Bulb Accuracy in Class III Brown Classification Maxillectomy Defects
Treatment of tumors in the paranasal region often requires maxillectomy procedures. While surgical reconstruction is preferred, prosthetic reconstruction using obturators becomes necessary when surgery is not feasible. Obturators separate oral and nasal cavities, restoring functions like chewing, speech, and facial aesthetics, while alleviating psychological distress. The emergence of rapid prototyping (RP) technologies since 1995 has revolutionized prosthetic construction. RP techniques like stereolithography and 3D printing enable layer-by-layer production of accurate 3D models from computer designs. Combined with imaging like CT and MRI, RP allows creation of highly precise extraoral facial prostheses. For intraoral defects, integrating 3D CAD and RP can enhance prosthetic outcomes compared to conventional gypsum models, although obtaining accurate impressions remains challenging due to factors like defect size, undercuts, and mucosal issues.
The treatment of tumors in the paranasal region often necessitates either palatal maxillectomy or radical maxillectomy procedures, which involve the surgical removal of a portion or the entire maxillary bone. While these surgical interventions are aimed at treating the underlying condition, they can result in significant functional and aesthetic deficits for the patient. In such cases, surgical and prosthetic interventions offer avenues to address these post-maxillectomy challenges, ensuring both functional and aesthetic outcomes. Despite the advantages associated with surgical reconstruction procedures, they may not always be feasible due to the patient's overall health condition or the extent of the defect. In these situations, prosthetic reconstruction becomes an imperative solution. Temporary or permanent obturators serve as effective prosthetic devices in this context, with the primary aim of separating the oral and sinonasal cavities. This separation is crucial in preventing issues such as hypernasal speech, which occurs when air escapes through the nasal cavity during speech, and fluid leakage into the nasal cavity, which can lead to discomfort and potential health complications. Beyond their functional role in separating the cavities, obturators play a pivotal role in restoring essential functions like chewing, swallowing, and speech. They provide support to the lips and cheeks, aiding in the restoration of facial contour and aesthetics. Moreover, these prosthetic devices contribute significantly to alleviating the social and psychological distress experienced by patients, as they help to restore a sense of normalcy and self-confidence. The emergence of rapid prototype production technology, also known as rapid prototyping (RP) or laser-layered manufacturing, has revolutionized the creation of three-dimensional solid models. This technique, which has seen global advancement since 1995, enables the layer-by-layer production of physical models directly from computer-aided designs in a single step. Unlike traditional computer-assisted design (CAD)-computer-aided manufacturing (CAM) systems that involve material removal, rapid prototype techniques employ technologies like lasers and numerical control to build models layer by layer, facilitating the creation of intricate internal details and smooth surfaces, even in complex structures. Various rapid prototype techniques, including stereolithography (SLA), laminated object manufacturing, selective laser sintering, fused deposition modeling, and three-dimensional printing, offer diverse options for model production. These techniques utilize different materials and layering methods but can be combined to achieve desired outcomes, making them highly versatile and adaptable to specific requirements. Rapid prototype production techniques present a viable alternative to conventional methods for constructing facial prostheses. By utilizing computer-aided imaging techniques such as computed tomography (CT), magnetic resonance imaging (MRI), and laser surface scanners, highly accurate extraoral facial prostheses can be crafted using CAD-CAM and RP technologies. These advanced techniques ensure excellent contours and tissue adaptation, resulting in prostheses that seamlessly integrate with the patient's facial features and enhance their overall appearance. While conventional gypsum models are typically used for prosthetic rehabilitation of intraoral deformities like maxillectomy defects, the integration of 3D CAD and RP technologies can significantly enhance outcomes. A crucial aspect of creating a functional and aesthetically pleasing prosthesis lies in obtaining an accurate impression of the defect site. However, this process is often complicated by various factors, such as the properties of the impression material, the size and nature of the defect, the presence of undercuts, and the condition of remaining teeth, all of which influence the accuracy of the impression. Additionally, challenges like pain, tears, and deformations during impression removal, as well as bleeding and mucosal adhesion, further complicate the process. Limitations in mouth opening may also hinder the optimal insertion of the impression materials, further emphasizing the need for advanced techniques and materials. ;