Anatomical consideration of ultrasonography-guided intraoral injection for temporal tendinitis.
Soo-Bin KimHyungkyu BaeKyung-Seok HuKyung-Seok HuShin-Ichi AbeHee-Jin KimPublished in: Clinical anatomy (New York, N.Y.) (2023)
Temporal tendinitis is characterized by acute inflammation often resulting from mechanical stress, such as repetitive jaw movements associated with jaw opening and closing and teeth clenching. Treatment for temporal tendinitis typically involves the administration of local anesthetic or corticosteroid injections. However, the complex anatomical structure of the coronoid process, to which the temporalis tendon attaches, located deep within the zygomatic arch, poses challenges for accurate injections. In this study, we aimed to establish guidelines for the safe and effective treatment of temporal tendinitis by using intraoral ultrasonography (US) to identify the anatomical structures surrounding the temporalis tendon and coronoid process. US was performed using an intraoral transducer on 58 volunteers without temporomandibular joint disease. The procedure involved placing the transducer below the occlusal plane of the maxillary second molar. Measurements were taken for the horizontal distance from the anterior border of the coronoid process, observed at the midpoint (MP) of the US images, and the depth of the coronoid process and temporalis muscle from the oral mucosa. The anterior border of the coronoid process was visualized on all US images and classified into three observed patterns at the MP: type A (anterior to the MP, 56.2%), type B (at the MP, 16.1%), and type C (posterior to the MP, 27.7%). The temporalis muscle was located at a mean depth of 3.12 ± 0.68 mm from the oral mucosa. The maxillary second molar is an intraoral landmark for visualizing the anterior border of the coronoid process. The new location information obtained using intraoral US could help identify the safest and most effective injection sites for the treatment of temporal tendinitis.
Keyphrases
- magnetic resonance imaging
- ultrasound guided
- skeletal muscle
- deep learning
- computed tomography
- high resolution
- liver failure
- contrast enhanced
- mass spectrometry
- convolutional neural network
- clinical practice
- minimally invasive
- hepatitis b virus
- magnetic resonance
- combination therapy
- machine learning
- stress induced
- cone beam computed tomography
- replacement therapy