Raúl Sampietro-Martínez1, Javier Pérez-Monreal2, Alba Sánchez-Torres3, Javier Bara-Casaus4, Cosme Gay-Escoda5. 1. DDS. MS. Master Degree Program in Oral Surgery and Orofacial Implantology (EFHRE International University/FUCSO). 2. MD, MSc, PhD, EBPh. Director of the Department of Vascular Doppler Ultrasound, MAZ Hospital. Zaragoza, Spain. Associate Professor of the Master Degree Program in Phlebology and Lymphology, University of Alcala. Madrid, Spain. 3. DDS, MS. Master of Oral Surgery and Orofacial Implantology. Associate Professor of the Oral Surgery Department, School of Dentistry, University of Barcelona, Spain. 4. MD, PhD, OMFS. Director of the Maxillofacial Institute of Sagrat Cor University Hospital, Barcelona, Spain. Co-Director of the Specialist Course in TMJ and Orofacial Pain, University of Barcelona. Director of the Postgraduate Course in Oral Medicine and Surgery of the Catalan Society of Odontology and Stomatology. 5. MD, DDS, MS, PhD, EBOS, OMFS. Chairman and Professor of the Oral and Maxillofacial Surgery Department, School of Dentistry, Uni¬versity of Barcelona. Director of the Master Degree Program in Oral Surgery and Implantology (EFHRE International University / FUCSO). Coordinator/Researcher of the IDIBELL Institute. Head of the Oral and Maxillofacial Surgery and Implantology Department, Teknon Medical Center, Barcelona, Spain.
Abstract
Background: The primary objective of this study was to determine the position and course of the greater palatine artery using color doppler ultrasound. The secondary objective was to determine the thickness of the palatine fibromucosa. Material and Methods: A pilot case series study was performed in a private clinic during February 2020. The scans were performed with a Mindray® M9 ultrasound machine (Mindray North America, NJ, USA) coupled to an L16-4Hs® hockey-type angled probe. For each participant, the arterial path and thickness of the palatal fibromucosa were determined at 5 different points. Results: A total of 6 volunteers (3 males and 3 females) with a mean age of 39.2 (±16) years were included. While the thickness of the fibromucosa decreased along the anterior area, the distance from the cementoenamel junction to the position of the artery was generally maintained up to the canine position, where it was found to be closed to teeth. Conclusions: Color doppler ultrasound allows accurate localization of the artery as well as measurement of the thickness of the palatine fibromucosa. It would help to select the best area for graft harvesting in order to avoid bleeding complications due to vascular sectioning. Key words:Hard palate, doppler ultrasonography, diagnosis, connective tissue graft. Copyright:
Background: The primary objective of this study was to determine the position and course of the greater palatine artery using color doppler ultrasound. The secondary objective was to determine the thickness of the palatine fibromucosa. Material and Methods: A pilot case series study was performed in a private clinic during February 2020. The scans were performed with a Mindray® M9 ultrasound machine (Mindray North America, NJ, USA) coupled to an L16-4Hs® hockey-type angled probe. For each participant, the arterial path and thickness of the palatal fibromucosa were determined at 5 different points. Results: A total of 6 volunteers (3 males and 3 females) with a mean age of 39.2 (±16) years were included. While the thickness of the fibromucosa decreased along the anterior area, the distance from the cementoenamel junction to the position of the artery was generally maintained up to the canine position, where it was found to be closed to teeth. Conclusions: Color doppler ultrasound allows accurate localization of the artery as well as measurement of the thickness of the palatine fibromucosa. It would help to select the best area for graft harvesting in order to avoid bleeding complications due to vascular sectioning. Key words:Hard palate, doppler ultrasonography, diagnosis, connective tissue graft. Copyright: