Conventional Endodontic microsurgery takes use of a preoperative scan and manual drilling of the osteotomy site with arbitrary measurements followed by retropreparation and forming the apical seal. One of the most critical disadvantages of conventional root-end resection include the damage to anatomically vital structures such as inferior dental nerve, mental nerve, adjacent root and maxillary sinus. In contrast, endodontic microsurgery using the guide template significantly reduces these damages. Pinsky et al confirmed in their in vitro study that the greater accuracyand consistency was achieved during endodontic surgery with surgical guidance without damaging vital structures. An error greater than 3 mm occurred over 22% of the time with freehand whereas none of errors occurred with surgical guidance.
Consequently, targeted endodontic microsurgery has garnered increasing attention as a viable alternative, offering a refined and precise approach to address such challenges.
Even the most skilled surgeons may find endodontic microsurgery difficult. Some medical professionals steer clear using freehand (FH) Endodontic microsurgery in regions where there is a chance of harming important anatomical features including the maxillary sinus, the mental foramen, and arteries. It is Perceived as complex sites include those with limited access, no direct sight, and areas where the apex is placed distant from the buccal cortical bone without any cortical plate fenestratio. Surgeons may be able to perform precise procedures in difficult-to-reach regions with guided Endodontic Microsurgery
Guided Endodontic Microsurgery is virtually planned on 3D software on the preoperative CBCT scan, and the surgeon executes the osteotomy and root-end resection (RER) under static or dynamic navigation.
Static navigation requires a customized 3D-printed surgical guide (3D-SG) to guide the drilling duringosteotomy and RER. Surgical guides contain a guide template that refers to the 3D location of the virtual Endodontic Microsurgery planned in the CBCT to drill accurately Prior research has demonstrated that 3D-SG can reduce the risk of intra-operative complications whileincreasing the precision and effectiveness of EMS. In comparison to free hand Endodontic Microsurgery, guided Endodontic Microsurgery with 3D-Surgical Guide shortens the surgical time, provides superior control over the resection level and bevel off the root, and enables a tailored osteotomy size.
Trephine burs have been used for the removal of failed implants and autogenous bone graft harvesting but have not previously been described in Endodontic Microsurgery .
Targeted Endodontic Microsurgery produces a single-step osteotomy; root-end resection; and biopsy with a defined perforation site, angulation, depth, and diameter. Previous reports have used 3D Surgical Guides to locate an ideal bone perforation site, but none have used trephine burs within a stent to define all parameters of osteotomy and root-end resection.
Also, no clinical study assessing the targeted approach of endodontic microsurgery with Oral health related quality of life has been done. Some of the RCT's are conducted assessing quality of life in patients after conventional periapical surgery, only two retrospective studies considering .Targeted Endodontic Microsurgery have been done and a lack of RCTs comparing targeted Endodontic Microsurgery with conventionalEMS warrants further research.
The aim of this study is to compare the effect of a static computer-aided surgical technique using a 3D- printed guide with a fully guided drill protocol on Oral Health Related Quality of Life against the conventional endodontic microsurgery in mandibular molars.
