Rotatory and reciprocating devices are most frequently used but have disadvantages, such as noise, vibration, and the potential for inducing thermal damage. Many patients are reluctant to be subjected to the use of an osteotome and mallet while awake, especially if repeated blows are required to separate the torus or exostosis from the bone. As a result of these factors, most patients who present with mandibular tori postpone and even avoid clinical treatment. Interest is growing in using alternatives to rotatory and manual instruments for osteotomies in oral and maxillofacial surgical procedures. Laser excision has better patient acceptance compared to conventional technique in removal of mandibular tori. Currently, there are few reports regarding the use of lasers in bone surgery and little is known about the effectiveness for bone ablation or the healing characteristics of the laser-irradiated bone tissue compared with conventional rotary instrumentation. The intention of this case report is to demonstrate the Er,Cr:YSGG laser use in a clinical setting for the atraumatic and effective excision of the mandibular lingual tori.

Currently, there are few reports regarding the use of lasers in bone surgery. The intention of this case report is to demonstrate the Er,Cr:YSGG laser use in a clinical setting for the atraumatic and effective excision of the mandibular lingual tori. The removal of the tori with the Er,Cr:YSGG laser device was done with the settings of 3.5 W, 40% water, 20% air and 20 Hz. Lasers have clinical advantages such as bacterial reduction at the surgical sites and increased comfort levels. The surgical field is cleaner, with less blood to obscure the surgeon’s field of vision. Laser technology has certain advantages, such as accuracy of the incision and absence of vibration and manual pressure during use.

The surgical procedure was planned by Implant placement and excision of tori in the same sitting. After aseptic preparation the area local anesthesia was administered, crestal incision (Fig 1) was given and torus was exposed with careful elevation of mucoperiosteum using periosteal elevator (Fig 2). To begin the sectioning and removal of the tori with the Er,Cr:YSGG laser device, the settings were adjusted to 3.5 W, 40% water, 20% air, and 20 Hz. Excision of tori was carried out using Er,Cr:YSGG laser, mz 6 tip at the base of the lesion ( Fig 3) with
approximately 1.0 mm from the tissue while sectioning the tori. Fig 4 showing excised torus. Implants were placed in 34, 36 and 37 region. Sutures were placed (Fig 5). After the procedure, the surgical site exhibited no edema, minimal bleeding, and no other adverse effects from the laser surgery. Postoperative instructions included: soft diet, salt water rinses and a prescription of paracetamol 500 mg thrice daily for three days. Patient was recalled for checkup on first post operative day and there was no swelling in the region. Post operative phase was uneventful and suture removal was done after 7 days. The patient was recalled again at 2 weeks and the healing appeared clinically complete.

Conclusion
Lasers have clinical advantages such as bacterial reduction at the surgical sites and increased comfort levels. Laser in surgical removal of exostosis appears to be justified on the grounds of reduced surgical time with more efficient cutting compared to micromotor and much better acceptance by the patients.