Comparison of the Results of Biostimulation Treatment of Inferior Alveolar Nerve Injury Using Nd:YAG and Diode Lasers With Different Wavelengths.
NCT07416006 · Status: COMPLETED · Phase: NA · Type: INTERVENTIONAL · Enrollment: 30
Last updated 2026-02-17
Summary
Intraoral surgical procedures such as sagittal split osteotomy, dental implant placement, and surgical extraction of third molars are widely performed interventions in oral and maxillofacial surgery. Although these operations are generally safe and predictable, they may cause direct or indirect injury to the inferior alveolar nerve, one of the main sensory nerves of the mandible responsible for the innervation of the lower teeth, alveolar bone, gingiva, lower lip, and chin. Damage to this nerve can occur due to mechanical trauma, compression, thermal injury, or stretching during surgery, as well as following facial or mandibular trauma. As a consequence, patients may experience various neurosensory disturbances such as anesthesia, hypoesthesia, paresthesia, or dysesthesia. These conditions often result in discomfort, reduced functional capacity, and psychological distress, affecting both esthetic and functional expectations after surgical recovery. Restoring normal nerve function in such cases remains a major clinical challenge in oral surgery and neuromodulation research.
The inferior alveolar nerve follows a delicate anatomical path through the mandibular canal, where it is easily affected by surgical manipulations. Even minor trauma may lead to transient or permanent sensory dysfunction. The pathophysiology of such nerve injuries involves axonal degeneration, demyelination, and subsequent alterations in nerve conduction. Depending on the severity, nerve regeneration may occur spontaneously or may require therapeutic intervention. The degree of recovery depends on the extent of axonal disruption, the inflammatory response in the surrounding tissue, and the capacity of Schwann cells to facilitate remyelination. Traditional treatment approaches for inferior alveolar nerve injury include observation, pharmacological support, surgical decompression, or microsurgical repair. However, outcomes of these methods are often unpredictable, and recovery is slow. Therefore, noninvasive therapeutic modalities that can enhance neuronal healing and accelerate sensory recovery have become an area of increasing interest in modern dentistry and maxillofacial surgery.
Among these, the use of laser biostimulation-also known as low-level laser therapy or photobiomodulation-has gained significant attention as a noninvasive, safe, and clinically applicable method to promote nerve regeneration. Laser biostimulation involves the application of light energy at specific wavelengths to biological tissues, leading to a cascade of photochemical and photophysical effects at the cellular level. When absorbed by mitochondrial chromophores, particularly cytochrome c oxidase, the photons increase cellular metabolism, enhance ATP synthesis, stimulate DNA and RNA synthesis, and promote cellular proliferation and differentiation. In neural tissues, this process can lead to activation of Schwann cells, enhancement of neurotrophic factor secretion, reduction of oxidative stress, and modulation of inflammatory mediators, thereby creating a favorable microenvironment for axonal regrowth. Consequently, photobiomodulation represents an advanced therapeutic approach to accelerate neural healing following both iatrogenic and traumatic nerve injuries.
Two of the most commonly used laser types for biostimulation in clinical practice are diode and Nd:YAG lasers. Both operate in the near-infrared region of the electromagnetic spectrum but differ in wavelength, absorption characteristics, and depth of tissue penetration. The diode laser emits light typically between 800 and 1000 nanometers, with the 980-nanometer wavelength being one of the most widely used in dentistry. Its energy is well absorbed by melanin and hemoglobin, making it particularly effective in soft-tissue applications, wound healing, pain modulation, and superficial tissue regeneration. The Nd:YAG laser, operating at 1064 nanometers, has a longer wavelength that allows deeper tissue penetration. It is less absorbed by superficial pigments and more effective in reaching submucosal, muscular, and neural tissues. The differences in penetration depth and absorption profiles mean that while diode lasers are efficient for surface-level biostimulation, Nd:YAG lasers are more suited for stimulating deeper anatomical structures such as nerves and bone.
Conditions
- Inferior Alveolar Nerve Injury
- Neurosensory Disturbance
- Paresthesia and Hypoesthesia
- Nerve Regeneration
- Photobiomodulation Therapy
- Nd:YAG Laser Biostimulation
- Diode Laser Therapy
- Post-Surgical Nerve Recovery
- Oral and Maxillofacial Surgery Complications
Interventions
- DEVICE
-
Nd:YAG Laser Biostimulation
Low-level Nd:YAG laser biostimulation applied at 1064 nm wavelength, 0.5 W power, 10 Hz frequency. Treatment performed intraorally and extraorally over the course of the inferior alveolar nerve twice per week for three weeks. Each session lasted approximately two minutes.
- DEVICE
-
Diode Laser Biostimulation
Low-level Diode laser biostimulation applied at 980 nm wavelength, 200 mW power, 10 Hz frequency, and 2 J energy per session. Treatment performed intraorally and extraorally twice per week for three weeks over the injured mandibular nerve area. Each session lasted approximately two minutes.
Sponsors & Collaborators
-
Ondokuz Mayıs University
lead OTHER
Study Design
- Allocation
- RANDOMIZED
- Purpose
- SUPPORTIVE_CARE
- Masking
- SINGLE
- Model
- PARALLEL
Eligibility
- Min Age
- 18 Years
- Sex
- ALL
- Healthy Volunteers
- Yes
Timeline & Regulatory
- Start
- 2024-10-27
- Primary Completion
- 2025-10-27
- Completion
- 2025-10-27
Countries
- Turkey (Türkiye)
Study Locations
More Related Trials
-
Influence of Mandibular Nerve Lateralization on Nutrition and Speech
NCT05659069 ·Status: ACTIVE_NOT_RECRUITING
-
Evaluation of Dental Anxiety in Second-Stage Implant Surgery With Er,Cr:YSGG Laser
NCT03871101 ·Status: COMPLETED ·Phase: NA
-
Evaluation of Healing Process After Laser Asissted Gingivectomy Techniques
NCT04304391 ·Status: COMPLETED ·Phase: NA
-
Clinical Efficacy Of 810 Nanometer Diode Laser As An Adjunct To Mechanical Periodontal Treatment Of Residual Periodontal Pockets
NCT02531555 ·Status: COMPLETED ·Phase: NA
-
Neurosensory Deficit of Inferior Alveolar Nerve Following Mandibular Orthognathic Surgery.
NCT03995511 ·Status: COMPLETED ·Phase: NA
-
Evaluation of the Effects of the Low-level Laser Therapy as an Adjunct to Nonsurgical Treatment in Patients With Periimplantitis
NCT07128134 ·Status: NOT_YET_RECRUITING ·Phase: NA
-
Temperature and Healing in Treatment of Gingival Enlargement
NCT04016064 ·Status: COMPLETED ·Phase: NA
-
The Effect of Music and White Noise on Patients' Anxiety and Pain During Surgery for Impacted Mandibular Third Molar
NCT06814366 ·Status: COMPLETED ·Phase: NA
-
The Effect of Different Adhesion Strategies on the Clinical Success
NCT06500546 ·Status: NOT_YET_RECRUITING ·Phase: NA
-
Evaluation of the Success of TheraCal PT in Pulpotomy Treatment of Primary Teeth Using Low-Level Laser Therapy
NCT07276685 ·Status: COMPLETED ·Phase: NA
-
Maxillary Labial Frenectomy: Diode Lasers Versus Surgical Scalpel
NCT06548516 ·Status: RECRUITING ·Phase: NA
-
The Effects of Guided Imagery on Postoperative Pain Management
NCT04610151 ·Status: COMPLETED ·Phase: NA
-
Impact of Mandibular Canal Trajectory on Paresthesia After Inferior Alveolar Nerve Lateralization
NCT05811741 ·Status: COMPLETED
-
The Effect of Implant-supported Prosthesis on Acoustic Voice Quality
NCT05692609 ·Status: RECRUITING
-
Effects of Low Medial Ramus Osteotomy on Neurosensorial Recovery During Post-Operative Period
NCT06662331 ·Status: COMPLETED ·Phase: NA
-
Retrospective Frenectomy Analysis: Techniques and Adjunctive Antimicrobials
NCT07054021 ·Status: COMPLETED
-
Photobiomodulation Effects on Pain, Edema, Paresthesia and Bone Regeneration After Maxillar Surgical Disjunction
NCT03814525 ·Status: UNKNOWN ·Phase: PHASE2
-
Effect of Augmented Reality on Dental Anxiety and Pain Perception in Children
NCT06530654 ·Status: COMPLETED ·Phase: NA
-
Effect of AI-Supported Child-Friendly Communication on Dental Anxiety in Pediatric Patients
NCT07133919 ·Status: RECRUITING ·Phase: NA
-
Should Preoperative Information Before Impacted Third Molar Extraction?
NCT05548790 ·Status: COMPLETED ·Phase: NA
-
Minimally Invasive Sagittal Split Ramus Osteotomy
NCT07118605 ·Status: COMPLETED ·Phase: NA
-
Effect of Er:YAG Laser on Hydrophilic Sealants
NCT03718689 ·Status: COMPLETED ·Phase: NA
-
Efficacy of Er,Cr:YSGG Laser in Partial Pupotomy
NCT04010929 ·Status: COMPLETED ·Phase: NA
-
Evaluation of Bite Force, Quality of Life, and Patients' Satisfaction
NCT05565261 ·Status: COMPLETED
-
Evaluation of the Color Change of the Laser and Chemical Vital Whitening Method in the Teeth
NCT04305483 ·Status: COMPLETED ·Phase: NA