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References

Barolet D. Light-emitting diodes (LEDs) in dermatology. Semin Cutan Med Surg. 2008; 27:227-238
Huang YY, Chen AC, Carroll JD, Hamblin MR. Biphasic dose response in low level light therapy. Dose Response. 2009; 7:358-383
Huang YY, Sharma SK, Carroll J, Hamblin MR. Biphasic dose response in low level light therapy – an update. Dose Response. 2011; 9:602-618
Roelandts R. A new light on Niels Finsen, a century after his Nobel Prize. Photodermatol Photoimmunol Photomed. 2005; 21:115-117
AlGhamdi KM, Kumar A, Moussa NA. Low-level laser therapy: a useful technique for enhancing the proliferation of various cultured cells. Lasers Med Sci. 2012; 27:237-249
Kim WS, Calderhead RG. Is light-emitting diode phototherapy (LED-LLLT) really effective?. Laser Ther. 2011; 20:205-215
Chow R, Armati P, Laakso EL, Bjordal JM, Baxter GD. Inhibitory effects of laser irradiation on peripheral mammalian nerves and relevance to analgesic effects: a systematic review. Photomed Laser Surg. 2011; 29:365-381
Holder MJ, Milward MR, Palin WM, Hadis MA, Cooper PR. Effects of red light-emitting diode irradiation on dental pulp cells. J Dent Res. 2012; 91:961-966
Sun G, Tunér J. Low-level laser therapy in dentistry. Dent Clin North Am. 2004; 48:1061-1076
Parker S. Low-level laser use in dentistry. Br Dent J. 2007; 202:131-138
Gursoy H, Ozcakir-Tomruk C, Tanalp J, Yilmaz S. Photodynamic therapy in dentistry: a literature review. Clin Oral Investig. 2013; 17:1113-1125
de Paula Eduardo C, de Freitas PM, Esteves-Oliveira M, Aranha AC, Ramalho KM, Simões A, Bello-Silva MS, Tunér J. Laser phototherapy in the treatment of periodontal disease. A review. Lasers Med Sci. 2010; 25:781-792
Gerschman JA, Ruben J, Gebart-Eaglemont J. Low level laser therapy for dentinal tooth hypersensitivity. Aust Dental J. 1994; 39:353-357
Orhan K, Aksoy U, Can-Karabulut DC, Kalender A. Low-level laser therapy of dentin hypersensitivity: a short-term clinical trial. Lasers Med Sci. 2011; 26:591-598
Flecha OD, Azevedo CG, Matos FR, Vieira-Barbosa NM, Ramos-Jorge ML, Gonçalves PF, Koga Silva EM. Cyanoacrylate versus laser in the treatment of dentin hypersensitivity: a controlled, randomized, double-blind and non-inferiority clinical trial. J Periodontol. 2013; 84:287-294
Kreisler MB, Haj HA, Noroozi N, Willershausen Bd. Efficacy of low level laser therapy in reducing postoperative pain after endodontic surgery – a randomized double blind clinical study. Int J Oral Maxillofac Surg. 2004; 33:38-41
Tanboga I, Eren F, Altinok B, Peker S, Ertugral F. The effect of low level laser therapy on pain during dental tooth-cavity preparation in children. Eur Arch Paediatr Dent. 2011; 12:93-95
Shigetani Y, Sasa N, Suzuki H, Okiji T, Ohshima H. GaAlAs laser irradiation induces active tertiary dentin formation after pulpal apoptosis and cell proliferation in rat molars. J Endod. 2011; 37:1086-1091
Matsui S, Tsujimoto Y, Matsushima K. Stimulatory effects of hydroxyl radical generation by Ga-Al-As laser irradiation on mineralization ability of human dental pulp cells. Biol Pharm Bull. 2007; 30:27-31
Igic M, Mihailovic D, Kesic L, Milasin J, Apostolovic M, Kostadinovic L, Janjic OT. Cytomorphometric and clinical investigation of the gingiva before and after low-level laser therapy of gingivitis in children. Lasers Med Sci. 2012; 27:843-848
Mârţu S, Amălinei C, Tatarciuc M, Rotaru M, Potârnichie O, Liliac L, Căruntu ID. Healing process and laser therapy in the superficial periodontium: a histological study. Rom J Morphol Embryol. 2012; 53:111-116
Igic M, Kesic L, Lekovic V, Apostolovic M, Mihailovic D, Kostadinovic L, Milasin J. Chronic gingivitis: the prevalence of periodontopathogens and therapy efficiency. Eur J Clin Microbiol Infect Dis. 2012; 31:1911-1915
Makhlouf M, Dahaba MM, Tunér J, Eissa SA, Harhash TA. Effect of adjunctive low level laser therapy (LLLT) on nonsurgical treatment of chronic periodontitis. Photomed Laser Surg. 2012; 30:160-166
Obradović R, Kesić L, Mihailović D, Antić S, Jovanović G, Petrović A, Peševska S. A histological evaluation of a low-level laser therapy as an adjunct to periodontal therapy in patients with diabetes mellitus. Lasers Med Sci. 2013; 28:19-24
Calderín S, García-Núñez JA, Gómez C. Short-term clinical and osteoimmunological effects of scaling and root planing complemented by simple or repeated laser phototherapy in chronic periodontitis. Lasers Med Sci. 2013; 28:157-166
Ozawa Y, Shimizu N, Abiko Y. Low-energy diode laser irradiation reduced plasminogen activator activity in human periodontal ligament cells. Lasers Surg Med. 1997; 21:456-463
Khadra M, Rønold HJ, Lyngstadaas SP, Ellingsen JE, Haanaes HR. Low-level laser therapy stimulates bone-implant interaction: an experimental study in rabbits. Clin Oral Implants Res. 2004; 15:325-326
Boldrini C, de Almeida JM, Fernandes LA, Ribeiro FS, Garcia VG, Theodoro LH, Pontes AE. Biomechanical effect of one session of low-level laser on the bone-titanium implant interface. Lasers Med Sci. 2013; 28:349-352
Omasa S, Motoyoshi M, Arai Y, Ejima K, Shimizu N. Low-level laser therapy enhances the stability of orthodontic mini-implants via bone formation related to BMP-2 expression in a rat model. Photomed Laser Surg. 2012; 30:255-261
Naka T, Yokose S. Application of laser-induced bone therapy by carbon dioxide laser irradiation in implant therapy. Int J Dent. 2012; 2012:409-496
Yang HW, Huang YF. Treatment of burning mouth syndrome with a low-level energy diode laser. Photomed Laser Surg. 2011; 29:123-125
Kato IT, Pellegrini VD, Prates RA, Ribeiro MS, Wetter NU, Sugaya NN. Low-level laser therapy in burning mouth syndrome patients: a pilot study. Photomed Laser Surg. 2010; 28:835-839
dos Santos Lde F, Carvalho Ade A, Leão JC, Cruz Perez DE, Castro JF. Effect of low-level laser therapy in the treatment of burning mouth syndrome: a case series. Photomed Laser Surg. 2011; 29:793-796
Muñoz Sanchez PJ, Capote Femenías JL, Díaz Tejeda A, Tunér J. The effect of 670-nm low laser therapy on herpes simplex type 1. Photomed Laser Surg. 2012; 30:37-40
Schindl A, Neumann R. Low-intensity laser therapy is an effective treatment for recurrent herpes simplex infection. Results from a randomized double-blind placebo-controlled study. J Invest Dermatol. 1999; 113:221-223
de Carvalho RR, de Paula Eduardo F, Ramalho KM, Antunes JL, Bezinelli LM, de Magalhães MH. Effect of laser phototherapy on recurring herpes labialis prevention: an in vivo study. Lasers Med Sci. 2010; 25:397-402
Jajarm HH, Falaki F, Mahdavi O. A comparative pilot study of low intensity laser versus topical corticosteroids in the treatment of erosive-atrophic oral lichen planus. Photomed Laser Surg. 2011; 29:421-425
Agha-Hosseini F, Moslemi E, Mirzaii-Dizgah I. Comparative evaluation of low-level laser and CO(2) laser in treatment of patients with oral lichen planus. Int J Oral Maxillofac Surg. 2012; 41:1265-1269
Cafaro A, Albanese G, Arduino PG, Mario C, Massolini G, Mozzati M, Broccoletti R. Effect of low-level laser irradiation on unresponsive oral lichen planus: early preliminary results in 13 patients. Photomed Laser Surg. 2010; 28:S99-103
Bjordal JM, Bensadoun RJ, Tunèr J, Frigo L, Gjerde K, Lopes-Martins RA. A systematic review with meta-analysis of the effect of low-level laser therapy (LLLT) in cancer therapy-induced oral mucositis. Support Care Cancer. 2011; 19:1069-1077
Gautam AP, Fernandes DJ, Vidyasagar MS, Maiya AG, Vadhiraja BM. Low level laser therapy for concurrent chemoradiotherapy induced oral mucositis in head and neck cancer patients – a triple blinded randomized controlled trial. Radiother Oncol. 2012; 104:349-354
Bensadoun RJ, Nair RG. Low-level laser therapy in the prevention and treatment of cancer therapy-induced mucositis: 2012 state of the art based on literature review and meta-analysis. Curr Opin Oncol. 2012; 24:363-370
Lončar B, Stipetić MM, Baričević M, Risović D. The effect of low-level laser therapy on salivary glands in patients with xerostomia. Photomed Laser Surg. 2011; 29:171-175
Vidović Juras D, Lukac J, Cekić-Arambasin A, Vidović A, Canjuga I, Sikora M Effects of low-level laser treatment on mouth dryness. Coll Antropol. 2010; 34:1039-1043
Pavlic V. The effects of low-level laser therapy on xerostomia (mouth dryness). Med Pregl. 2012; 65:247-250
Maver-Biscanin M, Mravak-Stipetic M, Jerolimov V. Effect of low-level laser therapy on candida albicans growth in patients with denture stomatitis. Photomed Laser Surg. 2005; 23:328-332
Maver-Biscanin M, Mravak-Stipetic M, Jerolimov V, Biscanin A. Fungicidal effect of diode laser irradiation in patients with denture stomatitis. Lasers Surg Med. 2004; 35:259-262
Simunović-Soskić M, Pezelj-Ribarić S, Brumini G, Glazar I, Grzić R, Miletić I. Salivary levels of TNF-alpha and IL-6 in patients with denture stomatitis before and after laser phototherapy. Photomed Laser Surg. 2010; 28:189-193
Igic M, Mihailovic D, Kesic L, Milasin J, Apostolovic M, Kostadinovic L, Janjic OT. Cytomorphometric and clinical investigation of the gingiva before and after low-level laser therapy of gingivitis in children. Lasers Med Sci. 2012; 27:843-848
Pejcic A, Kojovic D, Kesic L, Obradovic R. The effects of low level laser irradiation on gingival inflammation. Photomed Laser Surg. 2010; 28:69-74
Amorim JC, de Sousa GR, de Barros Silveira L, Prates RA, Pinotti M, Ribeiro MS. Clinical study of the gingiva healing after gingivectomy and low-level laser therapy. Photomed Laser Surg. 2006; 24:588-594
Ozen T, Orhan K, Gorur I, Ozturk A. Efficacy of low level laser therapy on neurosensory recovery after injury to the inferior alveolar nerve. Head Face Med. 2006; 2
Khullar SM, Brodin P, Barkvoll P, Haanaes HR. Preliminary study of low-level laser for treatment of long-standing sensory aberrations in the inferior alveolar nerve. J Oral Maxillofac Surg. 1996; 54:7-8
Khullar SM, Emami B, Westermark A, Haanaes HR. Effect of low-level laser treatment on neurosensory deficits subsequent to sagittal split ramus osteotomy. Oral Surg Oral Med Oral Pathol Oral Radiol Endod. 1996; 82:132-138
Markovic AB, Todorovic L. Postoperative analgesia after lower third molar surgery: contribution of the use of long-acting local anesthetics, low-power laser and diclofenac. Oral Surg Oral Med Oral Pathol Oral Radiol Endod. 2006; 102:4-8
Aras MH, Gungormus M. The effect of low-level laser therapy on trismus and facial swelling following surgical extraction of a lower third molar. Photomed Laser Surg. 2009; 27:21-24
Markovic A, Todorovic L. Effectiveness of dexamethasone and low-power laser in minimizing oedema after third molar surgery: a clinical trial. Int J Oral Maxillofac Surg. 2007; 36:226-229
Salmos-Brito JA, de Menezes RF, Teixeira CE, Gonzaga RK, Rodrigues BH, Braz R Evaluation of low-level laser therapy in patients with acute and chronic temporomandibular disorders. Lasers Med Sci. 2013; 28:57-64
Marini I, Gatto MR, Bonetti GA. Effects of superpulsed low-level laser therapy on temporomandibular joint pain. Clin J Pain. 2010; 26:611-616
Mazzetto MO, Hotta TH, Pizzo RC. Measurements of jaw movements and TMJ pain intensity in patients treated with GaAlAs laser. Braz Dent J. 2010; 21:356-360
Rochkind S, Kogan G, Luger EG, Salame K, Karp E, Graif M, Weiss J. Molecular structure of the bony tissue after experimental trauma to the mandibular region followed by laser therapy. Photomed Laser Surg. 2004; 22:249-253
Scoletta M, Arduino PG, Reggio L, Dalmasso P, Mozzati M. Effect of low-level laser irradiation on bisphosphonate-induced osteonecrosis of the jaws: preliminary results of a prospective study. Photomed Laser Surg. 2010; 28:179-184
Vescovi P, Manfredi M, Merigo E, Guidotti R, Meleti M, Pedrazzi G Early surgical laser-assisted management of bisphosphonate-related osteonecrosis of the jaws (BRONJ): a retrospective analysis of 101 treated sites with long-term follow-up. Photomed Laser Surg. 2012; 30:5-13
Vescovi P, Merigo E, Meleti M, Manfredi M, Fornaini C, Nammour S. Surgical approach and laser applications in BRONJ osteoporotic and cancer patients. J Osteoporos. 2012; 2012
Miloro M, Miller JJ, Stoner JA. Low-level laser effect on mandibular distraction osteogenesis. J Oral Maxillofac Surg. 2007; 65:168-176
Abtahi M, Poosti M, Saghravanian N, Sadeghi K, Shafaee H. The effect of low level laser on condylar growth during mandibular advancement in rabbits. Head Face Med. 2012; 8
Freddo AL, Hübler R, de Castro-Beck CA, Heitz C, de Oliveira MG. A preliminary study of hardness and modulus of elasticity in sheep mandibles submitted to distraction osteogenesis and low-level laser therapy. Med Oral Patol Oral Cir Bucal. 2012; 17:e102-e107
Kim SJ, Kang YG, Park JH, Kim EC, Park YG. Effects of low-intensity laser therapy on periodontal tissue remodeling during relapse and retention of orthodontically moved teeth. Lasers Med Sci. 2013; 28:325-333
Genc G, Kocadereli I, Tasar F, Kilinc K, El S, Sarkarati B. Effect of low-level laser therapy (LLLT) on orthodontic tooth movement. Lasers Med Sci. 2013; 28:41-47
Doshi-Mehta G, Bhad-Patil WA. Efficacy of low-intensity laser therapy in reducing treatment time and orthodontic pain: a clinical investigation. Am J Orthod Dentofacial Orthop. 2012; 141:289-297
Artes-Ribas M, Arnabat-Dominguez J, Puigdollers A. Analgesic effect of a low-level laser therapy (830 nm) in early orthodontic treatment. Lasers Med Sci. 2013; 28:335-341
Habib FA, Gama SK, Ramalho LM, Cangussú MC, Santos Neto FP, Lacerda JA Laser-induced alveolar bone changes during orthodontic movement: a histological study on rodents. Photomed Laser Surg. 2010; 28:823-830
Menezes S, Coulomb B, Lebreton C, Dubertret L. Non-coherent near infrared radiation protects normal human dermal fibroblasts from solar ultraviolet toxicity. J Invest Dermatol. 1998; 111:629-633
Danno K, Horio T, Imamura S. Infrared radiation suppresses ultraviolet B-induced sunburn-cell formation. Arch Dermatol Res. 1992; 284:92-94
Gao X, Xing D. Molecular mechanisms of cell proliferation induced by low power laser irradiation. J Biomed Sci. 2009; 16
Karu T. Mitochondrial mechanisms of photobiomodulation in context of new data about multiple roles of ATP. Photomed Laser Surg. 2010; 28:159-160
Carroll JD, Milward MR, Cooper PR, Hadis MA, Palin WM. Developments in low level light therapy (LLLT) for dentistry. Dent Materials. 2014; 30:(5)465-475

Low level light therapy (LLLT) for the treatment and management of dental and oral diseases

From Volume 41, Issue 9, November 2014 | Pages 763-772

Authors

Michael R Milward

BDS(Birm), MFGDP(Lond), MFDS RCPS(Glas), FHEA(UK), PhD(Birm)

Senior Lecturer/Honorary Consultant in Periodontology, University of Birmingham, School of Dentistry, St Chad's Queensway, Birmingham

Articles by Michael R Milward

Michelle J Holder

BSc

Research Technician in Oral Biology, University of Birmingham, School of Dentistry, St Chad's Queensway, Birmingham

Articles by Michelle J Holder

William M Palin

BMedSc, MPhil, PhD, FADM

Reader in Biomaterials, University of Birmingham, School of Dentistry, St Chad's Queensway, Birmingham

Articles by William M Palin

Mohammed A Hadis

PhD, BSc

Research Fellow in Biomaterials, University of Birmingham, School of Dentistry, St Chad's Queensway, Birmingham

Articles by Mohammed A Hadis

James D Carroll

Founder/CEO at THOR Photomedicine Ltd, 18A East Street, Chesham, HP5 1HQ

Articles by James D Carroll

Paul R Cooper

BSc, PhD

Professor of Oral Biology, University of Birmingham, School of Dentistry, St Chad's Queensway, Birmingham, B4 6NN, UK

Articles by Paul R Cooper

Abstract

Abstract: Low Level Light (Laser) Therapy (LLLT) is the direct application of light to stimulate cell and tissue responses (photobiomodulation) to promote healing, reduce inflammation and induce analgesia. Studies have demonstrated its application and efficacy for the treatment of a range of injuries and diseases at many sites within the body. However, its application in dentistry and for oral disease treatment has been limited. This review aims to provide background information on LLLT which relates to its current application in medicine, its mechanism of action and delivery parameters, while considering its potential for dental and oral therapeutic applications.

Clinical Relevance: Low level light therapy has the potential to have substantial impact for the treatment and management of oral diseases and pain.

Article

In 1967, Dr Endre Mester at Semmelweis Medical University in Budapest, Hungary, attempted to determine if the newly developed laser (Light Amplification by Stimulated Emission of Radiation) ‘ray of light’ caused cancer. In his studies, he shaved the hair from the backs of mice and subsequently exposed one group of animals to a low-powered ruby laser while the other unexposed group was used as the control. Instead of the treatment group developing cancer, as he had predicted, the hair on the treated mice grew back more rapidly than in the unexposed animals. This effect was subsequently described as ‘laser biostimulation’ and this work has subsequently underpinned thousands of research papers, and generated significant interest from NASA and the US Navy. At present, this field is generally termed Low Level Laser (or Light) Therapy (LLLT), phototherapy or photobiomodulation. The published data currently aims to describe its mechanism of action, the downstream physiological effects and its clinical benefits as demonstrated in both randomized clinical trials and in systematic reviews.1,2,3

The therapeutic effect of light in treating a wide range of diseases has been recognized for many centuries. Indeed, in the early part of the 20th century, exposure to sun and other natural light was commonly used to treat systemic diseases, ranging from dementia and tuberculosis to skin diseases such as lupus vulgaris and acne. More recently, within the last century, UV light therapies have been developed and are used to treat patients suffering from rickets (vitamin D deficiency), neo-natal jaundice, pain and a variety of dermatological disorders.1,4

Unlike many other applications in healthcare, the light or lasers used in LLLT are neither ablating nor do they provide a heat-based therapy, indeed their action is more analogous to photosynthesis in plants in the way that light exerts its effect (cellular and molecular transduction of light are discussed below). Today LLLT utilizes low power lasers or light emitting diodes (LEDs) of less than 500 mW in the red to near infrared (NIR) spectrum (600–1100 nm) (Figure 1), which emit minimal heat to promote tissue healing, reduce inflammation, and relieve pain.5 A large number of animal models and clinical studies have now demonstrated the beneficial healing effects of LLLT in a variety of both chronic and acute diseases and injuries. Recent studies have demonstrated that this non-invasive approach is beneficial in treating diseases of the joints, connective tissue, neuronal tissue, bone, skin, muscle and the vasculature (Figure 2a).1,2

Figure 1. LLLT utilizes low power laser/LED (<500 mW) in the red – NIR spectrum (600 nm–1000 nm) to promote tissue repair, reduce inflammation and relieve pain.
Figure 2. (a) The therapeutic areas and (b) cellular activities which are reportedly increased by LLLT.

Cellular-and tissue-associated therapeutic effects

Anti-inflammatory

The anti-inflammatory action of LLLT most likely occurs due to its ability to regulate the master transcriptional regulator NF-κB, which leads to a reduction in proinflammatory mediator activity. Several studies have shown the ability of LLLT to decrease cytokine levels in a variety of experimental and animal models, as well as human disease situations, indicating its utility in treating chronic and acute inflammatory disorders.6

Analgesia

The mechanism(s) of action which underlie the analgesic effects of LLLT remain unclear, however, evidence indicates that LLLT may have significant neuropharmacological effects relating to the synthesis, release and metabolism of a range of key neurochemicals, such as serotonin, acetylcholine, histamine and prostaglandin. In addition, the effect of LLLT on pain relief may also be explained by the ability to enhance synthesis of endorphins, as well as modulating nociceptor responses via c-fibre activity and bradykinin levels.7

Angiogenesis

Another important tissue process activated by LLLT is its capacity to promote neovascularization and angiogenic events and this may relate to its ability to increase cellular and tissue levels of pro-angiogenic mediators, including growth factors and nitric oxide (NO) (discussed below). These molecules subsequently act to promote endothelial cell and vascular responses via direct and indirect interactions.2,3

Wound repair

Within tissues, studies have shown that LLLT can promote cell growth, viability, cytoprotection, adhesion, migration, differentiation and hard and soft tissue formation (Figure 2b). Notably, these effects have been demonstrated in a range of cell types including stem cells, immune/blood cells, vascular cells, skin cells and many other hard and soft tissue-derived cells.2,3,8

Combined, these tissue and cellular responses promoted by LLLT enable its successful application for disease treatment and wound repair at many sites within the body (Figure 2a).

Use of light energy in dentistry

The application of light is routinely used by dentists, for example, in the curing (photopolymerization) of light-activated, resin-based restorations, caries detection and, more recently, ablative lasers, which have been used for calculus removal, osseous surgery and soft-tissue management.9,10 Current developments have now seen the use of cold diffuse lasers in photo-activated disinfection (PAD) or photodynamic therapy (PDT). This approach utilizes light indirectly to trigger photosensitive dyes to release antibacterial reactive oxygen species, which reduces the microbial load. PDT is now regarded as a useful adjunctive tool for treating infections in oral surgery, endodontics and periodontitis (eg Periowave™).11

The application of LLLT in dentistry is not well documented (in the UK, in particular), compared with many other areas of medicine. However, there now appears to be increased interest and evidence of its utility.8,9,10,12 Indeed, data is now emerging in favour of the therapeutic application of LLLT in a wide range of oral hard and soft tissues areas, covering many key dental specialties, including: endodontics, periodontics, orthodontics, oral medicine and oral surgery (Table 1, Figure 3).


SPECIALTY INDICATION LLLT EFFECT REFERENCES
Conservative Dentistry Dentine hypersensitivity
  • Reduced thermal sensitivity
    		• Gerschman et al, 1994;13Orhan et al, 2011;14Flecha et al, 201315
    Cavity preparation
  • Reduced discomfort
    		• Kreisler et al, 2004;16Tanboga et al, 201117
    Pulp therapy
  • Improved dentine formation
  • Promotion of pulp cell mineralization
    		• Shigetani et al, 2011;18 Matsui et al, 200719
    Periodontal Disease Chronic gingivitis
  • Reduced inflammation
  • Improved healing
    		• Igic et al, 2012;20 Mârţu et al, 2012;21 Igic et al, 201222
    Periodontitis
  • Reduced pocket depth
  • Reduced inflammation
  • Increased healing
    		• Makhlouf et al, 2012;23Obradović et al, 2013;24Calderín et al, 2013;25 Ozawa et al, 199726
    Titanium implants
  • Increased rate of bone formation
  • Improved osseo-integration and bone-implant interface strength
  • Improved healing
    		• Khadra et al, 2004;27 Boldrini et al, 2013;28 Omasa et al, 2012;29 Naka and Yokose, 201230
    Oral Medicine Burning mouth syndrome
  • Reduced symptoms, and reduced pain
    		• Yang and Huang, 2011;31 Kato et al, 2010;32 dos Santos Lde et al, 201133
    Herpes simplex virus
  • Improved healing and reduced re-occurrence of infection
    		• Muñoz Sanchez et al, 2012;34 Schindl and Neumann, 1999;35 de Carvalho et al, 201036
    Lichen planus
  • Reduced lesion size and pain
    		• Jajarm et al, 2011;37 Agha-Hosseini et al, 2012;38 Cafaro et al 201039
    Oral mucositis
  • Reduced incidence, duration and severity
    		• Bjordal et al 2011;40 Gautam et al 2012;41 Bensadoun and Nair, 201242
    Dry mouth
  • Regeneration of salivary duct duct epithelial cell
  • Improved salivary flow and improved antimicrobial characteristics
    		• Lončar et al, 2011;43 Vidović et al, 2010;44 Pavlic, 201245
    Denture stomatitis
  • Reduction in levels of yeast
  • Reduced levels of inflammation
    		• Maver-Biscanin et al 2005;46Maver-Biscanin et al 2004;47Simunović-Soskić et al 201048
    Oral Surgery Post-operative healing
  • Improved healing following gingivectomy
  • Reduced soft tissue inflammation
    		• Igic et al, 2012;49 Pejcic et al, 2010;50 Amorim et al, 200651
    Nerve paraesthesia
  • Improvements in mechanical sensory perception
    		• Ozen et al, 2006;52 Khullar et al, 199653; Khullar et al 199654
    Post third molar extraction
  • Reduced pain, swelling and incidence of trismus
    		• Markovic and Todorovic, 2006;55 Aras and Gungormus, 2009;56 Markovic and Todorovic, 200757
    Temporo-mandibular joint disorder
  • Reduced pain
  • Improved range of mandibular movement
    		• Salmos-Brito et al, 2013;58 Marini et al, 2010;59 Mazzetto et al, 201060
    Post-mandibular fracture
  • Improved bone healing
    		• Rochkind et al, 200461
    Bisphosphonate-related osteonecrosis of the jaw (BRONJ)
  • Reduced pain
  • Reduced oedema, pus and fistulas
  • Improved healing
    		• Scoletta et al, 2010;62 Vescovi et al, 2012;63 Vescovi et al, 201264
    Mandibular distraction
  • Improved bone trabeculation and ossification
  • Improved bone formation in condylar region
  • Improved osteogenesis
    		• Miloro et al, 2007;65 Abtahi et al, 2012;66 Freddo et al, 201267
    Orthodontics Tooth movement
  • Accelerated tooth movement
  • Improved osteoblast/osteoclast activity
  • Improved collagen deposition
    		• Kim et al, 2013;68 Genc et al, 2013;69 Doshi-Mehta and Bhad-Patil, 201270
    Orthodontic treatment-associated pain
  • Reduced pain levels and faster bone remodelling
    		• Artes-Ribas et al, 2013;71 Habib et al, 201072
    Figure 3. Potential application of LLLT for (a) TMJD, (b) soft tissue lesion (eg Herpes labialis), and (c) dentine hypersensitivity.

    In the field of conservative dentistry and endodontics, studies have indicated that LLLT may be efficacious in several areas relating to both pain management and induction of dental tissue repair. While the exact therapeutic mechanisms are not known, dentinal hypersensitivity in response to tactile and thermal stimuli has been shown to be reduced in patients receiving LLLT. Potentially, the therapeutic effects may relate to the analgesic, anti-inflammatory or repair inductive effects following LLLT application. Similarly, LLLT has been shown to reduce discomfort in patients following cavity preparation and this effect may also relate to the induction of cellular protective and analgesic mechanisms in response to restorative placements. Recently, both in our own laboratory studies and work performed in animal models has shown that LLLT can increase pulp cell repair and dental developmental responses, indicating the potential for its clinical application.8

    For periodontal diseases, LLLT has been shown to exert anti-inflammatory effects and decrease tissue swelling in both chronic gingivitis and periodontitis. Subsequently, it has been proposed as a potentially useful adjunctive therapy in conjunction with scaling, root planing, curettage and surgical treatment (Table 1). In addition, it has been demonstrated to exert oral healing effects within both the hard and soft tissues, as is demonstrated by reduced pocket depth and arrested bone loss deterioration in periodontitis patients receiving LLLT. Similarly, following implant placement, enhanced osseo-integration and improved healing within the surrounding hard and soft tissue interfaces has been observed following adjunctive application of LLLT (Table 1).

    In the oral medicine area, a range of different diseases and clinical conditions, generally involving the soft tissues, have been proposed to respond favourably to LLLT (Table 1). These conditions, which occur due to infectious agents, side-effects from other treatments or are of unknown aetiology, potentially benefit mostly from the anti-inflammatory properties of LLLT. In addition, and as a result of arrest of disease and promotion of beneficial cellular responses, enhanced healing is also often evident in many of the disorders treated (Table 1). LLLT application may also benefit several areas of oral surgery, in particular the post-operative healing phases for both the hard and soft tissues (Table 1). Furthermore, the analgesic properties of LLLT may offer clinical benefit in providing relief to the debilitating temporo-mandibular joint disorder (TMJD). While pain relief is likely to be important for TMJD treatment in the short-term (Table 1), it is also likely that the effect of LLLT on muscle function is central to its long-term successful treatment outcome. Interestingly, it is potentially the anti-apoptotic and cellular protective properties activated by LLLT which may provide the clinical benefit in bisphosphonate-related osteonecrosis of the jaw (BRONJ) (Table 1). In fact, LLLT for BRONJ has been shown to arrest the hard and soft tissue loss (Table 1). It is probable that the activation of the cells involved in alveolar bone and/or periodontal ligament remodelling is key to the ability of LLLT to enhance outcomes in mandibular distraction and orthodontic tooth movement. Notably, the safety profile and lack of identifiable side-effects of LLLT (discussed below) make its use appropriate in many areas of paediatric dentistry.

    Molecular signalling in LLLT

    While it has been proposed that cell activation by light is a natural process acquired and preserved through evolution, the exact mechanism by which it works is not yet fully elucidated.73,74 Cells are, however, known to respond to LLLT by increasing their metabolism, viability, mitochondrial activity, growth, movement and other wound healing associated processes (Figure 2b).2 Increases in molecules, such as growth factors, nitric oxide (NO), reactive oxygen species (ROS), ATP, RNA and DNA, have all been detected following light irradiation of cells and tissues.75,76 While imperceptible temperature changes in response to light are acknowledged, the ‘photodissociation theory’ is proposed to explain the body's positive response to LLLT.2 It is proposed that light absorption at appropriate wavelengths by mitochondria results in the production of energy which drives the observed positive cellular responses (Figure 4). The photodissociation theory proposes that light energy is absorbed by, and activates, the mitochondrial enzyme cytochrome C oxidase (COX) which subsequently releases its bound NO. The release of NO allows oxygen to re-bind with COX and subsequently enables the cellular respiration cycle to be resumed, leading to generation of energy in the form of ATP.2 It is notable that owing to the inflammation and cell stress which occur in response to disease, there is an increase in NO levels which bind and impede COX activity. It is believed that decreased COX activity limits tissue repair, which can occur while the disease processes are ensuing.76 The release of NO, ATP or growth factors from cells directly activated by light may subsequently result in molecular messages being sent to adjacent or even distant cells and tissues. This process results in a so-called ‘bystander effect’, which results in activation of tissue repair processes in recipient cells and tissues.2,3,76

    Figure 4. LLLT affects at the cellular level. Cytochrome C oxidase (COX) is regarded as the principal photoacceptor within cells present on the mitochondrial membrane. The release of nitric oxide (NO) by COX due to LLLT enables oxygen to rebind COX and respiratory chain activation to be resumed. This mechanism results in anti-inflammatory modulation of NF-κB and AP-1 activity and increased cellular activity due to energy synthesis (ie increases in ATP). Associated changes and activation of gene expression and intracellular signalling results in the cellular responses highlighted.

    Delivery and clinical application of LLLT

    Whilst many clinical LLLT devices utilize specific wavelengths in the 600–1000 nm spectrum (~660 nm and 810–830 nm are frequently used), successful treatment outcomes are also dependent on the parameters of the applied irradiation which include ‘dose’ (fluence, or radiant exposure measured in J.m -2), ‘intensity’ (properly termed, irradiance, W.m -2), treatment/irradiation time (s), treatment frequency, treatment intervals, total number of treatments, number of treatment target points and target area coverage. Different clinical applications will clearly require specific therapeutic regimes owing to the depth of penetration needed to irradiate the target cells as a consequence of light reflection, absorption, refraction and scattering through the tissue. The tissue composition affects how the irradiation penetrates, as light energy is transmitted more easily through mucosa and fat compared with bone, dental hard tissue and muscle. In addition to pigments, such as melanin, haemoglobin, lipids and water are significant absorbers of light and therefore can also limit transmission through tissue. In general, the deeper the penetration required, the longer the wavelength required (up to ~980 nm, the peak absorbance wavelength of water).1 Notably, while incorrect LLLT application is unlikely to be harmful, it may be ineffective, and subsequently the lack of standardization of treatment parameters within the literature has resulted in a lack of consistency in findings and generated significant controversy within the field.1,2,3

    Common clinical targets for LLLT are:

  • The site of injury, disease or dysfunction to promote healing, remodelling and reduce inflammation;
  • Lymph nodes to reduce oedema and inflammation;
  • Nerves to induce analgesia; and
  • Trigger points to reduce tissue tenderness and relax contracted muscle fibres.

    • The treatment times per therapeutic point are typically in the range of 30–60 seconds and as little as one, or up to 15 treatment target points may be irradiated, depending on the complexity of the disorder77 (Figure 3).

    There is relatively minimal risk associated with the application of LLLT, and any potential hazards are mostly ocular rather than representing any risk from excessive temperature rises within the recipient tissue. Indeed, most LLLT devices are class 3B lasers or LEDs, although some are defocused class IV lasers. In most cases, LLLT devices emit divergent beams (not collimated), so the ocular risk decreases over distance (in the range of several metres) and manufacturers are subsequently obliged to provide the nominal ocular hazard distance (NOHD) for users. Furthermore, protective goggles, specific for the wavelength used, must be worn by both the patient and the therapist when applying LLLT. In general, international regulatory standards help ensure minimal risk is associated with LLLT devices.77

    Conclusions

    While light therapies are standardly used in several medical areas, such as in the treatment of neonatal jaundice and rickets, the direct application of light as a therapeutic intervention within the oral maxillofacial region has thus far received minimal clinical attention. However, data now indicates that LLLT may provide a relatively safe (no known side-effects, non-invasive and non-pharmaceutical), simple and inexpensive therapeutic approach, which can be used separately or as an adjunct to conventional treatments and can be applied in the clinical setting or by patients independently. In addition, it may provide a therapeutic approach to treat diseases and disorders where there is currently minimal successful clinical intervention possible and/or which are refractory to existing treatments. Nowadays, it is increasingly considered beneficial for the patient's long-term well-being that their own cellular defence and repair responses are activated to enable tissue regeneration. The ability of LLLT to activate many cell types, including stem cells locally, by promoting their proliferation, migration and differentiation, is also clearly desirable. Subsequently, optimized LLLT approaches may obviate the need for stem cell therapeutic applications, which require cell isolation, expansion and subsequent implantation for patient treatment. However, further fundamental basic science and clinical studies are critical in order to identify the optimal parameters relevant for the use of LLLT accurately in treating distinct oral and dental diseases.