The fundamental pathophysiologic response for the survival of all organisms is the process of wound healing. Inadequate or lack of healing constitutes the etiopathologic basis of many oral and systemic diseases. Among the numerous efforts to promote wound healing, biophotonics therapies have shown much promise. Advances in photonic technologies and a better understanding of light-tissue interactions, from parallel biophotonics fields such as in vivo optical imaging and optogenetics, are spearheading their popularity in biology and medicine. Use of high-dose lasers and light devices in dermatology, ophthalmology, oncology, and dentistry are now popular for specific clinical applications, such as surgery, skin rejuvenation, ocular and soft tissue recontouring, and antitumor and antimicrobial photodynamic therapy. However, a less well-known clinical application is the therapeutic use of low-dose biophotonics termed photobiomodulation (PBM) therapy, which is aimed at alleviating pain and inflammation, modulating immune responses, and promoting wound healing and tissue regeneration. Despite significant volumes of scientific literature from clinical and laboratory studies noting the phenomenological evidence for this innovative therapy, limited mechanistic insights have prevented rigorous and reproducible PBM clinical protocols. This article briefly reviews current evidence and focuses on gaps in knowledge to identify potential paths forward for clinical translation with PBM therapy with an emphasis on craniofacial wound healing. PBM offers a novel opportunity to examine fundamental nonvisual photobiological processes as well as develop innovative clinical therapies, thereby presenting an opportunity for a paradigm shift from conventional restorative/prosthetic approaches to regenerative modalities in clinical dentistry.
AokiAMizutaniKSchwarzFSculeanAYuknaRATakasakiAARomanosGETaniguchiYSasakiKMZeredoJL. 2015. Periodontal and peri-implant wound healing following laser therapy. Periodontol 2000. 68(1):217–269.
5.
AranyPRChoAHuntTDSidhuGShinKHahmEHuangGXWeaverJChenACPadwaBL. 2014. Photoactivation of endogenous latent transforming growth factor-beta1 directs dental stem cell differentiation for regeneration. Sci Transl Med. 6(238):238ra269.
6.
AranyPRFlandersKCKobayashiTKuoCKStueltenCDesaiKVTuanRRennardSIRobertsAB. 2006. Smad3 deficiency alters key structural elements of the extracellular matrix and mechanotransduction of wound closure. Proc Natl Acad Sci U S A. 103(24):9250–9255.
AranyPRNayakRSHallikerimathSLimayeAMKaleADKondaiahP. 2007. Activation of latent TGF-beta1 by low-power laser in vitro correlates with increased TGF-beta1 levels in laser-enhanced oral wound healing. Wound Repair Regen. 15(6):866–874.
9.
AshcroftGSYangXGlickABWeinsteinMLetterioJLMizelDEAnzanoMGreenwell-WildTWahlSMDengC. 1999. Mice lacking SMAD3 show accelerated wound healing and an impaired local inflammatory response. Nat Cell Biol. 1(5):260–266.
10.
BjordalJMBensadounRJTunerJFrigoLGjerdeKLopes-MartinsRA. 2011. A systematic review with meta-analysis of the effect of low-level laser therapy (LLLT) in cancer therapy-induced oral mucositis. Support Care Cancer. 19(8):1069–1077.
11.
BjordalJMCouppeCChowRTTunerJLjunggrenEA. 2003. A systematic review of low level laser therapy with location-specific doses for pain from chronic joint disorders. Aust J Physiother. 49(2):107–116.
12.
BrondonPStadlerILanzafameRJ. 2005. A study of the effects of phototherapy dose interval on photobiomodulation of cell cultures. Lasers Surg Med. 36(5):409–413.
13.
BurgerEMendesACBaniGMBrigagaoMRSantosGBMalaquiasLCChavascoJKVerinaudLMde CamargoZPHamblinMR. 2015. Low-level laser therapy to the mouse femur enhances the fungicidal response of neutrophils against paracoccidioides brasiliensis. PLoS Negl Trop Dis. 9(2):e0003541.
14.
CalabreseEJBachmannKABailerAJBolgerPMBorakJCaiLCedergreenNCherianMGChiuehCCClarksonTW. 2007. Biological stress response terminology: integrating the concepts of adaptive response and preconditioning stress within a hormetic dose-response framework. Toxicol Appl Pharmacol. 222(1):122–128.
ChenWKonkelJE. 2015. Development of thymic Foxp3(+) regulatory T cells: TGF-beta matters. Eur J Immunol. 45(4):958–965.
17.
EmingSAMartinPTomic-CanicM. 2014. Wound repair and regeneration: mechanisms, signaling, and translation. Sci Transl Med. 6(265):265sr6.
18.
FekrazadRMirmoezziAKalhoriKAAranyP. 2015. The effect of red, green and blue lasers on healing of oral wounds in diabetic rats. J Photochem Photobiol B. 148:242–245.
19.
FernandesKPSouzaNHMesquita-FerrariRASilva DdeFRochaLAAlvesANSousa KdeBBussadoriSKHamblinMRNunesFD. 2015. Photobiomodulation with 660-nm and 780-nm laser on activated j774 macrophage-like cells: effect on m1 inflammatory markers. J Photochem Photobiol B. 153:344–351.
20.
FinnsonKWAranyPRPhilipA. 2013. Transforming growth factor beta signaling in cutaneous wound healing: lessons learned from animal studies. Adv Wound Care (New Rochelle). 2(5):225–237.
21.
FujimuraTMitaniAFukudaMMogiMOsawaKTakahashiSAinoMIwamuraYMiyajimaSYamamotoH. 2014. Irradiation with a low-level diode laser induces the developmental endothelial locus-1 gene and reduces proinflammatory cytokines in epithelial cells. Lasers Med Sci. 29(3):987–994.
22.
GarletGPSfeirCSLittleSR. 2014. Restoring host-microbe homeostasis via selective chemoattraction of tregs. J Dent Res. 93(9):834–839.
23.
HarrisonSJTyrerAELevitanRDXuXHouleSWilsonAANobregaJNRusjanPMMeyerJH. 2015. Light therapy and serotonin transporter binding in the anterior cingulate and prefrontal cortex. Acta Psychiatr Scand. 132(5):379–388.
24.
HashmiJTHuangYYSharmaSKKurupDBDe TaboadaLCarrollJDHamblinMR. 2010. Effect of pulsing in low-level light therapy. Lasers Surg Med. 42(6):450–466.
25.
HeckMSchadelSAMaretzkiDBartlFJRitterEPalczewskiKHofmannKP. 2003. Signaling states of rhodopsin: formation of the storage form, metarhodopsin III, from active metarhodopsin II. J Biol Chem. 278(5):3162–3169.
26.
HoffmanMMonroeDM. 2012. Low intensity laser therapy speeds wound healing in hemophilia by enhancing platelet procoagulant activity. Wound Repair Regen. 20(5):770–777.
27.
HuangYYNagataKTedfordCEHamblinMR. 2014. Low-level laser therapy (810 nm) protects primary cortical neurons against excitotoxicity in vitro. J Biophotonics. 7(8):656–664.
28.
IvanoffCSHottelTLGarcia-GodoyF. 2012. Dielectrophoresis: a model to transport drugs directly into teeth. Electrophoresis. 33(8):1311–1321.
29.
JoblingMFMottJDFinneganMTJurukovskiVEricksonACWalianPJTaylorSELedbetterSLawrenceCMRifkinDB. 2006. Isoform-specific activation of latent transforming growth factor beta (LTGF-beta) by reactive oxygen species. Radiat Res. 166(6):839–848.
30.
LallaRVBowenJBaraschAEltingLEpsteinJKeefeDMMcGuireDBMiglioratiCNicolatou-GalitisOPetersonDE. 2014. MASCC/ISOO clinical practice guidelines for the management of mucositis secondary to cancer therapy. Cancer. 120(10):1453–1461.
31.
LeeMTBirdPSWalshLJ. 2004. Photo-activated disinfection of the root canal: a new role for lasers in endodontics. Aust Endod J. 30(3):93–98.
LiuYHsuCYTeoCMTeohSH. 2013. Potential mechanism for the laser-fluoride effect on enamel demineralization. J Dent Res. 92(1):71–75.
34.
MedradoARPuglieseLSReisSRAndradeZA. 2003. Influence of low level laser therapy on wound healing and its biological action upon myofibroblasts. Lasers Surg Med. 32(3):239–244.
35.
MesterEKorényi-BothASpiryTScherATiszaS. 1973. Stimulation of wound healing by means of laser rays (clinical and electron microscopical study). Acta Chir Acad Sci Hung. 14(4):347–356.
36.
MesterESpiryTSzendeBTotaJG. 1971. Effect of laser rays on wound healing. Am J Surg. 122(4):532–535.
37.
NagataMJde CamposNMessoraMRPolaNMSantinoniCSBomfimSRFuciniSEErvolinoEde AlmeidaJMTheodoroLH. 2014. Platelet-rich plasma, low-level laser therapy, or their combination promotes periodontal regeneration in fenestration defects: a preliminary in vivo study. J Periodontol. 85(6):770–778.
38.
OhshiroT. 2014. Laser therapy two decades on: the phoenix flourishes. Laser Ther. 23(3):161–163.
39.
OliviGDiVitoEPetersOKaitsasVAngieroFSignoreABenedicentiS. 2014. Disinfection efficacy of photon-induced photoacoustic streaming on root canals infected with enterococcus faecalis: an ex vivo study. J Am Dent Assoc. 145(8):843–848.
40.
PeakeJMMarkworthJFNosakaKRaastadTWadleyGDCoffeyVG. 2015. Modulating exercise-induced hormesis: does less equal more?J Appl Physiol. 119(3):172–189.
41.
PeplowPVChungTYBaxterGD. 2010. Laser photobiomodulation of wound healing: a review of experimental studies in mouse and rat animal models. Photomed Laser Surg. 28(3):291–325.
42.
PolsteinLRGersbachCA. 2015. A light-inducible CRISPR-Cas9 system for control of endogenous gene activation. Nat Chem Biol. 11(3):198–200.
43.
PorcaroGAmossoEScarpellaRCariniF. 2015. Doxycycline fluorescence-guided er:Yag laser ablation combined with nd:Yag/diode laser biostimulation for treating bisphosphonate-related osteonecrosis of the jaw. Oral Surg Oral Med Oral Pathol Oral Radiol. 119(1):e6–e12.
44.
PostenWWroneDADoverJSArndtKASilapuntSAlamM. 2005. Low-level laser therapy for wound healing: mechanism and efficacy. Dermatol Surg. 31(3):334–340.
45.
SerhanCN. 2014. Pro-resolving lipid mediators are leads for resolution physiology. Nature. 510(7503):92–101.
46.
SgolastraFPetrucciASeverinoMGattoRMonacoA. 2013. Lasers for the treatment of dentin hypersensitivity: a meta-analysis. J Dent Res. 92(6):492–499.
47.
SharmaSKKharkwalGBSajoMHuangYYDe TaboadaLMcCarthyTHamblinMR. 2011. Dose response effects of 810 nm laser light on mouse primary cortical neurons. Lasers Surg Med. 43(8):851–859.
48.
ShigetaniYSasaNSuzukiHOkijiTOhshimaH. 2011. Gaalas laser irradiation induces active tertiary dentin formation after pulpal apoptosis and cell proliferation in rat molars. J Endod. 37(8):1086–1091.
49.
SperandioFFSimoesACorreaLAranhaACGiudiceFSHamblinMRSousaSC. 2015. Low-level laser irradiation promotes the proliferation and maturation of keratinocytes during epithelial wound repair. J Biophotonics. 8(10):795–803.
50.
SubbotinaLARadchenkoSNGolovkinaOLBubeev IuA. 2009. [Hemoaggregation dynamics in human-operator during percutaneous laser blood irradiation]. Aviakosm Ekolog Med. 43(3):56–60.
51.
SunGTunerJ. 2004. Low-level laser therapy in dentistry. Dent Clin North Am. 48(4):1061–1076.
52.
SuzukiMKatsumiAWatanabeRShironoMKatohY. 2005. Effects of an experimentally developed adhesive resin system and co2 laser irradiation on direct pulp capping. Oper Dent. 30(6):702–718.
53.
TzabazisAZKlukinovMCrottaz-HerbetteSNemenovMIAngstMSYeomansDC. 2011. Selective nociceptor activation in volunteers by infrared diode laser. Mol Pain. 7:18.
54.
WhelanHTSmitsRLJrBuchmanEVWhelanNTTurnerSGMargolisDACeveniniVStinsonHIgnatiusRMartinT. 2001. Effect of nasa light-emitting diode irradiation on wound healing. J Clin Laser Med Surg. 19(6):305–314.
55.
YuWNaimJOLanzafameRJ. 1997. Effects of photostimulation on wound healing in diabetic mice. Lasers Surg Med. 20(1):56–63.
56.
ZeitzerJMFisicaroRARubyNFHellerHC. 2014. Millisecond flashes of light phase delay the human circadian clock during sleep. J Biol Rhythms. 29(5):370–376.
Supplementary Material
Please find the following supplemental material available below.
For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.
For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.
