Effects of lasers on titanium dental implant surfaces: a narrative review

Despite the fact that very high success rates have been demonstrated for dental implants, they are susceptible to complications that may cause failure [1‐3]. One such complication is plaque-induced peri-implantitis, which can be prevented by appropriate methods that decontaminate and debride the implant surface. Conventional methods of debridement of dental implant surfaces have been found to be insufficient and may cause damage or alteration to the implant surface [4, 5]. It is for this reason that lasers have been investigated for applications in the treatment of peri-implant disease.

Titanium implants have surfaces with macro, micro and nano-scale features that are designed to enhance osseointegration and thus long-term stability of the interface between the implant surface and the adjacent bone. In non-surgical treatment approaches for peri-implantitis with lasers, preservation of the micro and nano-scale features has been considered valuable, in the hope that these could contribute to bone formation in peri-implant bony defects. This differs from the situation during surgical treatment of advanced peri-implantitis where implantoplasty may be undertaken to remove surface features and simplify debridement. How much conservative non-surgical laser treatments may alter or damage implant surfaces has been an area of previous research, with studies using a variety of laser wavelengths and laser irradiation parameters on a range of implant surfaces. The large number of possible combinations of laser parameters and implant systems makes this a difficult area of literature to navigate. Lasers may absorb directly into the titanium or titanium alloy of the dental implant, as well as into the microbial deposits which are formed on its surface [6]. Absorption into titanium can lead to degradation of macro, micro and nano-scale surface features [7].

High survival rates of dental implants have been reported by a number of authors [1‐3]. Systematic reviews of clinical outcomes with implant supported fixed dental prosthesis have shown 5-year survival rates of between 95.2% and 96.8% at 5 years [1‐3] and between 86.7% and 92.8% at 10 years [1, 3]. Despite this high survival rate, even successfully osseointegrated implants are susceptible to pathologic conditions that may eventually lead to failure [3, 4, 8]. Biological complications associated with dental implants may be defined as disturbances in the normal functioning of the implant as the result of biological factors that may affect the soft and hard tissues supporting the implant [9]. The incidence of biological complications such as peri-implantitis and soft tissue complications around implants has been reported between 8.6% and 9.7% at 5 years [1‐3]. Where other risk factors are present, such as a history of periodontal disease, poor oral hygiene, smoking and diabetes, the risk of developing biological complications is even higher [10‐12].

One of the main reported causes of post-integration failure is plaque-induced peri-implantitis [8, 13, 14]. Similar to periodontitis, the primary aetiological factor for peri-implantitis is microbial colonisation of the implant surface, which drives an associated inflammatory reaction in the adjacent soft and hard tissues, resulting in bone loss [4, 8, 15‐17]. To prevent this occurring, dental implants need monitoring and maintenance, including decontamination and debridement, at regular intervals throughout the lifespan.

In light of the similar aetiology of periodontitis and peri-implantitis, similar treatment modalities have been suggested [4, 18]. The treatment objective for both conditions is complete removal of the supra- and sub-gingival dental plaque biofilm, including areas which have mineralised to become calculus. Peri-implantitis treatment typically begins with a non-surgical approach to debridement and decontamination of the implant surface, which if unsuccessful will be followed by an open flap surgical approach and adjunctive treatments [16]. Both surgical and non-surgical therapy may include the adjunctive use of antiseptics or antibiotics [17, 19].

Conventional approaches to implant surface debridement have included mechanical treatment with hand scalers, sonic and ultrasonic scalers, using instrument tips made of plastic, carbon fibre or other materials in order to reduce damage to the surface. Other non-surgical treatment modalities include particle beams (air-powder abrasion), local delivery of antiseptic agents and photodynamic therapy, in varying combinations with or without local or systemic antibiotics [20‐28]. Whilst there are many possible treatment modalities, there is currently a lack of high-quality evidence that supports any particular approach being regarded as a gold standard [28].

It is important to consider whether novel approaches such as the use of laser treatments can give similar effects to existing conventional treatments but prevent damage to the implant surface. For example, in a study comparing the effect of Er:YAG laser treatment, chitosan brushes and titanium curettes, the curettes significantly altered the implant surface micro-texture, whilst the Er:YAG laser and the chitosan brush did not. Despite this, all three treatment modalities had a similar ability to remove Porphyromonas gingivalis [29]. Kotsovilis et al. in a 2008 systematic review of peri-implantitis therapy also pointed out that a significant limitation in the existing literature was that the duration of follow up may be too short to provide strong advice on which therapeutic methods have the highest efficacy over the longer term [17]. Given that methods such as hand scaling with metal instruments and ultrasonic scaling may damage the implant surface [3, 5], it is important to identify methods that are inherently safe for the surface being treated, and this is where interest in the use of lasers as alternative or adjunctive methods has arisen [30].

The overarching aim in treatment of peri-implantitis is to ensure that the treated implant fixture surface remains biocompatible, for adhesion of osteoblasts and fibroblasts. It is therefore necessary to balance the laser parameters being used for debridement against potentially deleterious effects on the surface and on the temperature of the metallic implant fixture. Ideal parameters for the therapeutic use of lasers in treating peri-implant disease should be determined for each laser wavelength in current use. Irradiation of the implant surface should maximise debridement and ensure thorough disinfection of the surface, as well as inactivation of toxins such as lipopolysaccharide, without causing deleterious changes to the implant surface. To optimise the laser parameters, it is necessary to consider not only the laser parameters but also the laser delivery system, since this will affect the power density and spatial distribution of energy provided onto the implant surface. Changing the wavelength has implications not only for absorption into the implant surface, into the biofilm and into adjacent targets such as hard and soft tissues, but also for the delivery of the laser energy through the delivery system. Adding to this are variables such as fibre or tip diameter and shape, and how these terminal parts of the delivery system interact with gingival crevicular fluid, blood or water. Laser debridement meant may require water irrigation to cool the implant surface as well as to flush away remnants of the biofilm which have been disrupted by the laser.

A wide variety of lasers have been utilised in the treatment both of periodontitis and peri-implantitis [31‐34]. The available wavelengths range from the visible spectrum (400–700 nm) through to the near infrared spectrum (700 nm–1500 nm), to the middle and far infrared spectrum (1500–11,000 nm) [35]. Within the infrared range, laser types of interest include the neodymium:yttrium aluminium garnet (Nd:YAG) laser at a wavelength of 1064 nm [36], the erbium:yttrium aluminium garnet (Er:YAG) laser at 2940 nm [37‐42], the erbium, chromium:yttrium, scandium, gallium, garnet (Er,Cr:YSGG) laser at 2780 nm [43, 44], the carbon dioxide (CO₂) lasers at 9300 and 10,600 nm [36, 45] and various diode lasers at various wavelengths ranging from 810 to 980 nm [46, 47].

Of these lasers, the Er:YAG laser has been the most extensively researched for non-surgical periodontal therapy, providing clinical outcomes similar to those seen with conventional mechanical debridement [48].

The specific action of each laser wavelength is dependent not only on the absorption of that laser energy into the target, but also on the characteristics of the delivery system. Depending on the system used, laser energy may be delivered to the target surface using optical fibres made of glass for visible and near infrared lasers or made of rare earth element oxide materials for near and middle infrared lasers. Other delivery systems used with metal and far infrared lasers include flexible hollow waveguides and articulated arms. Each delivery system can be fitted with handpieces or with tips or optical fibres, and the terminal part of the delivery system can either focus the energy or disperse it [92]. When tips or optical fibres are used, the design of the tip has a major influence on the spatial distribution of laser energy, and this influences how the laser interacts with the target [92]. Various modifications to fibre tips have been described, which alter the emission direction, beam divergence and spatial distribution of laser energy [92‐96].

The logistics of delivering laser energy to the threads or subgingival regions of a dental implant are considerable. A range of side firing fibres and tips have been developed specifically for this purpose. Some of these are rigid, whilst others are semi flexible or highly flexible. The rigidity of the delivery system tip influences whether any tactile feedback is provided to the operator. Tactile feedback may help the operator correctly position the tip into the region between the threads of a dental implant. A plain fibre tip will disperse the energy in a forward direction with a conical-shaped emission pattern. A typical glass fibre or rare earth element oxide fibre will disperse the energy with the divergence of less than 20° [97]. This low divergence does not suit the situation of a periodontal pocket around a dental implant. It is hence important to use fiber tip designs with greater lateral emissions to direct laser energy on the implant bone interface. Various modifications to optical fibre tips have been explored to increase the lateral emission of laser energy for the wavelengths of interest [97]. Techniques include grinding and polishing to give side firing or tapered tips [98], heating and pulling [99, 100] and chemical etching [101‐103]. A technique of combined etching and abrasion steps has been shown to produce conical fibre tips with multiple facets in a ‘honeycomb’ surface pattern, giving greatly increased lateral and decreased forward emissions compared to plain fibres [97].

The currently accepted theory for the mechanism of erbium laser ablation of dental hard tissues (enamel, dentine, cementum and bone) is a photo-mechanical action based on micro-explosions of water within the target. Conversion of the water to steam generates an increase in pressure, leading to micro-explosions [104, 105]. These same mechanisms also apply to the ablation of dental plaque biofilms and dental calculus. The explosions are accompanied by photothermal disinfection and by rapid fluid movement caused by cavitation events. The combination of these effects results in decontamination of the implant surface [106]. In contrast, photothermal events dominate for the Nd:YAG laser and for diode lasers. Bacteria are inactivated by direct heating actions [107]. Some diode lasers (940 and 980 nm) have sufficient water absorption to generate fluid agitation, and this can assist in debridement of implant surfaces [108, 109].

Other factors that may influence the ablative effect of lasers on mineralised and non-mineralised dental plaque biofilms on implant surfaces include the presence of water [110], the laser pulse energy and the spatial distribution of laser energy [111], the beam diameter [112] and the pulse duration [113]. Use of a water coolant during laser irradiation attenuates temperature changes on the target and thus minimise adverse effects on adjacent tissues [77]. As discussed earlier, the presence of water can also influence the interaction of water absorbing laser wavelengths on implant surfaces [63]. Optimisation of irrigation protocols is important for both safety and effectiveness. When a water absorbing laser is being used, excessive irrigation will dampen the ablation effects [77]. Under clinical conditions, Er:YAG lasers typically with pulse energies in the order of 50–200 mJ and with a continuous water mist spray are used [63]. Several studies indicate that water spray or a moist surface is essential for effective ablation of dentine, as it not only reduces thermal stress but also reduces charring of the ablated surface [114‐117]. Provided a moderately long pulse duration is used (in the order of 250–350 μs), no adverse effects on the smooth titanium abutment surfaces should occur [63]. Further work is needed to optimise water flow rates for effective ablation of implant surfaces. Considerations around irrigation should also consider whether the implant service being treated is supragingival or subgingival, and hence whether there is saliva or gingival crevicular fluid present.

Laser parameters for treating dental implant need to consider the pulse shape, pulse duration and pulse energy. The pulse shape (power versus time) is important because it determines how much of the pulse is above the ablation threshold of the target. In this situation, there are at least two targets with vastly different ablation thresholds—the dental plaque biofilm (whether mineralised or not) and the titanium or titanium alloy of the implant. There needs to be sufficient energy to ablate microorganisms in the biofilm, but not to ablate the titanium surface. The pulse duration influences the peak power. The greater the peak power, the more likely that cratering of the surface will occur and that plasma will be generated. Using longer pulses with lower peak power means that the likelihood of damaging the surface will be less. The influence of laser pulse energy on ablation has been well documented for dental hard tissues [118, 119], and the same principles in relation to surface alterations with erbium family lasers [50, 51, 53, 56, 68] and Nd:YAG lasers [5, 72, 76].

A further consideration is the beam profile, which is the spatial distribution of laser energy. All the energy can be concentrated into a single spot with a Gaussian beam profile, or the energy can be divided into a series of geometrical shapes, such as rings or dots, when the laser is in multimode operation. The configuration of the laser cavity influences the beam profile, and for this reason that can vary between lasers of the same wavelength. The energy distribution in the spot affects the laser to target interaction and the ablative effect of the laser [120]. Larger spot size means a lower power density and therefore a reduced ablative action. As the spot size becomes larger, any defects such as craters that form on the surface will be shallower, due to defocusing of the beam [112]. This defocusing action applies regardless of the spatial beam profile of the laser. Laser manufacturers should provide information about how the power density changes with distance for particular handpieces and fibres, stating actual measured values rather than calculated values, since actual measured values will take into account losses within the delivery system itself. Users can then make informed judgements regarding what the focused laser spot is likely to do on the target [111, 120]. Typically, manufacturers will provide information about the effective beam diameter that can be achieved with the delivery system components provided. Clinicians must bear in mind that changing the diameter of the fibre optic tip and the shape of the tip will alter the spot size [92].

Laser treatments of implant surfaces should avoid short pulse durations since these will have the highest peak power and the greatest ability to form plasma. The influence of pulse duration on ablation is well known in the literature for dental hard tissues, and the same principles apply with titanium and its alloys [113]. A short pulse duration can cause ablation at a lower pulse energy [113], whilst there will be little or no ablation at longer pulse durations for the same pulse energy [113]. This line of thinking explains how a titanium absorbing laser wavelength such as that from the Nd:YAG laser can be used safely to decontaminate implants, provided that an extremely long pulse duration is employed, to avoid causing surface alterations [76].

In addition to laser parameters, clinicians must bear in mind the nature of the target surface, both in a chemical sense and in terms of morphology. Different implant components may have compositional differences, such as grade 4 titanium being used for a fixture, but grade 5 titanium alloy (which contains aluminium and vanadium) being used for an abutment. With regard to the surface characteristics, a surface that appears smooth and highly polished to the naked eye will interact differently with laser light than the surface which appears matte. On reaching the surface, longer wavelengths of laser light may reflect even from surfaces that do not appear to be extremely smooth [35, 80]. Laser energy may reflect from highly polished titanium surfaces onto adjacent soft tissues, causing accidental ablation [80]. Clinicians need to carefully follow the manufacturers’ recommended maximum laser settings for treating implant surfaces and be aware of this risk of specular reflection. The issue has not been documented well in the literature for diode laser wavelengths, despite being well described for the far infrared carbon dioxide laser [121]. This laser type is not used widely in dental implant therapy, with diode lasers being much more commonplace. There is a significant gap in the literature regarding the interaction of diode laser wavelengths with dental implant surfaces of various types, and further work on this topic is necessary [122].

A significant deficiency in the literature is that, whilst clinical studies have been undertaken, the results for those are specific for the laser systems and implant materials used, for all the reasons mentioned above. It is not possible to generalise all lasers of the same wavelength, nor to all types of implant materials or implant surfaces. On the basis of laser to target interactions, results may vary even within the same laser system when there are changes to the delivery system, such as changing to a disposable fibre of a different diameter. This emphasises why it is important that further studies be done to establish what parameters can be used safely with implant components of different types.

The current literature supports the use of lasers in the treatment of peri-implant pathology, as an adjunct to traditional treatment methods, or in some cases as a replacement for them. The major considerations are around whether the use of lasers for surface debridement enhances the end result from a biological perspective (e.g. removal of biofilm, decontamination of the surface, and maintaining or enhancing its biocompatibility), whilst limiting the extent of change to the surface, at both the chemical and morphological levels. At the present time, there is no one ideal method for implant debridement and decontamination using conventional devices. Lasers are appealing; however, careful consideration must be given to the effect of laser irradiation on the implant surface. Whilst many studies have documented the extent of surface changes caused by laser irradiation of titanium implant surfaces, the results are bespoke to the particular laser system and target material combination that was used. Variables between lasers of the same wavelength or type (such as pulse duration, pulse shape, beam profile and delivery system) as well as between laser parameters (such as pulse energy, pulse frequency and irrigation characteristics) make comparisons between outcomes difficult. Adding to these factors is the influence of the terminal component of the delivery system on the spatial distribution of laser energy. Using tips that have been specially modified to improve the lateral emission of laser energy onto the side of the implant fixture may be appropriate given the morphology of the peri-implant pocket. The current study highlights the gaps in the current literature and the need for standardised studies to formulate recommended clinical protocols/settings for the use of lasers in different dental procedures.