View larger version (154K): [in this window] [in a new window]   Figure 2. Assembled and disassembled dentin cylinder model.

Infection of models. We used a micropipette with a sterile, gelloading tip to transfer 8 µL of an overnight BHI broth culture of E. faecalis 29212 to the canal space of each model. We performed this inoculation by removing the cervical cap of each assembled model, injecting the bacterial sample into the canal space and replacing the cervical cap. After inoculation, we incubated all models in a moist environment in a warm room (37 C) for seven days. We found this incubation period to be sufficient for adequate infection of the dentinal tubules on the basis of a study by Haapasalo and Orstavik,¹⁹ who found that E. faecalis would not grow significantly further into dentinal tubules of the root dentin if incubation was continued beyond seven days. We used sterile micropipettes to add 4 µL of BHI to the root canal of each root section once daily throughout the incubation period to prevent desiccation and provide nutrients for the bacteria within the tubules to grow.

Treatment of canals. After the seven-day incubation period, we dried the canals in all the models with sterile paper points. We treated groups 1, 2 and 3 (the control groups) as follows:

– we provided group 1 models with no disinfection treatment;

– we irrigated group 2 models with 1.5 mL of 2.5 percent sodium hypochlorite and then dried them;

– we irrigated group 3 models with 3.0 mL of 2.5 percent sodium hypochlorite and then dried them.

We lased the models from groups 4 through 18 using the Er,Cr:YSGG radially emitting laser tips inside the models’ canals. We used sterile gloves, a sterilized laser handpiece, sterilized water and sterilized Z2 type (200 µm diameter and 14 mm in length) radially emitting laser instrument tips for each sample. For the groups that we lased in the presence of an air-water spray (groups 4, 7, 10, 13 and 16), we carried out the lasing with the Er,Cr:YSGG laser unit set to emit 175 ± 25 milliwatts power output variation limit at 20 hertz, with 34 percent air and 28 percent water. We moved the radially emitting laser tip by hand up and down in the canal in a cervical-apical and apical-cervical direction at a rate of 1 mm per second (that is, 10 seconds to traverse the full 5-mm length of the canal in both directions). During this procedure, we kept the tip as close to the canal wall as possible.

For the groups lased without water, we set the laser power at either at 175 ± 25 mW power and 20 Hz (groups 5, 8, 11, 14 and 17) or at 350 ± 50 mW and 20 Hz (for groups 6, 9, 12, 15 and 18). The indicated laser emission settings (175 ± 25 mW and 350 ± 50 mW) take into consideration a variation of the measured power output of no more than 15 percent and a 68 percent attenuation of power that occurs as a result of using a 200-µm fiber tip. Therefore, the laser settings are representative of the actual power output calculated for the 200-µm fiber tips, not the display power shown on the laser unit. Each fiber tip was used to treat 10 models—that is, all the models in one experimental group. The measured power loss after 10 treatments was between 10 and 15 percent.

Recovery and quantification of E. faecalis from infected canals. Immediately after treatment, we uncapped all models of all the groups (1–18), dried the canals with paper points and then enlarged the canals with sterilized no. 5 and no. 6 Gates-Glidden burs through each orifice and the apical putty to allow dentinal filings to fall into the lower reservoir filled with 450 µL of BSG. (In a previous pilot study, we found the use of Gates-Glidden burs to be an effective method of recovering infected dentinal filings in the buffer reservoir [R.H. Stevens, unpublished data, October 2004].) We then used 50 µL of BSG to wash down remaining filings through the apical orifice to make a combined total of 500 µL of undiluted sample in the BSG reservoir. We conducted the drilling under aseptic conditions. We vortexed the undiluted samples and then allowed them to sit undisturbed for a few minutes before we prepared serial dilutions. The undiluted samples (containing the infected dentin filings) were diluted serially (10-fold dilutions) from 10^–1 to 10^–3 with BSG. We spread 50-µL aliquots from each dilution on modified thallous acetate (TA) agar plates (proteose peptone 1 percent, yeast extract 1 percent, glucose 1 percent, TA 0.2 percent, triphenyl tetrazolium chloride 0.01 percent, agar 1.3 percent), which is selective for enterococci.²⁷ We then incubated the plates overnight at 37 C, and we counted the resulting colonies.

Statistical methods. The original scale colony-forming unit (CFU) has a highly skewed distribution that is not well-summarized by an arithmetic mean. Therefore, we converted all original CFU values to a base 10 logarithmic scale (log CFU), since the distribution of the log CFU data was well-modeled by a normal (Gaussian) distribution. We then converted the base 10 log means to geometric means on the original scale by calculating the base 10 antilog of the log mean CFU value. We also computed the base 10 antilog of the log scale 95 percent confidence intervals to determine the original scale 95 percent confidence intervals.

We chose Enterococcus faecalis as the test microorganism in this study owing to its high frequency of isolation from cases of failed endodontic treatment, its resistance to calcium hydroxide treatment and its relative insensitivity to laser irradiation.

We used one-way analysis of variance methods to compare means on the log scale, including comparisons with controls. Using linear regression, we assessed the influence of time and the three laser conditions (low versus high wattage, wet versus dry technique) and their potential interactions on log CFU.

	RESULTS

TOP ABSTRACT MATERIALS AND METHODS RESULTS DISCUSSION CONCLUSIONS REFERENCES

 
Table 2 summarizes mean log CFU and CFU values for all 18 groups, along with the lower and upper boundaries of the 95 percent confidence interval for the geometric mean CFU.

View larger version (42K): [in this window] [in a new window]   Figure 3. Plot of mean logarithmic scale colony-forming units (log CFUs) over time for the three laser treatment conditions. mW: Milliwatts.

	DISCUSSION

TOP ABSTRACT MATERIALS AND METHODS RESULTS DISCUSSION CONCLUSIONS REFERENCES

 
In this study, we evaluated the ability of an Er,Cr:YSGG laser with radially emitting laser tips to eliminate E. faecalis from dentinal tubules of prepared root sections. We chose E. faecalis as the test microorganism in this study owing to its high frequency of isolation from cases of failed endodontic treatment,^17,18 its resistance to calcium hydroxide treatment^20–22 and its relative insensitivity to laser irradiation.^28–30 We believed that if laser treatment was effective in eliminating this organism from infected dentinal tubules, we could infer that it would be effective against any organism found in endodontic infections, and that this technology might have clinical application in disinfecting root canals during endodontic therapy.

The penetration of the laser into the root dentin is governed by several factors. At the wavelength of the Er,Cr:YSGG laser (2.78 µm), there is absorption by dentin owing to the presence of hydroxide and interstitial water (dentin matrix and intratubular). On the basis of the fact that each laser pulse is composed of approximately 150 micropulses and each micropulse is responsible for the penetration of this energy of about 3 µm into water, depending on fluence, it is possible to achieve expansion of intratubular water and the collapse of water vapor as deep as 1,000 µm or more. This effect, known as "micropulse-induced sequential absorption," with expansion and collapse of water vapor, is capable of producing acoustic waves strong enough to disrupt intratubular bacteria. This penetration of dentin may provide the laser with advantages versus conventional methods of dentin disinfection, such as sodium hypochlorite irrigation, in cases in which limited access of the agent to the interstices of the root canal system may limit antimicrobial activity.

We evaluated the antimicrobial efficacy of the laser treatment by quantifying posttreatment residual CFUs of E. faecalis from infected root dentin models on selective TA agar plates. On the basis of previous research¹⁹ and our earlier pilot evaluations (R.H. Stevens, unpublished data, October 2004), we designed the models and experimental conditions in this study to allow for the infection, incubation and recovery of E. faecalis from infected dentinal tubules in an effective manner for evaluating the antimicrobial effect of laser and sodium hypochlorite treatment while minimizing the risk of false positive (uncounted bacteria) and false negative (contamination) results.

In a regression model presented in Table 4, we analyze and compare the effect of the three different laser treatment variables: time, wattage and wet/dry condition. According to the wet/dry equation, the dry method provided a more effective means of decreasing the CFUs, as indicated by the lower residual CFU number, which represents a larger percentage CFU reduction as compared with the control. Overall, the model showed that the largest reduction in CFUs occurred when time and wattage were at the maximum (240 seconds and 350 mW respectively) and when we used the laser in the absence of a water spray. This model is consistent with the results in Table 3, which shows that the greatest reduction in CFUs, when compared with the nontreated control (group 1), is found in laser group 18. Group 18 had the longest time of exposure (240 seconds in incremental steps) and the maximum wattage (350 ± 50 mW) and underwent the dry technique. This resulted in group 18’s having the lowest percentage of residual CFUs, with only 0.29 percent of the CFUs of group 1. In other words, 99.71 percent of CFUs were eliminated (100 – 0.29 = 99.71 percent) by using the method of laser treatment.

Table 3 also shows that laser group 4—with only 15 seconds of laser exposure, wattage of 175 ± 25 mW and air-water spray—had 5.3 percent of the CFUs of the control group 1. The 94.7 percent (100 percent – 5.3 percent = 94.7 percent) still is considered a significant reduction in E. faecalis bacteria. However, the method used for group 18 was 18.27 times (0.29 mean CFU as a percentage of the control mean) more efficient than the group 4 method (5.3 mean CFU as a percentage of the control mean) in reducing the number of CFUs.

For each time point (except the 30-second treatment), the 350 ± 50 mW laser dry treatment group consistently showed the lowest number of residual CFUs recovered and lowest percentage as compared with the control group. These results were statistically significant. The effective results obtained for the 350 mW dry laser treatment may be attributed to the direct effect of the laser on water-containing bacteria. When water spray is used, the laser energy applied to the root canal dentin is diminished owing to this laser wavelength’s high absorption properties. This effect may explain the decreased effectiveness in bacterial reduction among the laser groups that used water spray. Some treatment groups—such as laser groups 6, 8 and 9—showed low CFUs at low treatment times of 15 and 30 seconds of exposure (Table 4). It is possible that even at these shorter times, the addition of laser power was capable of eliminating most of the cultivable E. faecalis in the models.

The reason for the inconsistent result for the 30-second laser treatment group (group 9) is not clear. The two sodium hypochlorite–treated groups difference from each other by more than twice (2.36 times) the mean CFU percentage of the control. The results were statistically significant when compared with the control but not significant when compared with each other.

The base 10 log scale of all three lased groups compiled together over time indicated a tendency for lower CFUs and higher percentage reductions of bacteria at higher treatment times, with some variability in data mentioned previously (at 15 seconds and 60 seconds). We found the overall percentage bacterial reduction in all laser treatment groups to be statistically significant as compared with the control for all groups and to other treatment groups in same cases.

The fiber tips used in this study were designed specifically to provide effective radial laser emission. The geometry was conical, with a cone angle of 60 ± 5 degrees. The energy density delivered at the root canal surface for the two output powers used was 8.12 joules per square centimeter for the 175 mW setting and 17.4 J/cm² for the 350 mW setting. Heat generation from this energy density could be a problem in terms of deleterious effects on the root surface. We conducted separate tests to measure the temperature increase in the absence of water cooling at the highest power setting. We recorded the temperature continuously with the laser firing for five seconds on and approximately 10 seconds off. The maximum temperature rise under these conditions, measured at approximately 500 µm from the canal wall, was 2.6 C during continuous recording (data not shown). For thicker sections of the root, the temperature rise at the root surface would be even lower. According to Eriksson and Albrektsson,³¹ an increase of temperature that is less than 10 C is considered safe for osseous tissue.

Although we did not find total elimination of viable organisms, we did achieve a significant reduction in the viable bacterial load, approaching sterility.

Jha and colleagues³² conducted a study examining the antimicrobial effects of the Er,Cr:YSGG laser. In that study, the investigators concluded that the "Er,Cr:YSGG laser instrumentation was [not] able to eliminate an E. faecalis infection in root canals" and that "the laser was completely ineffective in disinfecting root canals when sterile saline was used as an irrigation solution." While our results are in agreement with the first statement, they are in sharp contrast to the second. In contrast to the laser’s being "completely ineffective in disinfecting root canals," we found that a high degree of disinfection (99.7 percent) could be achieved by using the Er,Cr:YSGG laser. The difference in the results may be attributed to differences in the methodology used in the two studies. In the Jha and colleagues³² study, the researchers recovered residual viable bacteria after laser treatment of infected root dentin by collecting dentin shavings from the root canal wall. They then transferred dentin shavings to broth tubes and incubated them. The development of turbidity was taken as evidence of bacteria survival of the lasing treatment. However, this model is not quantitative in the sense that a single surviving bacterial cell from the infected dentin would give precisely the same result as would a million surviving organisms: in both cases, the tube receiving the infected dentin shavings turned turbid following incubation. Therefore, according to this model, it would be impossible to determine whether any reduction (disinfection) of the bacterial population had occurred. In our model, the surviving bacteria were quantified by immediately diluting and plating the material recovered from the lased infected dentin. This allowed us to detect and measure the degree of disinfection achieved by the laser treatment. Consequently, although we did not find total elimination of viable organisms (that is, sterilization), we did achieve a significant reduction in the viable bacterial load, approaching sterility.

Our results suggest that the Er,Cr: YSGG laser may be a valuable tool for root canal disinfection of E. faecalis when one uses radially emitting laser tips. One benefit of the laser over conventional treatment is that it has the ability to achieve significant disinfection of canals infected with E. faecalis, for which there is evidence that conventional calcium hydroxide is not as effective, owing to the resistance of this type of bacterium. Should modification of the lasing procedure permit predictable, total elimination of viable bacteria in the dentin, this could justify a one-visit endodontic treatment for infected root canals. Other potential benefits of using the laser include conservation of root structure and less emphasis on mechanical instrumentation, especially in curved roots. This benefit is promising, as the laser tips are flexible and come in sizes as small as 200 µm in diameter (equal to the diameter of the tip of a no. 20 file), both of which would minimize length of procedure and dependence on mechanical instrumentation. These tips are capable of penetrating narrow, long and curved canals more efficiently, in areas that sodium hypochlorite irrigation may not be able to reach. The results of our study show that the Er,Cr:YSGG laser is able to disinfect dentinal tubules of straight roots enlarged to the diameter of a no. 4 Peeso-type reamer using a 200-µm radially emitting laser tip for 15, 30, 60, 120 and 240 seconds of cumulative exposure. More studies are needed to test the ability of the laser to disinfect curved roots that have been instrumented minimally before dentinal tubule infection in our model system.

One of our goals was to determine if either the chemical disinfection or the laser treatments under specified conditions are capable of a 100 percent reduction in infection. None of the treatment conditions was able to demonstrate such effects. The dry technique at 240 seconds of cumulative laser exposure came the closest to this objective, with a mean residual CFU percentage of 0.29 percent, which was 2.86 times lower than the most effective sodium hypochlorite (3-mL) disinfection. Further studies to evaluate new treatment protocols that could count for completed bacterial eradication need to be considered in the future.

From all that we know of pulpal and periapical disease, the elimination of infection (that is, sterilization) and prevention of subsequent infection is at the heart of endodontic therapy. To date, no existing procedure allows the clinician to sterilize an infected root canal system quickly and easily and with absolute surety. Therefore, the goal of our work was to learn whether the use of this particular laser system (Er,Cr:YSGG) could reliably accomplish this goal of root canal sterilization. While our results did not demonstrate complete elimination of infection from our root dentin models, our test system did allow us to quantify the degree of change in bacterial load after laser treatment. We found that we could achieve a 99.7 percent (nearly 3-log) reduction in viable bacteria using the laser. Given the bacterial load typically reported to be present in infected root canal systems (10³–10⁵ CFU), a 3-log decrease in titer is a significant reduction in that it approaches the goal of complete elimination of infection. Clearly, more work needs to be done; however, our results are encouraging and suggest that we are at least close to our goal.

	CONCLUSIONS

TOP ABSTRACT MATERIALS AND METHODS RESULTS DISCUSSION CONCLUSIONS REFERENCES

 
We found statistically significant differences between all groups as compared with the control. The treatment with the lowest percentage mean CFU as compared with the control—0.29 percent—was the dry treatment lasting 240 seconds with the laser at P = 350 ± 50 mW. The next groups to follow were group 12 (60 seconds, P = 350 ± 50 mW, dry) with 0.47 percent and group 15 (120 seconds, P = 350 ± 50 mW, dry) with 0.59 percent. The sodium hypochlorite, 3-mL group ranked as the fourth best with 0.83 percent. Overall, the laser showed better results than the sodium hypochlorite did, but none of the treatments demonstrated complete elimination.

The Er;Cr: YSGG laser employing radially emitting laser tips demonstrated a considerable effect on bacterial reduction within dentinal tubules of roots infected with E. faecalis. The effect depended on the time, wattage and technique (wet versus dry), each variable being used as a separate predictor. Our study demonstrated that laser treatment with radially emitting tips could be considered as an alternative method for root canal disinfection of E. faecalis in endodontic treatments.