Comparison of Single Versus Multiple Low-Level Laser Applications on Bone Formation in Extraction Socket Healing in Rabbits (Histologic and Histomorphometric Study)

Comparison of Single Versus Multiple Low-Level Laser Applications on Bone Formation in Extraction Socket Healing in Rabbits (Histologic and Histomorphometric Study) Nesma Mohamed Khalil, BDS, MSc, PhD,* and Marwa G. Noureldin, BDS, MSc, PhDy Purpose:

This study evaluated the effect of low-level laser therapy (LLLT) on bone healing after tooth extraction in healthy rabbits and compared the effect between single and multiple doses of laser therapy.

Materials and Methods:

Thirty-six New Zealand white male rabbits were randomly divided into 3 equal groups: a control (C) group, a single laser (SL) group, and a multiple laser (ML) group. The mandibular right first premolar was extracted. The SL group received a single dose of diode laser immediately after extraction. The ML group received a dose immediately after extraction and then every 72 hours for 12 days. The C group extraction sites were left untreated by laser. Eighteen animals were sacrificed at each of the experimental periods 3 and 6 weeks after extraction. The sockets were removed from the harvested mandibles and prepared for light microscopic examination and histomorphometric analysis.

Results:

The SL and ML groups showed more bone formation and rapid maturation compared with the C group at 3 and 6 weeks postoperatively. At 6 weeks, the SL group showed the formation of compact bone. Furthermore, the ML group exhibited well-vascularized bone marrow spaces. Histomorphometric analysis showed an increase in the percentage of newly formed bone in the SL and ML groups compared with the C group. Moreover, the difference in the percentage of newly formed between the SL and ML groups was not statistically relevant.

Conclusion:

This rabbit model showed that single or multiple diode laser applications can be used to enhance bone formation after tooth extraction. Ó 2019 American Association of Oral and Maxillofacial Surgeons J Oral Maxillofac Surg 77:1760-1768, 2019

Tooth extraction is the most frequently performed surgical procedure in dentistry. Healing after extraction is a normal straightforward process that occurs in most cases. However, problems can occur and lead to a longer healing period that can be associated with discomfort to the patient.1

A blood clot is an essential step for the subsequent phases of tissue healing. Cells, such as fibroblasts, endothelial cells, macrophages, and osteoblasts, are attracted to the blood clot. These cells are fundamental for the development and maturation of tissue until complete healing is achieved.2

Received from Faculty of Dentistry, Alexandria University,

sity, Champolion Street, Azarita, Alexandria, Egypt; e-mail: nesma_

Alexandria, Egypt. *Lecturer, Department of Oral Biology.

[email protected] Received February 23 2019

yLecturer, Department of Oral and Maxillofacial Surgery.

Accepted March 27 2019

Conflict of Interest Disclosures: Neither author has any relevant

Ó 2019 American Association of Oral and Maxillofacial Surgeons

financial relationship(s) with a commercial interest.

0278-2391/19/30363-5

Address correspondence and reprint requests to Dr Khalil:

https://doi.org/10.1016/j.joms.2019.03.037

Department of Oral Biology, Faculty of Dentistry, Alexandria Univer-

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Several studies have described different methods to accelerate the repair process, including mechanical stimulation,3,4 low-intensity ultrasound,5,6 7,8 electromagnetic material, biological growth factors,9 and low-level laser therapy (LLLT).10,11 LLLT can biologically modulate and quicken the healing process by stimulating cell proliferation, vascularization, and bone formation.12 However, the suitable amount of energy required to provide notable new tissue formation with a higher quality of organization within a shorter period remains the most important question and has yet to be answered.13 The outcome of LLLT varies according to treatment parameters, which are power, power density, wavelength, energy, energy density, beam profile, duration, and frequency of treatment.14 The aim of this study was to evaluate the effect of LLLT on bone healing after tooth extraction in healthy rabbits and to compare the effect between single and multiple doses of laser.

Materials and Methods Thirty-six New Zealand white male rabbits (age range, 8 to 10 months; weight, 2 to 2.5 kg) were randomly divided into 3 equal groups (12 rabbits each): a control (C) group, a single laser (SL) group,

and a multiple laser (ML) group. This study was conducted according to the rules of research on experimental animals and approved by the Faculty of Dentistry at the Alexandria University (Alexandria, Egypt; institutional review board number 00010556IORG 0008839). According to MacNeill et al,15 42 days are needed for complete bone healing in rabbits. Therefore, in the present study, bone healing was assessed 3 and 6 weeks after extraction to investigate the first and last stages of bone healing. TOOTH EXTRACTION

The animals received an intramuscular injection of ketamine hydrochloride (35 mg/kg; Rotexmedica, Trittau, Germany) plus xylazine (5 mg/kg; Xyla-ject; Adwia Pharmaceuticals SAE, Cairo, Egypt). After onset of local anesthesia, the lower right first premolars were extracted. A straight elevator was used to luxate the tooth, and then the tooth was carefully rotated and extracted using forceps (Fig 1). The tip of the elevator was pressed against the apical part of the socket to break down the apical germinal tissue to halt tooth regrowth.16 To decrease pain, diclofenac sodium (75 mg/3 mL; Voltaren; GSK, Brentford, UK) was injected intramuscularly. After surgery, the antibiotic

FIGURE 1. Surgical phase. A, Extraction socket. B, Extracted tooth. Khalil and Noureldin. Laser for Bone Formation in Extraction Socket. J Oral Maxillofac Surg 2019.

1762 cefotaxime sodium (500 mg; Cefotax; Atlantic Pharmaceuticals, Inc, Atlanta, GA) was injected for 4 days. LASER APPLICATION

A diode laser device was used in this study (Lambda SpA, Brendola, Italy). Laser parameters were calibrated as 980-nm wavelength, 0.5-W power output, 60-second duration, and continuous wave mode. For the SL and ML groups, the diode laser tip was held in close contact to the socket (Fig 2), allowing all walls to be lasered.16 The SL group received a single dose immediately after extraction. The ML group received a dose immediately after extraction and then every 72 hours for 12 days. Extraction sites in the C group were left untreated by laser. HISTOLOGIC ANALYSIS

Eighteen rabbits (6 from each group) were euthanized with an overdose of ketamine 3 and 6 weeks postoperatively. The mandibles were obtained and split into 2 halves. A saw was used to obtain the socket area of the right mandibular first premolar. Specimens were fixed in 10% neutral buffered formalin, washed, and then decalcified in 10% trichloroacetic acid. After washing, the specimens were dehydrated in ascending grades of alcohol, cleared in xylene, and infiltrated and embedded in paraffin wax. Sections 4 to 5 mm thick were cut buccolingually from the paraffin blocks using a rotary microtome and stained with hematoxylin and eosin.17 Light microscopic examination of the sections was conducted by a calibrated examiner who was blinded to the experimental groups.

FIGURE 2. Laser application to the socket after tooth extraction. Khalil and Noureldin. Laser for Bone Formation in Extraction Socket. J Oral Maxillofac Surg 2019.

LASER FOR BONE FORMATION IN EXTRACTION SOCKET HISTOMORPHOMETRIC ANALYSIS

Histomorphometric evaluation of the newly formed bone was performed using ImageJ 1.46r (National Institutes of Health, Bethesda, MD). Three buccolingual sections from each specimen were obtained at different standardized depths. For each section, a photograph was taken at the apical third of the socket18,19 using the same magnification (100). On each photograph, the total surface area was measured. Then, the bone marrow spaces were outlined using the brush tool from the tool bar. Afterward, all bone marrow spaces were selected using the wand tracing tool and their surface area was measured. To obtain the surface area occupied only by bone, the bone marrow surface area was subtracted from the total area. The same procedure was repeated for the other 2 sections and the mean was obtained. The percentage of newly formed bone was calculated as follows20: % newly formed bone = (bone surface area/total surface area)  100 The same procedure was repeated for each of the 6 samples in each group. The results obtained were expressed as mean and standard deviation. Analysis of variance was used to compare all groups. The significance level was set at .05, and P values less than .05 were statistically significant. SPSS 20.0 (IBM Corp, Armonk, NY) was used for statistical analysis.

Results HISTOLOGIC RESULTS

After 3 Weeks Histologic examination of specimens obtained from the C group showed limited new bone formation radiating from the socket wall. The bone consisted of spicules containing large, numerous, and haphazardly arranged osteocytic lacunae covered by osteoblasts. Some osteoclasts also were seen lining some parts of the bone trabeculae. The bone marrow spaces appeared well vascularized (Fig 3). The SL group exhibited greater bone formation. The bone appeared more mature, with relatively thick cancellous bone trabeculae, which contained numerous parallel resting lines indicating successive bone formation (Fig 4). Similar to the SL group, the ML group exhibited more numerous and mature bony trabeculae compared with the C group. Wellvascularized bone marrow spaces were visible (Fig 5). After 6 Weeks Light microscopic examination of the 6-week specimens showed the formation of more bone compared with the 3-week specimens of the C, SL, and ML groups. In the C group, the socket

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FIGURE 3. Light micrographs of socket healing in the control group after 3 weeks. A, Newly formed bone spicules (arrows) can be seen extending from the socket wall for a limited distance toward the center of the socket and surrounding vascularized bone marrow spaces (stars). The central part of the defect contains dense fibrous tissue (arrowheads). B, Higher magnification of the inset in A showing the structure of the bony spicules, which contain numerous osteocytes (short arrows) and are lined by osteoblasts (long arrows). Areas of active bone formation are noted by the high density of bone-forming cells (arrowheads). Upper inset, Plump osteoblasts (arrows). Lower inset, Osteoclast cells on the endosteal surface of bone trabeculae (arrows) (hematoxylin and eosin stain; magnification, 40 in A, 100 in B, 400 in insets). Khalil and Noureldin. Laser for Bone Formation in Extraction Socket. J Oral Maxillofac Surg 2019.

was filled with cancellous bone trabeculae, which appeared relatively thin and disconnected, that surrounded well-vascularized bone marrow spaces. Moreover, the osteocytic lacunae were haphazardly

arranged (Fig 6). In contrast, in the SL and ML groups, more bone formation was observed, which appeared more organized than in the C group. In the SL group, compact and cancellous bone types

FIGURE 4. Light micrographs of the healing socket at 3 weeks in the single laser group. A, A larger amount of newly formed bone is seen extending from the socket wall toward its center. The socket exhibits thin newly formed bony spicules (solid stars), and the deeper portions contain denser and more mature bone trabeculae (hollow stars), which contain numerous resting lines (arrows). Blood vessels containing red blood corpuscles are seen in the bone marrow spaces (arrowheads). B, Higher magnification of the inset in A showing the structure of the woven bone. A line of demarcation (arrows) between the old and newly formed bone is visible. In the deeper areas of the socket, dense fibrous tissue is visible (arrowheads). Inset, Osteoblasts (short arrows) lining the bone surface, osteoclasts (long arrows), and large, irregularly arranged osteocytic lacunae (arrowheads) (hematoxylin and eosin stain; magnification, 40 in A, 100 in B, 400 in insets). Khalil and Noureldin. Laser for Bone Formation in Extraction Socket. J Oral Maxillofac Surg 2019.

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FIGURE 5. Light micrographs of the healing socket at 3 weeks in the multiple laser group. A, Newly formed bone with different trabecular thicknesses. Some trabeculae appear relatively thin (solid stars), whereas others appear relatively thick (hollow stars). B, Higher magnification of the inset in A showing the structure of the cancellous bone trabeculae surrounding well-vascularized bone marrow spaces (arrows). A line of demarcation is visible between the old and newly formed bone (arrowheads) (hematoxylin and eosin stain; magnification, 40 in A, 100 in B). Khalil and Noureldin. Laser for Bone Formation in Extraction Socket. J Oral Maxillofac Surg 2019.

were seen. The compact bone consisted of small osteons composed of a centrally located Haversian canal and concentric bone lamellae. Relatively plump osteoblasts were seen lining the bone trabeculae (Fig 7). Moreover, in the ML group, thick cancellous bone trabeculae were seen traversing the socket area and contained regularly distributed osteocytes. Bone marrow spaces were well vascularized. Remodeling of bone was evident by the presence of some osteoclasts in their lacunae (Fig 8).

HISTOMORPHOMETRIC ANALYSIS

The percentage of bone surface area in the different groups is presented in Table 1. At 3 weeks, the SL and ML groups showed an increase in the percentage of bone surface area compared with the C group; however, the difference between the SL and C groups was not significant (P = .108). At 6 weeks, there was a statistically significant increase in the percentage of bone surface area in the SL and ML groups compared with the C group (P = .008 and .019, respectively). In addition, no statistically significant difference between the SL and

FIGURE 6. Light micrographs of the socket healing at 6 weeks in the control group. A, Cancellous bone trabeculae fill the defect area especially at the central part of the socket (arrows), whereas other parts appear with relatively wide marrow spaces (arrowheads). B, Higher magnification of the inset in A showing the organization of the bone trabeculae, which appear relatively irregular and discontinuous. Wellvascularized bone marrow spaces (arrows) are seen. Inset, Flattened osteoblasts lining bone surface (arrows) and a relatively irregular arrangement of osteocytes (arrowheads) (hematoxylin and eosin stain; magnification, 40 in A, 100 in B, 400 in inset). Khalil and Noureldin. Laser for Bone Formation in Extraction Socket. J Oral Maxillofac Surg 2019.

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FIGURE 7. Light micrographs of the healing socket at 6 weeks in the single laser group. A, Formation of cancellous (solid stars) and compact bone (arrows) filling the socket. B, Higher magnification of the inset in A showing the structure of the compact bone, which consists of many small osteons (arrows). Inset, Continuous layer of osteoblasts (arrows) can be seen lining the bone trabeculae, which appear more voluminous than those seen in control group (hematoxylin and eosin stain; magnification, 40 in A, 100 in B, 400 in inset). Khalil and Noureldin. Laser for Bone Formation in Extraction Socket. J Oral Maxillofac Surg 2019.

ML groups was noted at 3 and 6 weeks postoperatively (P = .873 and .896, respectively).

Discussion LLLT can involve multiple laser applications, which require more time and higher costs compared with a single laser application. Most previous studies investigated the effect of multiple applications of low-level laser on bone healing.21-25 Few studies investigated the effect of a single laser application on bone

healing.26,27 Therefore, the present study was conducted to assess and compare the effect of a single dose versus multiple doses of diode laser on bone repair after tooth extraction in rabbits and whether a single laser application could be sufficient to provide similar effects as multiple laser applications. This was determined histologically and histomorphometrically. The rabbit model was chosen because it is simple to handle compared with rat and mouse models. Moreover, the Haversian systems of rabbits are similar to

FIGURE 8. Light micrographs of the healing socket at 6 weeks in the multiple laser group. A, Formation of relatively thick and interconnected cancellous bone trabeculae (solid stars) occupying the socket area and surrounding marrow spaces of different sizes and obvious vascularity (arrows). B, Higher magnification of the inset in A showing the organization of the bony trabeculae with relatively regularly distributed osteocytes (short arrows) and osteoblasts (long arrows) lining the outer surface of the trabeculae. Numerous blood vessels are visible (arrowheads). Inset, Osteoclasts (arrows) in Howship lacunae (hematoxylin and eosin stain; magnification, 40 in A, 100 in B, 400 in inset). Khalil and Noureldin. Laser for Bone Formation in Extraction Socket. J Oral Maxillofac Surg 2019.

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Table 1. COMPARISON AMONG THE 3 STUDIED GROUPS ACCORDING TO PERCENTAGE OF BONE SURFACE AREA

Control Group (n = 6) 3 wk Significance among groups 6 wk Significance among groups P0

57.9  8.1 P1 = .108, P2 = .043*, P3 = .873 68.7  4.8 P1 = .008*, P2 = .019*, P3 = .896 .018*

Single Laser Group (n = 6)

Multiple Laser Group (n = 6)

F Value

P Value

66.0  5.6

67.8  5.3

4.045*

.039*

80.0  4.4

78.6  7.1

7.483*

.006*

.001*

.014*

Note: Analysis of variance was used to compare F values, and pairwise comparison between 2 groups was performed using the Tukey post hoc test. The P value compared the 3 study groups. Abbreviations: P0, P value by Student t test for 3 versus 6 weeks; P1, P value for control versus single-laser group; P2, P value for control versus multiple-laser group; P3, P value for single-laser versus multiple-laser group. * Statistically significant at P # .05. Khalil and Noureldin. Laser for Bone Formation in Extraction Socket. J Oral Maxillofac Surg 2019.

those of humans, which is a vital advantage in terms of using the outcomes obtained with such animals for understanding human bone healing.28 LLLT involves the use of low levels of red and near infrared light for therapeutic purposes. It also is called ‘‘cold laser’’ because it does not produce heat in the penetrated tissues. The wavelength range of LLLT is 600 to 1,070 nm.29 Shorter wavelengths (<700 nm) are used for superficial tissues, and longer wavelengths have deeper penetration and a greater biological stimulatory effect.29-33 Therefore, in this study the wavelength of the diode laser used was 980 nm to ensure better penetration of the socket after extraction. In the present work, results of the single and multiple diode laser applications showed enhanced new bone formation and rapid maturation after tooth extraction. In the C group after 3 weeks, the bone consisted mainly of woven bone. However, in the SL and ML groups, mature bone was seen, which showed more thick cancellous bone trabeculae. In addition, at 6 weeks the osteoblasts lining the bone trabeculae in the SL group appeared more voluminous compared with the C group. This was in agreement with the report by Mirdan27 who used a single 980-nm dose of diode laser on rabbit dental sockets and concluded that there was stimulation and facilitation of the bone healing process in addition to its effect on coagulation of the blood, which provided a dressing for the wound site. This enhancement of new bone formation can be explained by the stimulatory effect of laser on the function of osteoblasts. Several studies found that LLLT was effective in the stimulation of osteoblastic

differentiation.34-36 Furthermore, laser can increase the expression of osteocalcin and several growth factors, including transforming growth factor-b1 and bone morphogenetic protein-2 from osteoblasts.37 In addition, histologic observations of the present work showed that LLLT at 6 weeks led to enhanced bone formation, which exhibited regularly distributed osteocytic lacunae, compared with the C group, which exhibited haphazardly arranged osteocytes. This is in accordance with the work of Tas Deynek and Ramoglu25 who found that laser application to expanded sutures in rats led to marked increases in osteoblasts and osteocytes compared with the control group. The effect of LLLT on cells is known as biostimulation. When the light reaches the cell, it is absorbed by a certain chromophore inside the mitochondria.29 This leads to excitation of electrons,38 controls reactive oxygen species production, increases the production of adenosine triphosphate,39 and upregulates the production of transcription factors.40 These transcription factors are key molecules for the regulation of other cellular activities, including the proliferation, differentiation, and secretion of growth factors and cytokines.30 Contrary to the present results, Bouvet-Gerbettaz et al41 and Coombe et al42 found that laser had no beneficial effect on the proliferation and differentiation of osteoblasts. Moreover, Atasoy et al23 studied the effect of multiple LLLT irradiation on tibia bone defects in rats and found no relevant difference in the number of osteoblasts, osteocytes, and osteoclasts and new blood vessel formation between the control and laser-irradiated groups. These conflicting

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outcomes of LLLT application on bone repair could have been caused by the variation of the physical parameters used by different researchers. The present histologic observations showed the presence of some osteoclasts on the endostea surface of bone trabeculae in the SL group at 3 weeks and in the ML group at 6 weeks. Schell et al43 reported that osteoclasts play an important role in all phases of bone healing. These cells not only resorb bone but also maintain the structural integrity of bone and its physiologic remodeling throughout life. Furthermore, Cackowski et al44 proved that osteoclasts can stimulate angiogenesis through the secretion of matrix metalloproteinase-9 (MMP-9). In adults, MMP-9 is mainly produced by osteoclasts and to a lesser extent by cells such as osteoblasts, macrophages, and neutrophils.45-47 One of the suggested mechanisms for the role of MMP-9 in enhancing angiogenesis is that it can release growth factors such as vascular endothelial growth factor from the bone matrix.48-50 Light microscopic observations of the ML group in the present study showed well-vascularized bone marrow spaces at 3 and 6 weeks and in the SL group at 3 weeks. Good vascularity is important during bone healing. This finding corresponds to the results of Tim et al51 who investigated the effect of LLLT (830 nm) on angiogenic genes in rat tibia bone defects. They concluded that laser increased the expression of angiogenic genes, such as angiopoietin-2 and -4, platelet-derived growth factor, and fibroblast growth factors-2 and -14, especially during the early stages of bone healing. Moreover, Garavello et al52 reported on the dual action of low-level laser on angiogenesis in tibia bone defect healing in rats. They found an increase in the number of blood vessels in the irradiated group after 1 week; however, after 2 weeks there was a notable decrease in the blood vessel count. In the authors’ opinion, this could be attributed to the shorter wavelength used in that study (633 nm), resulting in insufficient laser penetration. In the present study, histologic qualitative analysis showed the formation of compact bone in the SL group at 6 weeks. This indicates the rapid and enhanced bone remodeling and structural organization of the formed bone inside the socket after laser irradiation. Histomorphometric analysis of the present work was accomplished using ImageJ 1.46r software. Histomorphometry is used to evaluate bone healing and provide a numerical assessment to facilitate comparison among different groups.18 ImageJ has many advantages and is considered a reliable and inexpensive software for the evaluation of changes in different tissue structures.53 The present histomorphometric analysis confirmed the light microscopic observations, in which an increase in the percentage of bone surface

area was noted in the SL and ML groups compared with the C group at the 2 observational periods. However, the increase was not relevant in the SL group at 3 weeks. In addition, no relevant difference was detected between the SL and ML groups at the 2 observational periods. Furthermore, at 6 weeks, the SL group showed a larger percentage of bone surface area compared with the ML group (80 and 78.6%, respectively), but the difference was not significant (P = .896). These results suggest that the single laser application can be effective in enhancing bone formation compared with the multiple laser application. These findings corroborate those of Pretel et al26 who concluded that the application of diode laser at a single dose directly to surgically created bone defects in rats abbreviated the bone healing process and was effective in accelerating bone repair compared with non-lasered surgical wounds. However, Ng et al13 compared single versus multiple laser applications on the repair of the medial collateral ligament and stated that multiple laser treatments produced better outcomes compared with a single treatment using similar parameters. In conclusion, based on the present results, laser irradiation after tooth extraction can be effective in enhancing bone formation in the rabbit model. This can be attributed to its stimulatory effect on boneforming cells and enhanced angiogenesis. Furthermore, the single laser application can be as effective as multiple laser applications. This could be an important advantage in clinical practice to save time and lower the cost of several laser irradiations.

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