|Year : 2018 | Volume
| Issue : 4 | Page : 348-352
Clinical parameters, histological analysis, and laser Doppler flowmetry of different subepithelial connective tissue grafts
Ricardo Rabelo Eustachio1, Rafael Ferreira1, Nair Cristina Margarida Brondino2, Carla Andreotti Damante1, Maria Lucia Rubo De Rezende1, Adriana Campos Passanezi Sant'ana1, Sebastião Luiz Aguiar Greghi1, Mariana Schutzer Ragghianti Zangrando1
1 Department of Prosthodontics and Periodontics, Division of Periodontics, Bauru School of Dentistry, University of São Paulo, Bauru, SP, Brazil
2 Department of Mathematics, São Paulo State University, Bauru, SP, Brazil
|Date of Submission||12-Apr-2018|
|Date of Acceptance||25-Jun-2018|
|Date of Web Publication||20-Jul-2018|
Dr. Ricardo Rabelo Eustachio
Department of Prosthodontics and Periodontics, Division of Periodontics, Bauru School of Dentistry, University of São Paulo, Bauru, SP
Source of Support: None, Conflict of Interest: None
| Abstract|| |
Subepithelial connective tissue graft (SCTG) presents favorable outcomes. However, the harvesting technique can influence the anatomical and histological composition of the SCTG. Within the limitations of a case report, the behavior of SCTGs removed by two techniques was evaluated bilaterally in one patient using double blade scalpel (DBS) and de-epithelialized graft (DE). Clinical parameters, laser Doppler flowmetry (LDF) and histological analysis were assessed. Complete root coverage was observed bilaterally, as well as improvement in width and thickness of keratinized tissue 2 years postoperatively. The LDF analysis demonstrated better revascularization in the DBS recipient area compared to DE. The histological evaluation showed differences in tissue composition and organization of collagen fibers. Similar clinical outcomes were observed bilaterally, nevertheless greater morbidity and aesthetic was reported in the DE harvesting area.
Keywords: Connective tissue, histology comparative, laser-Doppler flowmetry, tissue harvesting
|How to cite this article:|
Eustachio RR, Ferreira R, Brondino NC, Damante CA, De Rezende ML, Sant'ana AC, Greghi SL, Zangrando MS. Clinical parameters, histological analysis, and laser Doppler flowmetry of different subepithelial connective tissue grafts. J Indian Soc Periodontol 2018;22:348-52
|How to cite this URL:|
Eustachio RR, Ferreira R, Brondino NC, Damante CA, De Rezende ML, Sant'ana AC, Greghi SL, Zangrando MS. Clinical parameters, histological analysis, and laser Doppler flowmetry of different subepithelial connective tissue grafts. J Indian Soc Periodontol [serial online] 2018 [cited 2020 Feb 25];22:348-52. Available from: http://www.jisponline.com/text.asp?2018/22/4/348/237199
| Introduction|| |
Periodontal plastic surgery can be defined as surgical procedures performed to prevent or correct anatomic, developmental, traumatic or disease-induced defects of gingival tissues, mucosa or alveolar bone.,, The indications of surgical procedures for root coverage (RC) are: to avoid abrasion or root caries, improve the inconsistency or disharmony of the gingival margin, for esthetic reasons, alveolar ridge defects, reduction of dentin hypersensitivity, and keratinized tissue augmentation.,,
The subepithelial connective tissue graft (SCTG) associated with coronally advanced flap is considered the gold standard treatment for RC in Miller Class I and II gingival recessions.,, However, SCTG can present different anatomical and histological characteristics depending on the harvesting technique. Different techniques are available to obtain SCTG from palatal donor site,,,,,,, including the de-epithelialized graft (DE), which is the removal of a free gingival graft with subsequent graft de-epithelization;, and double blade scalpel (DBS) technique, using a specific scalpel with two parallel blades, usually 1.5 mm apart. Regardless of the technique employed, the selected site for harvesting the SCTG must provide an adequate amount of tissue, avoiding risks to the patient with lower postoperative morbidity.,
Thus, the objective of this case report was to compare, by clinical parameters, laser Doppler flowmetry (LDF), and histological analysis, the behavior of SCTG removed by two techniques: DBS and DE.
| Case Report|| |
Patient, female, 29 years old, Caucasoid, complaining about bilateral tooth hypersensitivity at the region of premolars and molars, associated with esthetic impairment. Before performing any procedure, the patient was instructed about the actions involving the dental treatment and signed a free and informed consent and authorization form for the publication of clinical data in this study.
The patient presented thin periodontal biotype and Miller Class I  multiple gingival recessions in these areas, as well as traumatic brushing habits. The patient was instructed to perform tooth brushing by the modified Stillman technique. Surgical treatment of the recession defects was not scheduled until the patient reached bleeding on probing (BOP) and plaque index (PI) lower than 20%.
Surgeries were performed with an interval of 30 days, and both sides had the same surgical protocol except for the graft harvesting technique. Both surgeries were performed by a single trained surgeon. [Figure 1]a and [Figure 1]b demonstrate the initial clinical aspects of surgical areas with multiple gingival recessions in premolars and first molars. The technique employed in recipient sites was described by Zucchelli and De Sanctis  [Figure 1]c and [Figure 1]d. The split-full-split flap was raised [Figure 1]e allowing complete graft and RC without tension [Figure 1]f. Papillae de-epithelization was performed [Figure 1]g with Goldman-Fox scissor, and the graft was stabilized at the level of the cementoenamel junction [Figure 1]h. Suspensory sutures complemented by simple suture [Figure 1]i and [Figure 1]j promoted coronally advanced flap with total coverage of the SCTG and positioned 1 mm coronally to the cementoenamel junction using a 5-0 nylon suture. The right site received a DBS graft [Figure 2]a, [Figure 2]b, [Figure 2]c, [Figure 2]d and the left recipient site received DE [Figure 2]e, [Figure 2]f, [Figure 2]g, [Figure 2]h, drawn with a coin. In the DBS surgery, the DBS was positioned parallel to the long axis of the tooth, moving from distal to mesial, deepening all the extension of the active surface of the scalpel into the palatal tissue in regular movements [Figure 2]a. Internal lateral and apical incisions were made to remove the graft, leaving the most external portion of connective tissue and epithelium in the palate. The size of each graft was previously marked with the back of the blade on the palatal donor site [Figure 2]e. In both techniques, grafts were removed with approximately 1.5 mm of thickness. [Figure 2]b and [Figure 2]f demonstrate the anatomical differences of DBS graft and DE, respectively. Both grafts were de-epithelized using 15C (Swann-Morton ®) blades [Figure 2]c and [Figure 2]g. DBS palatal donor site presents an approximation of the incised edges [Figure 2]d, while the DE harvesting technique leaves an extensive area of secondary intention healing [Figure 2]h.
|Figure 1: (a) Intraoral view of multiple gingival recessions on the right side; (b) and left side; (c and d) surgical procedure involving premolars and first molars with oblique incisions by Zucchelli and De Sanctis; (e and f) split-full-split flap without tension; (g) papillae de-epithelization; (h) graft stabilization at the cementoenamel junction; (i and j) 5-0 nylon sutures with coronally advanced flap|
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|Figure 2: Graft harvesting techniques used in surgeries on the right side (a, c, e and g) and left side (b, d, f and h) (a) double blade scalpel; (b) donor site marking for later removal of de-epithelialized graft; (c) graft obtained by the double blade scalpel– DBS; and (d) de-epithelialized graft– de-epithelialized graft; (e and f) epithelium removal on the table and (g and h) suture of donor bed sites|
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The clinical measurements were performed by a single blinded and calibrated examiner. Data were collected at baseline and after 1 and 2 years postoperatively [Table 1].
|Table 1: Clinical parameters of double blade scalpel and de-epithelialized graft recipient sites at baseline and after 1 and 2 years postoperatively|
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The following periodontal parameters were assessed: Probing depth, BOP, PI, keratinized tissue width (KTW), soft tissue thickness (STT) and recession depth. STT was determined 1.5 mm apically to the gingival margin at the mid-buccal point with an anesthetic needle and round endodontic stop, using a digital caliper (MTX ®, Digital Caliper).
To determine the mean %RC, percentage of the gain of KTW (%GKTW) and Gain of STT (%GSTT) the formula proposed by Zucchelli et al. was used [Figure 3].
|Figure 3: Formula for clinical measurements evaluation, being Px the parameter of interest in percentage. This formula was used to calculate the (percentage of root coverage), (percentage of gain in soft tissue thickness) and (percentage of gain in keratinized tissue width)|
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Compared to the initial aspects [Figure 4]a and [Figure 4]b, evaluation after 1 [Figure 4]c and [Figure 4]d and 2 years [Figure 4]e and [Figure 4]f postoperatively revealed the stability of RC and gain of KTW. The coverage rate was 100% in premolars while the molars showed only partial coverage, but with an increase in keratinized tissue and reduction in recession depths. Only premolars received SCTG since they were the targeted elements in the RC and solely the coronally advanced flat was performed in both first molars.
|Figure 4: Multiple gingival recessions at right (double blade scalpel) and left sites (de-epithelialized graft) (a and b); root coverage with double blade scalpel (c) and de-epithelialized graft (d) after 1 year; root coverage with Double Blade Scalpel (e) and de-epithelialized graft (f) after 2 years|
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Evaluations with visual analog scales were made considering the aesthetics in recipient areas and morbidity in donor sites. After 2 years, the patient reported esthetic preference for the left side (DE), but this technique caused greater discomfort in the postoperative period (in analyses at 0, 7, 14, and 28 days). An esthetic analysis was also carried out (considering color, texture, and regularity of the gingival margin in comparison to adjacent tissues) by a periodontist blinded to the surgical procedures, who also considered the left side had the most favorable esthetics.
Laser Doppler flowmetry
For the blood flow assessment, a LDF (VMS-LDF2 DUAL CHANNEL-Laser Doppler Blood Flow and Temperature Monitor, trademark Moor instruments) was employed at baseline, 2, 7, 14, and 28 days after the surgical procedures. The appliance is equipped with two probes that were stabilized with the use of individual silicone guides, providing a standardized probe positioning for the consecutive measurements. The guide had two perforations corresponding to the central part of the grafted connective tissue, being one drilled in a more mesial position and the other more distally, both aligned. The measurements with the LDF lasted 2 min in the two points simultaneously, and the collected data were analyzed by the statistical software Matlab ® and Excel Worksheet, then plotted to generate centroid graphs, and drawn as a result of this flowmetry analysis [Figure 5].
|Figure 5: Centroid graphs generated by plotting of the measured data regarding flowmetry of grafts removed by Double Blade Scalpel and de-epithelialized graft technique. The flowmetry can be assessed in these graphs by the area and quantity of blue dots and the increase of these points in relation to flows at moments t-1 and t. Double Blade Scalpel: subepithelial connective tissue graft removed by double blade scalpel; de-epithelialized graft: subepithelial connective tissue graft removed by de-epithelialized graft technique|
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The Doppler flowmetry showed a difference between values obtained on each side of the mouth (compared to the baseline values), demonstrating that the mean flow measured from the DE graft tended to be lower when compared to the graft removed by DBS, at all moments. The DBS graft presented a pattern of flow that returns and overtakes the baseline levels at 28 days, while the DE presented a much lower and variable flow rate in all measured periods. In addition, the lowest area of blue points in DE centroid graphs shows a more heterogeneous flow pattern. In DBS, the largest area of the ellipse represents greater homogeneity of the flow and the revascularization process as well.
Incisional biopsies (fragment measuring 1 mm wide with graft length and thickness) were performed before de-epithelization of the grafts to confirm and analyze the nature of each harvested tissue. Histological sections were stained by H and E for evaluation on a microscope (Carl Zeiss, Germany) [Figure 6].
|Figure 6: Histological images of grafts before de-epithelization; (a-e) de-epithelialized graft at ×4 (a), ×20 (b and c) and ×40 (d and e). The double blade scalpel graft is presented (f-j), at ×4 (f), ×20 (g and h) and ×40 (i and j). The ×20 and ×40 represent the coronal portion (b, d, g and i) with the remaining epithelial portion of the grafts, followed by the connective tissue (c, e, h and j)|
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The palatal fibromucosa is characterized by a dense connective tissue (lamina propria) covered with ortho-keratinized epithelium and a layer composed of the considerable amount of fatty and glandular tissue (submucosa) with variable thickness,,, as shown in [Figure 6]a, [Figure 6]b, [Figure 6]c, [Figure 6]d, [Figure 6]e, [Figure 6]f, [Figure 6]g, [Figure 6]h, [Figure 6]i, [Figure 6]j. The images [Figure 6]e and [Figure 6]j evidence the different types of collagenization for each graft. In the DE graft, more organized collagen fibers [Figure 6]e give the appearance of denser connective tissue. In the DBS [Figure 6]j, it is possible to observe greater spacing between the fibers, leading to a looser aspect. These differences may be due to the predominance of each type of tissue present in the grafts. Normally there is a predominance of lamina propria in the DE grafts and submucosa in DBS, as shown on the ×4, in which the DBS [Figure 6]f presents the apical portion with more space between the tissue structures, characterizing a more disorganized tissue. However, individual variations should be considered in setting the tissue type of each graft.
| Discussion|| |
Regardless of the type of connective tissue harvested, complete RC was achieved bilaterally. Enlargement of the KTW (%GKTW) reached 16% for DBS and 33% for DE and thickness (%GSTT) showing 126% for DBS and 16% for DE, were observed after 2 years postoperatively. In the esthetic analysis, both patient and periodontist considered best results at the DE site; however, the patient reported increased postoperative morbidity in DE donor area. The LDF showed a tendency of better and constant revascularization at all periods of measurement for DBS graft about DE. Histological analysis revealed differences in graft composition, with greater quantity of fibrous connective tissue and less spacing between fibers in DE compared to DBS. However, further studies are required to confirm these differences with a statistically significant sample.
In the present case report, better results were observed for DBS in %GSTT 2 years postoperatively. STT measurements were determined 1.5 mm apically to the gingival margin and partial marginal necrosis of DE graft was observed after 7 days postoperatively. Therefore, these factors may have influenced an inferior %GSTT for the DE site. This finding is by Zuhr et al., who suggested that very dense and coarse connective tissue appears to undergo necrosis more easily. The LDF analysis suggested more heterogeneous results, with the lower mean flow in the DE grafted area compared to DBS. This result can be associated with the greater difficulty of revascularization of a denser SCTG regarding collagen fibers and less spacing between them, as observed in the histological evaluation. The operating principle of the LDF has some measurement-related limitations (small movements).
Although there are different techniques for obtaining SCTG ,,,,,,, some factors must be considered. The decision-making process regarding the best technique for harvesting the SCTG should be based on scientific evidence, but also should consider the amount of available tissue in the eligible sites, the morbidity to the patient  and in particular, the preference of the clinical operator. Within the limitations of a clinical case, this report showed no differences in the clinical results achieved by two distinct types of SCTG, despite the histological differentiation and a tendency of smaller initial revascularization in the DE graft, as verified by LDF.
| Conclusion|| |
Both techniques (DBS and DE) presented satisfactory clinical and esthetic outcomes in this case report. The different histological pattern of these types of grafts may be associated with variations in the revascularization process, verified by LDF. However, randomized clinical trials are required to better assess the real clinical differences as well as the results, using different types of SCTG harvesting techniques aiming at RC.
Declaration of patient consent
The authors certify that they have obtained all appropriate patient consent forms. In the form the patient(s) has/have given his/her/their consent for his/her/their images and other clinical information to be reported in the journal. The patients understand that their names and initials will not be published and due efforts will be made to conceal their identity, but anonymity cannot be guaranteed.
Financial support and sponsorship
This study was supported by FAPESP (São Paulo Research Foundation) grant #2012/13331-2for the purchase of laser Doppler flowmeter (VMS-LDF2 DUAL CHANNEL- Laser Doppler Blood Flow and Temperature Monitor, trademark Moor instruments). The foundation had no role in study design, data collection and analysis, decision to publish or preparation of the manuscript.
Conflicts of interest
There are no conflicts of interest.
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