The most frequent aesthetic complication following single implant treatment seems to be a lack of buccal convexity. This 'alveolar process deficiency' is the result of buccal bone remodeling following tooth extraction. A traditional approach to treat alveolar process deficiency is guided bone regeneration (GBR), however post-operative complications such as swelling, bleeding and pain are common and the aesthetic outcome may not be optimal. An alternative to the traditional GBR approach could be soft tissue contour augmentation using a connective tissue graft (CTG) at the buccal aspect. Possible advantages over GBR include less morbidity at the implant site, a superior aesthetic outcome since there is no need for vertical releasing incisions and less costs since there are no biomaterials to be used. The primary study objective is to compare the GBR and CTG group in terms of 2 and 3 dimensional tissue alterations, focusing on the amount of tissue gain and volume stability over time. The secondary study objectives are morbidity, overall radiographic, clinical and aesthetic outcomes.
Aim: This study aims to compare guided bone regeneration (GBR) with connective tissue graft (CTG) to re-establish buccal convexity at single implants. Sample size calculation: The sample size calculation was based on the primary study outcome (BSP) and was performed in SAS Power using the Satterthwaite t-test (De Bruyckere et al., 2018). The calculation was based on finding a mean difference of at least 0.5 mm between these groups with a standard deviation of 0.5 mm. This standard deviation was arbitrarily chosen given the lack of comparative studies. Alpha was set at 0.05 and the power was set at 0.80. This resulted in the inclusion of at least 17 patients per group. To compensate for possible drop-outs, 21 patients were included in each group. Randomization and allocation concealment: Patients were randomly assigned to the control group (GBR) or test group (CTG). Simple randomization was performed using sealed envelopes with an equal number of envelopes for every treatment group. Group allocation was revealed just prior to surgery by the surgeon and remained concealed for the evaluating investigator during the analytical stage of the project. Surgical procedure: In brief, a mucoperiosteal flap was raised in the control group by means of a midcrestal incision, sulcular incisions at both neighbouring teeth and a vertical parapapillary releasing incision at the distal neighbouring tooth. Following implant installation (NobelActive®, Nobel Biocare, Gothenburg, Sweden), the buccal concavity was augmented with deproteinized bovine bone mineral (DBBM) (Bio-Oss®; 0.25 - 1mm; Geistlich Biomaterials, Wolhusen, Switserland) and a collagen membrane (Creos® xenoprotect; 15x20mm; Nobel Biocare, Gothenburg, Sweden). Following apical release of the tissues, a cover screw was installed and primary wound closure was achieved (Seralon® 5/0, Serag Weissner, Naila, Germany). Aftercare included the use of a chlorhexidine rinse, systemic antibiotics (amoxicillin 1g, two times a day) and anti-inflammatory medication (ibuprofen 600mg) as deemed necessary by the patient. After 3 months, the implant was uncovered by means of a pouch procedure. A screw-retained provisional crown was placed as described by De Rouck et al. (2008), which was replaced by the permanent restoration (Procera® on ASC® abutment, Nobel Biocare, Gothenburg, Sweden) 3 months later. The flap design in the test group was identical to the one in the control group, yet without a vertical parapapillary releasing incision. Instead of augmenting with DBBM, an appropriately sized CTG harvested from the palatal flap or palatal mucosa in the premolar area was pulled into the envelope and immobilized (Seralon® 5/0, Serag Weissner, Naila, Germany). Non-submerged healing was respected. Aftercare and prosthetic procedures were identical in both groups. All surgical treatments and provisional restorations were performed by the same clinician. Referring dentists made permanent restorations.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
TREATMENT
Masking
SINGLE
Enrollment
42
One or two releasing incisions are made. The periosteum is released and multiple bone perforations are made in the buccal bone prior to the application of deproteinized bovine derived xenograft. A Creos® membrane (Nobel Biocare, Gothenburg, Sweden) is used to cover the occlusal part of the alveolar crest and the xenograft particles. Finally, multiple single monofilament sutures are used for primary tension-free wound closure.
A CTG is taken from the palate and transplanted to the buccal side between the alveolar bone and the buccal flap. The CTG is secured with single monofilament sutures.
Buccal soft tissue profile
The volumetric analysis software (Swissmeda/SMOP, Zürich, Switzerland) calculated a mean dimensional change (mm3) within the AOI (area of interest) for each patient at T5 (3 years). Given the variable size in AOI (mm2) among patients, the mean dimensional change per area was transformed to a mean linear change in buccal soft tissue profile (BSP) in mm.
Time frame: Year 1 and 3
Midfacial recession
Midfacial recession was registered between 6 months, 1 year and 3 years on the basis of digital surface models in STL format superimposed and imported in designated software (Swissmeda/SMOP, Zürich, Switzerland). Midfacial recession was calculated by subtracting the data from 1 and 3 years to 6 months of follow-up.
Time frame: Month 6; Year 1 and 3
Buccal bone thickness
The thickness of the buccal bone was measured (in mm) at t2 (1 year) and t3 (3 years) perpendicular to the long axis of the implant. Buccal bone was measured from the implant surface to the bone-soft tissue interface at 3 levels.
Time frame: Year 1 and 3
Buccal soft tissue thickness
The thickness of the soft tissues was measured (in mm) at t2 (1 year) and t3 (3 years) perpendicular to the long axis of the implant. Buccal soft tissue thickness was measured from the bone-soft tissue interface to the buccal soft tissue outline at the same levels as buccal bone thickness.
Time frame: Year 1 and 3
Pink Esthetic Score
The PES awards 7 parameters: mesial papilla, distal papilla, soft tissue level, soft tissue contour, alveolar process deficiency, soft tissue colour, soft tissue texture. Each parameter is assessed with a 0-1-2 score, yielding a PES score ranging from 0 (worst aesthetic outcome) to 14 (perfect aesthetic outcome).
Time frame: Year 1 and 3
Mucosal Scarring Index
The MSI is a composite index based on five parameters: width, height/contour, colour, suture marks and overall appearance. Each parameter is assessed with a 0-1-2 score, yielding an MSI score ranging from 0 (no scar) to 10 (most extreme scar).
Time frame: Year 1 and 3
Marginal bone loss
Marginal bone loss was recorded at the mesial and distal aspect of each implant. The distance from the implant-abutment interface to the first bone-to-implant contact (so-called bone level) was assessed on peri-apical radiographs taken with the long-cone paralleling technique. Mesial and distal values were averaged to receive one value per implant.
Time frame: Year 1 and 3
Probing depth
Probing depth was registered at four locations (mesiobuccal, buccal, distobuccal and palatal) around the implant to the nearest 0.5 mm. A mean value was calculated per implant.
Time frame: Year 1 and 3
Plaque
Plaque was assessed at four locations (mesiobuccal, buccal, distobuccal and palatal) around the implant. Each location was scored 0 or 1 (the absence or presence of plaque, respectively). Plaque was expressed as a percentage.
Time frame: Year 1 and 3
Bleeding on probing
Bleeding on probing was assessed at four locations (mesiobuccal, buccal, distobuccal and palatal) around the implant. Each location was scored 0 or 1 (the absence or presence of bleeding, respectively). Bleeding on probing was expressed as a percentage.
Time frame: Year 1 and 3
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