Articles - Forum Implantologicum

Article

Feature Article

Sep 24, 2025 // 9 min read

The Effect of the Type of Gap-Grafting Materials in Post-extraction Immediate Placement

DOI: 10.63580/ITI.FI.45766

immediate implant placement graft materials peri-implant gap soft tissue augmentation bone substitute materials

Abstract

Background: Immediate implant placement (IIP) is a widely adopted clinical approach aiming to reduce treatment time and increase patient satisfaction. However, dimensional changes following tooth extraction – particularly buccal bone resorption and soft tissue recession – remain a biological challenge that may compromise esthetic and biological outcomes. Grafting the peri-implant gap has emerged as a key intervention to support ridge stability. The type of grafting material – whether for bone or soft tissue augmentation – may substantially influence wound healing dynamics and long-term success.

Objectives: This article examines the role of graft materials in managing the peri-implant gap in conjunction with immediate implant placement. It summarizes current biological insights and clinical data on autogenous, allogeneic, xenogeneic, and alloplastic grafts, focusing on their regenerative potential, clinical indications, and impact on esthetic and volumetric outcomes.

Conclusion: Peri-implant gap-grafting enhances volume stability, particularly in cases with thin buccal bone or in patients with the highest esthetic demands. Slowly resorbing xenografts demonstrate predictable contour preservation, while faster-resorbing materials may result in faster remodeling. Soft tissue phenotype, defect morphology, and implant position determine clinical decision-making. Although current evidence supports grafting in selected scenarios, further standardized, long-term studies are needed to define optimal materials and protocols.

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Introduction

Immediate implant placement (IIP) following tooth extraction offers several advantages, including reduced treatment time, fewer surgical interventions, and preservation of soft and hard tissue contours (Chen & Buser 2014). This approach has gained increasing popularity among clinicians due to its efficiency along with high patient satisfaction. However, IIP presents distinct biological and clinical challenges, particularly related to the buccal contour and management of the peri-implant gap – a horizontal defect often observed between the implant and the buccal bone wall (Fig. 1).

The gap arises because implant diameters rarely match natural root dimensions, especially in the anterior maxilla, where roots are ovoid and the facial bone is thin (Araújo et al. 2005). If the gap is left unfilled, there is a risk of soft tissue ingrowth, impaired osseointegration, and a partial loss of the alveolar ridge – most notably at the buccal aspect (Botticelli et al. 2004). Numerous studies (Araújo et al. 2006; Cosyn et al. 2013; Hämmerle et al. 2012) highlight that buccal bone resorption can lead to mucosal recession and esthetic impairments or even implant or esthetic failures (Cosyn et al. 2012). This article explores the biological and clinical principles of peri-implant gap healing in immediate implant placement. It critically assesses the available evidence on autogenous, allogeneic, xenogeneic, and alloplastic grafts, with special attention to their role in dimensional stability, soft tissue management, esthetic outcomes, and clinical decision-making.

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Fig. 1: Schematic cross-sectional illustration of the clinical situation showing “filling the gap”. The cross-section demonstrates soft tissue, alveolar bone, an implant positioned within the alveolar socket, a peri-implant gap filled with bone graft material and covered with a resorbable membrane. Such illustrations emphasize the principle that gap grafting supports clot stability, reduces buccal collapse, and improves dimensional outcomes compared with ungrafted sites

Fig. 2: Immediate implant placement (flapless) and peri-implant gap. Clinical views showing palatal positioning of the implant within the extraction socket in the anterior (A) and posterior region (B). A horizontal buccal defect is visible, indicating the need for grafting to support dimensional stability. This figure highlights a frequent clinical scenario in which gap grafting is indicated to counteract buccal resorption

Fig. 3: Implant placement and gap grafting. Intraoperative views showing implant placement with xenogeneic bone substitute (deproteinized bovine bone mineral; DBBM) used to fill the peri-implant gap in the anterior zone (A) and posterior zone (B). A resorbable collagen membrane is placed to stabilize the graft and support guided bone regeneration and contour preservation

Fig. 4: Additional soft tissue grafting and healing abutment placement. (A) Buccal soft tissue grafting to enhance mucosal thickness. (B) Adaptation of the membrane and placement of the healing abutment. (C) Radiograph after installation of implant 11 with provisional healing cap. (D) Radiograph after installation of implant 46. The sequence demonstrates how soft tissue augmentation complements gap grafting to optimize long-term esthetic outcomes

Fig. 5: Postoperative mucosal healing. (A) Healing with a provisional healing cap. (B) Healing with a standard healing abutment. In both cases, two-week postoperative views show soft tissue closure and initial integration around the healing abutment

Fig. 6: Tissue maturation phase after 3 months. Clinical follow-up shows stable, well-adapted soft tissue contours with sufficient keratinized mucosa

Fig. 7: Final restorations in place. (A, B, C) Clinical view of the implant-supported restoration with stable mucosal conditions. The buccal contour shows slight volume loss consistent with expected remodeling. (D, E) Radiographs of the final restoration in place