Silvio Valdec1, Pavla Pasic2, Alex Soltermann3, Daniel Thoma4, Bernd Stadlinger2, Martin Rücker2. 1. Clinic of Cranio-Maxillofacial and Oral Surgery, Center of Dental Medicine, University of Zurich, University Hospital Zurich, Plattenstrasse 11, 8032, Zürich, Switzerland. silvio.valdec@zzm.uzh.ch. 2. Clinic of Cranio-Maxillofacial and Oral Surgery, Center of Dental Medicine, University of Zurich, University Hospital Zurich, Plattenstrasse 11, 8032, Zürich, Switzerland. 3. Institute of Surgical Pathology, University Hospital Zurich, Zurich, Switzerland. 4. Clinic of Fixed and Removable Prosthodontics and Dental Material Science, Center of Dental Medicine, University of Zurich, Zurich, Switzerland.
Abstract
INTRODUCTION: Ridge preservation can be performed with autologous bone, alloplastic bone substitute material or a combination of both. Dentin is similar to bone in its chemical composition. In its use as bone substitute material, it undergoes a remodelling process and transforms to bone. The presented case report introduces a technique in which the extraction socket is augmented with autologous, particulated dentin. MATERIAL AND METHODS: The fractured, non-savable mesial incisor of the upper jaw was carefully extracted in axial direction. After the extraction, the tooth was cleared from remaining periodontal tissue. The vital pulp tissue or a root canal filling, enamel and cementum were also removed. Following the particulation of the remaining dentin in a bone mill, the dentin particles were immediately filled orthotope into the alveolar socket. The soft tissue closure was performed with a free gingival graft of the palate. RESULTS: After an observation period of 4 months, an implant was placed in the augmented area, which osseointegrated successfully and could be restored prosthodontically in the following. The results of this method showed a functional and aesthetic success. CONCLUSION: The pre-implantological, autologous ridge preservation with dentin could be performed successfully. For the establishment of dentin as augmentation material for jaw augmentation procedures, a prospective, clinical trial is now necessary.
INTRODUCTION: Ridge preservation can be performed with autologous bone, alloplastic bone substitute material or a combination of both. Dentin is similar to bone in its chemical composition. In its use as bone substitute material, it undergoes a remodelling process and transforms to bone. The presented case report introduces a technique in which the extraction socket is augmented with autologous, particulated dentin. MATERIAL AND METHODS: The fractured, non-savable mesial incisor of the upper jaw was carefully extracted in axial direction. After the extraction, the tooth was cleared from remaining periodontal tissue. The vital pulp tissue or a root canal filling, enamel and cementum were also removed. Following the particulation of the remaining dentin in a bone mill, the dentin particles were immediately filled orthotope into the alveolar socket. The soft tissue closure was performed with a free gingival graft of the palate. RESULTS: After an observation period of 4 months, an implant was placed in the augmented area, which osseointegrated successfully and could be restored prosthodontically in the following. The results of this method showed a functional and aesthetic success. CONCLUSION: The pre-implantological, autologous ridge preservation with dentin could be performed successfully. For the establishment of dentin as augmentation material for jaw augmentation procedures, a prospective, clinical trial is now necessary.
Entities:
Keywords:
Alveolar ridge preservation; Autologous augmentation; Bone augmentation; Bone substitute; Particulated dentin
Subsequent to tooth extraction, a resorption of the host bone as defined by atrophy of the alveolar ridge can be observed. Sutton et al. classified the different degrees of alveolar ridge atrophy [32]. Bone resorption especially occurs in the frontal and premolar area of the jaw in the region of the thin buccal lamella. This may lead to a change in contour [11, 28]. Physiological reason for this atrophy is the periodontal ligament blending into the bone. Overall, a total clinically relevant loss of bone height of approximately 2–5 mm in the first 6 months can be observed in the vertical dimension [10, 20]. After 12 months, the alveolar ridge may lose up to 50% of its width. With regard to dental implants, this implicates that an implant insertion in a sufficient bone bed will often not be possible. In order to prevent this bone atrophy, different methods of alveolar ridge preservation have been described. The augmentation of extraction sockets with deproteinized bovine bone is clinically well established and has analysed in various studies [17, 18, 31]. Systematic reviews showed a preservation of the bone contour for this method [6, 15].Today, clinical techniques like the socket-shield technique are performed [9]. Applying this technique, a vestibular slice of the tooth root is left in the alveolar socket during tooth extraction. The reason is to prevent the resorption of the vestibular bony lamella. Studies show the osseointegration of implants having been inserted in such areas, thus indicating the biocompatibility of autologous tooth material [8, 13, 16]. The application of autologous dentin as a bone substitute for alveolar augmentation may serve as an alternative to the usage of xenogeny biomaterials. The chemical properties of dentin show a close relationship to bone and demonstrated a good osseous regeneration in an animal model [9].Aim of this case series is to demonstrate the augmentation with autologous dentin as an interesting alternative to the application of xenogeny grafts.
Material and methods
Clinical technique
Four patients between 36 and 65 years of age are presented in this case series. There was no financial compensation. All four patients suffered from a trauma, causing damage to one or two teeth of the anterior maxilla. The frontal tooth/teeth has/had to be extracted. The pulp of the extracted teeth of three patients and the root canal filling of one patient had to be removed. All patients were informed on the operative procedure and possible risks and signed an informed consent. Treatment options were discussed.After mouth rinsing with a chlorhexidine solution (Chlorhexamed® FORTE 0.2%, GlaxoSmithKline Consumer Healthcare GmbH & Co.KG, Bühl, Germany), local anaesthesia (4% Ubistesin® with 1: 200,000 adrenaline, 3M Espe AG, Seefeld, Germany) was applied. The tooth extraction was performed carefully using a special extraction-system (Benex II extraction-system, Helmut Zepf medical technology GmbH, Seitigen-Oberflacht, Germany) in order to preserve bone and soft tissue (Figs. 1 and 2).
Fig. 1
Extraction with the benex system
Fig. 2
The remaining root of tooth 11
Extraction with the benex systemThe remaining root of tooth 11The clinical and radiographic examination showed healthy periodontal structures; the buccal wall was intact without fenestration with a minimal thickness of 1 mm; the discrepancy between the buccal height of the socket and the palatal height was not more than 3 mm; and the socket was within the bony envelope in all four cases.The root surface was carefully cleaned from periodontal tissue. The pulp was removed, using a root canal instrument (K-file, Dema Dent AG, Bassersdorf, Switzerland). Layers of enamel and cementum were removed, using a rotating instrument (Diamond polisher, Rodent AG, Montlingen, Switzerland) (Figs. 3 and 4).
Fig. 3
Removal of the pulp
Fig. 4
Removal of enamel and the cementum
Removal of the pulpRemoval of enamel and the cementumSubsequently, the remaining dentin was cut into pieces (Bone rongeur forceps, Carl Martin BmbH, Solingen, Germany). These pieces of dentin were grinded using a bone mill (USTOMED INSTRUMENTE, Ulrich Storz GmbH & Co., Tuttingen, Germany) in order to achieve a particle size between 0.25 and 2 mm (Figs. 5 and 6).
Fig. 5
Autologous dentin in a bone mill
Fig. 6
Autologous dentin with the desired particle size
Autologous dentin in a bone millAutologous dentin with the desired particle sizeThe autologous, particulated dentin was mixed with autogenous blood from the operating site (Fig. 7) and carefully inserted into the alveolar socket under controlled pressure to the level of the palatal/vestibular bone plate (Fig. 8).
Fig. 7
Autologous, particulated dentin mixed with blood from the operating site
Fig. 8
Autologous, particulated dentin in the alveolar socket
Autologous, particulated dentin mixed with blood from the operating siteAutologous, particulated dentin in the alveolar socketAn autologous soft tissue graft was harvested from the patient’s palate using a soft tissue punch (Biopsy Punch, kai Europe GmbH, Solingen, Germany) (Fig. 9). The graft had a comparable dimension as the recipient site. The gingival graft was placed on top of the augmentation material, adapted and carefully sutured to the marginal gingiva after the sulcus epithelium was removed with a rotating diamond (Vicryl 6-0, Ermed AG, Schleithem, Switzerland) (Fig. 10).
Fig. 9
Soft tissue punch
Fig. 10
Soft tissue graft placed on the recipient site
Soft tissue punchSoft tissue graft placed on the recipient siteIn order to evaluate the ridge preservation properly, a cone beam computed tomography (CBCT, 3D Accuitomo, J. Morita Mfg. Corp., Kyoto, Japan) was taken post-surgery with a resolution of 0.25 mm (scan time 17.5 s, 90 kV, 5 mA). The findings were assessed on a computer (HP Compaq 6200 Pro Microtower PC, graphics card: Intel HD Graphics 2000 Dynamic Video Memory Technology, mouse: HP Compaq DC 172B; Hewlett Packard, Palo Alto, CA, USA) with a calibrated monitor (HP Compaq LA 2306x; Hewlett Packard, Palo Alto, CA, USA) using the reconstruction software Morita version I Dixel (J. Morita Mfg. Corp., Kyoto, Japan) (Figs. 11 and 12).
Fig. 11
Sagittal view
Fig. 12
Axial view
Sagittal viewAxial viewThe patients received antibiotics peri-operatively and for 7 days post-surgery (Amoxicillin® 750 mg 1-1-1).The first follow-up consultation was 7 days post-surgery. The patients did not report any discomfort, and wound healing was regular in all four cases. No clinical signs of significant infection or graft loss were present. The sutures were removed 14 days post-surgery. Consecutive follow-up examinations did not show any complications, and implant placement was performed after 3 to 4 months (Fig. 13a, b).
Fig. 13
a, b Clinical situation prior to implant placement
a, b Clinical situation prior to implant placementThe height and width of the ridge were sufficient prior to implant placement, which left at least 2 mm of buccal bone after implant placement.
Case presentation
The 1-year follow-up examination of the presented case showed an implant success, according to the appropriate clinical criteria [2] (Figs. 14, 15 and 16).
Fig. 14
Single tooth X-ray immediately after the augmentation using autogenous dentin
Fig. 15
Single tooth X-ray, showing a constant bone level 7 months after implant placement
Fig. 16
Single tooth X-ray, 1 year post-implantation, showing the finalized crown
Single tooth X-ray immediately after the augmentation using autogenous dentinSingle tooth X-ray, showing a constant bone level 7 months after implant placementSingle tooth X-ray, 1 year post-implantation, showing the finalized crownThe pink esthetic score (PES) was used for the evaluation of reproducible soft tissue around the final implant crown as a parameter for the aesthetic outcome [12]. Seven variables were evaluated comparing the soft tissue around the implant with the neighbouring reference tooth. Using a 0-1-2 scoring system, the mesial papilla, distal papilla, soft tissue level, soft tissue contour, alveolar process deficiency, soft tissue colour and texture were evaluated.The situation before the extraction of the tooth was scanned with an intraoral scanner (CEREC Omnicam®, Sirona-Dentsply, Bensheim, Germany), also the situation after the finalized prosthodontic restoration. The scans were superimposed, and the difference of the vertical and horizontal dimensions was calculated with specialized analysis software (Oracheck, Cyfex, Zurich, Switzerland).
Results
Four months post-extraction and augmentation with autologous, particulated dentin, all four patients received an implant placement in the augmented area. In all cases, a CBCT was taken in between the dentin augmentation and the implant placement.During implant placement, a biopsy of the bone from the augmented area was taken for histological examination (Fig. 17).
Fig. 17
Histology of dentin augmentation. a
Asterisk denotes incorporated dentin particle, surrounded by vital woven bone. Triangle shows reactive process in the bone marrow lacunae with osteoblast rimming. No signs of necrosis or infection (H&E stain, ×100 magnification). b Larger magnification at ×200. c EvG (Elastica van Gieson) stain, ×200
Histology of dentin augmentation. a
Asterisk denotes incorporated dentin particle, surrounded by vital woven bone. Triangle shows reactive process in the bone marrow lacunae with osteoblast rimming. No signs of necrosis or infection (H&E stain, ×100 magnification). b Larger magnification at ×200. c EvG (Elastica van Gieson) stain, ×200The final prosthetic solution demonstrated a functional and esthetical success of the used treatment method (Fig. 18).
Fig. 18
Finalized prosthetic restoration after 1 year
Finalized prosthetic restoration after 1 yearIn the presented case, a PES of 13 was evaluated, deducting one point for the soft tissue level under critical observation.A loss of 0.76 mm in the vertical dimension and a loss of 1.1 mm in the horizontal dimension could be observed in the calculation of the superimposed situations before extraction and 1 year after finalized prosthetic restoration (Figs. 19 and 20).
Fig. 19
Colour-coded superimposition of intraoral scans before extraction and after definitive prosthetic restoration
Fig. 20
Colour-coded superimposition of intraoral scans before extraction and after definitive prosthetic restoration
Colour-coded superimposition of intraoral scans before extraction and after definitive prosthetic restorationColour-coded superimposition of intraoral scans before extraction and after definitive prosthetic restoration
Within the limits of this case series, it has been shown that particulated dentin of autologous teeth may serve as an alternative to autologous bone for alveolar ridge preservation prior to implant therapy. However, randomized studies on this treatment option are necessary.
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