Abstract
Combining different procedures to reduce the number of surgical sessions and patient discomfort in implant placement and sinus floor elevation has been recommended, and evidence supports good outcomes. The aim of this study was to review the results of clinical studies on sinus floor elevation through extraction sockets and simultaneous immediate posterior implant placement. An electronic search was carried out in PubMed, Scopus, and Web of Science to find English articles published in or before August 2020. A manual search was also performed. Titles, abstracts, and the full-text of the retrieved articles were studied. Thirteen studies met our eligibility criteria: 6 retrospective case series, 3 case reports, 2 prospective cohort case-series, 1 prospective case series, and 1 randomized controlled trial. Overall, 306 implants were placed; 2 studies reported implant survival rates of 91.7% and 98.57%. The others either did not report the survival rate or reported 100% survival. Sinus floor elevation through a fresh extraction socket and simultaneous immediate implant placement appears to be a predictable modality with a high success rate. However, proper case selection and the expertise of the clinician play fundamental roles in the success of such complex procedures.
Maxillary sinus floor pneumatization occurring after posterior maxillary tooth extraction can jeopardize straightforward implant placement1. Following tooth extraction and discontinuation of the blood supply provided by the periodontal ligament (PDL), the alveolar ridge undergoes resorption2. The physiological process of ridge resorption during the bone healing and remodeling phase3 and pneumatization of the maxillary sinus4 are important factors that affect the amount of residual bone in the posterior maxilla. Both the quantity and quality of bone reflect the low density of bone in this region4, and any combination of the aforementioned factors can complicate dental implant placement in the posterior maxilla. Several approaches have been suggested to solve those problems5. Sinus floor elevation can be performed via the crestal and lateral approaches6-8. In 1976, Tatum was the first to describe the sinus floor elevation technique6, and the surgical approach for sinus floor elevation was published by Boyne and James in 19807. Because the lateral approach is an invasive technique associated with significant postoperative discomfort, Summers8 proposed the use of osteotomes and the crestal approach in 1994, claiming that that approach solved the problems of limited bone quality and quantity in the posterior maxilla.
Accessing the Schneiderian membrane via the crestal approach and elevating it after entering the sinus cavity were modifications made over time, and in 2017, Pawar et al.9 discussed their efficacy.
In the crestal approach for dental implant placement, the remaining bone height is what matters most in achieving primary stability10. Moraschini et al.11, in a comprehensive review in 2017, concluded that the remaining bone height is more important than the use or omission of graft materials and bone substitutes beneath the sinus membrane in the process of sinus lifting. Achieving primary implant stability is a common requirement of two of the most common implant surgeries: sinus floor elevation simultaneous with implant placement and immediate implant placement in fresh extraction sockets12.
The history of immediate implant placement in fresh extraction sockets dates back to 1976, when Schulte and Heimke13 suggested the approach as a strategy to save time. Alveolar bone remodeling starts immediately after tooth extraction. Evidence shows that the process of bone resorption begins 14 days after tooth extraction and can involve more than 20% of the buccal cortical bone2. Thus, immediate implant placement saves time, eliminates the need for a second surgical procedure, and decreases patient discomfort and the cost of treatment14,15. Previous studies claimed that immediate implant placement could prevent alveolar bone collapse16, but recent investigations have shown that it only limits bone remodeling and can even result in more bone loss compared with early implant placement17,18. Immediately placed implants have lower survival and success rates than delayed implant placements19, and marginal bone loss and peri-implant soft tissue changes are mentioned as shortcomings of immediate implant placement; however, there is a lack of data about the success/survival rate and marginal bone loss of delayed implant placements20.
In general, the posterior maxillary bone has a lower density than other parts of the jaw. Thus, achieving primary stability is more difficult, which could explain the lower success rate of immediate implants placed in the posterior maxilla compared with the mandible4,21. Given that the goal of implant treatment is functional reconstruction of the posterior maxilla, the treatment plan can include the extraction of hopeless teeth, time allocated for healing the extraction sockets, sinus floor elevation in a separate session via the lateral or crestal approach to increase bone height, and eventual implant placement. Alternatively, a treatment plan that condenses all of those procedures into a single session would be ideal for patients, with the benefit of a short course of treatment and fewer surgical procedures15.
Therefore, we extracted and reviewed the results of clinical studies about sinus floor elevation through the extraction socket and simultaneous, immediate implant placement.
This systematic review was conducted by following the principles of the PRISMA (Preferred Reporting Items for Systematic Reviews and Meta-Analyses) statement.
The focused question was: What are the differences among techniques presented for simultaneous closed sinus floor elevation with implant placement in fresh extraction sockets?
We included all human clinical studies of the immediate placement of implants in fresh extraction sockets in the posterior maxilla with sinus floor elevation via the same extraction sockets. The search was limited to English-language studies. Abstracts, letters, and reviews were excluded.
All patients who needed the extraction of a tooth/teeth in the posterior maxillary region, sinus floor elevation through the extraction socket(s), and immediate implant placement in the fresh socket(s) were included.
Studies were included if they mentioned simultaneous closed sinus floor elevation with implant placement in fresh extraction sockets in the posterior maxillary region. Studies that did not perform sinus floor elevation through a fresh socket in the posterior maxilla or did not place implants immediately were excluded.
The primary outcome was the survival/success rate of the installed implants with a minimum of six months of follow-up. The survival rate represents the persistence of implants, with no implant removal during follow-up, whereas the success rate represents criteria such as soft/hard tissue level, probing pocket depth, and bleeding on probing22. Also, the following variables were mentioned in some studies:
• Healing time between the surgical and prosthetic phases
• Detailed surgical protocols/materials
The information source were PubMed, Web of Science, and Scopus databases. The search was limited to English-language studies published before the end of August 2020. Hand searching was also conducted.
An electronic search was performed using the following keywords: Maxillary sinus AND (augmentation OR lift OR elevation) AND extraction, Maxillary sinus AND (augmentation OR lift OR elevation) AND osteotome sinus, Maxillary sinus AND (augmentation OR lift OR elevation) AND immediate implant placement.
Two reviewers conducted the search using those keywords and then performed an initial screening of the titles and abstracts they found. Any disagreements between the reviewers were resolved by discussion. The reviewers then reviewed the full-text of the selected articles.
Data were extracted from the full-text of the articles and tabulated for comparison. The following variables were evaluated: technique of tooth extraction, extraction with/without elevating a flap, distance from the tooth apex to the sinus floor, instrument and technique for elevating the sinus floor, magnitude of the elevation of the sinus membrane, use or no use of graft materials and bone substitutes, implant height, method of wound closure in the coronal implant region, success rate and survival of implants, and the duration of follow-up.
Review and data extraction were performed according to the PRISMA flow diagrams. After the full-text of the selected articles were reviewed, data were extracted and tabulated. Disagreements between reviewers were resolved by consensus.
The quality of the methodologies used in all the included studies was assessed. The criteria used were based on the ROBINS-I tool23: bias due to confounding, bias in selecting participants, bias in classifying interventions, bias due to deviation from the intended intervention, bias due to missing data, bias in outcome measurements, and bias in selecting the reported results. The criteria used for the one randomized controlled trial were obtained from the Cochrane Center: selection bias, performance bias, detection bias, attrition bias, and reporting bias. The degree of bias was categorized as low risk, moderate risk, and serious risk. In cases with no data about a criterion, ‘no information’ is stated. Two individual investigators (L.K. and A.K.) performed the assessment and resolved conflicts through discussion.
The initial search found 368 articles. After removing duplications and irrelevant studies, 89 studies were screened, which excluded 76 more articles because they did not perform sinus floor elevation through the socket of an extracted tooth or they did not place implants immediately after tooth extraction and sinus floor elevation. Therefore, 13 articles are described in this review.(Fig. 1) The results are reported in the form of questions and answers and presented in Tables 1 to 6.
Of the 13 articles reviewed, 12 provided the number of patients evaluated12,15,21,24-27,29-33, and one did not28. A total of 245 patients were evaluated. Six studies reported the mean age of the patients15,24,27,31-33. Four studies mentioned only the age range of patients (youngest and oldest)12,25,26,28. Three studies evaluated only one patient and provided their exact age21,29,30. In the 13 reviewed studies, the youngest patient was 18 years, and the oldest was 74 years.
Overall, 306 implant fixtures were placed in 245 patients. The number of patients matched the number of inserted implants in eight studies12,21,25,26,30-33. In one study33, 10 implants were placed for 10 patients; out of which 8 were considered to be fresh socket implant placements simultaneous with sinus floor elevation, whereas in 2 cases, radiographs revealed that (in contrast to the researcher’s belief at the time of surgery) the sinus membrane had not actually been elevated. In four studies, the number of implants placed was greater than the number of patients15,24,27,29. In one of those studies29, despite the immediate placement of two implants in one patient, only one was accompanied by sinus lifting. Another study did not report the number of implants placed28. In one study27, both premolar and molar sites underwent sinus lifting. Four studies15,24,32,33 evaluated only molar sites, and four studies12,29-31 evaluated only premolar sites. In the randomized controlled trial, implant placement was performed for 33 patients immediately after tooth extraction and sinus lifting (test group), whereas the other 35 patients received implant placement and sinus lifting three months after tooth extraction (control group)15. Even though sinus floor elevation is more commonly performed in the premolar and molar regions, one study reported performing sinus floor elevation at the canine site, in addition to the premolar site26.
Six articles did not mention the probable existence of infection in the sockets15,21,25,28,30,31; four articles did not have any infected teeth in their patients15,21,24,29, and three studies excluded infected cases15,32,33. In three studies, prophylactic antibiotics were recommended12,15,27. In the two of them that included periapical radiolucencies or endodontal lesions, the survival rates were similar in infected and non-infected sites12. Among the 70 dental implants installed in patients with a possible history of endo/periodontal disease, one fixture failed, but the exact etiology of that failure was not mentioned27.
Three studies reported using a Periotome for atraumatic tooth extraction12,27,30. Four studies did not mention the instruments used for tooth extraction21,25,28,29. Routine instruments available for tooth extraction, such as elevators and forceps, were used in the remaining studies. Among the 13 studies, one did not provide any information about the type of flap28, and 6 studies adopted the flapless technique21,24,27,29,30,32. In the six other studies, a full-thickness flap was elevated12,15,25,26,31,33.
An osteotome with a hand mallet was used for sinus floor elevation in nine studies12,15,25,26,28,29,30,31,33. However, in one study, piezosurgery was performed first to reach the Schneiderian membrane, and then the sinus membrane was elevated using an osteotome31. In another study, an osteotome was used with an electrical mallet to control the force27. In one study, a bone expander was used with a mallet, which was believed to be similar to traditional osteotomes24. However, in two studies, rounded drills were used to reach the intact sinus membrane, and then various instruments were used to detach and elevate it15,32.
Three of the 13 studies did not mention whether or not they used grafts or biomaterials27,28,30. Of the remaining 10 articles, two studies reported placing no graft material beneath the sinus membrane15,26. One study used plasma rich in growth factors (PRGF) as an autograft for sinus membrane elevation31. One study placed a collagen sheet beneath the sinus membrane24, and two studies used collagen compounds along with a xenograft25,32. One study used only a xenograft29. Another study used a xenograft or synthetic beta-tricalcium phosphates33, whereas another article reported using a xenograft in some cases and an allograft in others12. Only one article placed a xenograft with platelet rich fibrin (PRF) in the space between the implant and the socket walls21.
Five of the 13 articles used periapical radiography21,26,29,30,31, and four used periapical radiography along with an occlusal or surgical template to increase the accuracy of measurements24,25,27,33. One study used periapical or panoramic radiography12. One study used cone-beam computed tomography (CBCT)15, and another one used both CBCT and periapical radiography32. In one study, one patient had a panoramic radiograph in his records, but the type of radiography used for the other patients was not specified28.
Three studies mentioned the magnitude of sinus floor elevation15,25,31, of which two measured it directly and reported that it was approximately 2.9 mm25, 3.6 mm (case group), and 3.4 mm (control group)15. The other study31 estimated the magnitude of sinus floor elevation to be 4.2 mm by measuring the approximate distance from the implant apex to the sinus floor. Seven studies mentioned the implant height12,21,24,25,27,30,33. The most common implant height in all the reviewed studies was 13 mm; the shortest implant was 10 mm, and the longest was 15 mm.
Six studies evaluated the effect of using or not using bone grafts on the amount of bone gain, and their results can be categorized into two groups12,24,25,31-33. The first group, which reported bone gain, included the following studies. A study that used collagen sponges alone24 and reported that the mean bone height at baseline (time of surgery) was 6.02±0.75 mm, which increased to 8.05±1.58 mm at the one-year follow-up and remained constant at 8.01±1.46 mm thereafter. Another study used a combination of collagen and xenograft bone powder25 and reported 4.2±1.4 mm of bone gain at the 18-month follow-up. One study used an allograft in 4 out of 5 patients, and the remaining patient received a xenograft. The amount of bone gain was reported to be 1-4 mm at the 6- and 12-month follow-ups12. Another study used xenograft or beta tricalcium phosphate, and postoperative radiographs showed 2.5-6 mm of bone gain, with a mean value of 4.3 mm. Those patients showed optimal clinical stability and support of the prosthesis at their 2-year follow-up visits33.
The second group evaluated crestal bone loss. In 2008, Barone et al.25 reported no significant bone resorption after the placement of 12 implants despite elevating a full-thickness flap. Artzi et al.33 performed flap surgery for the placement of 12 implants in 2003 and reported no crestal bone resorption around the implant neck. In 2017, Chen et al.32 used the flapless technique to place 37 implants and comprehensively evaluated marginal bone resorption at the 6- and 12-month follow-ups. The mean crestal bone loss was 0.63 and 0.73 mm at the 6- and 12-month follow-ups, respectively32. Taschieri and Del Fabbro31 evaluated crestal bone loss in 2011 and reported that the peri-implant bone loss averaged 0.36±0.19 mm at the 12-month follow-up.
In two studies, the presented cases immediately received a temporary prosthesis that sealed the socket opening28,29. Two other studies used collagen sponges as appropriate closures for the socket opening27,32. One study comprehensively discussed the coronal seal26 and used three methods for this purpose: (A) providing mucosal coverage by elevating a flap, (B) using an adhesive bridge, and (C) placing a healing abutment. In some cases, a combination of those techniques (A and B or B and C) was used. In the study that used PRGF31, all implants were semi-submerged in mucosal tissue with/without PRGF. In another article, the wound was covered with a PRF membrane and loose sutures21. In the remaining cases12,15,25,26,30,32,33, the socket was partially sealed by suturing or the use of healing abutments. Of the studies that used sutures, one study reported using the palatal slipping flap technique for coronal coverage of the socket in some cases32. Another study released the flap and sutured it at the coronal part of the socket and then fabricated a temporary fixed prosthesis to prevent trauma to the surgical site; after 2 to 3 weeks, it was replaced with a removable prosthesis25.
Seven studies did not report any peri- or postoperative complications12,21,26,28-31. One study divided patients into three groups according to the distance from the apex to the sinus floor32 and reported that one patient in group 1 developed mild rhinosinusitis and cough in the first three days postoperatively, one patient from group 2 and one patient from group 3 developed fatigue, and other patients reported dental pain. Two studies reported sinus membrane perforation during the surgical procedure in two (test group) and one (control group)15 and three33 patients. Nasal bleeding was also reported in two patients in the same study33. Two other studies reported pain and swelling as well as nasal bleeding postoperatively24,27, but they also reported that those symptoms resolved within 24 to 48 hours without significant complication. Another study reported only pain and swelling postoperatively25.
Nine studies did not attach a temporary prosthesis to the implant platform before delivery of the final restoration12,15,21,25,26,30-33. Two studies by a single group of researchers25,27 fabricated a temporary prosthesis 70 days after implant placement and then delivered the final prosthesis 2 to 3 months after that. In two other studies, the treatment was accomplished by immediate delivery of a fixed prosthesis temporarily connected to the implant28,29. In one of them, the crown was out of the occlusion29 and in the other, it was loaded immediately28. In terms of time lapse until restoration, one study reported 3 to 4 months31, another indicated 4 months28, three studies mentioned 5 months24,28,29, seven studies15,21,25,26,30,32,33 reported 6 months, and one study12 reported 5 to 6 months between the surgical procedure and final restoration.
In 10 articles, all the implants were stable during the healing and follow-up periods with no failures12,15,21,24,26,29-33. One study did not specify the number of patients or implants and only mentioned the successful management of the cases28. Failures were reported in two studies25,27, which were both case-series. One of them reported the failure of 1 out of 12 implants due to infection and abscess25 that occurred 6 weeks after the surgical procedure and was categorized as an early failure. In the other study27, 1 out of 70 implants failed one month after placement, and it was successfully replaced with another implant after 6 months. Thus, those two studies reported a 91.7% success rate25 and 98.57% survival rate27 for the implants. In other studies, both those rates were 100%12,15,21,24,26,29,31-33 or no information about the survival or success rate was given28,30.
Two studies reported regular recall sessions from the time of surgery until delivery of the final prosthesis12,25. In one of them25, the postoperative patients were followed up monthly for up to 6 months for prophylaxis. After delivery of the final prosthesis, all patients showed up for regular recall sessions after 2 to 4 months. The duration of follow-up was 18 months, and radiographic examinations were carried out at 6 and 18 months postoperatively. In the second study12, the recall sessions were scheduled at 2 weeks, 2 months, and 5 months during the healing period. The final prosthesis was delivered 6 to 14 months postoperatively. After that, all patients were followed up at 6 and 12 months. One study mentioned only the time of delivery of the final prosthesis at 4 months postoperatively28 and did not mention the timing of the other follow-up sessions. Three studies followed up with patients at 12 months15,30,32 without mentioning the frequency of recall sessions during that time period. Two other studies reported a final follow-up visit with patients at 2 years27,33 but did not mention recall sessions during that period. In two studies conducted by a single group of researchers24,27, the recall sessions and radiographic examinations were scheduled at 70 days postoperatively. In one of them27, follow-up and radiographic examinations were scheduled 1 and 2 years later, but in the second study24, the follow-up sessions were scheduled annually after prosthesis delivery for a mean of 9.76±5.27 years (range, 4-17 years). In one study, radiography was performed at the time of prosthesis delivery. Of the 10 patients in that study, 1 was followed up at 12 months, 2 were followed up at 18 months, 4 were followed up at 24 months, 1 was followed up at 30 months, and 2 were followed up at 36 months26. One study reported 4 years of follow-up but did not mention the time interval between recall sessions29. In another study, the prosthesis was delivered 4 months postoperatively, and recall sessions were then scheduled 6 and 12 months after that and continued annually, with a mean follow-up time of 35.6 months (range, 24-50 months)31. In only one study, there were no recall sessions after definitive restoration delivery21.
Our assessment of the risk of bias is presented in Fig. 2. Most of the 11 non-randomized studies reported a low risk of bias in confounding. The three highest values with a moderate risk of bias were for deviation from the intended intervention (67%), classification of intervention and outcome measurements (50%), and missing data (42%). For the only randomized controlled trial, blinding of the outcome assessment was evaluated as high risk. Besides randomization bias, which presented a low risk, other criteria were reported to carry a moderate risk of bias. Considering all the values related to the risk of bias assessment, the studies included were categorized as being of moderate quality.
Sinus floor elevation with a crestal approach can be performed through the site of a healed extraction socket in an edentulous posterior maxilla (Summers’ technique) or through a fresh extraction socket as explained by Fugazzotto34 in 1999. Immediate implant placement in a fresh extraction socket at the same time as sinus floor elevation through that socket has been attempted only since 200033.
This relatively new approach has combined tooth extraction, socket healing, sinus floor elevation to increase bone height, and implant osseointegration into a single procedure15. Analyzing all the documented data collected in different studies on this topic can enhance our understanding of this technique.
The characteristics required for the success of immediate implant placement in the clinical setting include (I) atraumatic tooth extraction, (II) sterile and minimally invasive surgical procedures, and (III) adequate primary stability of the implant35,36. Of those three parameters, atraumatic tooth extraction is an important starting point because preservation of the bony socket walls is critical for achieving maximum bone formation around an implant placed in a fresh extraction socket. What matters most during tooth extraction is the precision needed to prevent traumatization of the socket.
Our aim in this systematic review was to review different techniques and determine their advantages and disadvantageous for immediate implant placement and sinus floor elevation through a fresh extraction socket in the posterior maxilla.
The elevation of a full-thickness flap can be associated with a higher risk of crestal bone resorption37. On the other hand, flapless surgery can cause errors in correct implant placement due to inadequate visualization of the surgical site38. Three sources, the PDL, bone marrow, and external periosteum, provide blood supply to the buccal bone around the teeth39,40. Following tooth extraction, the blood supply provided by the PDL is no longer available. A thin buccal plate is mainly composed of cortical bone, so in those cases, the periosteum would be the only source of blood supply to the buccal bone plate41. Therefore, elevating a flap can impair the blood supply to the buccal bone plate provided by the periosteum37, which can aggravate resorption of the buccal bone plate following tooth extraction41. Faster soft-tissue healing, decreased perioperative hemorrhaging, shorter surgical time, and less patient discomfort postoperatively are other advantages of flapless surgery. On the other hand, the surgical procedure in flapless surgery is performed blindly, which can lead to fenestration of the osteotomy site and implant mispositioning42,43. A meta-analysis conducted in 2014 compared the flap and flapless surgical procedures for implant placement in healed extraction sockets and indicated that the risk of implant failure was higher in flapless surgery in most of the reviewed studies38. It should be noted that in immediate implant placement, the coronal part of the socket allows adequate visualization of implant placement in the alveolar housing, and the soft and hard tissue conditions are favorable, so there would be no need to elevate a flap unless the surgeon wanted to reposition the flap coronally to cover the coronal part of the socket. In that case, there would be no need to elevate a full-thickness flap because a partial-thickness flap would serve that purpose. Therefore, it seems that crestal bone resorption following flap elevation in immediate implant placement is a more important issue than mispositioning of the implant.
In this review, an equal number of studies used the flap technique12,15,25,26,31,33 and flapless surgery21,24,27,29,30,32, although more implants were placed with the flapless technique (173 implants) than via flap surgery (125 implants). Implant failure occurred with both techniques.
The correlation between crestal bone resorption and flap/flapless surgery was also previously reviewed44. Those results showed that the mean magnitude of resorption was less than 1 mm or not significant25,31-33. According to the implant success criteria, that amount of resorption is within the clinically acceptable range45. Moreover, a study conducted in 2017 found no significant difference in ridge resorption following immediate implant placement with the flap or flapless technique41, which is in agreement with our findings.
Since the introduction of the closed sinus lift technique with the crestal approach8, osteotomes have been conventionally used for this purpose. In 2005, a meta-analysis reported 95.7% and 96% success/survival rates at 24 and 36 months, respectively, following implant placement with the osteotome technique, and those rates were similar to those with conventional implant placement in a partially edentulous posterior maxilla46. However, another study reported that the risk of membrane perforation posed by techniques such as the hydraulic sinus lift procedure at the crestal site was less than that with the conventional use of osteotomes9.
Osteotome use can be accompanied by some complications. The mallet strokes used in the original crestal technique to create a “green stick” fracture and access the sinus membrane can cause discomfort and complications for patients47. However, osteotomes are still popular for crestal sinus lifting, such that in 10 out of the 13 studies reviewed here, an osteotome was the main instrument used for sinus floor elevation12,15,25-31,33. One study used an electrical mallet instead of a hand mallet because the authors believed that it enabled better control of the force applied to the osteotome and decreased postoperative patient discomfort by decreasing trauma to the bone and craniofacial structures27. The authors in one of the reviewed studies used specific separating instruments to elevate the sinus membrane and reported no sign of membrane perforation during surgery32. Only two studies mentioned perforation of the sinus membrane during surgery, but they also reported that it caused no implant failure during one-year15 and two-years of follow-up12. According to the available evidence, particularly a systematic review conducted in 2016, membrane perforation is the most common complication of sinus lifting, but no significant association has been found between the implant success rate and sinus membrane perforation48. Therefore, use of osteotomes is still the gold standard for the crestal approach.
In 1994, Summers8 suggested that a minimum of 5-6 mm of residual bone height is required to ensure primary stability of the implant. Measuring the primary bone height beneath the sinus floor is easier in a healed edentulous ridge than in a fresh extraction socket. The references used for such measurements might be different in fresh extraction sockets, which is one of the limitations to accurately measuring bone changes when performing sinus lifting through an extraction socket. Our data indicate that the minimum residual bone height relative to the inter-radicular crest (as reference) was 4.54±0.64 mm32. That value was 5 mm when the interproximal crest served as the reference29. Neither of those studies reported any implant failures. A systematic review in 2014 reported that a bone height less than 4 mm was associated with a lower success rate with the osteotome technique10. In contrast, a meta-analysis conducted in 2018 showed that the survival rate of implants placed in residual bone with ≤4 mm of height was only slightly lower than that of implants placed in residual bone with >4 mm of height49. It seems that the amount of residual bone between the apex and the sinus floor and the amount of inter-radicular bone are more important to primary implant stability and the failure rate than the proximal bone level. Implant failure was reported in only two cases in the articles reviewed here. In one of the failed cases25, the minimum bone thickness between the tooth apex and sinus floor was only 2 mm but was deemed adequate for primary stability of the implant, and the reason for failure after six weeks was infection and abscess, not inadequate primary stability. The other study that reported a failed case mentioned nothing about the distance from the tooth apex to the sinus floor, nor did it specify the reason for implant failure27. However, it should be noted that in our study, similar to the meta-analysis conducted in 201849, measurements were made on periapical or panoramic radiographs; only one study used CBCT with periapical radiography for that purpose32, which could limit the accuracy of the reviewed results.
For vertical and horizontal bone expansion, osteotomes25, bone expanders and mallets24, and expander screws50 were applied in premolar, molar, and both premolar and molar sites, respectively. The overall results with these methods showed survival and success rates comparable to those of standard surgery, ranging from 95% to 100%, indicating that the choice of devices does not have a notable effect on the outcomes. Also, a recent study showed that transcrestal sinus floor elevation has no negative effect on the long-term survival rate of implants51.
The application of graft materials below the sinus membrane following its elevation is a challenging topic in sinus lifting with the crestal approach52. Some of the studies reviewed here evaluated how using or not using graft materials affected bone gain, bone loss, and the survival and success rates of implants48,53.
Two reasons have been suggested for new bone formation in a sinus cavity that has undergone sinus floor elevation using an osteotome: osteogenic activity after a mini-fracture of bone at the sinus floor and the role of mesenchymal cells present in the Schneiderian membrane54. Therefore, maintaining the sinus membrane in an elevated position, either with graft materials and bone substitutes or by the implant apex, can trigger new bone formation beneath the membrane so long as the blood clot is preserved11. A randomized clinical trial in 2013 evaluated the survival rates of implants with and without grafting and reported similar residual bone heights and survival rates of 95.2% and 95%, respectively54. The marginal bone loss did not differ significantly between the two groups after 3 years, but the amount of bone gain in the graft group was significantly higher than that in the no graft group after 6 months. However, bone gain significantly decreased after 3 years in the graft group, whereas it continued to grow slowly in no-graft group. At the 3-year follow-up, the final volume of bone within the sinus was equal in the two groups (around 3 mm)54. Nonetheless, a meta-analysis conducted in 201849 reported that the results of studies about bone gain supported the use of graft materials beneath the sinus membrane. In this meta-analysis49, the amount of marginal bone loss in the bone graft group was slightly higher than that in the no-graft group, but that difference was not significant. However, the amount of bone gain did differ significantly between the groups. No significant difference was found in the implant survival rate with the use and non-use of a bone graft beneath the sinus membrane, which was in agreement with the findings of a meta-analysis conducted in 201711. In this review, we evaluated studies that performed sinus lifting with and without the placement of bone grafts, but more studies used an autogenous bone graft29, bone substitute12,21,25,29,32,33, or collagen sponges24 than did not place any biomaterial beneath the sinus membrane26. All studies that reported bone gain used some sort of collagen material or bone substitute beneath the sinus membrane. However, it is noteworthy that in the only study that used PRGF to keep the sinus membrane elevated, the elevation averaged 2.9±0.8 mm, but the amount of bone gain was not mentioned at the time of prosthesis delivery or the follow-up sessions31. Therefore, our results are in line with the findings of a recent meta-analysis49 that showed that greater increase in bone height can be expected when using bone grafts.
Sinus floor elevation through a fresh extraction socket and simultaneous immediate implant placement seems to be a proper treatment choice and has noticeably high success. Nevertheless, case selection and the capability of the clinician are important factors.
Controlled clinical trials are seriously lacking on this topic and are therefore recommended. Calculating important data, including initial bone height, amount of sinus lifting, clinical and radiographic criteria pertaining to the success of implants, follow-up to the prosthetic and loading phases, and split mouth designs, are suggested for further studies. Also, some important factors such as patient-oriented outcomes, digital workflow, and presence of sinus septa in the apical socket should be emphasized in further research.
Acknowledgements
This research did not receive any specific grant from any funding agency in the public, commercial, or not-for-profit sector.
Notes
Authors’ Contributions
All authors have participated in the study. The concept and study design were done by M.E. L.K. and A.K. participated in data collection and wrote the manuscript. F.H. and P.F.A. participated in data analysis. The study was revised critically by M.K. The final approval was performed by R.A.
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Table 1
Study | Keywords related to sinus lift through a fresh socket in the title | Study design | No. of patients | No. of implants with sinus lift |
---|---|---|---|---|
Artzi et al.33 (2003) | Internal sinus membrane elevation in immediate post-extraction phase | Prospective case series | 10 | 10 |
Barone et al.25 (2008) | Fresh extraction socket and osteotome sinus floor elevation | Retrospective case series | 12 | 12 |
Kolhatkar et al.12 (2011) | Sinus floor elevation via extraction socket | Retrospective case series | 5 | 5 |
Bruschi et al.24 (2013) | Localized management of sinus floor technique in fresh socket | Retrospective case series | 53 | 68 |
Taschieri and Del Fabbro31 (2011) | Post-extraction osteotome sinus floor elevation using PRGF | Prospective single cohort case series | 15 | 15 |
McCrea26 (2012) | Trans-socket elevation/fracture/perforation of sinus floor | Retrospective case series | 10 | 10 |
Mandelli et al.29 (2013) | Sinus floor elevation and immediately loaded post-extraction implant | Case report | 1 | 2 |
Crespi et al.27 (2013) | Electrical mallet and osteotome sinus floor elevation | Retrospective case series | 32 | 70 |
Ebenezer et al.28 (2015) | Indirect sinus lift in immediate implant | Retrospective case series | NM | NM |
Falcón30 (2015) | Post-extraction implant with internal sinus floor elevation | Case report | 1 | 1 |
Chen et al.32 (2017) | Transcrestal sinus floor augmentation in fresh extraction socket | Prospective cohort case series | 37 | 37 |
Liu et al.15 (2019) | Sinus floor elevation using the trans-alveolar approach | Randomized controlled trial | 68 | 75 |
Sun et al.21 (2019) | NM | Case report | 1 | 1 |
Table 2
Study | Target site | Method of tooth extraction | Flap/flapless | Sinus lifting tool | Graft material used |
---|---|---|---|---|---|
Artzi et al.33 (2003) | Molar | Root hemisection, elevator, forceps | Flap | Osteotome | Synthetic beta-tricalcium phosphate xenograft |
Barone et al.25 (2008) | Premolar | NM | Full thickness with vertical release | Osteotome | Mixture of collagen gel and porcine bone particles |
Kolhatkar et al.12 (2011) | Premolar | Periotome and straight elevator | Flap | Osteotome | 4 allografts and 1 xenograft |
Bruschi et al.24 (2013) | Molar | Root hemisection | Flapless | Bone expander and mallet | Collagen sheet |
Taschieri and Del Fabbro31 (2011) | Premolar | Elevator and forceps | Full-thickness flap | Piezosurgery and osteotome | PRGF |
McCrea26 (2012) | Canine and premolar | Periotome | Full-thickness flap | Osteotome | None |
Mandelli et al.29 (2013) | Premolar | NM | Flapless | Osteotome | Xenograft |
Crespi et al.27 (2013) | 36 molars and 34 premolars | Molar hemisection | Flapless or partial flap to mobilize, if necessary | Osteotome and electrical mallet | NM |
Ebenezer et al.28 (2015) | NM | NM | NM | Osteotome | NM |
Falcón30 (2015) | Premolar | Periotome and elevator | Flapless | Osteotome | |
Chen et al.32 (2017) | Molar | Root hemisection and intra-radicular drilling | Flapless | Specific membrane separating instruments and evaluation with endoscope-guided technique | Gelatin sponge and bone powder |
Liu et al.15 (2019) | Molar | NM | Full thickness with vertical release | Osteotome | None |
Sun et al.21 (2019) | Molar | NM | Flapless | NM | Bio-Oss collagen with PRF |
Table 3
Study | Method of coronal coverage of the socket | Pre- and postoperative complications | Healing period (mo) | Two-stage/one stage | Frequency of failure |
---|---|---|---|---|---|
Artzi et al.33 (2003) | Healing abutment and coronal repositioning of flap around its neck | Epistaxis in 2 patients, micro-perforation of the sinus during surgery | 6 | One stage | None |
Barone et al.25 (2008) | Release of periosteum and suturing the flap around the implant neck | Pain and swelling | 6 | 2 stage | 1 early failure 6 wk postoperatively |
Kolhatkar et al.12 (2011) | 2 cases of healing abutment, 3 cases of suturing | None | 5-6 | One stage in 2 patients and two-stage in 3 patients | None |
Bruschi et al.24 (2013) | Collagen sheet | Pain, swelling, and epistaxis (resolved after 24 to 48 hr) | 5 | Two stage | None |
Taschieri and Del Fabbro31 (2011) | Mucous membrane or PRGF | None | 3-4 | Two stage | None |
McCrea26 (2012) | Coronal repositioning of flap, healing abutment, adhesive bridge | None | 6 | One stage in 2 patients and two-stage in 8 patients | None |
Mandelli et al.29 (2013) | Temporary restoration, leaving it out of occlusion | None | 5 | One stage (temporary restoration) | None |
Crespi et al.27 (2013) | Suturing the collagen piece and tissue covering the implant | Pain, swelling, and epistaxis (resolved after 24 to 48 hr) | 5 | Two stage | 1 early failure 1 mo postoperatively |
Ebenezer et al.28 (2015) | Immediate temporary restoration and immediate loading | NM | 4 | One stage | None |
Falcón30 (2015) | Suturing | None | 6 | Two stage | None |
Chen et al.32 (2017) | Palatal slipping flap or ultra-wide healing abutment |
1 patient in Group 1: mild rhinosinusitis and cough for 3 days 1 patient in Group 2: fatigue 1 patient in Group 3: fatigue Other patients: toothache |
6 | One/two stage | None |
Liu et al.15 (2019) | Healing abutment and suturing | Perforation of the sinus during surgery in two patients in test group and one patient in control group | 6 | One stage | None |
Sun et al.21 (2019) | Healing abutment, loose suturing with PRF coverage | None | 6 | Two stage | None |
Table 4
Study | Follow-up period | Method of measuring bone changes | Mean baseline alveolar bone height (mm) | Distance from tooth apex to sinus floor (mm) | Magnitude of surgical sinus floor elevation (mm) |
---|---|---|---|---|---|
Artzi et al.33 (2003) | 2 yr | PA with surgical template | 7.8 (6-9) | NM | NM |
Barone et al.25 (2008) | 18 mo | PA with occlusal stent | 7.8±1.9 | Minimum of 2 | Distance from sinus floor to implant apex: 4.2±1.4 |
Kolhatkar et al.12 (2011) | 6-12 mo | PA or panoramic radiography | NM | <1 or 2 | NM |
Bruschi et al.24 (2013) | 9.76±5.27 yr | PPA with occlusal template and reference point | 6.02±0.75 | NM | NM |
Taschieri and Del Fabbro31 (2011) | 35.6 mo (24-50 mo) | PA | Minimum of 7 | NM | 2.9±0.8 |
McCrea26 (2012) | 12-36 mo | PA | NM | NM | NM |
Mandelli et al.29 (2013) | 4 yr | PA | 5 | NM | NM |
Crespi et al.27 (2013) | 2 yr | PPA with occlusal template | 6.55±1.34 | NM | NM |
Ebenezer et al.28 (2015) | NM | - | NM | NM | NM |
Falcón30 (2015) | 12 mo | PA | NM | 2 | NM |
Chen et al.32 (2017) | 12 mo | PA and CBCT |
Distance from coronal inter-radicular crest to sinus floor: Group 1: 6.60±1.01 Group 2: 5.33±0.63 Group 3: 4.54±0.64 |
NM | NM |
Liu et al.15 (2019) | 12 mo | CBCT |
4.7±0.52 (test group) 4.9±0.63 (control group) |
NM | NM |
Sun et al.21 (2019) | None | PPA | 6 | 4 | NM |
(PA: periapical radiography, NM: not mentioned, PPA: parallel periapical radiography, CBCT: cone-beam computed tomography)
Table 5
Study |
Implant height (mm) |
Mean bone height/bone gain after the healing period (mm) | Bone height/bone gain during the follow-up period after prosthesis delivery (mm) | Bone loss after the healing period (mm) | Bone loss during the follow-up period after prosthesis delivery (mm) |
---|---|---|---|---|---|
Artzi et al.33 (2003) | 10 or 13 | 4.3 (2.5-6) | NM | NM | NM |
Barone et al.25 (2008) | 10, 11.5, 13 | NM | 4.2±1.4 | No significant bone loss | NM |
Kolhatkar et al.12 (2011) | 12, 13 | 1-4 | NM | No crestal bone loss around implant neck | NM |
Bruschi et al.24 (2013) | 13, 15 | Mean height of 7.99±1.16 |
Mean height at 1 yr: 8.05±1.58 Mean height at 2 yr: 8.03±1.49 In long-term: 8.01±1.46 |
NM | NM |
Taschieri and Del Fabbro31 (2011) | NM | NM | NM | NM | At 12 mo: 0.36±0.19 |
McCrea26 (2012) | NM | No change was noted in sinus floor bone | NM | NM | |
Mandelli et al.29 (2013) | NM | NM | NM | NM | NM |
Crespi et al.27 (2013) | 10, 13 |
At 70 days: 2.63±1.01 At 1 yr: 4.03±1.18 At 2 yr: 4.08±1.25 |
NM | NM | |
Ebenezer et al.28 (2015) | NM | NM | NM | NM | NM |
Falcón30 (2015) | 13 | Gain: 4.5 | NM | NM | NM |
Chen et al.32 (2017) | NM | NM | NM | Mean marginal bone height: 0.63 and 0.73 | |
Liu et al.15 (2019) | NM | NM | NM |
Test group: 0.65±0.12 (alveolar bone shrinkage on buccal side) 0.3±0.10 (alveolar bone shrinkage on palatal side) 0.60±0.18 (bone loss in vertical direction on buccal side) 0.24±0.12 (bone loss in vertical direction on palatal side) |
Test group: 0.21±0.12 (alveolar bone shrinkage on buccal side) 0.12±0.09 (alveolar bone shrinkage on palatal side) 0.21±0.11 (bone loss in vertical direction on buccal side) 0.15±0.08 (bone loss in vertical direction on palatal side) |
Sun et al.21 (2019) | 10 | NM | NM | NM |
Table 6
Study | Survival/Success rate | Conclusion |
---|---|---|
Artzi et al.33 (2003) | Survival: 100% | A combination of these two techniques as one single procedure yields results comparable to each of the techniques alone in the short-term, decreases the treatment time and cost, and enhances the prosthetic rehabilitation of the posterior maxilla. |
Barone et al.25 (2008) | Success:91.7% | This technique yields predictable results and enables horizontal and vertical expansion. |
Kolhatkar et al.12 (2011) | Survival: 100% | Authors provided a decision-making flowchart for clinicians wanting to use the combined technique. This technique shortens the treatment time and is flexible for placement of longer implants close to the sinus. |
Bruschi et al.24 (2013) | Survival: 100% | This technique enables horizontal and vertical expansion and allows for placement of implants with a larger diameter in the maxillary molar area with 100% successful osseointegration that can well tolerate occlusal loads. |
Taschieri and Del Fabbro31 (2011) | Success: 100% | This technique can enable safe and efficient sinus floor elevation along with immediate implant placement. Use of PRGF in this technique can stimulate bone regeneration and soft tissue healing and enhance treatment acceptance by patients. |
McCrea26 (2012) | Success: 100% | Same socket/osteotomies can be used as a conduit for modified sinus floor penetration/elevation without the use of an autograft, allograft, or xenograft. This technique significantly shortens the treatment time and decreases the need for further surgical interventions. |
Mandelli et al.29 (2013) | Success and survival: 100% | Sinus lifting simultaneous with fresh socket implant placement decreases the treatment time. The success of this procedure depends on the primary stability of the implant. Splinting two adjacent implants results in predictable osseointegration. |
Crespi et al.27 (2013) | Survival:98.57% | Use of an electrical mallet for bone condensation is fast, accurate, and cost-effective, and it seems to be a suitable instrument for preparing the upper parts of the socket for simultaneous sinus lifting and implant placement. |
Ebenezer et al.28 (2015) | NM | Indirect sinus lifting with the crestal approach using an osteotome is simple, non-invasive, and fast. The apical bone pushed into the sinus can serve as a bone graft and tent for the sinus membrane. Also, the bone at the sinus floor can increase the primary stability of the implant. |
Falcón30 (2015) | NM | The flapless technique is less invasive and further decreases the treatment time and postoperative patient discomfort. |
Chen et al.32 (2017) | Survival: 100% | The combination of these two techniques yields predictable results, especially when inter-radicular bone is used. The relationship between the molar root and sinus can have an inverse correlation with the radicular bone height and a direct correlation with the sinus floor thickness. Normally, the sinus membrane thickness increases postoperatively due to the formation of a blood clot and the infiltration of goblet cells, which returns to normal after the healing period. Root infection is an odontogenic factor responsible for increased membrane thickness. Eliminating the infected root allows the membrane to become thin again. |
Liu et al.15 (2019) | Survival: 100% | Immediate implant placement combined with maxillary sinus floor elevation using the trans-alveolar approach and non-submerged healing is feasible for the maxillary molar area, and the clinical effect is satisfactory. |
Sun et al.21 (2019) | NM | Flapless, immediate implant placement into a fresh molar socket with PRF is a feasible procedure. PRF promotes bone and soft tissue regeneration and has anti-inflammatory properties. In addition, the procedure involves a minimally invasive technique that reduces surgical complexity. |