Background： Dental implant therapy has become a standard rehabilitation method for patients suffered from missing teeth in the posterior maxilla. Because of disuse atrophy and continuous pneumatization of the maxillary sinus, insufficient bone height for dental implantation is common in the posterior maxilla which necessitates sinus augmentation to increase the bone volume. In this surgical technique the Schneiderian membrane is elevated and then bone graft materials are placed into the newly created subantral space to increase bone volume for implant therapy. Previous studies showed that the survival rates for dental implants in combination with sinus augmentation are high. However, the long-term stability of sinus graft and factors influencing graft stability have seldom been examined. Purpose: By examination of the changes in sinus graft volume over a long period and analysis of the relations between graft alteration and various clinical parameters, the long-term efficacy of the sinus augmentation technique is determined. Materials and Methods： Patients who received dental implantation in combination with sinus augmentation at the Department of Oral Maxillofacial Surgery, National Taiwan University Hospital during 2002 to 2008 were included in the study. A total of 47 patients were followed for at least two years. Macroporous biphasic calcium phosphate （MBCP） or deproteinized freeze dried bone allograft （DFDBA） were used as graft materials in 60 maxillary sinus augmentation with total 102 implants. Clinical factors that may influence implant success and graft stability were recorded. Changes in graft height were calculated in three locations, 2 mm mesial to implant, directly above implant, and 2 mm distal to implant. The GSH ratio （follow-up grafted sius height versus original sius height） were calculated as follow-up grafted sinus height versus original sinus height. The relationship between grafted sinus floor and implant was classified into three groups: Group I, in which the grafted sinus floor was above the implant apex; Group II, in which the implant apex was level with the grafted sinus floor; and Group III, in which the grafted sinus floor was below the implant apex. The relations between various clinical parameters and implant success or graft stability were analyzed statistically by Chi Square Test, Student t Test, Logistic Regression Model. Results： There were 2 implants defined as failure, and the overall implant success rate was 98.03%. No clinical factor was significantly related to implant success, all P>0.05. In average, the long term graft change at the site 2 mm mesial to implant was 1.55±2.29 mm （mean±SD）（loss 20.02%）; directly above implant was 1.08±1.50 mm （loss 11.09%）; 2 mm distal to implant was 1.42±2.27 mm （loss 14.67%）. When DFDBA grafts were considered separately, the long term change at the site 2 mm mesial to implant was 3.17±2.50 mm （loss 40.25%）; directly above implant was 1.52±1.33 mm （loss 14.78%）; 2 mm distal to implant was 3.21±2.50 mm （loss 35.02%）. In MBCP group, the long term change at the site 2 mm mesial to implant was 0.84±1.80 mm （loss 10.95%）; directly above implant was 0.90±1.54 mm （loss 9.54%）: 2 mm distal to implant was 0.65±1.67 mm （loss 5.95%）. For all sinus grafts, the mean follow-up GSH ratio 2 mm mesial to implant was 1.87±4.58; 2 mm distal to implant was 3.51±3.77. Loss of graft height at mesial site was smaller than that at the distal, and the difference was significant statistically （P<0.05）. In DFDBA group, the follow-up GSH ratio at the site 2 mm mesial to implant was 0.66±0.82; 2 mm distal to implant was 3.23±3.14. And the difference was significant statistically （P<0.05）. In MBCP group, follow-up GSH ratio at the site 2 mm mesial to implant was 2.43±5.6; 2 mm distal to implant was 3.63±4.03, but the difference was not significant statiscally （P>0.05）. The relations between grafted sinus floor and implant apex were as follows: 73 implants （72.2%） were in group I, 11 implants （10.8%） group II, 17 implants （16.8%） group III. In DFDBA group, 15 implants （50.00%） were in group I, 2 implants （6.67%） group II, 13 implants （43.33%） group III. In MBCP group, 58 implants （81.69%） were in group I, 9 implants （12.68%） group II, 4 implants （5.63%） group III. Concerning the relations between graft stability and various clinical parameters were, we found that: graft materials, implant related location, intraoperative sinus membrane perforation and method of access window protection, were significantly associated with graft stability. The grafts were significantly more stable when MBCP was used comparing to DFDBA （P<0.05）. Graft changes were significantly more obvious mesial to the implants comparing to the distal aspects （P<0.05）. Graft loss was noted if membrane perforation happened during augmentation surgery （P<0.05）. Graft changes were more marked when access windows were protected by collagen membrane comparing to window bone plate replacement （P<0.05）. Conclusions: Sinus augmentation is now a routine bone graft technique for implant therapy. In the retrospective study, we noted that sinus grafts decfeased in size in the long term, although this phenomenon was not related to implant success. We also found that graft material, implant related location, intraoperative sinus membrane perforation were factors associated with long term graft stability.