Stabilizing dental implants with a fiber-reinforced calcium phosphate cement: An in vitro and in vivo study
Sónia de Lacerda Schickert, John A. Jansen, Ewald M. Bronkhorst, Jeroen J.J.P. van den Beucken, Sander C.G. Leeuwenburgh
Abstract
Stabilization of dental implants by means of biomaterials such as bioceramic granules and cements is currently compromised by the poor mechanical properties of these bioceramics. Recently, our group developed a calcium phosphate cement reinforced with poly(vinyl alcohol) fibers with improved flexural strength and toughness. Herein we evaluated the capacity of these fiber-reinforced calcium phosphate cements to stabilize dental implants in vitro and in vivo using a range of mechanical and biological test methods. In vitro, filling of circumferential crestal peri‑implant bone defects with synthetic bone analogues with fiber-reinforced calcium phosphate cement demonstrated superior implant stability as compared to fiber-free calcium phosphate cement over a 12-week period. Similarly, filling of circumferential crestal peri‑implant bone defects with fiber-reinforced calcium phosphate cement effectively stabilized dental implants installed in a rabbit femoral condyle defect as assessed via both Implant Stability Quotient (ISQ) and torque-out measurements. Moreover, histological and histomorphometric evaluation demonstrated the osteocompatibility of fiber-reinforced calcium phosphate cement, as evidenced by absence of soft tissue ingrowth, direct contact between the bone and cement, and gradual degradation of the biomaterial and replacement by newly-formed bone. These data demonstrate that fiber-reinforced calcium phosphate cement stabilize dental implants during osseointegration. STATEMENT OF SIGNIFICANCE: Dental implants can be placed immediately after a tooth is removed. However, in some cases the implant might not have enough bone surrounding it and becomes loose. To solve this, bioceramics have been used to fill the implant-bone gap. However, these materials have poor mechanical properties and are often not capable to stabilize the implant. Recently, our research group developed a new bone cement that is reinforced with fibers and has, therefore, enhanced mechanical properties. In this study, we have proven that by molding this cement into the implant-bone gap, we stabilize the implant and allow for a direct connection between the implant and the surrounding bone. Using this innovative cement is therefore a safe and efficient way of stabilizing dental implants.