Polycaprolactone-20% tricalcium phosphate scaffolds in combination with platelet-rich plasma for the treatment of critical-sized defects of the mandible: a pilot study.

PURPOSE: Our group has recently fabricated 3-dimensional scaffolds of unique architecture to mediate favorable cell binding, proliferation, and differentiation. In this study, the osteoconductive and bioactive polycaprolactone-20% tricalcium phosphate (PCL-TCP) scaffolds were assessed for the treatment of critical-sized defects of the mandible, with respect to new bone formation. Platelet-rich plasma (PRP) was combined with some scaffolds to test if bone regeneration could be enhanced. MATERIALS AND METHODS: Autologous PRP was prepared from whole blood collected from 8 mongrel dogs. In each dog, 3 defects (18 x 10 x 7 mm) were created at either the left or right mandible and treated with 1 of 2 treatment modalities: 1) grafting with scaffolds alone; or 2) grafting with scaffolds loaded with PRP. The scaffolds were stabilized using 2 dental implants each to prevent rotation. Micro-CT and histologic analysis were carried out on samples after 6 and 9 months. RESULTS: Micro-CT measurements showed that PRP-treated defects had 98.3% and 58.3% more bone volume fraction than defects grafted with scaffolds alone at 6 and 9 months, respectively (P < .05). No significant difference was noted between caudal and frontal situated PRP-treated defects, but a significant difference was observed between male and female dogs. Histologic analyses verified the deposition of osteoid and new bone trabeculae throughout the section at 6 months. The defect margins were filled with mature bone trabeculae at 9 months but the middle section of the scaffolds manifested disturbed mineralization. The scaffolds experienced 33% degradation from 6 to 9 months. PRP treatment had negligible effect on the degradation of the scaffolds. CONCLUSIONS: The pilot study showed that the treatment of critical-sized defects of the mandible with PCL-TCP scaffolds may be augmented by the addition of PRP.

Integrative haptic and visual interaction for simulation of PMMA injection during vertebroplasty.

In vertebroplasty, physician relies on both sight and feel to properly place the bone needle through various tissue types and densities, and to help monitor the injection of PMMA or cement into the vertebra. Incorrect injecting and reflux of the PMMA into areas where it should not go can result in detrimental clinical complication. This paper focuses on the human-computer interaction for simulating PMMA injection in our virtual spine workstation. Fluoroscopic images are generated from the CT patient volume data and simulated volumetric flow using a time varying 4D volume rendering algorithm. The user's finger movement is captured by a data glove. Immersion CyberGrasp is used to provide the variable resistance felt during injection by constraining the user's thumb. Based on our preliminary experiments with our interfacing system comprising simulated fluoroscopic imaging and haptic interaction, we found that the former has a larger impact on the user's control during injection.

Relationship between CT intensity, micro-architecture and mechanical properties of porcine vertebral cancellous bone.

BACKGROUND: In vivo assessment of bone density is insufficient for the evaluation of osteoporosis in patients. A more complete diagnostic tool for the determination of bone quality is needed. Micro-computed tomography imaging allows a non-destructive method for evaluating cancellous bone micro-architecture. However, lengthened exposure to ionizing radiation prevents patients to be imaged by such a system. The aim for this study was to elucidate the relationships between image intensity (of Hounsfield units), cancellous bone micro-architecture and mechanical properties. METHODS: Using pig vertebral cancellous bone, the bone specimens were imaged using clinical and micro-computed tomography scanners and subsequently subjected to uniaxial compression testing. RESULTS: Results indicate that micro-architecture can be predicted using clinical image intensity. Micro-architectural parameters relevant to osteoporosis study, such as percent bone volume, trabecular bone pattern factor, structure model index, trabecular thickness and trabecular separation have shown significant correlation with R2 values of 0.83, 0.80, 0.70, 0.72, and 0.54, respectively, when correlated to Hounsfield units. In addition, the correlation of mechanical properties (E, sigma yield, and sigma ult) in the superior-inferior direction (the primary loading direction), to micro-architecture parameters has also been good (R2 > 0.5) for all except tissue volume, tissue surface and degree of anisotropy. INTERPRETATION: This proves that the predictive power of bone strength and stiffness was improved with the combination of bone density and micro-architecture information. This work supports the prediction of micro-architecture using current clinical computed tomography imaging technology.