Load measurement accuracy from sensate scaffolds with and without a cartilage surface.

ABSTRACT The use of "sensate" scaffolds covered with tissue-engineered cartilage has emerged as a possible treatment option for focal articular cartilage defects. The ability to monitor joint loading provides several benefits that can be useful in both clinical and research situations. Previous studies have shown that these scaffolds can accurately monitor in vivo joint loading during various activities. However, the effect that an articular cartilage layer or soft tissue overgrowth has on scaffold sensitivity has not been tested. Eight scaffolds were tested with cartilage samples taken from four hounds. Three strain gauges were attached to each scaffold and a servo hydraulics system was used to test sensitivity while the scaffold was in contact with cartilage, metal, or silicone surfaces. Strain gauge sensitivity was calculated from load and strain measurements collected during testing. There was no significant difference between the mean strain gauge sensitivities when the scaffolds were in contact with the different surfaces: cartilage 30.9 +/- 16.2 muepsilon/N, metal 31.8 +/- 18.6 muepsilon/N, and silicone 30.6 +/- 12.3 muepsilon/N. These results indicate that "sensate" scaffolds can be calibrated and used to monitor load with the presence of an articular cartilage layer.

Sensate scaffolds coupled to telemetry can monitor in vivo loading from within a joint over extended periods of time.

Polymer scaffolds have been used as a tool to provide growth and integration of engineered tissue substrates to repair damaged tissues in many organ systems including articular cartilage. Previous work has shown that "sensate" scaffolds, with integrated strain gauges have the potential for use as both a delivery vehicle for engineered cartilage as well as a device that can measure real time, in vivo joint loading. The purpose of this study was to use an implanted subminiature telemetry system to collect in vivo joint loading measurements over an extended period following placement of a "sensate" scaffold. Measurements were collected from seven of nine sensors that were implanted into the stifles of three canines. The limb loading rates and load distribution through gait were dependent on stride time but did not vary with time post op. The peak loads were not dependent on stride time but significantly increased with time post op. This demonstrated that peak loading measured with "sensate" scaffolds can be used to monitor healing. The portability of the "sensate" scaffolds coupled to telemetry systems highlights the potential use of this system in a clinical research setting to gather important information to improve tissue engineering and rehabilitation regimens.