A comparison ofIn Vitro andIn Vivo degradation of two CPC strain gauge coatings

Strain gauging enables the measurement of bone deformation during physical activity, leading to a better understanding of the physiological effects of loading on bone growth and remodeling. Development of a technology that will withstand long-term in vivo exposure and bond securely to bone is imperative for accurate, consistent measurement collection. Polysulfone is currently used to attach calcium-phosphate ceramic (CPC) particles, which promote bone-to-gauge bonding, to polyimide-backed strain gauges. This study evaluated the use of an implant-grade epoxy as an alternative CPC-polyimide adhesive. Polyimide-epoxy-CPC interfaces were loaded to failure and shear strengths calculated. In vitro studies providing a constant flow of medium over test specimens were designed, and long-term in vitro fluid exposure studies of the epoxy's shear strength were conducted. Average shear strength of polysulfone-polyimide interfaces were reported to be 7 MPa. The average shear strength of the epoxy-polyimide interface before long-term in vitro exposure was 17 MPa, which is stronger than the shear strength of the bone-CPC interface. The strength of the epoxy-polyimide interface decreased to 6.8 MPa after 24 weeks in vitro and 3 MPa after 24 weeks in vivo.

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Evaluation of a new CPC‐to‐gauge bonding technique with the use of in vitro fluid flow

Fernandez

Szivek

Margolis

2003

J Biomed Mater Res

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Morphology and mechanical behavior of TTCP-derived calcium phosphate cement subcutaneously implanted in rats

Tsai

Lin

2008

J Mater Sci: Mater Med

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A pre-hardened, TTCP-derived CPC was immersed in Hanks' solution as well as subcutaneously implanted into abdomen of rats. The implant-soft tissue interfacial morphology was examined and properties of the CPC were evaluated and compared under in vitro and in vivo conditions. The results indicate that the surface of immersed samples appeared rougher and more porous than that of implanted samples and was covered with a layer of fine apatite crystals. The CPC samples implanted for 4 weeks or longer were surrounded by a layer of fibrous tissue, which was further surrounded by a soft tissue capsule comprising numerous fat cells. The soft tissue capsule had a non-uniform distribution in thickness, which increased most significantly between 4 weeks and 12 weeks after implantation. None of polymorphic cells, osteoblast cells or bone cells adjacent to the implant were observed. The majority of original TTCP powder was transformed into apatite after 1 day of either immersion in Hanks' solution or implantation. The average porosity values of samples immersed in Hanks' solution for 4 weeks or longer were significantly larger than those immersed for 1 day or 1 week. The porosity values of samples implanted for different times were not significantly different. The DTS values of Hanks' solution-immersed samples largely decreased after a few weeks of immersion. The implanted samples maintained their strengths throughout the study.

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An Implantable Strain Measurement System Designed to Detect Spine Fusion

Szivek

Roberto

Slack

et al. 2002

Spine

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A comparison ofIn Vitro andIn Vivo degradation of two CPC strain gauge coatings

Cited by 3 publications

References 11 publications

Evaluation of a new CPC‐to‐gauge bonding technique with the use of in vitro fluid flow

Evaluation of a new CPC‐to‐gauge bonding technique with the use of in vitro fluid flow

Morphology and mechanical behavior of TTCP-derived calcium phosphate cement subcutaneously implanted in rats

An Implantable Strain Measurement System Designed to Detect Spine Fusion

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