Nondestructive evaluation of bone cement and bone cement/metal interface failure

Abstroet-Artiiicial joint replacement is becoming increasingly important in orthopedics. Several hundreds of thousands of operations, especially of the hip joint, have already been performed. The design of such joints depends largely on how accurately they can be modeled analytically such that their

We evaluated the microstructural characteristics of newly formed bone tissue at the interface with cement. The bonecement interfaces of the femoral components of nine hip prostheses retrieved after loosening were investigated by means of X-ray diffraction on microareas and microhardness. The bone fa

## Abstract Despite the widespread use of cement as a means of fixation of implants to bone, surprisingly little is known about the micromechanical behavior in terms of the local interfacial motion. In this work, we utilized digital image correlation techniques to quantify the micromechanics of the

## Abstract The cement–bone interface plays an important role in load transfer between cemented implant systems and adjacent bone, but little is known about the micromechanical behavior of this interface following in vivo service. Small samples of postmortem‐retrieved cement–bone specimens from cem

## Abstract Loosening is recognized as one of the primary sources of total hip replacement (THR) failure. In this study the influence of the bone surface texture on loosening of the cement/bone interface was studied. Model cemented hip replacements were prepared and subjected to cyclic loads that i

We developed a bioactive bone cement (BABC) that consists of apatite and wollastonite containing glass ceramic (AW-GC) powder and bisphenol-A-glycidyl dimethacrylate (Bis-GMA) based resin. In the present study, the effectiveness of the BABC for repair of segmental bone defects under load-bearing con