The purpose of this study is to decrease a stress shielding effect shown in the hip joint. To conduct this study, the clad materials were produced by using an explosion welding method with two materials that were different in the elastic modulus like Ti-6Al-4V alloy and pure Ti. As for the clad materials, the Ti-6Al-4V alloy with large elastic modulus was designed as the neck of femur, and the pure Ti with small elastic modulus as the body of femur. The joints of clad materials formed by the explosion welding showed the typical wave shape, and its thickness was about 0.2㎛. New crystal or grain structure was not formed in the joints. In addition, the Vickers hardness in the joints formed the middle value between the base metal and clad metal. As a result of manufacturing prototype by processing the clad materials in three dimensions, this study gained good shape, and if it is to be applied to clinical in the future, this researcher can expect good results. From the result of this research above, it may be summed up as follows. It is considered as the stress shielding phenomenon showed on the hip joint can be decreased to a certain degree if this researcher is to utilize two clad materials with different elastic modulus like Ti-6Al-4V alloy and pure Ti
In this study, a large modulus of elasticity of the titanium alloy in use, to create artificial hip stress shielding effect appears to reduce the head portion is excellent in the strength of Ti-6Al-4V, making bone pusher which requires low elastic modulus relative modulus of pure titanium grade 2, using a small two metal after welding by explosion welding hip was made. Explosion pressure welding by the welding region with respect to the mechanical properties and the tissue was observed.
In a total hip arthroplasty, the artificial hip joint is composed of an acetabular cup and a femoral head. To minimize the wear of the joint, the bearing surface should be precisely spherical. There were concerns that the press-fitting of the acetabular cup to the pelvis may cause the deformation of the cup and accelerate the wear of the joint, but its in-vivo measurement was challenging. In this paper, 3 dimensional finite element(FE) models of a pelvis and acetabular cups of Metasul 50mm and Pinnacle 50-60mm cups were used to simulate the deformation of the acetabular cups. For Metasul cups, the change of inner radius with respect to the location and the maximum shrinkage of the inner radius were found. For the Pinnacle cups, maximum change of the outer diameter were found and compared with the literature. FE model showed that the maximum shrinkage of the inner radius of the Metasul cup was 23μm (1.0mm press-fit, Bone stiffness 17GPa case). The shrinkage occurred mainly on the anterior and posterior side of rim of the cup, and the amount was proportional to the press-fit amount. The diametric change of the Pinnacle cup was 0.16mm on average, which was in same range of the clinically reported value. In conclusion, under the normal condition the reduction of the inner radius of the Metasul cup was too small to cause the jamming or the excessive wear.
고관절 시행에서 식립각도는 추후 환자의 운동범위나 힘의 분배조건에 따라 폴리에틸렌 라이너의 마모에도 영향을 미친다. 인공관절요소로부터 마모입자는 골괴사나 다른 생화학적으로 많은 합병증을 일으킨다. 이런 점에서 인공고관절에서 마모와 정렬각도를 수술 후 추시를 통해 측정하는 것은 중요하다. 특히 관절면의 마모를 측정하는 것은 그 량이 크지 않아 상당한 정밀도를 요구한다. 현재 널리 쓰이는 상용 소프트웨어는 재현성과 측정방법의 표준화가 되어 있지 않아 사용에 많은 어려움이 있다. 본 논문에서는 일반 병원의 방사선촬영 환경에서 CAD만 추가로 구비하면 행할 수 있는 인공관절면 마모와 식립각 측정법을 제시한다. 인공관절만의 X-ray영상을 이용한 본 방법의 정확도와 정밀도 평가를 수행하였다. 또한 실제 인공고관절환자의 X-ray영상을 가지고 2년추시에 따른 마모와 식립각을 측정하였다. 본 연구에서 제시한 CAD를 이용한 방법은 마모측정에서 정확도 0.06 mm, 정밀도 0.05 mm, 식립각은 0.27°의 정밀도를 갖는다.