Introduction

Femoral neck impingement occurs clinically in total hip replacements (THR) when the acetabular liner articulates against the neck of a femoral stem prosthesis. This may occur in vivo due to factors such as prostheses design, patient anatomical variation, and/or surgical malpositioning, and may be linked to joint instability, unexplained pain, and dislocation. The Standard Test Method for Impingement of Acetabular Prostheses, ASTM F2582 −14, may be used to evaluate acetabular component fatigue and deformation under repeated impingement conditions. It is worth noting that while femoral neck impingement is a clinical observation, relative motions and loading conditions used in ASTM F2582-14 do not replicate in vivo mechanisms. As written, ASTM F2582-14 covers failure mechanism assessment for acetabular liners of multiple designs, materials, and sizes. This study investigates differences observed in the implied and executed kinematics described in ASTM F2582-14 using a Prosim electromechanical hip simulator (Simulation Solutions, Stockport, Greater Manchester) and an AMTI hydraulic 12-station hip simulator (AMTI, Watertown, MA).

INTRODUCTION

Multiple sources have consistently reported oxidation indices less than 0.1 with Marathon® inserts implanted up to 10 years. Understanding effects of oxidation level on UHMWPE wear in vivo is of great value. The objective of this study is to characterize the wear performance of Marathon® acetabular inserts at various levels of artificially induced oxidation, quantified using Bulk Oxidation Index (BOI) as determined per ASTM F2102, and to ascertain if wear rate is affected by progressive polyethylene oxidation.

Introduction

Adolescent idiopathic scoliosis (AIS) is the most common paediatric spinal deformity, affecting about 3% of school-aged children worldwide. This disorder occurs in otherwise healthy children who bear no obvious deficiencies in the components of the spinal column itself. The cause of AIS is poorly understood, as is implied by the name. Lesions of the bony composition of the vertebrae, the vertebral endplates, the paraspinous muscles, or the neurological system each have been proposed to explain disease pathogenesis. Progress has been hampered by the absence of an obvious AIS animal model. Consequently we have used genetic studies in human populations to identify factors underlying AIS susceptibility.

The complex inheritance and population frequency of AIS suggest that many genetic factors are involved in this disease. To search comprehensively for such factors we previously undertook the first genome-wide association study (GWAS) of AIS susceptibility in a cohort of 419 families in Texas, USA. We found that chromosome 3 SNPs in the proximity of the CHL1 gene yielded strongest results, which we replicated in additional cohorts (rs10510181 OR 1·49, 95% CI 1·29–173, p=2·58×10–8). CHL1 is of interest because it encodes an axon guidance protein and is functionally related to the ROBO3 gene that causes hereditary gaze palsy with progressive scoliosis (HGPPS), a rare disease marked by severe scoliosis. Here we expanded the study to 702 Texas families.

Background and methods: Adolescent idiopathic scoliosis (AIS) is the most common spinal deformity in children, with a prevalence of 1–2%. The disease generally displays complex inheritance. Various family studies have produced many first reports of AIS susceptibility regions, but confirmation of these is lacking. In the present study we investigated extension of our own data, and reproducibility of other published results, by testing linkage in a new collection of fifty-four AIS families. Altogether fifteen candidate regions were evaluated in a two-stage design.

Results: Strongest results were obtained for linkage to microsatellite loci within a candidate region of proximal 8q previously identified by chromosomal breakpoint mapping. Although positive lod scores were obtained for other regions, none exhibited significance less than or equal to P = .05. Lod scores remained stable after analysis of an independent panel of SNP loci in the 8q candidate region and were strengthened with inclusion of additional affected family members (multipoint NPL = 3.02, P = 0.001). Two SNPs near the peak of linkage produced evidence of association to AIS susceptibility. Both SNPs are found within plausible candidate genes for AIS susceptibility.

Conclusion: These results support linkage of the 8q11-8q13 region to AIS susceptibility. Bashiardes et al. previously described a chromosomal break in the 8q11 region that disrupted the gamma-1- syntrophin (SNTG1) gene and segregated with AIS in an extended kindred. In that study, possible rare splice site mutations were identified an additional affected family and one sporadic case. The peak of linkage and association detected in this study appears to be distinct from the SNTG1 gene. This suggests the possibility that more than one gene in the region may contribute to disease. A more detailed analysis of the region encompassing this linkage peak, and the SNTG1 gene, is warranted in larger family collections.