This study aimed to examine the effect of high tibial osteotomy (HTO) on the ankle and subtalar joints via analysis of static radiographic alignment. We hypothesised that surgical alteration of the alignment of the proximal tibia would result in compensatory distal changes. 35 patients recruited as part of the wider Biomechanics and Bioengineering Centre Versus Arthritis HTO study between 2011 and 2018 had pre- and postoperative full-length weightbearing radiographs taken of their lower limbs. In addition to standard alignment measures of the limb and knee (mechanical tibiofemoral angle, Mikulicz point, medial proximal tibial angle), additional measures were taken of the ankle/subtalar joints (lateral distal tibial angle, ground-talus angle, joint line convergence angle of the ankle) as well as a novel measure of stance width. Results were compared using a paired T-test and Pearson's correlation coefficient. Following HTO, there was a significant (5.4°) change in subtalar alignment. Ground-talus angle appeared related both to the level of malalignment preoperatively and the magnitude of the alignment change caused by the HTO surgery; suggesting subtalar positioning as a key adaptive mechanism. In addition to compensatory changes within the subtalar joints, the patients on average had a 31% wider stance following HTO. These two mechanisms do not appear to be correlated but the morphology of the tibial plafond may influence which compensatory mechanisms are employed by different subgroups of HTO patients. These findings are of vital importance in clinical practice both to anticipate potential changes to the ankle and subtalar joints following HTO but it could also open up wider indications for HTO in the treatment of ankle malalignment and osteoarthritis

INTRODUCTION. Postoperative functional limitations after Total Knee Arthroplasty (TKA) are caused, in part, by a mismatch between a patient's natural anatomy and conventional “off-the-shelf” implants. To address this, we propose a new concept combining off-the-shelf femur and tibia implants with custom polyethylene tibial inserts designed to account for a patient's unique anatomy. Our goal in this study was to use knee specific computational modeling to determine the neutral path of motion and laxity of an intact knee under axial compression and shear forces through full flexion and compare intact motion against the same knee implanted with a conventional off-the-shelf vs. a custom tibial insert. METHODS. 3D models of a healthy knee joint were acquired from an open development repository funded by the National Institute of Biomedical Imagining and Bioengineering (Harris et al., 2016). The knee model was virtually implanted with conventional (off-the-shelf) posterior cruciate retaining (CR) components including the femoral component, tibial tray, and a conventional insert. A custom CR tibial insert was designed taking into account native articular geometry and compatibility with placement of the off-the-shelf femoral/tibial tray. Bone, cartilage and implant models were imported into ANSYS Workbench. Ligaments were calibrated using data from in-vitro experimental tests (Harris et al., 2016). The following load conditions were applied to the femur: 20 N axial compression (neutral path), 20 N axial compression with 80 N anterior shear force, and 20 N axial compression with 80 N posterior shear force. Simultaneously for each loading condition, the knee was flexed from 0 – 120 degrees. A circular axis system was used to describe the motion of the femur relative to the tibia. RESULTS. For the intact case, neutral path was characterized by greater posterior femoral displacement on the lateral side than on the medial side, especially in early flexion. Neutral path of the custom insert was closer to intact condition than the conventional insert. Overall AP laxity was similar between intact and implanted models except at 30 degrees where increased laxity occurred posteriorly for the implanted models, likely due to resection of the anterior cruciate ligament (ACL) as part of the TKA procedure. For intact and implanted models, AP laxity significantly decreased at the higher flexion angles. DISCUSSION. Our findings indicate that motion with a custom tibial insert was closer to intact than the conventional design. Nonetheless, custom articular surface alone may not fully reproduce intact motion due to limitations such as resection of the ACL, and such custom inserts may benefit from guiding features such as a cam, post, or retention of the native ACL to more closely reproduce normal knee function. We did not simulate specific activities of daily living. Increasing the magnitudes of compression and shear forces would not change the neutral path of motion, although, a reduction in laxity would be expected

Introduction. Periprosthetic joint infection (PJI) and particle-induced osteolysis are closely related to peri-implant local immunity and macrophage function. We previously demonstrated that titanium particles attenuate the immune response of macrophages caused by chronic inflammation [1]. In a separate study, we have determined that UHMWPE wear particles containing vitamin E (VE) induce less osteolysis compared to HXL UHMWPE wear particles in a murine calvarium model [2]. For this study we hypothesized that macrophages exposed to HXL UHMWPE particles containing VE would better maintain their ability to respond to S. aureus compared to HXL UHMWPE without VE. Methods. A gamma-sterilized, HXL UHMWPE tibial bearing containing VE (E1, Biomet, “VE-PE”) and 100kGy irradiated and melted UHMWPE (“CISM 100”) were cryomilled to particles by Bioengineering Solutions (Oak Park, IL). In the first in vitro study, RAW 264.7 mouse macrophages were exposed (inverted co-culture) to either VE-PE particles or CISM100 particles and lipopolysaccharide (LPS) for 1–7 days. Macrophage viability was measured using a cell counting kit (CCK-8). Control group with no particles and a LPS group were also included. Terminal deoxynucleotidyl transferase dUTP nick end labeling (TUNEL) staining was performed to determine macrophage apoptosis rate in response to particle exposure over time. In the second study, macrophages were exposed to VE-PE or CISM100 particles for 48h, then exposed to LPS for 30 min. Subsequently, reactive oxygen species (ROS) generation and extracellular regulated protein kinase (ERK) phosphorylation were measured. In a third study, after exposure to particles for 48h, fatigued macrophages were co-cultured with bioluminescent S. aureus strain Xen29 for 3h and 6h. Bioluminescence signal was determined to measure the total amount of bacteria. Bacterial live/dead staining and optical density at 600 nm (OD 600) were also performed to determine S. aureus viability. Statistical analysis was performed using one-way or two-way ANOVA with a post hoc examination. *indicates p<0.05. Results. CISM100 particles significantly decreased macrophage viability at day 5 and day 7 (p<0.05, Fig. 1A), while the viability of macrophages exposed to VE-PE particles was similar to controls (macrophages not exposed to particles). After 48h, macrophages exposed to VE-PE particles showed a lower TUNEL-positive rate (less apoptosis) compared to CISM100 particles (Fig. 1B, C). 48h-exposure to VE-PE particles increased ROS generation and ERK phosphorylation in 30 min-LPS-activated macrophages when compared to CISM100 particles (Fig. 2). This immune response caused by VE-PE particles resembles that of macrophages without particles. Furthermore, 48h exposure to E1 particles showed less S. aureus at 6h (Fig. 3). Conclusions. These results suggest that VE-PE particles cause reduced macrophage apoptosis and protect the macrophages' immune response. VE-PE particles also preserved the innate immunity of macrophages, unlike CISM100, as evidenced by the S. aureus co-culture study. Thus, patients with vitamin-E containing implants may be less likely to develop PJI

Introduction. UHMWPE particle-induced osteolysis is one of the major causes of arthroplasty revisions. Recent in vitro findings have suggested that UHMWPE wear particles containing vitamin-E (VE) may have reduced functional biologic activity and decreased potential to cause osteolysis (Bladed C. L. et al, JBMR B 2012 and 2013). This is of significant importance since VE-stabilized cross-linked UHMWPEs were recently introduced for clinical use, and there is no in vivo data determining the effects of wear debris. In this study we hypothesized that particles from VE-stabilized, radiation cross-linked UHMWPE (VE-UHMWPE) would cause reduced levels of osteolysis in a murine calvarial bone model when compared to virgin gamma irradiated cross-linked UHMWPE. Methodology. Study groups were the following: 1). Radiation cross-linked VE-UHMWPE (0.8% by weight) diffused after 100 kGy; 2). Radiation cross-linked virgin UHMWPE (virgin UHMWPE); 3). Sham controls. Particle generation and implantation: UHMWPE was sent to Bioengineering Solutions (Oak Park, IL) for particle generation. After IACUC approval, C57BL/6 mice (n=12 for each group) received equal amount of particulate debris (3mg) overlying the calvarium and were euthanized after 10 days. Micro-CT scans: High resolution micro-CT scans were performed using a set voltage of 70 kV and current of 70 µA. Topographical Grading Scale: Each calvarial bone was blindly scored using the following scale: 0=No osteolysis, defined as intact bone; 1=Minimal osteolysis, affecting 1/3 or less of the bone area; 2=Moderate osteolysis, affecting at least 2/3 of the bone area; 3=Severe osteolysis, defined as completely osteolytic bone. Histology: H&E and TRAP staining was done on tissue to confirm micro-CT findings and quantify osteoclasts. Statistical Analysis: Inter-rater analysis was done using Cohen's kappa analysis. An inter-rater coefficient >0.65 was considered as high inter-rater agreement. Comparison between groups was made using one-way ANOVA with post hoc Bonferroni correction for multiple comparisons. Correlations are reported as Spearman's rho. P-value<0.05 was considered statistically significant. Results. More than 83% of the VE-UHMWPE and more than 85% of the virgin UHMWPE particles measured less than 1 µm in mean particle size. There was a statistically significant greater level of osteolysis visualized on the topographical grading scale in calvaria implanted with virgin UHMWPE wear particles. Micro-CT findings were confirmed histologically (Fig. 1). A greater amount of inflammatory tissue overlaying the calvaria was observed in the virgin UHMWPE group when compared to both shams and VE-UHMWPE groups. Post hoc analysis revealed significant difference between VE-UHMWPE and virgin UHMWPE for the topographical osteolysis grading score (p=0.002) but no difference in osteoclast counts (p=0.293). Discussion and Conclusion. This is the first in vivo study reporting the effects of clinically-relevant UHMWPE particles generated from a VE-UHMWPE implant that is in current clinical use. These results suggest that VE-UHMWPE particles have reduced osteolysis potential in vivo when compared to virgin, highly cross-linked UHMWPE in a murine calvarial bone model. Arthroplasty procedures using VE-UHMWPE might be less susceptible to peri-prosthetic loosening caused by wear debris

Introduction. In vitro findings (Bladed CL et al. ORS 2011 and J Biomed Mater Res B Appl Biomater, 2012) have suggested that UHMWPE wear particles containing vitamin-E (VE) may have reduced functional biologic activity and decreased osteolytic potential. Currently, there is no in vivo data determining the effects of wear debris from this new generation of implants. In this study we hypothesized that particles from VE-stabilized, radiation cross-linked UHMWPE (VE-UHMWPE) would cause reduced levels of osteolysis in a murine calvarial bone model when compared to virgin gamma irradiated cross-linked UHMWPE. Methods. Study groups: 1). Radiation cross-linked VE-UHMWPE, 0.8% by weight, diffused after 100 kGy; 2). Radiation cross-linked virgin UHMWPE (virgin UHMWPE); 3). Shams. Particle generation and implantation: UHMWPE was sent to Bioengineering Solutions for particle generation. After IACUC approval, C57BL/6 mice (n = 12 for each group) received 3 mg of particulate debris overlying the calvarium and euthanized after 10 days. Micro-CT scans: Performed using an X-Tek-HMX-ST-225 with 70 kV voltage and 70 μA current. Topographical Grading Scale: Each calvarial bone was blindly scored with the following scale: 0 = No osteolysis, defined as intact bone; 1 = Minimal osteolysis, affecting 1/3 or less of the bone area; 2 = Moderate osteolysis, affecting at least 2/3 of the bone area; 3 = Severe osteolysis, defined as completely osteolytic bone. Histology H&E and TRAP staining was performed. Statistical Analysis: Inter-rater analysis was performed using Cohen's kappa analysis. Inter-rater coefficient >0.65 was considered as high inter-rater agreement. Comparison between groups was made using one-way ANOVA with post hoc Bonferroni correction for multiple comparisons. Correlations are reported as Spearman's rho. A p-value<0.05 was considered statistically significant. Results. More than 83% of the VE-UHMWPE and more than 85% of the virgin UHMWPE particles measured less than 1 μm in mean particle size. There was a statistically significant greater level of osteolysis visualized on the topographical grading scale in calvaria implanted with virgin UHMWPE wear particles. The micro-CT findings were confirmed histologically (Fig. 1). A greater amount of inflammatory tissue overlaying the calvaria was observed in the virgin UHMWPE group when compared to both shams and VE-UHMWPE groups. Post hoc analysis revealed significant difference between VE-UHMWPE and virgin UHMWPE for the topographical osteolysis grading score (p = 0.002) but no difference in osteoclast count (p = 0.293). Discussion/Conclusion. This is the first in vivo study reporting the effects of clinically-relevant UHMWPE particles generated from a VE-UHMWPE implant that is in current clinical use. These results suggest that VE-UHMWPE particles have reduced osteolysis potential in vivo when compared to virgin, highly cross-linked UHMWPE in a murine calvarial bone model