Laboratory experiments and computational models were used to predict bone-implant micromotion and bone strains induced by the cemented and cementless Biomet Oxford medial Unicompartmental Knee Replacement (UKR) tibial implants. Ten fresh frozen cadaveric knees were implanted with cementless medial mobile UKRs, the tibias were separated and all the soft tissues were resected. Five strain gauge rosettes were attached to each tibia. Four Linear Transducers were used to measure the superior-inferior and transverse bone-implant micromotions. The cementless UKRs were assessed with 10 cycles of 1kN compressive load at 4 different bearing positions. The bone-constructs were re-assessed following cementation of the equivalent UKR. The cemented bone-implant constructs were also assessed for strain and micromotion under 10000 cycles of 10mm anterior-posterior bearing movement at 2Hz and 1kN load. The cadaveric specimens were scanned using Computed Tomography, and 3D computer models were developed using Finite Element method to predict strain and micromotion under various daily loads. Results verify computer model predictions and show bone strain pattern differences, with cemented implants distributing the loads more evenly through the bone than cementless implants. Although cementless implants showed micromotions which were greater than computer predictions, the micromotions were as expected significantly greater than those of cemented implants. The computer models reveal that bone strains approach 70% of their failure limit at the posterior and anterior corners adjoining the sagittal and transverse cuts (less pronounced in cemented implants). The base of the keel also develops high strains which can approach failure depending on the amount the implant press-fit. The contributions of the anterior cruciate and patellar tendon forces exacerbate the strains in these regions. This may explain why fractures emanate from the base of the keel and the sagittal cut.Methods
Results and Discussion
Shockwave treatment in our unit is provided in conjunction with our Urological colleagues. Shock Wave Therapy has been used as a last option in patients with difficult and chronic Orthopaedic conditions with an informed consent for all patients.
Patients were consented by the Orthopaedic surgeon and the treatment was administered by urologist The cases included:
4 Humeral fractures: 1 Case in HIV +ve 19 years old 5 Femoral non-union: 1 case bilateral in Osteogenesis imperfecta 4 Tibial non-union: 1 Recurent Fracture in 65 years old man 2 Osteochondritis of the Talus 2 Osteochondritis of the knee 4 Scaphoid fractures: 1 case had been fixed and grafted. Medial Epicondyle fracture non union 5th Metacarpal Fracture Trochanteric Bursitis Tennis Elbow 4 Planter fasciitis – The Shock wave Machine used is Storz SLX – F2 Electromagnetic shock wave generator which focus the shock wave low energy high frequency in focal zone with no harm to other tissues. Frequency 4 htz = 4 shockwave/sec – Energy level 1–3 generate pressure value in the focal area of 5–30 megapascal – Size of focal zone 9X 50 mm or 6X 28 mm – Total shock wave applied per session 2000 to 3000 shock – large focus and small focus were used in fracture of large bones and small bones respectively. Most of cases required 2–3 session with 4–6 weeks interval. – in Soft tissue Treatment Less energy was used and patients required 1 to 2 sessions.
– Clinical and radiological union in 3 of the 4 Humeral Fracture including HIV+ve and in 2 of 3 tibial fracture and 1 of 2 scaphoid. – 50% pain relief in Psedo arthrosis – Union is promoted by Cellular stimulation and pain relief is by unknown mechanism but explained by increase vascularity and neuro-modulation. – None of the patient’s have so far required subsequent operative interventions, several had residual symptoms.
Acetabular centre positioning in the pelvis has a profound effect on hip joint function. The force–and moment-generating capacities of the hip muscles are highly sensitive to the location of the hip centre. We describe a novel 3D CT-based system that provides a scaled frame of reference (FOR) defining the hip centre coordinates in relation to easily identifiable pelvic anatomic landmarks. This FOR is more specific than the anterior pelvic plane (APP) alone, giving depth, height and width to the pelvis for both men and women under-going hip surgery. CT scans of 22 normal hips were analysed. There were 14 female and 8 male hips. The APP was used as the basis of the coordinate system with the origin set at the right anterior superior iliac spine. After aligning the pelvis with the APP, the pelvic horizontal dimension (Dx) was defined as the distance between the most lateral points on the iliac crests, and its vertical dimension (Dy) was the distance between the highest point on the iliac wing and the lowest point on ischial tuberosity. The pelvic depth (Dz) was defined as the horizontal distance between the posterior superior iliac spine and the ipsilateral ASIS. The ratios of the hip centre’s x, y, and z coordinates to their corresponding pelvic dimensions (Cx/Dx, Cy/Dy, Cz,Dz) were calculated. The results were analysed for men and women. For a given individual the hip centre coordinates can be derived from pelvic landmarks. We have found that the mean Cx/Dx measured 0.09 ± 0.02 (0.10 for males, 0.08 for females), Cy/Dy was 0.33 ± 0.02 (0.30 for males, 0.35 for females), and Cz/Dz was 0.37 ± 0.02 (0.39 for males and 0.36 for females). There was a statistically significant gender difference in Cy/Dy (p=0.0001) and Cz/Dz (p=0.03), but not in Cx/Dx (p=0.17). Anteversion for the male hips averaged 19° ± 3°, and for the female hips it was 26° ± 5°. Inclination measured 56° ± 1° for the males and 55° ± 4° for the females. Reliability testing showed a mean intra-class correlation coefficient of 0.95. Bland-Altman plots showed a good inter-observer agreement. This method relies on a small number of anatomical points that are easily identifiable. The fairly constant relationship between the centre coordinates and pelvic dimensions allows derivation of the hip centre position from those dimensions. Even in this small group, it is apparent that there is a difference between the sexes in all three dimensions. Without the need for detailed imaging, the pelvic points allow the surgeon to scale the patient’s pelvis and thereby know within a few millimetres the ‘normal’ position of the acetabulum for both men and women. This knowledge may be of benefit when planning or undertaking reconstructive hip surgery especially in patients with hip dysplasia or bilateral hip disease where there is no reference available for planning the surgery.
Although acetabular centre positioning has a profound effect on hip joint function, there are very few studies describing accurate methods of defining the acetabular centre position in 3D space. Clinical and plain radiographic methods are inaccurate and unreliable. We hypothesize that a 3D CT-based system would provide a gender-specific scaled frame of reference defining the hip centre coordinates in relation to easily identifiable pelvic anatomic landmarks. CT scans of thirty-seven normal hips (19 female and 18 male) were analysed. The ratios of the hip centre coordinates to their corresponding pelvic dimensions represented its horizontal (x), vertical (y), and posterior (z) scaled offsets (HSO, VSO, and PSO). The mean HSO for females was 0.08 ± 0.018, mean VSO was 0.35 ± 0.018, and mean PSO was 0.36 ± 0.017. For males HSO averaged 0.10 ± 0.014, VSO was 0.32 ± 0.015, and PSO was 0.38 ± 0.013. There was a statistically significant gender difference in all three scaled offsets (p=0.04, 0.002, and 0.03 for HSO, VSO, and PSO respectively). Inter-observer agreement tests showed a mean intra-class correlation coefficient of 0.95. We conclude that this frame of reference is gender-specific giving a unique scale to the patient and allowing reliable derivation of the position of the hip centre from the pelvic dimensions alone. The gender differences should be borne in mind when positioning the centre of a reconstructed hip joint. Using this method, malpositioning, particularly in the antero-posterior (or z) axis, can be identified and addressed in a malfunctioning hip replacement. Pathological states, such as dysplasia and protrusio, can also be accurately described and surgery addressing them can be precisely planned.
Using software adapted for the specific purpose, femoral cortical volume was measured at three different levels at a fixed distance from the lower border of the lesser trochanter on both sides: 6mm distal to the tip of the prosthesis (z), At the top of the cylindrical portion(x) Midway between x and z (y). Accuracy and precision of the of the method was also assessed.
No significant trend was noted with change of volume of bone with time. In the three cases who had cemented hips on their other side, the cemented hips exhibited substantially more stress shielding than their cementless controls (ratios of 0.82, 0.74 and 0.85). A high correlation between the test and standard measurements was noted. The interobserver agreement between two observers was also good.
Periprosthetic bone remodeling after uncemented hip replacement has always been a matter of research and debate. DEXA analysis of bone density was studied by previous groups but not the cross sectional cortical volume. We report a validated CT based algorithm for accurate measurement of cortical volume in these group of patients. Twenty two patients who have undergone Uncemented Furlong total hip replacement agreed to undergo CT scan of their hips for our study. The mean age was 74.6 yrs. The mean follow up was 5.4 yrs. Using software adapted for the specific purpose, femoral cortical volume was measured at three different levels at a fixed distance from the lower border of the lesser trochanter on both sides:
6mm distal to the tip of the prosthesis (z), At the top of the cylindrical portion(x) Midway between x and z (y). Accuracy of the method was assessed by measuring the volume of artificial cavities created on a polyurethane pelvis. Assessment of precision of method was done by calculating the level of agreement between two observers. The mean cortical volume in the proximal cylindrical portion (x), midpoint(y) and the portion of bone distal to the prosthesis (z) were 458 mm3, 466 mm3, 504 mm3 respectively. The corresponding cortical volumes in the contralateral native femur in unilateral hip replacements were 530 mm3(x), 511 mm3(y), 522 mm3 (z) giving a ratios of 0.86(x), 0.91(y) and 0.97(z). The mean cortical volumes on the left side of bilateral hips were 490 mm3(x), 499 mm3(y) and 528 mm3 (z). The mean cortical volumes on the right side were 456 mm3(x), 463 mm3 (y) and 516 mm3 (z). No significant trend was noted with change of volume of bone with time. In the three cases who had cemented hips on their other side, the cemented hips exhibited substantially more stress shielding than their cementless controls (ratios of 0.82, 0.74 and 0.85). A high correlation between the test and standard measurements was noted. The interobserver agreement between two observers was also good. In a fully coated uncemented femoral component, with documented long term results, it is to be expected that load will be shed steadily along the length of the prosthesis. In this study we have confirmed this supposition, with volumetric data, by showing that an almost normal bone just below the tip of the stem (97% volume) reduces to a bone volume of 91% by the middle of the stem and then 86% by the shoulder of the prosthesis. This decrease in the volume of cortical bone effectively normal at the tip of the prosthesis while not optimal appears to stabilize early with no trend of continued reduction over a decade. The effect of cementation on stress shielding was only examined incidentally in this study but appears to contribute to more marked bone loss.
Acetabular and pelvic fractures are amongst the most challenging to treat, still requiring major open surgery. The operations to reduce and fix them entail lengthy operative time, significant blood loss and use of ionising radiation. We report on the initial stages of developement of a minimally invasive method for navigated reduction and percutaneous fixation of acetabular fractures (NRFA). A commercial navigation platform (Acrobot Ltd.) will be adapted for use with this technique. CT based planning will be used to identify the correct realignment of the the bone fragments, which will then be reduced percutaneously with the aid of two tracked arms attached to the navigation system. Schanz pins, which are inserted in pre-operatively planned sites in each fragment using safe trajectories, are handled as joysticks to manipulate the fracture under computer assistance. Registration of the fragments after insertion of the joysticks will be carried out by means of fluoroscopic images of the AP and Judet views of the fractured acetabulum. Once reduction is achieved by following on-screen instructions, the joysticks are held in place by a custom clamping system connected to one of the arms, while the other is used for percutaneous insertion of column screws. This technique is potentially suitable for a number of acetabular fractures which include transverse, anterior column, posterior column, T-fractures and some associated both columns fractures. These constitute over 50% of Letournel’s and 60% of Matta’s original series of acetabular fractures. Furthermore, this percutaneous technique could reduce bleeding, wound complications, hospital stay and cost of treatment. Intra operative ionising radiation would be greatly reduced for both patients and the surgeons. Adequate training with the use of this software may provide a greater number of surgeons the capability to surgically treat these complex fractures.
