We report a series of 668 patients (699 hips) with an average follow up of 10.5 years (range, 10–11 years) following THR using a cemented custom-made titanium femoral stem and a cemented high-density polyethyl-ene acetabular component. The fate of every implant is known. The mean age at operation was 68 years (24 – 94 years). The indication for THR was as follows: primary OA (629), RA (18), AVN (10), intracapsular femoral neck fracture (5), Perthes disease (3), developmental hip dysplasia (2) and SUFE (1). The mean pre-operative Harris Hip Score was 19 (range 10 – 42). One hundred and seventy-four patients (26%) were deceased at the time of their 10-year review. Four hundred and ninety-four patients were subsequently reviewed of which 88 patients (13%) were assessed by telephone review as they were too frail to attend. The average 10-year Harris Hip Score was 92 (range 43 – 100). The average 10-year Oxford Hip Score was 19 (range 12 – 46). 99.2% reviewed at 10 years stated that they were satisfied with their THR. Revision surgery occurred in 21 cases (3%). Seventeen femoral components were revised for infection, one for recurrent dislocation and one was iatrogenically loosened during socket revision. There were no cases of revision for aseptic loosening of the stem. Dislocation occurred in 18 cases, of which 4 became recurrent (0.6%). Six patients had a postoperative sciatic nerve palsy (0.9%) with 4 making a full recovery. There was one case of femoral nerve palsy. Eleven patients developed a DVT (1.6%). Six patients had a PE (0.9%) all of which were non-fatal. There were 16 deep and 3 superficial wound infections. Thirty-eight patients had symptomatic trochanteric bursitis post-surgery. In conclusion, the 10-years results of the custom femoral stem are encouraging with an overall high level of patient satisfaction

We describe the results of 81 consecutive revision total hip replacements with impaction grafting in 79 patients using a collared polished chrome–cobalt stem, customised in length according to the extent of distal bone loss. Our hypothesis was that the features of this stem would reduce the rate of femoral fracture and subsidence of the stem.

The mean follow-up was 12 years (8 to 15). No intra-operative fracture or significant subsidence occurred. Only one patient suffered a post-operative diaphyseal fracture, which was associated with a fall. All but one femur showed incorporation of the graft. No revision for aseptic loosening was recorded.

The rate of survival of the femoral component at 12 years, using further femoral revision as the endpoint, was 100% (95% confidence interval (CI) 95.9 to 100), and at nine years using re-operation for any reason as the endpoint, was 94.6% (95% CI 92.0 to 97.2).

These results suggest that a customised cemented polished stem individually adapted to the extent of bone loss and with a collar may reduce subsidence and the rate of fracture while maintaining the durability of the fixation.

CT and advanced computer-aided design techniques offer the means for designing customised femoral stems. Our aim was to determine the Hounsfield (HU) value of the bone at the corticocancellous interface, as part of the criteria for the design algorithm.

We obtained transverse CT images from eight human cadaver femora. The proximal femoral canal was rasped until contact with dense cortical bone was achieved. The femora were cut into several sections corresponding to the slice positions of the CT images. After obtaining a computerised image of the anatomical sections using a scanner, the inner cortical contour was outlined and transferred to the corresponding CT image. The pixels beneath this contour represent the CT density of the bone remaining after surgical rasping. Contours were generated automatically at nine HU levels from 300 to 1100 and the mean distance between the transferred contour and each of the HU-generated contours was computed.

The contour generated along the 600-HU pixels was closest to the inner cortical contour of the rasped femur and therefore 600 HU seem to be the CT density of the corticocancellous interface in the proximal part of cadaver femora. Generally, femoral bone with a CT density beyond 600 HU is not removable by conventional reamers. Thus, we recommend the 600 HU threshold as one of several criteria for the design of custom femoral implants from CT data.

In the past it has been widely accepted that bone remodelling of the proximal femur after cementless total hip replacement is a result of the altered mechanical environment. Usually, there is are distribution of the stresses in the bone, and subsequently bone mass, from the metaphysis to the proximal part of the diaphysis. The design rationale for some cementless stems is to transmit load to the proximal femur and thus to preserve the bone mineral content in this area. The aim of the present study was to investigate the relationship between postoperative strain shielding of the proximal femur and the bone remodelling after insertion of two different cementless femoral stems. Experimental study: Twelve pairs of human cadaveric femurs were instrumented with strain gauge rosettes in Gruen zones2 to 7 and the cortical strains were measured during simulation of one leg stance before and after insertion of a custom stem (Unique, SCP) or an anatomic stem (ABG, Stryker-Howmedica). Clinical study: In a prospective, randomized study including 80 patients, the same types of stems were inserted and the bone mineral density (BMD) was measured during the first two years postoperatively using DEXA. Then, the pattern of remodelling was compared with the gradient of strain shielding in each of the Gruen zones in the frontal plane. In Gruen zone 7 the relative cortical strain shielding was45% in the femurs with a custom stem and 87% in the femurs with an anatomic stem. In zone 6 the corresponding figures were 2% and 38%, in zone 5 0% and15% and in zone 3 0% and 20%. The DEXA measurements showed a decrease in BMD in zone 7 of 22% and 23% for the two stems, respectively. In the other zones the bone loss was smaller and there was no difference between the stems. In the proximal zones there was a highly significant difference in strain shielding between femurs receiving a customor an anatomic stem. However, there was no difference in the pattern of bone remodelling. The bone remodelling around these two stems does not seem to mirror the gradient of strain shielding

Introduction. We have been developed lateral flare stem and have been using it since 1989. It was custom stem at first. After being experienced, using the same software, off-the-shelf version lateral flare stem (Revelation) was developed in 1996 in the U.S. We could start using it since 2001 in our country. Lateral flare stems are designed to reproduce physiological proximal load transfer lateral side as well as medial side. It was obtained by having bigger and more accurate proximal part with lateral flare. The design is optimized by matching with 3D insertion path. Using many custom stems including different length and off-the-shelf standard stems, we have come to feel that as for this high proximal fit and load transfer design, it is not necessary to having long distal part and sometimes it is harmful to obtain good proximal load transfer in some situation such as type A (champagne flute) canal. So we have developed short version of the stem. Many makes of the hip stems have included short stems recently. Some aimed to improve easier insertion, some aimed to improve the volume of residual bone quantity. We have aimed to improve proximal fit expecting more proximal and more physiological load transfer to the femur. Objectives. Our objectives are to comare standard stem and short stem from biomechanical aspect and clinical aspect. Materials and methods. As for the biomechanical aspect, finite element analyses were done with standard and short stem. As for the clinical aspect, the very last 25 cases of the standard stems; which we have 12 years clinical experience; done at Nagoya City University, the very first 25 cases of the short stems, and the next 25 cases were examined. The distance between stem and cortical bone on medial and lateral side at lateral flare hight of the stem and the bottom of arc deposite coated area. Alignment was assessed by the angle of the stem and canal axis. Result. By the FEA, small stress point was observed at the tip of the standard stem which pushes canal wall from inside (Fig. 1), which was disappeared at the tip of the short stem. Less micromotion was observed in short stem too. No significant difference was observed in the stem cortical distance. No significant difference of stem alignment was observed between standard stem and all 50 short stems but better alignment (p = 0.07) was seen in the second 25 cases of the short stem than standard stem. Between the first 25 and the second 25 case high difference (p = 0.01) was seen. (Fig. 2). Discussion. The standard lateral flare stem has very physiological proximal load transfer in most of the cases, sometimes longer distal part could effect to the alignment because of the femoral bending. Short stem could be expected have better alignment being free from femoral bending. On the contrary, distal part could be the insertion guide during the surgery. For the short stem, learning curve exists to realize potentially better alignment

Introduction: For longer lasting and bone conserving cementless stem fixation, stable and physiological proximal load transfer from the stem to the canal should be one of the most essential factors. According to this understanding, we have been developing a custom stem system with lateral flare and an off-the-shelf (OTS) lateral flare stem system was added to the series. On the other hand, dysplastic hips are often understood that they have larger neck shaft angle as well as larger anteversion. In other words they are in the status called “coxa valga.” From this point of view we had been mainly using custom stems for the dysplastic cases before. After off-the-shelf lateral flare stem system; which is designed to have very high proximal fit and fill to normal femora; was added, we have been using 3D preoperative planning system to determine custom or OTS. Then in most of the cases, OTS stem were suitably selected. Our pilot study of virtual insertion of OTS lateral flare stem into 38 dysplastic femora has shown very tight fit in all 38 cases. The reason was analyzed that the excessive anteversion is twist of proximal part over the distal part and the proximal part has almost normal geometry. In the present study, 59 femora were examined by the 3D preoperative planning system how the excessive anteversion effect to the coxa valga status. Materials and Methods: Fifty-nine femoral geometry data were examined by the 3D preoperative planning system. Thirty-three hip arithritis, 3 RA, 2 metastatic bone tumours, 5 AVN, 1 knee arthritis, 12 injuries, and 3 normal candidates were included. Among them one arthritic Caucasian and one AVN South American were included. The direction of the femoral landmarks; centre of femoral head (CFH), lesser trochanter (LTR), and asperas in 3 levels (just below LTR, upper 1/3, mid femur; A1-3); were assessed as the angle from knee posterior condylar (PC) line. Neck shaft angle of each case was assessed from the view perpendicular to PC line and neck shaft angle form the view perpendicular to CFH and femoral shaft (i.e. actual neck shaft angle). Results: Average anteversion was 34.4 +/−9.9 degree. CFH and LTR correlated well (i.e. they rotate together). A1, A2, A3 correlated well (i.e. they rotate together). LTR and A1 correlate just a little, LTR and A2 were independent each other. So the twist existed around A1. Neck shaft angle was 138.7+/−6.6 in PC line view and in actual view 130.3+/−4.4. No excessive neck shaft angle was observed in actual view. Even the case that has the largest actual neck shaft angle (140.4), the virtual insertion showed good fit and fill with the lateral flare stem. Conclusion: In many high anteversion cases, coxa valga is a product of the observation from non perpendicular direction to CFH-shaft plane. Selection or designation of the stem for high anteversion cases should be carefully determined by 3D observation

18 years ago laboratory studies were started to develop a CT-based uncemented customised femoral stem in order to optimise the fixation and strain distribution to the proximal femur in uncemented femoral components. An individual design also aimed to optimise the biomechanics of the joint and to enable use of uncemented stems in femurs with abnormal shape and dimension. The developed prosthesis has now been in clinical use for 13 years. The aim of this paper is to present the preliminary results of a prospective clinical study of this prosthesis. Patients and methods: 685 hips have been operated. 58.8 % of the patients were women. Mean age was 51 years (20–69). 42.3 % of the hips were dysplastic. A high number of hips without major anatomic abnormality of the upper femur were included. The prostheses were designed to obtain a neck anteversion of 10 degrees after insertion, optimised medial femoral head offset and correction of leg length discrepancies up to 3 cm. All patients were followed with radiological and clinical examination. Merle d’Aubigné score was used. RSA and DEXA-studies have been performed in some groups of the patients. Finally, study of the gluteal muscular function in hips with optimised medial femoral head offset after insertion of custom stems was compared to hips where optimisation had not been achieved with use of standard stems. Results: We experienced that use of this type of prosthesis is very simple and offers obvious advantages in abnormal size and geometry of the upper femur. Nine patients sustained a peroperative fissure in the proximal femur (1.3 %). These fissures were treated successfully with cerclage wires. Eight patients sustained a femoral fracture by a fall accident. Four fractures healed after osteosynthesis without loosening of the prosthesis. A long stem pros-thesis had to be used in the other four. No stem loosening was seen except in one case where a non-union after subtrochanteric osteotomy prevented stem fixation. Dislocation occurred in ten hips (1.5%). In four of these the acetabular component had to be replaced. Average total score at 7 years (125 hips) was 17.1 (preop 9.4), at 10 years (56 hips) 17.0 (preop 9.4). The pain scores at the corresponding observations were 5.7 (preop 2.7) and 5.6 (preop 2.8). DEXA-studies showed comparable preservation of femoral bone stock in hips treated with custom and standard stems (ABG). RSA-studies showed no significant stem migration. Superior function of the gluteal muscles was obtained after normalisation of the medial femoral head offset after insertion of a custom stem when compared to hips where normalisation had not been achieved by a standard stem. Conclusions: Use of custom femoral components enables optimisation of the biomechanics of the hip and eliminates the need for highly modular femoral stems. The rate of peroperative fissures and postoperative instability is relatively low indicating adequate fit of the stem and adequate design of the femoral neck. Use of custom prostheses offers obvious advantages in highly abnormal femurs. The mid-term clinical results up to 10 years are promising with a very low risk of aseptic loosening. However, it remains to see whether use of such pros-theses will give superior long term results compared to standard uncemented stems in “normal” femurs

Aims: The aim of this study was to measure implant migration and bone remodelling of the proximal femur two years after insertion of a customized or a standard femoral stem. Materials and methods: In a prospective, randomized study 26 hips (26 patients) have been examined postoperatively and after 3, 6, 12 and 24 months using radiostereometry (RSA) and DEXA. Thirteen hips received a customized femoral stem (Unique, SCP as) and 13 hips received a standard uncemented femoral stem (ABG¨, Stryker-Howmedica). An uncemented acetabular cup (Duraloc¨, DePuy) was used in all hips. The mean age of the patients was 55 (24–67) years. Results: The median displacement of the custom/ standard femoral stems was 0.04/0.01 mm along the - medial-lateral axis, 0.08/0.02 mm along the proximal-distal axis and 0.03/0.08 mm along the anterior-posterior axis, respectively. Statistically, there was no difference between the two groups. One custom stem subsided 5.2 mm at one year, but showed no further migration at two years. The mean decrease in bone mineral density (BMD) in all Gruen zones was 6% in the Custom-group and 7% in the ABG-group. The most pronounced bone loss was seen in Zone 7 and was 21% and 25% for the two groups, respectively. Discussion: We found no statistically signiþcant difference in short-term stem migration comparing a customized and a standard, uncemented femoral stem. Furthermore, the changes in bone mineral density were almost equal in femurs with either type of prosthesis

Aims: An argument against the use of canal-þlling, customized femoral stems has been that such implants have a large cross-sectional area and therefore are stiffer than standard, uncemented implants and thus induce more stress shielding and bone loss in the proximal femur. The purpose of this study was to evaluate the association between the volume of an uncemented, customized femoral stem and the postoperative changes in peri-prosthetic bone mineral density (BMD) measured with DEXA. Material and methods: Forty-eight patients with a mean age of 46 years had a THR using a customized femoral stem (Unique, SCP, Norway). BMD was measured in the 7 Gruen zones postoperatively and after then 3, 6, 12 and 24 months. Based on the 3-D computer model of the implant the volume of the intrafemoral part of the stem was computed. The association between the relative change in BMD at the 2 years follow-up and the volume of the stem was assessed using Pearsonñs correlation test. Results: A statistically signiþcant correlation between the volume of the intrafemoral part of the stem and change in BMD was found in Gruen zones 2, 4, 5 and for the overall BMD in all zones. No such correlation could be found for the most proximal zones (1, 6 and 7). Conclusions: No consistent or strong association between the volume of the femoral stem and the periprosthetic stress shielding at 2 years postoperatively was found in this study. In particular, the bone remodelling in the most proximal part of the femur was not correlated to the size of the stem. Contrary to other studies, our þndings imply that stem size or stiffness is not a major determinant for proximal femoral stress shielding following total hip replacement

To maximise the long-term survivorship of any hip prosthesis it is important to recreate joint centre. Normal joint centre is determined by horizontal offset and vertical height of the acetabular and femoral components. In this study joint centre and horizontal offset were analysed in 200 consecutive patients operated on from October 1998 in whom the opposite hip was normal. Joint centre was defined relative to the acetabulum and femur both pre- and post-operatively. On the acetabular side a horizontal line was drawn across the pelvis immediately below each teardrop. A vertical line was drawn at right angles through the middle of each teardrop. Acetabular offset was defined as the horizontal distance from the vertical trans teardrop line to head centre. For femoral offset a screened x-ray was taken to show maximum offset. The anatomical axis was drawn and the offset was defined as the distance from the anatomical axis to head centre. Our results show on the acetabular side there was an overall tendency to leave the joint centre medial and so decrease acetabular offset. However, we found that 90% of our sockets were placed within 6 mm of normal joint centre. We attribute this accuracy to the principle of visualising the transverse acetabular ligament intra-operatively and using this landmark to control depth of socket insertion. Conversely, on the femoral side there was a slight tendency to increase the offset. Nevertheless, 98% of the custom stems were within 10mm of normal joint centre. When we looked at total horizontal offset i.e. the combination of femoral and acetabular offset we found that joint centre had been restored to within 10mm in 93% of cases. This study confirms the effectiveness of the custom femoral stem and Duraloc socket in restoring joint centre

The operation technique and prosthetic materials for total hip replacement (THR) have continuously improved. Still, defining the end-point of the prosthetic stem insertion into the femur canal relies on the feeling of the orthopaedic surgeon. This consists of a sense of mechanical stability when exerting torque forces on the prosthesis as well as a feeling of the prosthesis being well fixed and not displaceable along the axis of the femur. Stability and survival of the implant is directly related to the long term fixation stability of the prosthesis stem. But, excessive press-fitting of a THR femoral component can cause intra-operative fractures. In our centre custom made stem prostheses are commonly used to increase the optimal fit in the femoral canal. We report the first per-operative use of a non invasive vibration analysis technique for the mechanical characterization of the primary bone-prosthesis stability. From in vitro studies a protocol has been derived for per-operative use. The prosthesis neck is attached to a shaker using a stinger provided with a clamping system. The excitation is realized through white noise in the range 0–12.5 kHz, introducing a power of approximately 0.5W into the femur-prosthesis system. The input force and the response acceleration are measured in the same point with an impedance head mounted between the shaker and the stinger. The Frequency Response Function (FRF) is measured and recorded by a Pimento vibration analyzer connected to a portable computer provided with the appropriate software. All equipment is installed in the surgical theatre but outside the so-called laminar flow area. The surgeon inserts the implant in the femoral canal through repetitive controlled hammer blows. After each blow, the FRF of the implant-bone structure is measured directly on the prosthesis neck. The hammering is stopped when the FRF graph does not change noticeably anymore. The amount of FRF change between insertion steps is quantified by the Pearson’s correlation coefficient R between successive FRFs. A correlation between the FRFs of successive stages of R=(0.99 +/− 0.01) over the range 0–10000 Hz is proposed as an endpoint criterion. Non-cemented custom made stem insertion was studied in 30 patients. In 26/30 cases (86.7%), the correlation coefficient between the last two FRFs was > 0.99 when the surgeon stopped the insertion. In 4 cases, the surgeon decided to stop the insertion because of suspected bone fragility, the final correlation coefficient was lower. In one case an abnormal change in the FRF graph triggered inspection of the femur bone. A small fracture was observed and insertion was stopped. In a second case FRF graph showed an oscillating behaviour, while the stem was visibly not completely inserted. After withdrawal of the stem and readjustment of the femoral canal, the stem could be reinserted and the Pearson’s correlation index at end of insertion was 0.998. The use of custom made stem prosthesis, made exactly to fit into the femoral canal increases the risk of excessive press fit and intra-operative fractures. Vibration analysis showed to be a useful tool to define end of the stem insertion

Introduction. Total hip arthroplaty (THA) using direct anterior minimal invasive (AMI) surgery is an attractive option to achieve a quicker habilitation. However, high complication rates were reported and very often related to technical difficulties at the time of surgery. We hypothesized that 3D preoperative planning may allow to anticipate these difficulties and to decrease the complications rates when using an AMI approach. Material and methods. A prospective observational study included 191 consecutive patients who underwent a primary cementless THA using an AMI. A 3D CT-scan based pre-operative planning was performed in order to anticipate the potential difficulties that may be encountered especially regarding the hip anatomy reconstruction and the implants stability. The components size and position were planned in order to restore the leg length, the offsets, and the anteversions. Postoperatively, a CT scan was performed in order to compare the final anatomy to the planning. Results. The real implants were the same than the ones planned in 94% for the cup, 96% for the stem and 100% for the neck. The hip anatomy was restored with a high accuracy: 0.1±3mm for the hip rotation centre, −1.6±3 mm for the leg length and 0.1±2.5mm for the femoral offset. All the surgical difficulties were anticipated. No false route and no dislocation occurred. A motorized reaming procedure of the femur was required in 6 patients because a very dense bone associated to a narrow femoral diaphysis. A varus neck was used in 60 % of cases mainly in order to compensate a decrease in the acetabular offset generated by the reaming procedure imposed by the acetabular dysplasia. A retroverted neck was used in 8% of patients because of a torsional abnormality and allowed to increase the stability (Figure 1). A severe femoral dysplasia was treated with a custom stem in 7% of cases in order to avoid a rotational osteotomy of the femur a trochanteromy (Figure 2). Discussion. No complication happened at the time of surgery and no dislocation occurred afterwards. False routes were avoided probably also thanks to the shape of the anatomic stem which presents an anterior sagittal curvature. This shape allowed an easier rasping procedure despite the limited exposure of the femur. Conclusion. 3D planning anticipates the potential surgical difficulties at the time of THA, and allow to increase the safety and the accuracy of the surgical procedure

Improving the adaptation between the implant and the patient bone during total hip arthroplasty (THA) may improve the survival of the implant. This requires a perfect understanding of the tridimensional characteristics of the patient hip. The perfect evaluation of the tridimensional anatomy of the patient hip can be done pre-operatively using X-rays and CT-scan. All patients underwent a standard x-rays evaluation in the same center according to the same protocol. Pre-operatively, the frontal analysis of the hip geometry was performed and the optimal center of rotation, CCD angle, neck length and lever arm was analyzed to choose the optimal solution for proper balance of the hip in order to obtain adequate range of motion, appropriate leg length, and correct tension of the abductors muscles. Standard or lateralized monoblock stems can be valid or modular neck shape can be choosen among 9 available shape. These 9 frontal shapes are available in standard, anteverted or retroverted shapes, leading to 27 potential neck combinations. In case of important hip deformation, a custom implant can be used in order to balance the extra-medullar geometry without compromising the intra-medullary adaptation of the stem. We prospectively included 209 hips treated in our institution with total hip arthroplasty performed using a supine Watson-Jones approach and the same anatomic stem. The mean patient age was 68 years and the mean BMI 26 Kg/m². Intra-operatively the sagittal anatomy of the hip was analyzed and standard, ante or retro modular necks were tested for the frontal shape defined pre-operatively. According to the pre-operative frontal planning, non-standard necks were required in 24 % of the cases to restore the anatomy of the hip. Intra-operatively, a sagittal correction using anteverted neck was required in 5% of the cases and retroverted necks in 18% of the cases. Harris hip score improved from 56 to 95 points at min. 5 year follow-up. No leg length discrepancy greater than 1 cm was observed. Restoration of the lever arm (mean 39.3 mm, range 30 to 49 mm) and of the neck length (55.2, range 43 to 68 mm) was adapted for 95% compared to the non operate opposite side. Disturbed anatomy like in DDH or post-traumatic cases may require additional solutions to balance the hip such combined osteotomy or customized stem and neck

A clinical and radiographic study was conducted on 97 total hip arthroplasties (79 patients) performed for congenital hip dislocation using three-dimensional custom cementless stem. The mean age was 48 years (17 to 72). The mean follow up was 123 months (83 to 182). According to Crowe, there were 37 class 1, 28 class 2, 13 class 3 and 19 class 4. The average lengthening was 25 mm (5 to 58 mm), the mean femoral anteversion 38.6° (2° to 86°) and the correction in the prosthetic neck −23.6° (71° to 13°). The average Harris hip score improved from 58 to 93 points. Six hips (6.2%) required a revision. The survival rate was 97.7% ± 0.3% at 13 years. Custom cementless stem allows anatomical reconstruction and good functional results in a young and active population with disturbed anatomy, while avoiding a femoral osteotomy

Introduction. Since 1989, we have been developing lateral flare stem. The concept of lateral flare stem is to deliver proximal part big enough to fill the proximal cavity that most of the cement stems can fill and most of the cementless stems cannot. Also having distal part polished, much less distal load transfer occurs than cement stem. Thus, we can expect high proximal load transfer to prevent stress shielding. To deliver lateral flare stem, straight insertion path cannot be available, as proximal lateral part to fill inside the greater throchanter collides to the greater trochanter. So 3-Dimension insertion path was calculated to deliver that part through the narrow made by neck osteotomy. The first generation of the lateral flare stem was custom made. The second generation was designed as an off-the-shelf stem from what we have learned by the experience of custom stems. With the third generation, the stem was shortened to achieve more proximal load transfer. Direct Anterior Approach (DAA) developed by Judet is one of less invasive hip approach. With a stem with straight insertion path, the extended line of proximal femoral axis should come out of the skin. To achieve this position, proximal end of the femur has to be fully pulled up. (Fig.1) Some of the cases would be able to be lifted up but some have difficulty. Using lateral flare stem with curved 3 dimensional insertion path, even the axis extension does not come out of the skin, it would be expected to be inserted. In the present study, 3D insertion path of the lateral flare short stem for DAA was analyzed. Materials and methods. Preoperative CAT scan data were transferred to STL data by Mimics®. The procedures after that were done by Magics®. First, neck osteotomy was done, externally rotated, and mild extension that doesn't make the axis come out of the skin was added. Then insertion path was verified keeping the stem attached medial sidewall of the canal (Fig. 2). In actual case, skin translation and pelvis rotation was assessed by 3D scanner. (Fig. 3). Results. Three D scanner revealed that the pelvis rotation is less than detective limit, and the upper skin incision where the stem passes remains almost the same place by dropping the leg. Lateral flare short stem could be inserted without lifting the femur out of the skin. So it was expected that lateral flare short stem has high applicability for DAA. Discussion. We can expect less invasive THA with DAA. However, once we have problem during surgery such as hard insertion or fracture and so forth, it is very hard to recover from those difficulties, because with supine position we cannot access posterior side of the leg. By easier insertion, less stress for bone and other tissues, we can reduce the risks. Even cases with easier femoral lift up, pulling femur less can reduce those risks

Aims

Professional dancers represent a unique patient population in the setting of hip arthroplasty, given the high degree of hip strength and mobility required by their profession. We sought to determine the clinical outcomes and ability to return to professional dance after total hip arthroplasty (THA) or hip resurfacing arthroplasty (HRA).

Introduction and Method: For 16 years, now, we have been using custom made femoral stems (titanium stem, HA coated) based on preoperative patient CT scans in young patients presenting with symptomatic osteoarthritis of the hip. The aim was to provide optimum initial fit-and-fill of the stem in the femoral medullary canal, conferring the best chance of secondary osteoin-tegration. This, with a goal of long term survivorship. The custom stem also enables dialling-in correction of the (often abnormal) femoral neck version (in young patients presenting with arthritis) to a more normalised 15 degrees of anteversion. Results: We present the long term results (5–16 year, mean of 10 years), clinical, survivorship and radiological, of 312 primary total hip arthroplasties in 280 patients, all of whom were under the age of 50 years of age (mean age 40). At 10 years we have a survivorship, if femoral aseptic loosening is used as an end point, of 97.6%. There was a deep infection rate of 1.2%, and a dislocation rate of 1.9%. There were no cases of thigh pain, and no intra-operative femoral neck/shaft fractures. Discussion: The under 50’s with hip arthritis requiring total hip arthroplasty are a highly challenging group, they are young, active and tend to have distorted anatomy. Our results are superior to those previously published using either cemented or standard uncemented stems. Thus, justifying the increased initial financial outlay on the custom-made stem

Introduction: Since 1992 over 3000 custom-made cemented titanium femoral components have been implanted during total hip replacement in our centre. Stems are machined using CAD-CAM. Measurements are made from screened AP and lateral x-rays of known magnification. Normal joint centre is recreated by controlling offset and vertical height of the femoral component. Method: Joint centre and limb length were analysed radiologically in consecutive 100 patients following total hip replacement for unilateral arthritis. Joint centre was defined relative to the pelvis and femur. The anatomical axis and offset of the femur were defined using a screened x-ray of known magnification taken to show maximum offset. Femoral centre height was defined relative to the greater trochanter. Results: In general, acetabular joint centre was placed medial and high, tending to reduce limb length slightly. Conversely, on the femoral side the tendency was to leave the component proud, producing an increase in limb length. Most patients had limb length restored to within 6mm of normal. This study confirms the effectiveness of the Belfast Custom Stem in restoring joint centre and limb length

Introduction. To obtain a better range of motion and to reduce the risk of dislocation, neck and cup anteversion are considered very important. Especially for the reduction of the risk of dislocation, the mutual alignment between neck and cup anteversion (combined anteversion) is often discussed. A surgeon would compare the neck direction to the calf direction with the knee in 90 degrees flexion. When an excessive anteversion was observed, the neck anteversion would be reduced using modular neck system or setting the stem a little twisted inside the canal with the tradeoff of the stem stability. Another choice would be the adjustment of cup alignment. Combined anteversion is defined the summation of cup anteversion in axial plane and stem anteversion in axial plane. But in realty the impingement occurs with 3 dimensional relationships between neck and cup with very complicated geometries. In that meaning, the definition of the angles could be said ambiguous too. The bowing of the femur also makes the relationships more complicated. Upon those backgrounds, we have been performing 3D preoperative planning for total hip arthroplasty on every case. In the present study, in vivo position of the stem in each case was determined then the anteversion observed on surgical view and anteversion around femoral mechanical axis are compared using 3D CAD software. Materials and Methods. Ten recent cases from our hip arthroplasty with 3D preoperative planning were reviewed for this purpose. The bone geometries were obtained from CAT scans with very low X-ray dose using Mimics® (Materialize, Belgium). Preoperative planning for Revelation stem® (DJO, USA) was performed using Mimics® (Materialize, Belgium). Femoral mechanical axis was defined as a line between center of femoral head and the middle point of medial and lateral epicondyle of the femur. Then mechanical anteversion is assessed from posterior condylar line. On the other hand, the calf was rotated 90 degrees around epiconlylar axis of each femur, and in vivo stem position was estimated then, stem axis was aligned perpendicular to the view. The anteversion in the surgical view was assessed from that view as the angle toward the calf. (Fig. 1) Using in vivo stem alignment, the impingement angle was also assessed. Results. Anteversion was in average 10 degree overestimated in the surgical view. Only one case was considered to have impingement risk and reduction of the anteversion was performed using custom stem. Discussion. In real surgical view, the anteversions are often observed to be more. In the present study instability of the knee was not considered. If the surgeon has performed inappropriate modification of the stem and cup anteversion, it can increase the risk of the dislocation and worse mechanical conditions. The in vivo prosthesis alignment should not be discussed with the angles from surgical view, but should be well planed 3 dimensionally preoperatively

A modular neck allows to choose the offset of the femoral head and the degree of anti-retroversion, lateralization and varus-valgus intraoperatively. At the G. Pini Institute we have been using modular necks in custom prostheses since 1989. Excellent results in this application did open the way to a larger use in off-the-shelf prostheses. Modular necks can be now coupled with different stems, leaving the surgeon free to use the preferred prosthetic stem design. Modular necks have been implanted in more than 50,000 in the world. Medium term results in custom prosthesis and the experience in off-the-shelf non-cemented stems are presented, together with further improvements of this technology under study. From 1989 to December 1999, 481 custom stems have been implanted. All patients but ten received modular necks. The prostheses were made of a titanium alloy and HA coated. 61 % of patients had dysplastic oxarthrosis. 372 implants performed between 1989 and 1996 were retrospectively evaluated. Data from off-the-shelf prosthesis, at a shorter follow-up, are also reported. Laboratory data showed that the use of an elliptical Morse cone of the neck reduced wear debris production to less than 1 mg/year. In custom implants, (mean follow-up: 7 years), we did not observe any thigh pain or radiological signs of osteolysis or fretting. Mean leg-length discrepancy was 2.8 cm pre-op and 0.3 cm post-operatively. Off-the-shelf implants also showed good clinical and radiological results. New design modular necks will increase the possible range of motion and provide more solutions for positioning the center of rotation. Modular neck is a safe and reliable solution to obtain the correct position of the center of rotation intra-operatively, without side effects. Applications in off-the-shelf prostheses allow to reduce costs while maintaining the advantages of this technology