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Original Article
10 (
2
); 69-72
doi:
10.4103/JOASP.JOASP_23_22

Effect of body mass index on the conventional method of templating in uncemented total hip arthroplasty: A prospective study

Department of Orthopaedics, Military Hospital, Jaipur, Rajasthan, India
Department of Orthopaedics, Armed Forces Medical College, Pune, Maharashtra, India

Address for correspondence: Dr. Kamparsh Thakur, Department of Orthopaedics, Golden Jubilee Block, Armed Forces Medical College, Wanowarie, Pune, Maharashtra, India. E-mail: drkamparsh@gmail.com

Licence
This is an open access journal, and articles are distributed under the terms of the Creative Commons Attribution-NonCommercial-ShareAlike 4.0 License, which allows others to remix, tweak, and build upon the work non-commercially, as long as appropriate credit is given and the new creations are licensed under the identical terms.
Disclaimer:
This article was originally published by Wolters Kluwer - Medknow and was migrated to Scientific Scholar after the change of Publisher.

How to cite this article: Sharma A, Thakur K, Prasad M, Vig V. Effect of body mass index on the conventional method of templating in uncemented total hip arthroplasty: A prospective study. J Orthop Spine 2022;10:69-72.

Abstract

BACKGROUND:

Preoperative templating is an important step in total hip arthroplasty (THA). Results of traditional as well as digital method of templating are well established in various studies. Very few studies have evaluated the effect of body mass index (BMI) and gender on templating. Our study was undertaken to evaluate the effect of BMI and gender in accurate size estimation in uncemented THA components by conventional method of templating.

MATERIALS AND METHODS:

Preoperative radiographs were templated for 60 patients who underwent primary uncemented THA. BMI and gender of patients were noted during preoperative evaluation. Patients were grouped as per gender and divided into three groups as per BMI (underweight <18.5, normal 18.5-24.9, overweight >25). The estimated preoperative template size was compared with the actual implant size used. P-value of <0.05 was considered to be significant.

RESULTS:

Acetabular component was exactly templated in 63.33% and femoral component in 76.6% cases. Gender and BMI had no statistical difference in component size prediction. Post-operative analysis of THA performed showed statistically significant association between high BMI and limb length discrepancy and restoration of femoral offset.

CONCLUSION:

In our study, we found that femoral component is more accurately predicted. No statistically significant effect of gender and BMI was seen in accuracy of conventional method of templating in implant size estimation. However, BMI is found to affect limb length assessment during surgery and restoration of femoral offset.

Keywords

BMI
gender
templating
total hip arthroplasty

Introduction

Total hip arthroplasty (THA) is one of the most satisfying and effective surgeries performed in orthopedics. Results of THA are very successful in patients with hip arthritis complaining of persistent pain and disability.[1] Preoperative templating encompasses anticipation of type of implants to be used, size and position, determining offset, calculation of limb length inequality and any potential intra-op problem, using preoperative radiographs to restore biomechanical forces around the hip.[2,3,4] Periprosthetic fractures as a result of overestimation of implant size as well as component loosening due to underestimation of implant size can be prevented by accurate implant size selection.[5] Obesity prevalence is increasing in our society due to modern lifestyle.[6] It has been proposed that the thickness of subcutaneous fat may obscure bony landmarks which deteriorate optimal implant positioning and prolong operative time. The effect of body mass index (BMI) on THA functional outcome, quality of life, and complication rate has been investigated in many clinical studies.[7] Studies have evaluated the effect of BMI in results and functional outcome of THA. However, few studies have assessed the effect of BMI in templating.[8] With increasing prevalence of obesity, the effect of BMI on preoperative templating is becoming important for consideration. Studies have shown gender-specific variation in various pelvic parameters.[9] The effect of gender in templating results are not known. The hypothesis of our study was that BMI and gender have no effect on templating in THA.

Material and Methods

Patients undergoing primary uncemented hip arthroplasty were included in the study. Patients who underwent cemented or hybrid THA or patients with fixed rotational deformity were excluded from the study.

Patient parameters including BMI were documented and recorded.

Well centered and exposed radiographs were taken pre-operatively.[10,11] As compared with normal anteroposterior (AP) view of pelvis, the AP view was taken with centering on the pubic symphysis. For templating purposes, a wider radiograph was taken with the proximal extent up to antero-superior iliac spine (ASIS) and distal extending to mid shaft of femur. To calculate the offset of the hip accurately on radiographs, the anteversion of hip was also considered. By internally rotating both lower limbs, femoral neck was brought parallel to the film, so that the full length of neck was seen, and offset was calculated properly. To determine the rotation on radiograph the lesser trochanter was assessed. In normal resting position of limb with 15°–20° external rotation, lesser trochanter is more prominent and usually measures more than 5 mm from femoral cortex. However, in 15°–20° of internal rotation, the value lies between 2–5 mm and will not be seen or less than 2 mm in case of excessive internal rotation. All the X-rays were obtained with 100 cm of distance from the tube to the X-ray plate. We controlled magnification by taking a standard object, metallic femoral head of 36 mm in between both thighs near pubis in plane of greater trochanter. Once X-rays were found to be of acceptable magnification and well centered, anatomical and mechanical landmarks were marked on X-ray, as described by Scherlink et al.[11] Templated size of acetabular and femoral component, limb length difference, and femoral offset were documented.

Procedure of acetabulum templating

Well positioned and centered anteroposterior pelvis and lateral X-rays of hip were taken. Landmarks marked on acetabular side were superolateral corner of acetabulum, illioischial line, and teardrop. Inter-teardrop line was drawn first. The inclination of acetabular component was decided by drawing a line 45° to inter-teardrop line at the teardrop. The acetabular component was chosen so that its distal and medial-most parts lie just lateral to teardrop with inferior margin at obturator foramen. The acetabulum component was chosen, not crossing the illioischial line with adequate preservation of subchondral bone. While assessing lateral coverage, large osteophytes were not considered and the component with adequate lateral coverage was chosen. The component that fulfilled all the above criteria and causing minimum loss of subchondral bone was chosen and its center was marked on the X-ray. The templated acetabulum component was recorded.

Procedure of femoral templating

After acetabular templating, the center of acetabulum component was marked and used as the new center of rotation of hip. The axis of femoral shaft was drawn on AP and lateral X-ray. The femoral component was chosen which perfectly fit the proximal femur, axis aligned with femoral shaft axis, and consideration was given for minimal loss of medullary canal. The center of femoral stem was marked and adjusted for limb length in relation to acetabular center of rotation.

All patients were operated using posterolateral approach. The intraoperatively-used component was recorded. Postoperative radiographs were analyzed for restoration of horizontal offset, acetabular component inclination, and limb length discrepancy.

Statistical analysis

Descriptive statistics (frequency and percentages) were calculated for sample demographic characteristics of the study participants. Chi-square analysis was done to find out the association of BMI with various preoperative predictions and surgical outcomes among study participants. A value of P < 0.05 was taken as statistically significant.

Results

There were 60 participants in this study with mean age of 55.95 (±9.82) years. The sample comprised of 36 male and 24 female patients. The cases were further divided into three groups based on their BMI as underweight, normal, and overweight. Other demographic features of the study participants are shown in Table 1.

Table 1: Demographic parameters of study participants
Study population
Total (N = 60)
n (%)
Age group (years)
   30-45 9 (15.0)
   45-60 32 (53.3)
   60-75 19 (31.7)
Gender
   Male 36 (60.0)
   Female 24 (40.0)
BMI classification
   Underweight 2 (3.3)
   Normal 42 (70.0)
   Overweight 16 (26.7)

BMI = body mass index

The association of BMI [Table 2] and gender [Table 3] with various preoperative predictions and surgical outcomes were explored but no significant association was found.

Table 2: Association of BMI with various preoperative predictions among study participants
Characteristics BMI
P-Value
Underweight Normal Overweight
Accurate acetabular prediction
   Yes 1 29 8 0.374
   No 1 13 8
Accurate femoral prediction
   Yes 1 23 12 0.356
   No 1 19 4

BMI = body mass index

Table 3: Association of gender with various preoperative predictions among study participants
Templating Accurate Not accurate P-Value
Acetabular component
   Male 24 12 0.43
   Female 14 10
Femoral component
   Male 22 14 0.285
   Female 13 11

Postoperative association of BMI and restoration of offset, limb length discrepancy were also explored [Table 4] and significant association between high BMI and poor restoration of horizontal offset and limb length was found.

Table 4: Association of BMI with postoperative limb length discrepancy and horizontal offset variation among BMI groups in study participants
Characteristics BMI
P-Value
Underweight and normal Overweight
Limb length difference
   Up to 9 mm 43 11 0.009
   Outliers 1 5
Horizontal restoration of offset
   Exactly 43 10 0.001
   Outliers 1 6

BMI = body mass index

Postoperative radiographs were evaluated to assess inclination and anteversion of acetabulum template in 45º ± 10º and 15º ± 10º. All patients were found to have acetabular inclination in safe range with average of 43.33º ± 0.429º and anteversion of 18º.

Discussion

The goal of a successful THA is to achieve a painless and functional hip replacement. Accurate templating in various studies has shown increased precision during surgery, decreased operative time, reduced revision rates, and reduced overall complication rate.[2,12] Presently, with the advent of new software and 3D templating, more accurate prediction of component and potential intraoperative problems can be anticipated. However, one of the limiting factors in the use of advance templating methods is the affordability of expensive software. Hence, the traditional method of templating still finds its place in the setting where affordability of these software is an issue due to financial constraints.

In our study, we found more accurate prediction of femoral component as compared with acetabular components. We successfully templated 76.6% femoral components, whereas our accuracy of prediction for acetabular component was 63.3%. Results from our study are comparable with results obtained by other authors. The study conducted by Eggli et al.[3] of 100 THA performed reported predicting more than 90% of the components size accurately. In the study conducted by Untana et al.[2] in 2009, exact size was estimated in 42.2% of acetabular components and 68.8% of femoral components on templating preoperative radiographs in patients undergoing uncemented THA. Eggli et al.[3] suggested that decrease in accuracy in prediction was due to the peculiar feature of acetabular component. He attributed this decrease in prediction mainly to the variation in the intraoperative component used. The intraoperative component varied as it was difficult to control the pelvic fixation during surgery and with change in position the acetabulum component varied.

A few studies have postulated the effects of BMI on preoperative templating. The study conducted by Holzer et al.[12] showed poor size estimation in patients with higher BMI as compared with patients with normal BMI. The decrease in prediction of femoral component in patients with high BMI is due to improper positioning of radio-opaque reference objects while performing X-rays and consequently resulting in magnification errors.[12] However, results published by Sershon et al. found no significant effect of BMI on results of THA templating. In our study, there were 2 underweight, 42 normal weight, and 16 overweight patients. In our study, we were unable to find any statistically significant effect of BMI on prediction of hip arthroplasty components.

While assessing the effect of gender in templating, Sershon et al.[8] and Holzer et al.[12] found no gender-specific differences in prediction of size. Similarly, we had comparable results when gender was in consideration.

Restoration of femoral offset, placement of acetabulum in safe zone, and limb length discrepancy in acceptable limits are goals of successful arthroplasty. Horizontal offset is measured by distance from center of head to femoral axis. Al-Amiry, et al.[13] in their study showed significant impact of BMI on offset restoration. They ascribed the mechanical difficulty in restoring the offset to the increased adipose tissue and lack of a reliable method of intraoperative assessment of offset restoration. Our study also showed more higher offset variation in the high BMI group of patients. Our offset variation was 37.5% in the overweight group which was found to be statistically significant.

Limb length discrepancy is one of the common complications after THA. Currently, most studies accept less than 10 mm of variation. Intraoperative measurement of limb length in lateral position is done by palpating bony landmarks—patella and heel level and assessing soft tissue tension. Palpation of these landmarks is obscured by drapes and more so difficult in the presence of increased adipose tissue. Our study had 10% of patients who had variation in limb length vis-a-vis 15% in the study by Al-Amiry, et al.[13] Most of our limb length difference was found in the high BMI group, similar to the study by Al-Amiry, et al.[13] Statistically analyzing variation of limb length in all BMI groups showed P-value of 0.01 which is significant.

It has been recommended to place acetabular component in safe zone by Lewinnek.[14] In their study, to reduce the risk of postoperative dislocation, it was recommended to place a cup in 45º ± 10º of inclination and 15º ± 10º of anteversion. In our study, we were able to place all our cups in an acceptable range of inclination. Average inclination and anteversion obtained in our study were 43.33º and 18º respectively. Three of our components had excessive anteversion with no component in retroverted position.

Limitation of our study is in terms of small sample size. However, decrease in incidence of hip disease in the Indian population as compared with the western world explained this low number of hip arthroplasty performed. Presently, more sophisticated methods of templating are available; however, their high cost prevents their use.

Conclusion

We rejected our null hypothesis as there was no statistically significant effect of BMI and gender on component size prediction on conventional radiographs in patients undergoing THA. However, the conventional method of templating resulted in an accurate prediction of 63.3% acetabulum and 76.6% of femoral component in our study. Our study showed significant association between high BMI and limb length discrepancy and poor restoration of femoral offset. Thus, conventional method of templating still is an effective method of estimating the component size.

Financial support and sponsorship

Not applicable.

Conflicts of interest

There are no conflicts of interest.

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