Influence of total hip arthroplasty on sagittal lumbar-pelvic balance: Evaluation of radiographic parameters

Miranda, Saulo Fouani de; Corotti, Vitor Gustavo de Paiva; Menegaz, Phelipe; Ueda, Welington; Vialle, Emiliano Neves; Vialle, Luiz Roberto

doi:10.1016/j.rbo.2018.04.005

Abstract

Objective

To prospectively analyze the radiographic variables of lumbosacral sagittal balance in the pre- and postoperative period of patients submitted to total hip arthroplasty (THA).

Methods

A prospective, observational, comparative study that evaluated pre- and postoperative radiographic parameters of 71 patients, submitted to 72 total hip arthroplasties in a 3-year period (2014-2017) for primary coxarthrosis, of whom 28 performed late postoperative control (6 months) through the Surgimap Spine software (Surgimap, New York, NY, USA). Statistical analysis was performed using the Student t-test, the analysis of covariance (ANCOVA) model, and the Kolmogorov-Smirnov test. The data were analyzed using the IBM SPSS Statistics for Windows, Version 20.0 (IBM Corp., Armonk, NY, USA). A p-value < 0.05 indicated statistical significance.

Results

A total of 72 cases, presenting a mean age of 57.9 years old, predominantly females (60.6%) and patients > 50 years old (71.8%). There was an overall decrease in lumbar lordosis values in the immediate postoperative period, without major global changes in late evolution. It was found that patients with a pelvic incidence ≥ 60° tended to have their other sagittal balance parameters elevated.

Conclusion

There was no significant difference between the radiographic variables of sagittal lumbopelvic balance in the evaluated periods. Lumbar lordosis and pelvic incidence were the main modifying factors. Improvement of low back pain after THA, without changes in parameters, suggests different pathology mechanisms still to be clarified.

Keywords
hip arthroplasty; spine; low back pain

Resumo

Objetivo

Analisar prospectivamente as variáveis radiográficas do equilíbrio sagital da coluna lombossacral no pré e pós-operatório dos pacientes submetidos a artroplastia total de quadril (ATQ).

Métodos

Estudo prospectivo, observacional e comparativo que avaliou parâmetros radiográficos pré e pós-operatórios imediatos de 71 pacientes submetidos a 72 ATQs em três anos (2014-2017) por coxartrose primária, dos quais 28 fizeram controle pós-operatório tardio (6 meses), através do programa Surgimap Spine (Surgimap, Nova York, NY, EUA). A análise estatística foi feita com o teste t de Student, o modelo de análise de covariância (ANCOVA, na sigla em inglês) e o teste de Kolmogorov-Smirnov. Os dados foram analisados com o programa IBM SPSS Statistics for Windows, Versão 20.0 (IBM Corp., Armonk, NY, EUA). Valores de p < 0,05 indicaram significância estatística.

Resultados

Os 72 casos avaliados apresentaram uma idade média de 57,9 anos, com predominância do sexo feminino (60,6%) e de pacientes > 50 anos (71,8%). Houve uma diminuição global nos valores da lordose lombar no pós-operatório imediato, sem grandes alterações globais na evolução tardia. Aferiu-se que pacientes com uma incidência pélvica ≥ 60° tendem a ter os demais parâmetros do equilíbrio sagital elevados.

Conclusão

Não houve diferença significativa entre as variáveis radiográficas do equilíbrio sagital lombopélvico nos períodos avaliados. A lordose lombar e a incidência pélvica foram os principais fatores modificantes. A melhoria da lombalgia pós-ATQ sem alterações desses parâmetros sugere diferentes mecanismos da patologia ainda a serem esclarecidos.

Palavras-chave
artroplastia de quadril; coluna vertebral; dor lombar

Introduction

As life expectancy increases in our population, more and more patients are experiencing degenerative changes that require surgery. The spine and hip are important disability sources in the elderly, and their symptoms often overlap. The clinical definition of which change is most relevant and should be treated first is difficult.

Sagittal balance (SB) is a mechanical system consisting of osteoarticular and neuromyofascial elements of the spine-pelvis structure of the lower limbs; it depends on the gravity center axis variation with the dual hip-femoral axis. This allows a direct correlation of the postural balance as a predictive and prognostic factor of some spinal disorders, particularly lumbar degenerative diseases.¹1 Jackson RP, McManus AC. Radiographic analysis of sagittal plane alignment and balance in standing volunteers and patients with low back pain matched for age, sex, and size. A prospective controlled clinical study. Spine 1994;19(14):1611-1618

The concept that the pelvis is part of the spine has been well-established since Duval-Beauperre defined the pelvic vertebra to highlight the impact of pelvic position over spine posture and alignment.²2 Duval-Beaupère G, Robain G. Visualization on full spine radiographs of the anatomical connections of the centres of the segmental body mass supported by each vertebra and measured in vivo. Int Orthop 1987;11(03):261-269

It is very challenging to assess normal pelvic-spine axis values because there is a large group of asymptomatic individuals even at the range extremes for each SB variable. Several radiographic angles and measurements help us understand this relationship. Among them, the most common include lumbar lordosis (LL), pelvic tilt (PT), pelvic incidence (PI) and sacral slope (SS). Their lines and reference values according to Morvan et al³3 Morvan G, Wybier M, Mathieu P, Vuillemin V, Guerini H. [Plain radiographs of the spine: static and relationships between spine and pelvis]. J Radiol 2008;89(5 Pt 2):654-663, quiz 664-666 are shown in Table 1, and their schematic drawings are shown in Figure 1.

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Table 1
Angles and normal values for sagittal balance variables

Fig. 1
Schematic drawing of the angular variables of sagittal balance (SS, sacral slope; PT, pelvic tilt).

During the last 3 decades, spinal surgery specialists have increasingly studied the importance of SB, correlating it to sagittal imbalance and spinal degenerative consequences.

In total hip arthroplasty (THA), the relationship between the pelvis and the spine is necessarily modified; however, little is known about its influence on the posture of the patients. Theoretically, the anterior dislocation of the vertical axis of the spine results in greater energy expenditure and lumbar spine symptoms.

The present study aims to prospectively compare pelvic lumbar SB radiographic parameters, including the relationship between the spine and the pelvis, in the preoperative, immediate postoperative and late postoperative period of THA, considering the age and gender of the patients, and to determine the impact of the procedure in altering these variables.

Methodology

The present study was approved by the Ethics Committee through the Plataforma Brasil website.

This is a prospective, observational, comparative study in which patients undergoing elective THA surgery for primary coxarthrosis were evaluated according to pelvic lumbar radiographic parameters before and after the procedure.

Radiographs were prospectively taken at 3 defined moments to evaluate SB measurements: at the preoperative period (1 day before surgery), immediate postoperative period (2 to 4 months after surgery), and late postoperative period (4 to 6 months after surgery).

Only patients with surgical indication for primary coxarthrosis were included in the study, thus excluding all patients who received partial prosthesis, with proximal femoral fractures or whose radiographs were deemed inadequate.

From April 2014 to March 2017, 120 THAs for coxarthrosis were performed. A total of 20 patients with no adequate preoperative radiographies were excluded; in addition, 21 patients were excluded due to radiographic technique nonconformation, and 8 were lost to follow-up. Therefore, 71 patients, or 72 surgeries (since 1 patient required a bilateral arthroplasty), complying with all image quality and radiographic conformation requirements, were included. From these patients, 28 had appropriate late postoperative radiographs and were included in the evaluation.

Preoperative and immediate postoperative radiographs were taken during hospitalization, while late postoperative radiographs were taken during returns to the outpatient facility. All of the radiographic examinations were performed according to the following protocol: lateral lumbosacral image in orthostatic position and including the proximal aspect of the femur (Fig. 2).

Fig. 2
Example of measurements: Lateral orthostatic lumbosacral X-ray at the preoperative, immediate postoperative and postoperative period.

The ES evaluation was performed using LL, SS, PT and PI measurements. These measurements were analyzed by the same spinal surgery resident using the Surgimap Spine application (Surgimap, New York, NY, USA) (Fig. 3), a free software that makes radiographic measurements more accurately compared with printed radiography and that integrates measurements with tools for spine assessment and surgical planning.⁴4 Dimar JR II, Carreon LY, Labelle H, et al. Intra- and inter-observer reliability of determining radiographic sagittal parameters of the spine and pelvis using a manual and a computer-assisted methods. Eur Spine J 2008;17(10):1373-1379^,⁵5 Akbar M, Terran J, Ames CP, Lafage V, Schwab F. Use of Surgimap Spine in sagittal plane analysis, osteotomy planning, and correction calculation. Neurosurg Clin N Am 2013;24(02):163-172

Fig. 3
Example of measurements using Surgimap software: Lateral orthostatic lumbosacral X-ray including femoral heads.

Quantitative variables results were described by mean, median, minimum and maximum values and standard deviation (SD) of the mean. Qualitative variables were described as frequencies and percentages. The comparison between two evaluations was made considering the Student's t-test for paired samples. The normality condition of the variables was assessed by the Kolmogorov-Smirnov test. P values < 0.05 indicated statistical significance. Data were analyzed using IBM SPSS Statistics for Windows, Version 20.0 (IBM Corp., Armonk, NY, USA).

Results

A total of 71 patients were included, totaling 72 THAs (with 1 bilateral case), of which 28 had late postoperative control data. The average age of the population was 57.9 years old (ranging from 27 to 85 years old), with a higher prevalence of patients > 50 years old (71.8%). There was a higher prevalence of female (60.6%) compared with male patients (39.4%). In addition, the right side was the most commonly instrumented (55%).

The LL evaluation revealed a general decrease in values according to the gender and age of the patients at the immediate postoperative period; in the long term, these values remained similar to the ones obtained before the procedure (Table 2).

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Table 2
Lumbar lordosis range at the preoperative, postoperative and late postoperative period classified per grade

Comparing measures obtained at the preoperative and immediate postoperative periods, none of the analyzed variables showed a statistically significant difference. Regarding SS, there was an average difference of 0.4°, which represents a small increase in SS after THA. The PT values decreased, on average, 1.4°, whereas PI showed a decrease of 1.1° (Table 3).

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Table 3
Comparison of values obtained at the pre- and postoperative periods, their difference and statistical analysis

The analysis of results obtained at the preoperative and late postoperative evaluations considered 28 cases with complete data. The mean values of the analyzed variables showed no significant difference. However, PT and PI approached a p-value < 0.05. There was an average increase of 0.7° in SS. The PT and PI values decreased, on average, 2.5° and 2.6°, respectively (Table 4).

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Table 4
Comparison of values obtained at the pre- and late postoperative periods, their difference and statistical analysis

At the evaluation of differences between late and immediate postoperative measurements, there was a smaller reduction in all parameters.

The ES evaluation patients < 50 years old did not reveal changes in the immediate or late postoperative values compared with the preoperative data. In the group > 50 years old, there were no statistically significant differences.

None of the measured variables showed statistically significant differences between genders at any time period.

There was statistical significance in the evaluation of some parameters when the population was divided according to PI ≥ 60° and < 60°. The LL, SS, and PT presented significantly higher values in patients with PI ≥ 60°. Moreover, in the comparison between the late postoperative and preoperative periods, the PT decrease was greater in patients with PI values < 60° (- 3.3 versus - 1; p < 0.05). At the same comparison, SS increased 2.3° in patients with PI ≥ 60°; however, in the group with PI < 60°, the SS remained practically unchanged (0.1°; p < 0.05) (Table 5).

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Table 5
Comparison of values obtained at the evaluated periods according to the pelvic incidence (PI) range (≥ 60∘ and < 60º), their difference and statistical evaluation

Dividing the sample into patients with LL ≥ 40° and LL < 40°, it was noted that the first group had higher preoperative mean values, both in SS (44.1° versus 26.9°, respectively; p < 0.001) and PI (57° versus 46.1°, respectively; p < 0.05). The remaining variables were not statistically significant.

Discussion

Since Hippocrates described the spinal elements and curves, 2 thousand years ago, experts have been trying to elucidate the complex details shaping the SB and its influences on clinical presentations.⁶6 Le Huec JC, Roussouly P. Sagittal spino-pelvic balance is a crucial analysis for normal and degenerative spine. Eur Spine J 2011;20 (Suppl 5):556-557

The mechanic behavior of the spine and pelvis is complex and synergistic with bony parts, intervertebral discs, muscles and tendons.⁷7 Eyvazov K, Eyvazov B, Basar S, Nasto LA, Kanatli U. Effects of total hip arthroplasty on spinal sagittal alignment and static balance: a prospective study on 28 patients. Eur Spine J 2016;25(11):3615-3621 This set works cohesively and presents defensive features against disc degenerative or facet injuries, even in people with extreme sagittal measurements who tend to develop degenerative injuries. In general, if there is no good elastic and global functionality, the spine morphotypes will determine the mechanical and degenerative behavior of the spine.¹1 Jackson RP, McManus AC. Radiographic analysis of sagittal plane alignment and balance in standing volunteers and patients with low back pain matched for age, sex, and size. A prospective controlled clinical study. Spine 1994;19(14):1611-1618

A series of radiographic parameters has been proposed to describe an imbalance in sagittal alignment of the pelvic spine; a change in these values would lead to the development of compensatory mechanisms⁸8 Lazennec JY, Brusson A, Rousseau MA. Hip-spine relations and sagittal balance clinical consequences. Eur Spine J 2011;20 (Suppl 5):686-698, resulting in pain and decreased quality of life⁹9 Buckland AJ, Vigdorchik J, Schwab FJ, et al. Acetabular anteversion changes due to spinal deformity correction: bridging the gap between hip and spine surgeons. J Bone Joint Surg Am 2015;97 (23):1913-1920.

The association between low back pain and osteoarthritis was described by Offierski et al 4 decades ago as hip-spine syndrome;¹⁰10 Offierski CM, MacNab I. Hip-spine syndrome. Spine 1983;8(03): 316-321 despite several studies performed since then, data are still scarce to understand the exact pathophysiological mechanisms of this condition. It is now believed that hip osteoarthritis may significantly decrease the ability of the hip to maintain postural balance; the decreased mobility and increased joint forces may increase energy expenditure, leading to muscle fatigue. This would result in a fixed hip flexion position, leading to pelvic anteversion, compensatory lumbar hyperlordosis and, consequently, to low back pain due to overload or dislocation of the posterior facets.⁷7 Eyvazov K, Eyvazov B, Basar S, Nasto LA, Kanatli U. Effects of total hip arthroplasty on spinal sagittal alignment and static balance: a prospective study on 28 patients. Eur Spine J 2016;25(11):3615-3621^,¹¹11 Bisson EJ,McEwen D, Lajoie Y, BilodeauM. Effects of ankle and hip muscle fatigue on postural sway and attentional demands during unipedal stance. Gait Posture 2011;33(01):83-87

Duval-Beaupère et al¹²12 Duval-Beaupère G, Schmidt C, Cosson P. A Barycentremetric study of the sagittal shape of spine and pelvis: the conditions required for an economic standing position. Ann Biomed Eng 1992;20(04): 451-462 described the relationship between pelvic anatomy and lumbar lordosis, an important correlation between the PI angle and LL; this latter parameter is strongly related to the shape of the pelvis. In our study, considering LL values from the three evaluated periods, a variation with no statistical significance was noted when the lumbar curve was classified as hyperlordotic, hypolordotic or normolordotic. The group presenting values considered normal ranged from 31.9 to 35.7%, while the group with increased curves presented a 1% reduction (Table 2).

Previous studies have shown that characteristic changes in sagittal balance occur with advancing age, resulting in symptoms of low back pain and spinal degeneration.¹⁰10 Offierski CM, MacNab I. Hip-spine syndrome. Spine 1983;8(03): 316-321^,¹³13 Gelb DE, Lenke LG, Bridwell KH, Blanke K, McEnery KW. An analysis of sagittal spinal alignment in 100 asymptomatic middle and older aged volunteers. Spine 1995;20(12):1351-1358 Vendantam et al¹⁴14 Vedantam R, Lenke LG, Keeney JA, Bridwell KH. Comparison of standing sagittal spinal alignment in asymptomatic adolescents and adults. Spine 1998;23(02):211-215 demonstrated that aging leads to a shift from sagittal to anterior alignment on the sacral axis. We attempted to evaluate the influence of variables such as gender and age on the alteration of sagittal balance parameters, but our study showed no correlation with such data. A study published by Kulcheski et al,¹⁵15 Kulcheski AL, Soler I, Graells X, Benato ML, Baretta G. Avaliação angular do equilíbrio sagital em pacientes obesos. Coluna/Columna 2013;12(03):224-227 concluded that obese patients usually present sagittal parameters alterations resulting from compensatory mechanisms related to overweight.

The pelvic view was described by Legaye et al¹⁶16 Legaye J, Duval-Beaupère G, Hecquet J, Marty C. Pelvic incidence: a fundamental pelvic parameter for three-dimensional regulation of spinal sagittal curves. Eur Spine J 1998;7(02):99-103 as a morphological pattern varying according to the hip axis and sacral obliquity related to the ilium. It has an important correlation with the spinal-pelvic slope, SS and LL. Lower PI values are related to a decrease in LL and SS. The main statistically significant results consider the fact that patients with high, > 60°, preoperative IP values also presented higher values in the remaining variables (Table 5). Vaz et al¹⁷17 Vaz G, Roussouly P, Berthonnaud E, Dimnet J. Sagittalmorphology and equilibrium of pelvis and spine. Eur Spine J 2002;11(01): 80-87 emphasized that patients with low-grade PI would be less adaptable to changes in sagittal balance variables; on the other hand, in subjects with high-grade IP, SS would not cause this limitation, representing a better power of variation from other angles.

Previous studies showed that the most common PI in the asymptomatic population and, therefore, more mechanically adjusted, is, on average, 50°.¹⁸18 Barrey C, Jund J, Noseda O, Roussouly P. Sagittal balance of the pelvis-spine complex and lumbar degenerative diseases. A comparative study about 85 cases. Eur Spine J 2007;16(09):1459-1467 These patients present a lower amount of degenerative conditions due to the lower concentration of pressure points on spinal structures (better load distribution).¹⁹19 Labelle H, Roussouly P, Berthonnaud E, et al. Spondylolisthesis, pelvic incidence, and spinopelvic balance: a correlation study. Spine 2004;29(18):2049-2054 Low PI leads to disc conditions because the tendency to approach the gravity line near the lumbosacral junction generates a lesser dispersion of pressure on the intervertebral disc, increasing forces in the pulpous nucleus. In the high-PI morphotype (hyperlordotic patients), there is an overload on the posterior elements of the lumbar spine, increasing the possibility of lesions on facets and interarticular pars. However, not all patients with extreme PI values develop spinal conditions, just as not all patients with spinal conditions have extreme PI values.¹⁹19 Labelle H, Roussouly P, Berthonnaud E, et al. Spondylolisthesis, pelvic incidence, and spinopelvic balance: a correlation study. Spine 2004;29(18):2049-2054

In general, when evaluating the analyzed variables, there were no significant changes between time periods, as previously described in the literature by Ben-Galim et al²⁰20 Ben-GalimP, Ben-GalimT, Rand N, et al. Hip-spine syndrome: the effect of total hip replacement surgery on low back pain in severe osteoarthritis of the hip. Spine 2007;32(19):2099-2102 in a prospective study with 25 patients, which was ratified by Radcliff et al²¹21 Radcliff KE, Orozco F, Molby N, et al. Change in spinal alignment after total hip arthroplasty. Orthop Surg 2013;5(04):261-265 in 2013.

Weng et al,²²22 Weng WJ,WangWJ,WuMD, Xu ZH, Xu LL, Qiu Y. Characteristics of sagittal spine-pelvis-leg alignment in patients with severe hip osteoarthritis. Eur Spine J 2015;24(06):1228-1236 when comparing patients with or without coxarthrosis, found that the first group presented greater pelvic anteversion, greater hip joint flexion, and an anterior inclination of the spine. Eyvazov et al⁷7 Eyvazov K, Eyvazov B, Basar S, Nasto LA, Kanatli U. Effects of total hip arthroplasty on spinal sagittal alignment and static balance: a prospective study on 28 patients. Eur Spine J 2016;25(11):3615-3621 and Ben-Galim et al²⁰20 Ben-GalimP, Ben-GalimT, Rand N, et al. Hip-spine syndrome: the effect of total hip replacement surgery on low back pain in severe osteoarthritis of the hip. Spine 2007;32(19):2099-2102 showed that functional alterations of the hip, such as coxarthrosis, generate sagittal alignment abnormalities, and that joint function correction in hips with advanced arthrosis by means of arthroplasty produces a significant reduction in the visual scale and Owestry score for low back pain. Total hip arthroplasty is increasingly seen as an improvement factor in low back pain, spinal biomechanical function and hip complaints.²³23 Buckwalter JA, Saltzman C, Brown T. The impact of osteoarthritis: implications for research. Clin Orthop Relat Res 2004(427, Suppl) S6-S15^,²⁴24 Morrey BF, Adams RA, KesslerM. A conservative femoral replacement for total hip arthroplasty. A prospective study. J Bone Joint Surg Br 2000;82(07):952-958

Theoretically, THA would allow radiographic values compensation due to hip extension recovery, but this has not been demonstrated in the literature. In fact, the PT and the other variables changed slightly after arthroplasty, as previously described.²⁵25 Murphy WS, Klingenstein G, Murphy SB, Zheng G. Pelvic tilt is minimally changed by total hip arthroplasty. Clin Orthop Relat Res 2013;471(02):417-421^,²⁶26 Blondel B, Parratte S, Tropiano P, Pauly V, Aubaniac JM, Argenson JN. Pelvic tilt measurement before and after total hip arthroplasty. Orthop Traumatol Surg Res 2009;95(08):568-572

The limitation of the number of patients analyzed, the postoperative follow-up period, and the radiographic technical difficulty in uniformly measuring variables may have influenced the results of this study.

Although there is still controversy on which condition should be treated first, a follow-up with hip and spine specialists is indicated. More recent results have suggested that coxarthrosis should be treated earlier, as it has shown a greater influence on the postoperative improvement of low back pain.²⁰20 Ben-GalimP, Ben-GalimT, Rand N, et al. Hip-spine syndrome: the effect of total hip replacement surgery on low back pain in severe osteoarthritis of the hip. Spine 2007;32(19):2099-2102

The individualization of patients who are THA candidates is increasingly required, especially in those with low back pain. Sagittal balance assessment can prevent technical errors such as excessive anteversion of the acetabular component, posterior impingement, early component wear, and even major postoperative complications, such as instability and dislocations.²⁷27 Miki H, Kyo T, Kuroda Y, Nakahara I, Sugano N. Risk of edgeloading and prosthesis impingement due to posterior pelvic tilting after total hip arthroplasty. Clin Biomech (Bristol, Avon) 2014;29(06):607-613^,²⁸28 ShonWY, Sharma V, Keon OJ, Moon JG, Suh DH. Can pelvic tilting be ignored in total hip arthroplasty? Int J Surg Case Rep 2014;5 (09):633-636

Conclusion

The study of SB has been an important orthopedic tool to elucidate the mechanics, pathophysiology and their relationships with spinal disorders. Their responses are directly responsible for better diagnosis, management, planning, therapeutic decision and outcomes.

The present work adds data to the literature, validating other studies already reported. The change in global SB variables was not significant postoperatively, which reinforces previous studies with the theory that there are more complex mechanisms not yet described that would be responsible for the clinical and symptomatic improvement of patients undergoing THA. However, the evaluation of sagittal balance in candidates to this procedure is important, and it should be performed during the surgical planning period. Further studies will elucidate the pathophysiology of a condition which is increasingly common in the current population, with great socioeconomic impact.

*
Work performed at the Orthopedics and Traumatology Service of the Hospital Universitário Cajuru (PUC-PR), Curitiba, PR, Brazil. Originally Published by Elsevier Editora Ltda.

References

¹
Jackson RP, McManus AC. Radiographic analysis of sagittal plane alignment and balance in standing volunteers and patients with low back pain matched for age, sex, and size. A prospective controlled clinical study. Spine 1994;19(14):1611-1618
²
Duval-Beaupère G, Robain G. Visualization on full spine radiographs of the anatomical connections of the centres of the segmental body mass supported by each vertebra and measured in vivo. Int Orthop 1987;11(03):261-269
³
Morvan G, Wybier M, Mathieu P, Vuillemin V, Guerini H. [Plain radiographs of the spine: static and relationships between spine and pelvis]. J Radiol 2008;89(5 Pt 2):654-663, quiz 664-666
⁴
Dimar JR II, Carreon LY, Labelle H, et al. Intra- and inter-observer reliability of determining radiographic sagittal parameters of the spine and pelvis using a manual and a computer-assisted methods. Eur Spine J 2008;17(10):1373-1379
⁵
Akbar M, Terran J, Ames CP, Lafage V, Schwab F. Use of Surgimap Spine in sagittal plane analysis, osteotomy planning, and correction calculation. Neurosurg Clin N Am 2013;24(02):163-172
⁶
Le Huec JC, Roussouly P. Sagittal spino-pelvic balance is a crucial analysis for normal and degenerative spine. Eur Spine J 2011;20 (Suppl 5):556-557
⁷
Eyvazov K, Eyvazov B, Basar S, Nasto LA, Kanatli U. Effects of total hip arthroplasty on spinal sagittal alignment and static balance: a prospective study on 28 patients. Eur Spine J 2016;25(11):3615-3621
⁸
Lazennec JY, Brusson A, Rousseau MA. Hip-spine relations and sagittal balance clinical consequences. Eur Spine J 2011;20 (Suppl 5):686-698
⁹
Buckland AJ, Vigdorchik J, Schwab FJ, et al. Acetabular anteversion changes due to spinal deformity correction: bridging the gap between hip and spine surgeons. J Bone Joint Surg Am 2015;97 (23):1913-1920
¹⁰
Offierski CM, MacNab I. Hip-spine syndrome. Spine 1983;8(03): 316-321
¹¹
Bisson EJ,McEwen D, Lajoie Y, BilodeauM. Effects of ankle and hip muscle fatigue on postural sway and attentional demands during unipedal stance. Gait Posture 2011;33(01):83-87
¹²
Duval-Beaupère G, Schmidt C, Cosson P. A Barycentremetric study of the sagittal shape of spine and pelvis: the conditions required for an economic standing position. Ann Biomed Eng 1992;20(04): 451-462
¹³
Gelb DE, Lenke LG, Bridwell KH, Blanke K, McEnery KW. An analysis of sagittal spinal alignment in 100 asymptomatic middle and older aged volunteers. Spine 1995;20(12):1351-1358
¹⁴
Vedantam R, Lenke LG, Keeney JA, Bridwell KH. Comparison of standing sagittal spinal alignment in asymptomatic adolescents and adults. Spine 1998;23(02):211-215
¹⁵
Kulcheski AL, Soler I, Graells X, Benato ML, Baretta G. Avaliação angular do equilíbrio sagital em pacientes obesos. Coluna/Columna 2013;12(03):224-227
¹⁶
Legaye J, Duval-Beaupère G, Hecquet J, Marty C. Pelvic incidence: a fundamental pelvic parameter for three-dimensional regulation of spinal sagittal curves. Eur Spine J 1998;7(02):99-103
¹⁷
Vaz G, Roussouly P, Berthonnaud E, Dimnet J. Sagittalmorphology and equilibrium of pelvis and spine. Eur Spine J 2002;11(01): 80-87
¹⁸
Barrey C, Jund J, Noseda O, Roussouly P. Sagittal balance of the pelvis-spine complex and lumbar degenerative diseases. A comparative study about 85 cases. Eur Spine J 2007;16(09):1459-1467
¹⁹
Labelle H, Roussouly P, Berthonnaud E, et al. Spondylolisthesis, pelvic incidence, and spinopelvic balance: a correlation study. Spine 2004;29(18):2049-2054
²⁰
Ben-GalimP, Ben-GalimT, Rand N, et al. Hip-spine syndrome: the effect of total hip replacement surgery on low back pain in severe osteoarthritis of the hip. Spine 2007;32(19):2099-2102
²¹
Radcliff KE, Orozco F, Molby N, et al. Change in spinal alignment after total hip arthroplasty. Orthop Surg 2013;5(04):261-265
²²
Weng WJ,WangWJ,WuMD, Xu ZH, Xu LL, Qiu Y. Characteristics of sagittal spine-pelvis-leg alignment in patients with severe hip osteoarthritis. Eur Spine J 2015;24(06):1228-1236
²³
Buckwalter JA, Saltzman C, Brown T. The impact of osteoarthritis: implications for research. Clin Orthop Relat Res 2004(427, Suppl) S6-S15
²⁴
Morrey BF, Adams RA, KesslerM. A conservative femoral replacement for total hip arthroplasty. A prospective study. J Bone Joint Surg Br 2000;82(07):952-958
²⁵
Murphy WS, Klingenstein G, Murphy SB, Zheng G. Pelvic tilt is minimally changed by total hip arthroplasty. Clin Orthop Relat Res 2013;471(02):417-421
²⁶
Blondel B, Parratte S, Tropiano P, Pauly V, Aubaniac JM, Argenson JN. Pelvic tilt measurement before and after total hip arthroplasty. Orthop Traumatol Surg Res 2009;95(08):568-572
²⁷
Miki H, Kyo T, Kuroda Y, Nakahara I, Sugano N. Risk of edgeloading and prosthesis impingement due to posterior pelvic tilting after total hip arthroplasty. Clin Biomech (Bristol, Avon) 2014;29(06):607-613
²⁸
ShonWY, Sharma V, Keon OJ, Moon JG, Suh DH. Can pelvic tilting be ignored in total hip arthroplasty? Int J Surg Case Rep 2014;5 (09):633-636

Publication Dates

Publication in this collection
13 Dec 2019
Date of issue
Nov-Dec 2019

History

Received
23 Dec 2017
Accepted
10 Apr 2018

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial No Derivative License, which permits unrestricted noncommercial use, distribution, and reproduction in any medium provided the original work is properly cited and the work is not changed in any way.

[1] *
Work performed at the Orthopedics and Traumatology Service of the Hospital Universitário Cajuru (PUC-PR), Curitiba, PR, Brazil. Originally Published by Elsevier Editora Ltda.

SS Variable	Line 1	Line 2	Normal value
Lumbar lordosis (LL)	Superior L1 plate	Terminal S1 plate	41 ± 11º/46 ± 11º
Pelvic tilt (PT)	Line vertical to the ground	Midpoint from the sacral plate to the femoral head axis	10º-25º
Pelvic incidence (PI)	Perpendicular to the sacral plate	Midpoint from the sacral plate to the femoral head axis	45º-65º
Sacral slope (SS)	Superior S1 plateau	Line horizontal to the ground	30º-50º

	n	Mean	Median	Minimum	Maximum	Standard deviation	p-value ^a a Student's t-test for paired samples (p < 0.05).
Pelvic tilt
Preoperative	72	13,3	14,5	-1,3	36	10.1
Postoperative	72	11,9	11	-11	39	10.30
Difference (postoperative-preoperative)	72	-1,4	-1	-33	29	9.9	0.219
Pelvic incidence
Preoperative	72	55,9	53	25	100	13.0
Postoperative	72	54,8	52	20	100	13.5
Difference (postoperative-preoperative)	72	-1,1	0	-21	15	6.3	0.158
Sacral slope
Preoperative	72	42,4	42	-2	74	11.0
Postoperative	72	42,9	41	23	85	11.5
Difference (postoperative-preoperative)	72	0,4	0	-25	29	8.5	0.658
Lumbar lordosis
Preoperative	72	-57,3	-58	-96	-2	13.6
Postoperative	72	-56,8	-56	-116	-27	14.3
Difference (postoperative-preoperative)	72	0,5	0	-53	33	12.1	0.750

	n	Mean	Median	Minimum	Maximum	Standard deviation	p-value ^a a Student's t-test for paired samples (p < 0.05).
Pelvic tilt
Preoperative	28	16.0	16	0	34	7.8
Postoperative	28	13.5	13	-4	33	7.5
Difference (postoperative-preoperative)	28	-2.5	-2	-24	17	7.9	0.105
Pelvic incidence
Preoperative	28	57.1	57	32	100	12.8
Postoperative	28	54.5	52	31	87	14.9
Difference (postoperative-preoperative)	28	-2.6	-3.5	-17	14	7.6	0.085
Sacral slope
Preoperative	28	40.3	41	18	74	10.7
Postoperative	28	41.1	39	28	69	10.5
Difference (postoperative-preoperative)	28	0.7	-2	-13	26	8.2	0.632

Variable	Evaluation	Preoperative PI	n	Mean	Minimum	Maximum	Standard deviation	p value^a a Student's t-test for independent samples (preoperative evaluation); adjusted analysis of covariance (ANCOVA) for preoperative evaluation (for remaining assessments); p < 0.05.
Pelvic tilt	Preoperative	< 60	49	9,8	-13	34	9.0
		≥ 60	23	20,7	9	36	8.3	< 0.001
	Postoperative	< 60	49	9,1	-11	32	9.4
		≥ 60	23	17,8	-1	39	10.0	0.157
	Late postoperative	< 60	18	10,5	-4	23	6.4
		≥ 60	10	18,9	11	33	6.3	0.017
	Difference	< 60	49	-0,7	-33	29	9.8
	(postoperative-preoperative)	≥ 60	23	-3,0	-33	13	10.2	0.157
	Difference (late postoperative-	< 60	18	-3,3	-24	7	8.0
	preoperative)	≥ 60	10	-1,0	-10	17	7.8	0.017
	Difference (postoperative-	< 60	18	-0,1	-18	10	6.4
	late postoperative)	≥ 60	10	-0,6	-19	17	9.1	0.672
Sacral slope	Preoperative	< 60	49	39,3	-2	57	10.1
		≥ 60	23	49,2	31	74	9.9	< 0.001
	Postoperative	< 60	49	39,4	23	61	9.1
		≥ 60	23	50,4	31	85	12.6	0.050
	Late postoperative	< 60	18	35,7	28	48	6.1
		≥ 60	10	50,7	33	69	10.0	0.007
	Difference	< 60	49	1	-25	29	8.9
	(postoperative-preoperative)	≥ 60	23	1,2	-14	21	7.7	0.050
	Difference (late postoperative-	< 60	18	-0,1	-13	26	8.8
	preoperative)	≥ 60	10	2,3	-9	13	7.1	0.007
	Difference (late postoperative-	< 60	18	-1,1	-10	11	6.2
	postoperative	≥ 60	10	0,7	-16	16	8.6	0.112
Lordosis	Preoperative	< 60	49	-53,9	-77	-2	12.6
		≥ 60	23	-64,5	-96	-34	13.1	0.002
	Postoperative	< 60	49	-53,9	-71	-31	10.6
		≥ 60	23	-64,7	-116	-27	17.8	0.077
	Late postoperative	< 60	18	-55,2	-75	-39	9.5
		≥ 60	10	-65,3	-82	-40	11.9	0.402
	Difference	< 60	49	0,8	-32	33	10.9
	(postoperative-preoperative)	≥ 60	23	-0,2	-53	28	14.6	0.077
	Difference (late postoperative-	< 60	18	-4,2	-32	11	11.5
	preoperative)	≥ 60	10	-0,8	-14	14	8.6	0.402
	Difference (late postoperative-	< 60	18	-3,8	-20	11	7.7
	postoperative)	≥ 60	10	3,2	-9	39	14.9	0.263

LL	Preoperative period		Postoperative period		Late postoperative period
	n	%	n	%	n	%
Hyperlordosis^a a Women > 57º; Men > 52º.	47	65.3	40	55.6	18	64.3
Normolordosis^b b Women 35º to 57º; Men 30º to 52º.	23	31.9	30	41.7	10	35.7
Hypolordosis^c c Women < 35º; Men < 30º.	2	2.8	2	2.8	0	0
Total	72	100	72	100	28	100

Brasil

Brasil

Influence of total hip arthroplasty on sagittal lumbar-pelvic balance: Evaluation of radiographic parameters* * Work performed at the Orthopedics and Traumatology Service of the Hospital Universitário Cajuru (PUC-PR), Curitiba, PR, Brazil. Originally Published by Elsevier Editora Ltda.

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Influence of total hip arthroplasty on sagittal lumbar-pelvic balance: Evaluation of radiographic parameters^* * Work performed at the Orthopedics and Traumatology Service of the Hospital Universitário Cajuru (PUC-PR), Curitiba, PR, Brazil. Originally Published by Elsevier Editora Ltda.