Abstract
Purpose
In-brace radiograph of adolescents with idiopathic scoliosis (AIS) has been shown to reflect brace efficacy and the possibility of achieving curve correction. Conversely, the first out-of-brace radiograph could demonstrate the patient’s ability to maintain the correction. We aimed to determine which of the two radiographs is the best predictor of the Cobb angle at the end of treatment (final radiograph).
Design
Retrospective cohort study of a prospective dataset.
Methods
The population was selected based on the following inclusion criteria: AIS, age 10–18 years; Risser score 0–2; Cobb angle 25–40°; brace treatment; availability of all radiographs. Statistics: Pearson correlations provide a first exploration of data. The univariate and multivariate logistic regression model tested the predictors. Finally ROC curve provided a check of model accuracy.
Results
A total of 131 patients were included (mean age 13.0 ± 1.3, Cobb angle 33.2 ± 5.5°; 78% females). At the end of treatment, 56% had stabilised, 9% had progressed, and 44% had improved. The difference between the in-brace and final radiographs was 8.0 ± 6.0°, while the difference between the first out-of-brace and final radiographs was 1.8 ± 5.2°. The best predictor of final outcome was the first out-of-brace radiograph (0.80), compared to in-brace (0.68) and baseline (0.59) radiographs. The best cut-offs to predict avoidance of progression were 30% and 10% of the correction rates for the in-brace and first out-of-brace radiographs, respectively.
Conclusion
The first out-of-brace radiograph predicts end results better than the in-brace radiograph. It offers an excellent clinical reference for clinicians and patients. The first out-of-brace radiograph should be considered an essential element of future predictive models.
Level of Evidence 1
Diagnostic: individual cross-sectional studies with consistently applied reference standard and blinding.
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Introduction
Scoliosis is a three-dimensional deformity with maximal progression during growth [1]. When the risk of progression is high, the Risser score is between 0 and 2. When scoliosis is between 25 and 40 degrees, brace treatment is required [1]. Randomised controlled trials (RCTs) have confirmed bracing effectiveness [2, 3], supporting the conclusions of a large number of observational studies [4,5,6]. Brace effects depend on different factors: the deformity’s characteristics, brace type, construction and material used, brace wear dosage, patients’ reactions to the brace, and correct and consistent brace wear throughout therapy [7, 8].
In-brace radiograph (IB-XR) has traditionally been considered a proxy for brace quality. It has been used to determine the effect of bracing, predict the end-of-growth results, and compare the impact of different braces [9]. Katz recommended a 25% in-brace correction rate since it was associated with a 73% success rate [10]. Other authors have suggested a 40–50% correction rate to halt progression [4, 11, 12]. The SOSORT consensus on brace action agreed that the initial in-brace correction or primary correction, together with compliance, are the most important factors in predicting treatment success [13]. The factors determining in-brace correction include the Cobb angle of all curves, the lumbopelvic relationship, and the sagittal and coronal imbalance [4, 14]. Nevertheless, the correction rate does not always reflect the brace effectiveness [15]. The in-brace correction varies according to the orthotic device, such as hypercorrective, Cervico-Thoraco-Lumbo-Sacral Orthosis (CTLSO), and Thoraco-Lumbo-Sacral Orthosis (TLSO). Individual subject characteristics influence this outcome, such as spine flexibility, vertebral rotation, skeletal maturity [16], curve magnitude, curve type, and localisation [7].
According to our clinical experience, we hypothesised that the IB-XR reflects the spine’s potential for correction, while the first out-of-brace radiograph (FOB-XR) taken at the end of daily weaning from the brace shows the ability of the patient to maintain the correction, which is linked to his/her muscle strength and neuromotor capacity [17].
Consequently, the end-of-treatment radiograph (EOT-XR) is expected to be different from the IB-XR, while the FOB-XR could act as a target to be achieved during gradual weaning off the brace and for the end-of-growth result. This study aimed to determine if FOB-XR is better than IB-XR at predicting the outcome in a cohort of consecutive patients treated with a brace for adolescent idiopathic scoliosis (AIS) until the end of growth.
Methods
Study design
This was a retrospective observational cohort study, analysing prospective routinely collected data.
Participants
On the search date (18-1-2019), the original sample included 14,507 patients affected by spinal deformities, with an age range of 10–18 years. We applied SRS standard criteria for inclusion [18]: Risser score 0–2; Cobb angle 25–40°; age over 10 years. Furthermore, we included only patients with the availability of baseline radiograph within 3 months from the first evaluation; IB-XR within 1 month and FOB-XR within 6 months from brace start; and end of treatment radiograph after 48 h without the brace. Exclusion criteria were the diagnosis of secondary scoliosis or other associated neurological disorders, treatment discontinuation, and not finishing treatment.
Protocols
At the start, all patients had a baseline radiograph taken within 3 months of the first visit. Figure 1 shows the radiographic protocol. The Italian National Health system takes an average of 2 months to provide braces for free to scoliosis patients. The IB-XR is taken after 1 month of regular brace wear. The time between the START-XR and IB-XR ranges from 4 to 6 months. The FOB-XR is taken after 4–6 months of brace wear, i.e. 7–9 months after the START-XR. We always prescribe brace wearing for a minimum of 18 h to a maximum of 24 h per day. The FOB-XR is always taken at the end of the prescribed daily weaning period. This interval varies from a minimum of 0 h to a maximum of 6 h without the brace. The end-of-treatment radiograph (END-XR) is taken at the end of growth, after 48 h without the brace. Figure 2 shows an example of radiographs taken during the treatment of one patient. Previous studies have described the braces we used [19]. Brace treatment always includes scoliosis-specific exercises [19]: in almost 50% of cases, these follow the Scoliosis Scientific Exercises Approach (SEAS) school [20], while the remaining can be described as usual physiotherapy [21].
Model variables
We measured the Cobb angle on the following radiographs:
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START-XR: first radiograph within 3 months of the baseline clinical evaluation
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IB-XR: 1 month after starting brace treatment
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FOB-XR: after 4–6 months of brace wear
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EOT-XR: last radiograph to decide if treatment should be stopped; this radiograph is taken after 48 h without the brace
Primary outcome variables
The primary outcome variable was defined by multiple binary outcome variables, obtained by measuring the result at the EOT-XR according to recognised clinically crucial thresholds [22]. The 30° Cobb threshold represents the “safety” threshold, which implies no problems in adulthood. The 45° Cobb threshold, close to the surgical threshold, is associated with higher risks of progression in adulthood [1]. We considered a variation within 5° Cobb from START-XR to EOT-XR to define curve changes according to the measurement error of the Cobb method [23].
Secondary outcome variable
The secondary outcome was defined by a continuous variable represented by the change in Cobb angle from START-XR to EOT-XR.
Explanatory variables
The primary explanatory variable was the Cobb angle at the most significant curve, measured on all radiographs taken from baseline to the end of treatment. Furthermore, to account for baseline characteristics, we tested the following variable in both univariate and multivariate models: Cobb angle, TRACE score for trunk aesthetic, rib hump in millimetres, angle of trunk rotation in degrees (ATR) and Risser score. If a variable showed no significant effect in the univariate model, the variable was not included in the multivariate model.
Statistics
All analyses were conducted with STATA version 15.0 for Windows. We used descriptive and inferential statistics for demographic descriptions according to the data distribution. A preliminary investigation of the association between radiograph measurements and the end-of-treatment Cobb angle was done through the Pearson correlation. To test the role of different radiographs in predicting the outcomes at the end of treatment, we performed sequential univariate and multivariate binary logistic regression models for binary response variables. During model specification, the choice of explanatory variables included in the final multivariate model was guided by the performance of the variables in the univariate model. During model calibration, we tested the accuracy of the provided models by drawing the Receiver Operator Curve (ROC) for the different cut-offs of the rate of correction of IB-XR and FOB-XR and for Cobb changes from START-XR to EOT-XR.
For the secondary analysis, we ran a univariate linear regression model. We ran stepwise forward and backward regression to select the variables included in the final multivariate model.
Results
Patient characteristics
We included 131 subjects. Seventy-eight per cent were female, with a mean age of 13.0 ± 1.3 years and an average Cobb angle at the most significant curve of 33.2 ± 5.5° (Table 1).
Fifty-six per cent of the participants showed stabilisation of their largest curve at the end of the treatment (i.e. progressed less than 5 Cobb degrees), 9% had progressed, and 44% had a reduction of 6 Cobb degrees or more from the baseline (i.e. improved). The Cobb variation between IB-XR and EOT-XR was 8.0 ± 6.0°, and the Cobb variation between FOB-XR and EOT-XR was 1.8 ± 5.2°.
The highest correlation found was 0.80 between the FOB-XR and EOT-XR (Table 2).
The univariate model showed that the odds ratio (OR) of ending below 30° increased by 21% as the Cobb angle at baseline decreased (OR = 0.79, CI 95% 0.73–0.86, p = 0.000); 20% as the IB-XR Cobb decreased (OR = 0.80, CI 95% 0.74–0.87, p = 0.000) and 31% as the FOB-XR Cobb decreased (OR = 0.69, CI 95% 0.61–0.78, p = 0.000). The size of the hump in millimetres (OR 0.94, CI 95% 0.89–1.00) and the TRACE score (OR 0.98, CI 95% 0.95–1.00) were added to the final multivariate logistic model, but they had no influence on the OR of the IB-XR nor the FOB-XR. The predictor variables included in the unadjusted and adjusted binary logistic regression model were not significantly associated with the failure outcome. The odds of stability or improvement were 28% higher for 1° Cobb variation from baseline to IB-XR (CI 95% 1.1–1.6) and 28% higher for each degree of Cobb variation from START-XR to FOB-XR (CI 95% 1.1–1.5) (Table 3).
Furthermore, when considering the correction rate, the odds of ending the treatment without progression was 5% higher per unit per cent increase in the rate of correction obtained at IB-XR and 10% higher per unit per cent increase in the rate of correction obtained at the FOB-XR (CI 95% 1.07–1.12) (Table 4).
We did not develop the multivariate model because none of the clinical baseline characteristics significantly predicted the odds of ending without progression. Considering the widespread use of the rate of correction as a reference for treatment performance, we decided to test the accuracy of this binary model. ROC curves were drawn for the different cut-offs of the correction rate for IB-XR and FOB-XR and for changes from START-XR to FOB-XR. The IB-XR correction rate compared to the FOB-XR correction rate for the main cut-off point is shown in Table 5. The best cut-off to predict the avoidance of progression was 30% of the correction rate. The best cut-off of the FOB-XR was 10% of the correction rate.
The ROC showed an acceptable balance between specificity and sensitivity of the model, with an AUC of 72% and 78% for IB-XR and FOB-XR, respectively (Fig. 3).
End-of-treatment Cobb angle is predicted by the following regression equation (R squared 0.88): Cobb at end = 1.81 (intercept) + 0.57 (Cobb at FOB-XR) + 0.30 (IB-XR) + 0.17 (Cobb at baseline), as shown by the adjusted coefficients reported in Table 6.
Discussion
The present study showed that both FOB-XR and IB-XR are good predictors of the end-of-growth results, thus confirming that for good results, we need corrective braces and good brace management, with consistent brace wear, gradual weaning, and scoliosis-specific exercises. FOB-XR performed better than IB-XR. FOB-XR reflects the real correction and gives a specific target for clinicians, patients and parents to predict end results. We decided to test both the Cobb variation across radiographs taken during treatment and the correction rate to enhance the presented results’ generalisability.
Brace treatment is recommended to halt progression of the curve and ensure a better quality of life in adulthood [1]. Regarding the brace effect, there is a long tradition of referencing the in-brace correction. Many authors have claimed the need for 30–50% curve correction to define brace effectiveness or to ensure a better probability of positive results. Other authors have specified higher rates, at least for severe curves. Whatever the case, a good correlation between the in-brace correction and the final results has been demonstrated [9] and was confirmed by the current findings. Katz found that 25% of in-brace correction was associated with a 73% success rate [10], with success being considered a curve progression below 6 Cobb degrees. Landauer stated that over 40% of correction was significantly related to a successful outcome [4]. Goodboy recommended 45% in-brace correction to achieve treatment success [12]. To our knowledge, this is the first study to test how much correction should be kept at the first test of brace removal to achieve successful results. To allow comparison with other published results, we decided to use different outcome measures. The ROC curves indicated that the best predictor of success was the 30% correction rate in the IB-XR and the 10% correction rate in the FOB-XR.
We should highlight the solid clinical relevance of the present results. They will help clinicians assess short- and long-term brace outcomes and guide clinical choices and outcome communication with patients and their families. They also offer interesting insights for future research in the field. According to the present results, we recommend including the FOB-XR in future prognostic models when exploring brace treatment expectations. Patients will benefit too since they will better understand how treatment works and how to interpret brace results during the therapeutic path.
From the start of treatment, patients, families and clinicians look forward to predicting the end-of-growth results. An early indication of a good chance of success is essential for clinical decision-making. Most importantly, it helps to motivate patients by encouraging them to adhere to the prescribed regimen and protocol.
The low level of missing data is a strength of routinely collected medical records and is dependent on the regular data checking, data completion, and data updates made by all the clinicians operating at our institute. Some patients showed worsening of the curve at IB-RX; this was not related to the brace effect but was usually due to the time between radiographs. To minimise ionising radiation, the START-XR can be done within the 3 months before the first visit. Therefore, it is possible that some patients performed the IB-XR 4 months after the START-XR. Curve progression could have occurred before brace fitting. There is, on average, a 2 month waiting list in Italy for obtaining a brace from the Public Health System. When this happens, the patients and their brace are checked and corrected if needed. We considered this factor a normal life variation controlled with a time variable added into the model. The time variable was insignificant, and therefore, it was not included in the final model. Since we aimed to test the prognostic role of radiographs, we did not exclude patients with the worst results from the analysis.
The present results highlight the different roles played by two essential parts of brace treatment. The IB-XR is fundamental to checking brace efficacy. When assessing the correction obtained, we encourage considering all the factors potentially involved, including patients’ characteristics [16] such as spine flexibility, vertebral rotation, and skeletal maturity [7, 24]. Technical features of brace construction and wearing could impact brace correction too [25, 26]. Furthermore, correct prescription, brace type, brace material, and dosage, which stem from the clinical choices made by the expert clinicians, are expected to play a role in the brace correction. IB-XR should be used to optimise the correction by adjusting the brace accordingly [27].
Conversely, the FOB-XR plays a different role, shown by the more robust association with the end-of-growth results: it should be used to predict end results, adjust clinical choices, and motivate patients to comply with the prescription.
Conclusion
The FOB-XR reflects the real correction achieved and achievable by the patient and gives physicians, patients, and parents a specific target to predict results at the end of treatment. The FOB-XR is an important factor for future predictive models investigating the factors that determine the end-of-growth results in adolescents with idiopathic scoliosis.
Change history
31 May 2022
A Correction to this paper has been published: https://doi.org/10.1007/s00586-022-07246-3
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SN declares stock from ISICO. FDF, FN, GR, FZ and SD have nothing to declare.
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The study was approved by the local ethics committee (approval number: 254_2016bis).
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Negrini, S., Di Felice, F., Negrini, F. et al. Predicting final results of brace treatment of adolescents with idiopathic scoliosis: first out-of-brace radiograph is better than in-brace radiograph—SOSORT 2020 award winner. Eur Spine J 31, 3519–3526 (2022). https://doi.org/10.1007/s00586-022-07165-3
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DOI: https://doi.org/10.1007/s00586-022-07165-3