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Kim, Lenke, Pizones, Castelein, Trobisch, Yagi, Kelly, and Chang: Adolescent Idiopathic Scoliosis: Is the Feasible Option of Minimally Invasive Surgery using Posterior Approach?

Abstract

The purpose of this systematic review and meta-analysis is to perform a systematic review and meta-analysis of previous studies on minimally invasive scoliosis surgery (MISS) in adolescents with idiopathic scoliosis (AIS). Some data on MISS in AIS compared with conventional open scoliosis surgery (COSS) are conflicting. A systematic literature search was conducted in Medline, Embase, and Cochrane Library, including studies reporting outcomes for MISS in AIS. The meta-analysis compared the operative, radiological, and clinical outcomes and complications between MISS and COSS in patients with AIS. Of the 208 records identified, 15 nonrandomized studies with 1,369 patients (reviews and case reports are excluded) were included in this systematic review and meta-analysis. The mean scale was 6.1, and eight of the 15 included studies showed satisfactory quality using the Newcastle-Ottawa scale. For operative outcomes, MISS had significant benefits in terms of estimated blood loss (standard mean difference [SMD], −1.87; 95% confidence interval [CI], −2.94 to −0.91) and hospitalization days (SMD, −2.99; 95% CI, −4.45 to −1.53) compared with COSS. However, COSS showed significantly favorable outcomes for operative times (SMD, 1.71; 95% CI, 0.92–2.51). No significant differences were observed in radiological outcomes, including Cobb’s angle of the main curve and thoracic kyphosis. For clinical outcomes, MISS showed significant benefits on the visual analog scale score (SMD, −0.91; 95% CI, −1.36 to −0.47). The overall complication rates of MISS were similar to those of COSS (SMD, 0.96; 95% CI, 0.61–1.52). MISS using the posterior approach provides equivalent radiological and clinical outcomes and complication rates compared with COSS. Considering the lower estimated blood loss, shorter hospitalization days, and longer operative times in MISS, COSS is still the mainstay of surgical treatment in AIS; however, MISS using the posterior approach is also one of the surgical options of choice in the case of moderate AIS.

Introduction

Minimally invasive surgery (MIS) in the spine field has become a widely employed practice in degenerative spine disorders, with approaches ranging from discectomy and fusion to deformity correction [1,2]. The advantages of MIS compared with conventional open surgery include smaller incisions, less blood loss, and musculoligamentous sparing, which contribute to lower complication rates [3]. Owing to its distinct characteristics, MIS has been explored for treating various diseases, including adolescent idiopathic scoliosis (AIS) [3,4].
Regarding its biomechanics, AIS is generally recognized as a three-dimensional deformity. Thus, the surgical goal of AIS is to correct the scoliotic (i.e., coronal deformity) and sagittal deformity [5]. To restore coronal and sagittal balance, pedicle screw instrumentation (PSI) with rod derotation (RD) using the posterior approach is a standard surgical treatment in AIS [6]. Despite the rapid evolution of MIS, attempts to perform MIS in AIS have been challenging because it requires correction of a much larger curve, longer instrumentation, and specific surgical techniques, such as RD and direct vertebral rotation (DVR) [7].
In AIS, conventional open scoliosis surgery (COSS) by the posterior approach has been proven effective in achieving powerful fixation using PSI and three-dimensional deformity correction using RD and DVR [6]. However, COSS has the drawback of a significantly long surgical incision, which leads to postoperative dissatisfaction among adolescents [5,7,8]. Consequently, the demand for MIS using posterior approaches has increased. In 2008, Sarwahi et al. [7] first introduced the MIS technique for patients with moderate AIS using three skin incisions of approximately 2 inches (5.08 cm). MISS in AIS has been performed by many skilled surgeons [923]. Particularly, the coin-hole technique reported by Yang et al. [14] has been introduced to overcome wound-related problems from MISS using the posterior approach. However, outcomes for surgical treatment of AIS using the posterior approach between COSS and MISS are conflicting [923]. Given the paucity and conflicting data, this systematic review and meta-analysis assessed the operative, radiological, and clinical outcomes, including the complication rates, between MISS and COSS using the posterior approach in moderate AIS.

Materials and Methods

The protocol for this systematic review and meta-analysis was registered in advance with the International Prospective Register of Systematic Reviews (PROSPERO; CRD42023430522). This systematic review and meta-analysis was performed and reported according to the Meta-analysis of Observational Studies in Epidemiology and the Preferred Reporting Items for Systematic Reviews and Meta-analyses checklists. The protocol for this review was not published [24,25].

1. Search strategy and selection criteria

Various databases, including PubMed/Medline, Embase, and the Cochrane Library, were searched on May 27, 2023, for MISS studies comparing COSS in AIS. The search syntax was as follows: (“idiopathic”[All Fields] OR “idiopathically”[All Fields] OR “idiopathics”[All Fields]) AND (“scoliosis”[MeSH Terms] OR “scoliosis”[All Fields] OR “scolioses”[All Fields]) AND (“minimal*”[All Fields]) AND (“invasibility”[All Fields] OR “invasible”[All Fields] OR “invasion”[All Fields] OR “invasions”[All Fields] OR “invasive”[All Fields] OR “invasively”[All Fields] OR “invasiveness”[All Fields] OR “invasives”[All Fields] OR “invasivity”[All Fields])) in PubMed/Medline, “idiopathic” AND (“scoliosis”/exp OR “scoliosis”) AND “minimal*” AND “invasive” in Embase, and (“idiopathic scoliosis”) AND (“minimal* invasive”) in Cochrane Library using Medical Subject Headings (MeSH) terms to identify studies published in English.
After removing duplicate articles in Endnote, two reviewers independently screened the extracted studies for eligibility based on the titles and abstracts using Covidence (Melbourne, VIC, Australia). After title and abstract screening, the same two reviewers independently reviewed full-text articles; any disagreements on the eligibility of full-text articles were resolved by consensus or discussion with a third reviewer. Studies that reported MISS in moderate AIS, including randomized controlled trials, cross-sectional studies, and cohort studies (retrospective or prospective studies), were included in this review. Moderate AIS was defined as the major curve’s Cobb angle <70° or 80°, and flexibility >50% on side-bending films in patients with AIS. Case reports, reviews, language other than English, non-availability of full-text articles, nonfusion surgery, MISS using anterior approaches, and revision surgery of MISS were excluded. The outcomes of interest of MISS in comparison with those of COSS were operative (estimated blood loss, operative time, and hospitalization days), radiological (Cobb’s angle of the main curve and thoracic kyphosis), and clinical (Scoliosis Research Society [SRS]-22r score, and Visual Analog Scale [VAS] for surgical site pain) outcomes, as well as complications (overall, surgical site infection [SSI], implant failure, and pedicle screw misplacement).

2. Data extraction

The same four reviewers, working in pairs, independently extracted the data using a predefined data extraction file. Two reviewers independently performed the risk-of-bias assessment and extracted the study data. The following baseline characteristics were extracted from the included studies: first author, year of publication, study design, period, country in which the study was performed, setting, number of included patients, mean age, sex, mean follow-up duration, MIS indication for patients with AIS, and MIS techniques.

3. Quality assessment

The same two reviewers independently assessed the quality of the nonrandomized studies using the Newcastle-Ottawa Scale in the meta-analysis [26]. Any discrepancy was resolved by the two authors after discussion. Publication bias was assessed using funnel plots.

4. Statistical analysis

Continuous variables were extracted as the mean±standard deviation by converting the values for the extracted data using the methods described in the Cochrane Handbook for Systematic Reviews of Interventions, if sufficient information was available [27]. They were presented as standardized mean differences (SMDs) with a 95% confidence interval (CI) using the inverse variance weighting method. Dichotomous variables were extracted as absolute numbers and/or percentages, pooled using the Mantel-Haenszel method, and presented as odds ratios (ORs) with a 95% CI. The random-effects model was used for all analyses, and statistical heterogeneity between studies was assessed by visual inspection of forest plots and I2 and χ2 statistics for heterogeneity. For the subgroup assessment, the difference in effect estimates between the two subgroups was assessed as described in the Cochrane Handbook for Systematic Reviews of Interventions [27]. The significance level across the subgroups was determined by testing for subgroup differences. We also assessed potential publication bias by visual inspection of funnel plots of risk ratios and standard errors. Statistical analyses were performed using RevMan Web (Cochrane, London, UK) or the Meta package in R ver. 4.3.0 (R Foundation for Statistical Computing, Vienna, Austria).

Results

1. Search

After screening 208 articles from the title and abstracts, 26 articles were identified in the reports for eligibility. After reviewing the full-text articles, 11 articles were excluded as follows: review articles (n=6), other article types such as case reports and letters (n=3), and studies including nonrelevant outcomes of MISS and COSS (n=2). Finally, 15 nonrandomized studies were included in this systematic review and meta-analysis (Fig. 1).

2. Baseline study characteristics

A total of 15 nonrandomized studies with 1,369 patients—of whom 805 were treated with MISS and 564 with COSS—were included. Five of the included studies only assessed the outcome of MISS and included COSS information. The baseline study characteristics of the included studies are summarized in Table 1.

3. Quality assessment

All 15 included studies were non-randomized; thus, we assessed the risk of bias using the Newcastle-Ottawa Scale. The mean scale was 6.1 (range, 5–7), and eight of the 15 included studies showed satisfactory quality. The details of the quality assessment in this study are presented in Table 2.

4. Operative outcome measures

The estimated blood loss in eight studies, operative time in eight studies, and number of hospitalization days in seven studies were measured as operative outcomes. All of the measured operative parameters exhibited heterogeneity (I2=96%, estimated blood loss; I2=94%, operative time; I2=96%, hospitalization days). For the estimated blood loss, the overall pooled effect showed that MISS was associated with a significant reduction in estimated blood loss compared with COSS (SMD, −1.87; 95% CI, −2.94 to −0.91; p<0.001) (Fig. 2A). For the operative time, the overall pooled effects showed that MISS had a significantly longer operative time than COSS (SMD, 1.71; 95% CI, 0.92–2.51; p<0.001) (Fig. 2B). For hospitalization days, the overall pooled effect showed that MISS was associated with a significant reduction in hospitalization days compared with COSS (SMD, −2.99; 95% CI, −4.45 to −1.53; p<0.001) (Fig. 2C).
To evaluate radiological outcomes, Cobb’s angle of the main curve was measured in 10 studies and thoracic kyphosis in eight studies. Heterogeneity was observed as I2=86% in Cobb’s angle of the main curve and I2=79% in thoracic kyphosis. For Cobb’s angle of the main curve, the overall pooled effect revealed that MISS did not show significant differences in Cobb’s angle of the main curve compared with COSS (SMD, −0.3; 95% CI, −0.70 to 0.10; p=0.15) (Fig. 3A). For thoracic kyphosis, no significant differences were observed between MISS and COSS (SMD, −0.20; 95% CI, −0.59 to 0.19; p=0.31) (Fig. 3B). Cobb’s angle of the main curve was measured in >10 studies. The presented funnel plots were relatively symmetrical, indicating no evidence of publication bias (Fig. 3C).
For the clinical outcomes, the postoperative VAS score was measured in two studies and the SRS-22r score in four studies. Heterogeneity was observed in the SRS-22r score (I2=83%); however, it was not observed in the VAS (I2=56%). For VAS, the overall pooled effect showed that MISS was associated with a significant reduction in postoperative VAS compared with COSS (SMD, −0.91; 95% CI, −1.36 to −0.47; p<0.001) (Fig. 4A). For the SRS-22r score, the overall pooled effect of the SRS-22r score showed no significant difference between MISS and COSS (SMD, 0.31; 95% CI, −0.29 to 0.91; p=0.31) (Fig. 4B).
The presence of overall complications, such as SSI, implant failure, and pedicle screw misplacement, were evaluated for the comparison of the complication rates between MISS and COSS. None of the data regarding the complication-related parameters had heterogeneity as an overall complication (I2=0%), SSI (I2=5%), implant failure (I2=0%), or pedicle screw misplacement (I2=0%). The overall pooled effect of overall complication (OR, 0.96; 95% CI, 0.61–1.52; p=0.87), SSI (OR, 1.63; 95% CI, 0.82–3.22; p=0.16), implant failure (OR, 1.36; 95% CI, 0.47–3.93; p=0.57), and pedicle screw misplacement (OR, 1.18; 95% CI, 0.94–1.48; p=0.15) showed no significant difference between MISS and COSS (Fig. 5).

Discussion

In the era of MISS in spine surgery, the demand for MISS in AIS has increased to overcome the disadvantages of COSS [14]. Since Sarwahi et al. [7] initially suggested the MISS technique in AIS, many studies on the surgical outcomes of MISS in AIS have been published [923]. In these studies, conflicting results have been observed, such as those for complications; however, the causes of these discrepancies have been explained from various perspectives. Considering the pooled effect estimate in outcome measures, this meta-analysis provided the advantages of MISS in moderate curves of AIS: less blood loss, fewer hospitalization days, and lower postoperative pain score with equivalent radiological correction than COSS in the surgical treatment of AIS using posterior approaches. Meanwhile, COSS is favorable with respect to the operative time. Furthermore, no differences were found in the complications between MISS and COSS. However, radiation exposure in the management of AIS is one of the problems that needs caution for adolescents, which was not considered in this study. Thus, future studies with long-term follow-up data need to be established.
MISS using the posterior approach involves distinctive procedures compared with COSS. First, two or three shorter incisions are made during MISS compared with the long longitudinal single incisions in COSS [10]. A small scar length is considered one of the factors in functional outcomes in the perioperative period [14,16]. Second, MISS for facetal fusion involved less extensive soft tissue dissection and decreased area of subperiosteal exposure, whereas COSS was performed with posterior fusion with wide bone and soft tissue exposure [9,17]. Third, Yang et al. [15] used a tubular retractor as a coin-hole technique to protect the surrounding soft tissue area of the operation field. These distinctive characteristics of MISS have resulted in less estimated blood loss and fewer hospitalization days [10,16]. However, MISS is still in its early stages; therefore, the operative time did not reflect the learning curve of MISS [3,18,28]. Yang et al. [18] suggested that MISS has a mild learning curve with 46 cases of experience. Furthermore, in our meta-analysis, Sarwahi et al. [10] in 2021 showed an SMD of 0.15 of and 95% CI of −0.03 to 0.33, which are the results from proficient and skilled experience. Thus, current data are mostly the results of MISS using the posterior approach performed by proficient surgeons for moderate AIS curves, requiring careful interpretation of our meta-analysis.
The radiological outcomes of MISS were consistently equivalent or similar to those of COSS. Our focused radiological outcome measures were Cobb’s angle of the main curve in the coronal alignment and thoracic kyphosis in the sagittal alignment. Guo et al. [29] noted that anterior column overgrowth leads to harmful effects of thoracic kyphosis, which potentially contributes to cervical alignment. Thus, thoracic hypokyphosis in sagittal alignment is a critical issue for treating AIS [3032]. In addition, Schlösser et al. [33] suggested that the RD-only technique can lead to inappropriate correction of thoracic kyphosis instead of proper correction of the main curves, or vice versa. Therefore, MISS provided equivalent radiological outcomes in Cobb’s angle of the main curve and thoracic kyphosis compared with COSS. However, MISS using the posterior approach has a limitation for three-dimensional correction in larger and stiffer curves [1416].
Regarding clinical outcomes between MISS and COSS, VAS was only measured in the studies by Sarwahi et al. [9,10]. In 2016, Sarwahi et al. [9] did not find significant differences in VAS between MISS and COSS; however, small-sized sample data were measured with an early stage of MISS. After 5 years, Sarwahi et al. [10] in 2021 showed the advantages of postoperative VAS in MISS with large-sized sample data. The benefit of postoperative VAS affected the management of the perioperative period; thus, it may have been associated with shorter hospital stays in MISS [10]. Contrary to the VAS findings, the SRS-22r score was not significantly different between MISS and COSS. SRS-22r was measured based on function, pain, self-image, mental health, and satisfaction. The cosmesis in SRS-22r was only part of the factor; thus, a future trial is needed to evaluate cosmesis as a new measurement tool, such as scar cosmesis assessment and a rating scale from short-term to long-term follow-up between MISS and COSS [34].
In the background of the coin-hole technique by Yang et al. [14], the initial study of the MIS technique by Sarwahi et al. [9,10] reported a higher complication rate in MISS than in COSS in terms of wound problems such as late-onset wound problems (from 1 month after the MISS to 3-year follow-up) and hypertrophic scars. By employing the 20- to 24-mm diameter tubular retractor system, adequate exposure of the surgical field has been established as a form of coin hole, which reduces skin–muscle damage during free-hand pedicle screw insertion [15]. Although the overall pooled effect of SSI showed no significant difference, the OR of SSI was higher in the MISS technique by Sarwahi et al. [9,10] (OR, 2.15 from the random-effect model) than in the method by Yang et al. [16,17,19] (OR, 1.26 from the random-effect model) between MISS and COSS in AIS. However, all results in this meta-analysis were not fully considered a learning curve, which is an important factor in assessing complication rates. Therefore, an updated meta-analysis considering the learning curve is essential [5,18,28]. The intraoperative pedicle screw misplacement rate was relatively higher in MISS than in COSS (OR, 1.18; 95% CI, 0.94–1.48; p=0.15). MISS with limited surgical vision had obstacles to the process of free-hand pedicle screw insertion [19]. Limited surgical vision in coin hole and angled lesions to insert the pedicle screw may intraoperatively lead to pedicle screw misplacement [10,19,35]. However, these results showed no significant differences, indicating an acceptable range of pedicle screw placement in MISS compared with COSS despite limited surgical vision.
Although MISS using the posterior approach is a feasible option based on our analysis, special attention is needed when making judgments based on these results. MISS provides equivalent outcomes in terms of radiological, clinical, and complication rates. Meanwhile, in operative parameters, COSS required more bleeding loss (approximately 187 mL) and longer hospitalization days (approximately 3 days) than MISS. However, COSS is favorable with respect to the operative time (approximately 1.71 hours) compared with MISS in our meta-analysis. The requirement of a longer operative time can be a factor in surgeons’ hesitation to choose MISS. Although COSS is still a mainstay of the surgical treatment of moderate AIS using the posterior approach, this meta-analysis provides the need for future research on the preferences of surgeons.
Several possible limitations in this systematic review and meta-analysis must be considered. First, the missing article regarding MISS actually existed, which could have influenced the results of the meta-analysis. Although some missing articles may have existed in other databases, the included articles were from a relatively sound evidence-based database using a highly sensitive search strategy. Second, our study contained very small sample sizes. Although MIS in AIS has been sufficiently developed, MIS research remains in the early stages; thus, these data were also included, and consistent results were observed in this meta-analysis. After more evidence is presented, the efficacy and safety should be reevaluated with an updated meta-analysis. Third, heterogeneity was observed in nearly all our meta-analysis results. This may have been caused by several factors, including differences in the MISS technique between surgeons, not considering the learning curve in the current meta-analysis, and poor methodology quality from nonrandomized studies. Fourth, the definition of parameters was slightly different, such as thoracic kyphosis from T1 to T3 or T4 to T12, which also influenced the results. Lastly, the data conversion process may have affected the results by unifying the continuous data into mean±standard deviations. In this systematic review and meta-analysis, the studies of Sarwahi et al. [7,9,10] had a large influence; however, they expressed data as medians and interquartile ranges. Based on this meta-analysis, some concerns existed regarding heterogeneity and poor evidence data from nonrandomized studies [24]. Therefore, in the research of MISS in AIS, large-sample-sized randomized controlled trials with the same standard of MISS technique are needed to support our meta-analysis results. Despite these limitations, MISS offers significant advantages: our included studies consistently demonstrated its superior estimated blood loss and lower hospitalization days, with radiological outcomes in AIS comparable to those of COSS.

Conclusions

This systematic review and meta-analysis provide comparable evidence for the efficacy and safety of MISS using the posterior approach in AIS. MISS using the posterior approach provides equivalent radiological and clinical outcomes and complication rates compared with COSS. Considering the lower estimated blood loss, shorter hospitalization days, and longer operative times in MISS, COSS is still the mainstay of surgical treatment in AIS; however, MISS using the posterior approach is also one of the surgical options of choice in moderate AIS.

Notes

Conflict of Interest

No potential conflict of interest relevant to this article was reported.

Author Contributions

HJK and DGC conceptualized the study. HJK designed the study. HJK and DGC analyzed and interpreted the data. HJK acquired the data. HJK drafted the manuscript. LGL, JP, RC, PDT, MY, and MPK critically reviewed the work. LGL, JP, RC, PDT, MY, and MPK verified the data in the study. All authors had full access to all the data and had final responsibility for the decision to submit for publication.

Fig. 1
A flow chart of this systematic review and meta-analysis.
asj-2023-0408f1.jpg
Fig. 2
Comparison of operative outcome measures in this meta-analysis. (A) Estimated blood loss. (B) Operative time. (C) Hospitalization days. MISS, minimally invasive scoliosis surgery; COSS, conventional open scoliosis surgery; SD, standard deviation; SMD, standard mean difference; IV, inverse variance; CI, confidence interval; df, degrees of freedom.
asj-2023-0408f2.jpg
Fig. 3
Comparison of radiological outcome measures in this meta-analysis. (A) Cobb’s angle of the main curve. (B) Thoracic kyphosis. (C) Funnel plot for Cobb’s angle of the main curve to assess the publication bias. MISS, minimally invasive scoliosis surgery; COSS, conventional open scoliosis surgery; SD, standard deviation; SMD, standard mean difference; IV, inverse variance; CI, confidence interval; df, degrees of freedom; SE, standard error; MD, mean difference.
asj-2023-0408f3.jpg
Fig. 4
Comparison of clinical outcome measures in this meta-analysis. (A) Visual Analog Scale (VAS). (B) Scoliosis Research Society-22r (SRS-22r) score. MISS, minimally invasive scoliosis surgery; COSS, conventional open scoliosis surgery; SD, standard deviation; SMD, standard mean difference; IV, inverse variance; CI, confidence interval; df, degrees of freedom.
asj-2023-0408f4.jpg
Fig. 5
Comparison of complication measures in this meta-analysis. (A) Overall complications. (B) Surgical site infection. (C) Implant failure. (D) Pedicle screw misplacement. MISS, minimally invasive scoliosis surgery; COSS, conventional open scoliosis surgery; SD, standard deviation; SMD, standard mean difference; M-H, Mantel-Haenszel; CI, confidence interval; df, degrees of freedom. (Continued on next page.)
asj-2023-0408f5.jpg
Table 1
Baseline characteristics of studies included in systematic reviews and meta-analysis
Study Design Period Country Settings No. of patients Age (yr) Sex (male:female) FU (yr) Indications for AIS patients MIS technique




Total I C I C I C I C
Sarwahi et al. [9] (2016)a) R 2007–2009 USA Single institute 23 7 15 15.5±2.6 15.4±1.9 1:6 2:13 2.0 2.0 (1) Cobb angle <70º; (2) flexibility >50% on side bending films MIS technique developed by Sarwahi et al.

Sarwahi et al. [10] (2021)a) P 2013–2018 USA Single institute 485 192 293 15.1±1.9 15.0±2.4 25:167 66:227 2.6±0.2 2.3±0.2 (1) Cobb angle <70º; (2) flexibility >50% on side bending films MIS technique developed by Sarwahi et al.

Si et al. [11] (2021) R 2007–2015 China Multi-center 112 64 48 13.2±1.7 14.6±1.9 20:44 14:34 2.6±0.4 2.7±0.5 (1) Lenke 1–4 curve; (2) age 12–18 yr; (3) Cobb angle <70º; (4) flexibility >50% on side bending films MIS technique developed by Sarwahi et al.

de Bodman et al. [12] (2017) P 2013–2016 Switzerland Single center 70 70 NA 15±4.5 NA 8:62 NA 2 NA NS Posterior MIS technique (with 3 incision) using the slots of reduction tubes

de Bodman et al. [13] (2020) R 2013–2016 Switzerland Two tertiary centers 93 93 NA 15.2±2.2 NA 11:82 NA 4.4±1.0 NA (1) Cobb angle <70º–80º; (2) flexibility >50% on side bending films Posterior MIS technique (with 3 incision) using the slots of reduction tubes

Yang et al. [14] (2020)b) P 2015–2017 South Korea Single institute 84 84 NA 15.2±5.6 NA 7:77 NA 1 NA (1) Cobb angle 45º–80º; (2) age 11–18 yr; (3) Risser stage 1–4 Coin-hole technique developed by Yang et al. (MISS)

Yang et al. [15] (2021)b) R 2014–2015 South Korea Single institute 34 34 NA 15.2±3.0 NA 0:34 NA 2 NA (1) Cobb angle 45º–80º; (2) age 11–18 yr; (3) Risser stage 1–4 Coin-hole technique developed by Yang et al. (MISS)

Yang et al. [16] (2021) (2) R 2015–2016 South Korea Single institute 49 24 25 15.0±1.9 14.0±1.5 0:24 0:25 4.6±0.2 9.7 (1) Cobb angle 45º–80º; (2) age 11–18 yr; (3) Risser stage 1–4 Coin-hole technique developed by Yang et al. (MISS)

Yang et al. [17] (2023) R 2014–2015 South Korea Single institute 86 43 43 15.7±2.0 14.6±2.4 5:38 6:37 2.0 2.0 (1) Cobb angle 45º–80º; (2) age 11–18 yr; (3) Risser stage 1–4 Coin-hole technique developed by Yang et al. (MISS)

Yang et al. [18] (2023) (2) R 2015–2017 South Korea Single institute 76 76 NA 15.7±2.1 NA 6:70 NA 1.0 NA (1) Cobb angle 45º–80º; (2) age 11–18 yr; (3) Risser stage 1–4 Coin-hole technique developed by Yang et al. (MISS)

Nam et al. [19] (2023) R 2014–2020 South Korea Single institute 76 28 48 17.7±4.7 17.6±5.5 1:27 11:37 NA NA (1) Cobb angle 45º–80º; (2) age 11–18 yr; (3) Risser stage 1–4 Coin-hole technique developed by Yang et al. (MISS)

Miyanji et al. [20] (2015) P 2019–2012 Canada Multi-center 46 23 23 16.8±0.4 16.4±0.3 3:20 4:19 2.0 2.0 NS Three midline skin incision with mini-open

Zhu et al. [21] (2017) R 2012–2014 China Single institute 45 15 30 16.5±1.6 15.1±1.7 2:13 3:27 2.3±0.3 2.7±0.3 (1) Lenke 5C curve; (2) age 14–18 yr; (3) Cobb angle <70º; (4) flexibility >50% on side bending films (1) Two 3–5 cm midline skin incision; (2) Pedicle screw fixation under the guidance of O-arm navigation

Urbanski et al. [22] (2019) P 2016–2018 Poland Single institute 8 4 4 15.5±2.1 21.3±10.0 0:4 1:3 N/A NA Lenke 5C curve (1) A midline skin incision; (2) pedicle screw fixation under the guidance of O-arm navigation

Syundyukov et al. [23] (2023) R 2014–2020 Russia Single center 82 47 35 16.1±2.2 15.7±1.5 3:44 4:31 8.4±0.5 3.9±1.1 (1) Lenke type I curve; (2) Cobb angle 30º–70º (1) Three posterior skin incision; (2) pedicle screw fixation and correction with MIS devices applied by Urbanski et al.

I, intervention group; C, control group; FU, follow-up; AIS, adolescent idiopathic scoliosis; MIS, minimally invasive surgery; R, retrospective design; P, prospective design; NA, not applicable; NS, not specified; MISS, minimally invasive scoliosis surgery; SD, standard deviation.

a) Values and

b) values are respectively presented as median (25th percentile–75th percentile) and mean (minimum–maximum), which were converted to mean±SD for the purpose of quantitative synthesis. All of the continuous values are expressed as mean±SD.

Table 2
Assessment of quality for included cohort studies in the systematic review and meta-analysis
Study Selection Comparability Outcome Total points (9/9) Quality



Representativeness of the exposed cohort Selection of the non-exposed cohort Ascertainment of exposure Demonstration that outcome of interest was not present at start of study Comparability of cohorts on the basis of the design or analysis controlled for confounders Assessment of outcome Was follow-up long enough for outcomes to occur Adequacy of follow-up of cohorts
Sarwahi et al. [9] (2016) - - 7 Good

Sarwahi et al. [10] (2021) - - - 6 Poor

Si et al. [11] (2021) - 7 Good

de Bodman et al. [12] (2017) - - - - 5 Poor

de Bodman et al. [13] (2020) - - - - 5 Poor

Yang et al. [14] (2020) - - - 6 Good

Yang et al. [15] (2021) - - - - 5 Poor

Yang et al. [16] (2021) (2) - 7 Good

Yang et al. [17] (2023) - 7 Good

Yang et al. [18] (2023) (2) - - - 6 Good

Nam et al. [19] (2023) - - - - 5 Poor

Miyanji et al. [20] (2015) - - 7 Good

Zhu et al. [21] (2017) - 7 Good

Urbanski et al. [22] (2019) - - - - 5 Poor

Syundyukov et al. [23] (2023) - - 6 Poor

Newcastle-Ottawa Scale star template was used for assessment of quality for the non-randomized studies in this systematic review and meta-analysis. From Wells G, Shea B, O’Connell D, et al. The Newcastle-Ottawa Scale (NOS) for assessing the quality of non-randomized studies in meta-analysis [Internet]. Ottawa (ON): Ottawa Hospital Research Institute; 2000 [cited 2023 May 26]. Available from: https://www.ohri.ca/programs/clinical_epidemiology/oxford.asp [26].

References

1. Kim HJ, Yang JH, Chang DG, et al. Adult spinal deformity: a comprehensive review of current advances and future directions. Asian Spine J 2022 16:776–88.
crossref pmid pmc pdf
2. Kim HJ, Yang JH, Chang DG, et al. Proximal junctional kyphosis in adult spinal deformity: definition, classification, risk factors, and prevention strategies. Asian Spine J 2022 16:440–50.
crossref pmid pdf
3. Lener S, Wipplinger C, Hernandez RN, et al. Defining the MIS-TLIF: a systematic review of techniques and technologies used by surgeons worldwide. Global Spine J 2020 10(2 Suppl): 151S–167S.
crossref pmid pmc pdf
4. Kim YH, Ha KY, Kim YS, et al. Lumbar interbody fusion and osteobiologics for lumbar fusion. Asian Spine J 2022 16:1022–33.
crossref pmid pmc pdf
5. Cheng JC, Castelein RM, Chu WC, et al. Adolescent idiopathic scoliosis. Nat Rev Dis Primers 2015 1:15030.
pmid
6. Suk SI, Kim JH, Kim SS, Lim DJ. Pedicle screw instrumentation in adolescent idiopathic scoliosis (AIS). Eur Spine J 2012 21:13–22.
crossref pmid pdf
7. Sarwahi V, Wollowick AL, Sugarman EP, Horn JJ, Gambassi M, Amaral TD. Minimally invasive scoliosis surgery: an innovative technique in patients with adolescent idiopathic scoliosis. Scoliosis 2011 6:16.
crossref pmid pmc pdf
8. Hegde S, Badikillaya V, Kanade U, Akbari K, Achar S, Reddy H. Are we looking at a paradigm shift in the management of adolescent idiopathic scoliosis?: comprehensive retrospective analysis of 75 patients of nonfusion anterior scoliosis correction with 2–5-year follow-up: a single center experience. Asian Spine J 2023 17:529–37.
crossref pmid pmc pdf
9. Sarwahi V, Horn JJ, Kulkarni PM, et al. Minimally invasive surgery in patients with adolescent idiopathic scoliosis: is it better than the standard approach?: a 2-year follow-up study. Clin Spine Surg 2016 29:331–40.
pmid
10. Sarwahi V, Galina JM, Hasan S, et al. Minimally invasive versus standard surgery in idiopathic scoliosis patients: a comparative study. Spine (Phila Pa 1976) 2021 46:1326–35.
pmid
11. Si G, Li T, Wang Y, Liu X, Li C, Yu M. Minimally invasive surgery versus standard posterior approach for Lenke Type 1–4 adolescent idiopathic scoliosis: a multicenter, retrospective study. Eur Spine J 2021 30:706–13.
crossref pmid pdf
12. de Bodman C, Miyanji F, Borner B, Zambelli PY, Racloz G, Dayer R. Minimally invasive surgery for adolescent idiopathic scoliosis: correction of deformity and peri-operative morbidity in 70 consecutive patients. Bone Joint J 2017 99-B:1651–7.
pmid
13. de Bodman C, Ansorge A, Tabard A, Amirghasemi N, Dayer R. Clinical and radiological outcomes of minimally-invasive surgery for adolescent idiopathic scoliosis at a minimum two years’ follow-up. Bone Joint J 2020 102-B:506–12.
crossref pmid pdf
14. Yang JH, Chang DG, Suh SW, et al. Safety and effectiveness of minimally invasive scoliosis surgery for adolescent idiopathic scoliosis: a retrospective case series of 84 patients. Eur Spine J 2020 29:761–9.
pmid
15. Yang JH, Kim HJ, Chang DG, Suh SW. Minimally invasive scoliosis surgery for adolescent idiopathic scoliosis using posterior mini-open technique. J Clin Neurosci 2021 89:199–205.
crossref pmid
16. Yang JH, Kim HJ, Chang DG, Suh SW. Comparative analysis of radiologic and clinical outcomes between conventional open and minimally invasive scoliosis surgery for adolescent idiopathic scoliosis. World Neurosurg 2021 151:e234–40.
crossref pmid
17. Yang JH, Kim HJ, Chang DG, Suh SW. Fusion rates based on type of bone graft substitute using minimally invasive scoliosis surgery for adolescent idiopathic scoliosis. BMC Musculoskelet Disord 2023 24:30.
crossref pmid pmc pdf
18. Yang JH, Kim HJ, Chang DG, Nam Y, Suh SW. Learning curve for minimally invasive scoliosis surgery in adolescent idiopathic scoliosis. World Neurosurg 2023 175:e201–7.
pmid
19. Nam Y, Chang DG, Kim HJ, et al. The accuracy and safety of a pedicle screw using the freehand technique in minimally invasive scoliosis surgery. Neurospine 2023 20:240–7.
crossref pmid pmc pdf
20. Miyanji F, Desai S. Minimally invasive surgical options for adolescent idiopathic scoliosis. Semin Spine Surg 2015 27:39–44.
crossref
21. Zhu W, Sun W, Xu L, et al. Minimally invasive scoliosis surgery assisted by O-arm navigation for Lenke type 5C adolescent idiopathic scoliosis: a comparison with standard open approach spinal instrumentation. J Neurosurg Pediatr 2017 19:472–8.
crossref pmid
22. Urbanski W, Zaluski R, Kokaveshi A, Aldobasic S, Miekisiak G, Morasiewicz P. Minimal invasive posterior correction of Lenke 5C idiopathic scoliosis: comparative analysis of minimal invasive vs. open surgery. Arch Orthop Trauma Surg 2019 139:1203–8.
pmid pmc
23. Syundyukov AR, Nikolaev NS, Vissarionov SV, Kornyakov PN, Bhandarkar KS, Emelianov VU. Less correction with minimally invasive surgery for adolescent idiopathic scoliosis compared to open surgical correction. J Child Orthop 2023 17:141–7.
crossref pmid pmc pdf
24. Page MJ, McKenzie JE, Bossuyt PM, et al. The PRISMA 2020 statement: an updated guideline for reporting systematic reviews. BMJ 2021 372:n71.
crossref pmid pmc
25. Stroup DF, Berlin JA, Morton SC, et al. Meta-analysis of observational studies in epidemiology: a proposal for reporting: meta-analysis of observational studies in epidemiology (MOOSE) group. JAMA 2000 283:2008–12.
crossref pmid
26. Wells G, Shea B, O’Connell D, et al. The Newcastle-Ottawa Scale (NOS) for assessing the quality of non-randomized studies in meta-analysis [Internet] Ottawa (ON): Ottawa Hospital Research Institute. 2000 [cited 2023 May 26]. Available from: https://www.ohri.ca/programs/clinical_epidemiology/oxford.asp

27. Cumpston M, Li T, Page MJ, et al. Updated guidance for trusted systematic reviews: a new edition of the Cochrane Handbook for Systematic Reviews of Interventions. Cochrane Database Syst Rev 2019 10:ED000142.
pmid
28. Kimchi G, Orlev A, Hadanny A, Knoller N, Harel R. Minimally invasive spine surgery: the learning curve of a single surgeon. Global Spine J 2020 10:1022–6.
crossref pmid pdf
29. Guo X, Chau WW, Chan YL, Cheng JC. Relative anterior spinal overgrowth in adolescent idiopathic scoliosis: results of disproportionate endochondral-membranous bone growth. J Bone Joint Surg Br 2003 85:1026–31.
pmid
30. Pesenti S, Lafage R, Henry B, et al. Deformity correction in thoracic adolescent idiopathic scoliosis. Bone Joint J 2020 102-B:376–82.
crossref pmid pdf
31. Clément JL, Pelletier Y, Solla F, Rampal V. Surgical increase in thoracic kyphosis increases unfused lumbar lordosis in selective fusion for thoracic adolescent idiopathic scoliosis. Eur Spine J 2019 28:581–9.

32. Brink RC, Schlosser TP, Colo D, et al. Anterior spinal overgrowth is the result of the scoliotic mechanism and is located in the disc. Spine (Phila Pa 1976) 2017 42:818–22.
crossref
33. Schlosser TP, Abelin-Genevois K, Homans J, et al. Comparison of different strategies on three-dimensional correction of AIS: which plane will suffer? Eur Spine J 2021 30:645–52.
crossref pmid pdf
34. Huang LC, Chen DZ, Chen LW, Xu QC, Zheng ZH, Dai XF. The use of the Scar Cosmesis Assessment and rating scale to evaluate the cosmetic outcomes of totally thoracoscopic cardiac surgery. J Cardiothorac Surg 2020 15:250.
crossref pdf
35. Lewis D, Marya S, Carrasco R, Sabou S, Leach J. Comparative outcome data using different techniques for posterior lumbar fusion: a large single-center study. Asian Spine J 2023 17:807–17.

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