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Determining the fate of cranial sutures after surgical correction of non-syndromic craniosynostosis
Accepted Manuscript Determining the fate of cranial sutures after surgical correction of non-syndromic craniosynostosis So Young Kim, M.D, Hyung-Jin Shi, So Young Lim, M.D PII:
S1010-5182(17)30269-X
DOI:
10.1016/j.jcms.2017.08.009
Reference:
YJCMS 2754
To appear in:
Journal of Cranio-Maxillo-Facial Surgery
Received Date: 6 January 2017 Revised Date:
4 July 2017
Accepted Date: 11 August 2017
Please cite this article as: Kim SY, Shi H-J, Lim SY, Determining the fate of cranial sutures after surgical correction of non-syndromic craniosynostosis, Journal of Cranio-Maxillofacial Surgery (2017), doi: 10.1016/j.jcms.2017.08.009. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
ACCEPTED MANUSCRIPT Determining the fate of cranial sutures after surgical correction of non-syndromic craniosynostosis
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So Young Kim, M.D1., Hyung-Jin Shi2, So Young Lim, M.D3.
From the 1Department of Plastic and Reconstructive Surgery, Inje University Sanggye Paik
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hospital, Inje University School of Medicine, Seoul; the 3Department of Plastic Surgery,
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Samsung Medical Center, Sungkyunkwan University School of Medicine, Seoul; and Department of Neurosurgery, Samsung Medical Center, Sungkyunkwan University School
of Medicine, Seoul, Korea
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The authors have no conflicts of interest to declare.
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There were no funding sources for this study.
Corresponding author:
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So Young Lim, M.D., Ph.D.
Departments of Plastic and Reconstructive Surgery, Samsung Medical Center, Sungkyunkwan University School of Medicine, 81 Irwon-ro, Gangnam-gu, Seoul 06351, Korea. Tel.: +82-2-3410-2239; Fax: +82-2-3410-0036 E-mail: [email protected]
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Summary
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Purpose: “Secondary craniosynostosis” (SCS) refers to a loss of sutures after corrective vault
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reconstruction. There are no prior studies that comprehensively review SCS in various types
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of non-syndromic craniosynostosis. We assessed idiopathic and iatrogenic SCS using 3-
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dimensional computed tomography (3D CT). We also performed a systematic review to
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estimate the overall incidence of SCS in each craniosynostosis type, and to characterize its
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clinical features.
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Materials and Methods: We retrospectively reviewed the CT images of patients who
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underwent surgical correction of craniosynostosis for all types of craniosynostosis between
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August 1999 and December 2015. A literature search of the Medline and Ovid databases was
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conducted in October 2016 using the search term “secondary craniosynostosis.”
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Results: In our series, iatrogenic SCS was observed in all patients who had manipulated
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normal patent sutures to variable extents. Three (17.6%) cases of idiopathic SCS developed
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on sagittal sutures, and were confirmed with a 12-month follow-up CT. In a pooled analysis
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of 10 articles, overall SCS developed in 123 of 1205 patients (10.2%). Iatrogenic SCS cases
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made up 87 of 1205 cases (7.2%), whereas 38 (3.1%) were idiopathic. Idiopathic SCS most
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commonly developed at the bi-coronal suture (n = 32, 84.2%), followed by the sagittal suture
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(n = 4, 10.5%) and uni-coronal suture (n = 1, 2.6%).
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Conclusion: This is the first review not only to describe SCS in all types of non-syndromic
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craniosynostosis, but also to classify SCS into iatrogenic and idiopathic types based on the
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underlying pathogenesis.
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Keywords: secondary craniosynostosis, secondary synostosis
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INTRODUCTION
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Regardless of the surgical method, the ideal result after synostosis correction is neo-
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suture formation and maintenance of a craniectomy gap with minimal defects along the
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craniotomy line. Unfortunately, however, several authors have reported synostosis of other
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sutures that were previously patent before synostosis correction (Marucci et al., 2008; Arnaud
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et al., 2009; Adamo and Pollack, 2010; Seruya et al., 2013). For example, a representative
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case included newly developed coronal synostosis after extended sagittal strip craniectomy
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with bilateral parietal wedge osteotomies for sagittal synostosis correction (Agrawal et al.,
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2006; Cetas et al., 2013; Kuang et al., 2013; Seruya et al., 2013). In these studies, newly
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developed synostoses were called secondary craniosynostosis (SCS). Secondary
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craniosynostosis is defined as a closure in other sutures that were previously open after
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corrective vault reconstruction. In children with syndromic synostosis, SCS occurred after the
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primary surgery in 10.8-36.8% of cases due to an underlying genetic disorder frequently
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related to the fibroblast growth factor receptor gene, which affects all parts of the cranium
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(Esmaeli et al., 2014). In contrast, in patients with non-syndromic synostosis, the incidence of
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SCS after primary surgical correction varied from a few case reports to more than 80%. We
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hypothesize that the discrepancy in the incidence of SCS may be attributable to different
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types of surgical treatment and the extent of surgery. In other words, it is possible that
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previous studies reported mixed results by including both iatrogenic SCS caused by surgical
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manipulation and idiopathic SCS considered as genuine SCS that developed postoperatively
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despite non-surgical manipulation during primary surgery.
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In this study, we assessed all kinds of cranial suture patency following surgical correction
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using follow-up 3-dimensional computed tomography (3D CT). We also identified both
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iatrogenic and idiopathic SCS in 4 kinds of nonsyndromic synostoses. Furthermore, we 2
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performed a systematic review of previous literature regarding SCS to estimate the overall
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incidence of SCS for each craniosynostosis type, and investigated the characteristics of
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patients who might have had a bearing on both kinds of SCS.
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MATERIALS AND METHODS
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Patients and CT imaging for SCS
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After Institutional Review Board approval, a retrospective review was performed for
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patients who underwent surgical correction for all kinds of craniosynostosis between August
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1999 and December 2015. Patients were included if they underwent 3D craniofacial CT both
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preoperatively and at least 12 months postoperatively to confirm the quality of re-ossification
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in the craniectomy gap, and to evaluate overall cranial vault volume and morphology.
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Patients were excluded if they had a syndromic craniosynostosis, did not have a postoperative
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follow-up CT, or had a prior cranial vault reconstruction. Related demographics and surgical
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data were reviewed from the medical records. The normal sutures that were manipulated
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during surgery were identified through review of the intraoperative photographs. 3D CT scan
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images not only provided an overview of which cranial sutures were patent versus closed, but
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also revealed other signs of increased intracranial pressure, including copper beating. SCS
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was identified by comparing pre- and postoperative CT images, and was classified into either
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iatrogenic or idiopathic SCS. Iatrogenic SCS developed in the area of surgical manipulation,
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whereas idiopathic SCS occurred in areas free of surgical manipulation.
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Surgical technique
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All surgical procedures were performed by our senior author and a neurosurgeon. We performed open osteotomy designs for synostosis correction, and fixation techniques with
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resorbable plate osteosynthesis. Specifically, in early 2 cases around 2000, Biosorb (Bionx,
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Tampere, Finland) plates were used, and then a variety of geometric plate and mesh panels
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from several corporations, including Rapidsorb (Synthes, West Chester, PA, USA), Inion CPS
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(Inion, Tampere, Finland), and LactoSorb (Walter Lorenz Surgical Inc, Jacksonville, FL),
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were used and cut into multiple smaller elements as needed. For the surgical correction for
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sagittal synostosis, we performed a modified pi craniectomy with barrel stave osteotomies of
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the bi-temporal area. Bi-coronal sutures were manipulated with this procedure (Fig. 1). For
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patients with bi-coronal/uni-coronal and metopic synostosis, fronto-orbital advancement with
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or without transposition of the frontal bone flap was performed. For bi-coronal synostosis, the
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anterior part of the sagittal suture was partially manipulated. In most cases of uni-coronal
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synostosis, the previously patent contralateral coronal suture was manipulated (Fig. 2). In
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metopic synostosis, bi-coronal sutures were involved in the surgical procedure. In a few cases,
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distraction osteogenesis was used to focus on the areas of the skull with fused sutures in order
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to minimize the extent of the procedure. Therefore, there were no manipulated normal patent
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sutures after distraction osteogenesis was complete. There were no cases of lambdoid
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synostosis in this series.
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Literature review of secondary craniosynostosis
A literature search of the Medline and Ovid databases was conducted in October 2016
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using the search terms “secondary craniosynostosis,” “restenosis,” and “secondary operation.”
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A manual search was also performed to identify additional, relevant papers. A total of 318
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papers were obtained through this search. After excluding articles that were not related to 4
ACCEPTED MANUSCRIPT nonsyndromic synostosis based on a review of their titles, 50 abstracts were included. Case
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reports that reflected the incidence of SCS were also included. Studies were excluded based
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on predefined exclusion criteria (Fig. 3), which eventually yielded 10 papers for final analysis.
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The following data were extracted using a standardized data extraction form (Table 1). We
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reviewed the surgical methods established in each paper. We classified SCS based on 2 types,
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iatrogenic and idiopathic, according to the aforementioned definition. In addition, we
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investigated routine follow-up images (x-ray or CT scans). A pooled analysis of SCS
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incidence was performed. Chi-square or Fisher exact, paired-samples t, and Mann-Whitney U
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tests were conducted. A p-values <0.05 were considered statistically significant. All statistical
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analyses were conducted using SPSS 19.0 (SPSS Inc., Chicago, IL, USA).
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RESULTS
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Clinical results
In our series, after excluding 3 patients due to a lack of postoperative CT and follow-up
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loss, 17 patients (14 boys and 3 girls) met inclusion criteria. There were 4 types of
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craniosynostosis, including 8 sagittal, 3 bi-coronal, 5 uni-coronal and 1 metopic synostosis.
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Mean age at the time of surgery was 18 months (range, 6 months to 10 years), and 4 (23.5%)
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patients underwent primary synostosis correction before 6 months of age. Most patients
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underwent open craniectomies with cranial vault remodeling, and fixation using resorbable
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sutural osteosynthesis. Distraction osteogenesis was performed in 2 patients with uni-coronal
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synostosis (Table 2). Except for 2 cases of distraction osteogenesis, manipulated normal
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patent sutures were confirmed in 15 patients intraoperatively. Table 3 details the involvement
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of normal patent sutures for each patient. There were no major or permanent complications of
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surgery, including cerebrospinal fluid (CSF) leak, brain injury, infection, or hematoma. The mean follow-up period was 5.5 years. On postoperative CT scan (a minimum of 12 months to 10 years after surgery), iatrogenic SCS was observed in all patients who had
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manipulated normal patent sutures. The extent of this iatrogenic SCS varied across patients.
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Among 9 patients with bi-coronal manipulation (8 in sagittal and 1 in metopic synostosis),
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uni-coronal SCS developed in 2 patients, and bi-coronal SCS in 7 (Fig. 4). All 3 patients with
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contralateral coronal manipulation for the correction of uni-coronal synostosis developed
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partial iatrogenic contralateral coronal SCS. Among 3 patients with partial sagittal
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manipulation for surgical correction of bicoronal synostosis, partial sagittal SCS developed in
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2 patients, whereas 1 patient developed complete sagittal SCS (even in the non-manipulated
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portion of the sagittal suture) (Fig. 5). Including this complete sagittal SCS, 3 cases (17.6%)
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of idiopathic SCS developed on the sagittal suture in this study, as confirmed with 12-month
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follow-up CT (including 1 metopic shown in Fig. 6, and 1 uni-coronal and 1 bi-coronal
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synostosis). Detailed patient-related characteristics and time to develop idiopathic SCS are
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shown in Table 4. None of these 3 patients showed clinical signs of increased ICH and
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underwent a secondary operation. There was no evidence of iatrogenic or idiopathic lambdoid
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SCS in this study.
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Systematic review of literature with pooled analysis
Overall SCS incidence by craniosynostosis type
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Ten papers representing a total of 1205 patients were included in this SCS incidence
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review (Hudgins et al., 1998; Agrawal et al., 2006; Marucci et al., 2008; Arnaud et al., 2009;
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Adamo and Pollack, 2010; Cetas et al., 2013; Kuang et al., 2013; Seruya et al., 2013; Esmaeli
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et al., 2014; Yarbrough et al., 2014). Six of the 10 papers, representing 585 patients, described 6
ACCEPTED MANUSCRIPT sagittal SCS synostosis, and 1 paper included metopic synostosis. In contrast, the remaining 3
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papers described all different kinds of craniosynostosis. Most studies described open
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craniectomy with cranial vault remodeling, except 1 study, which used an endoscopic assisted
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procedure. However, synostosis correction extensiveness varied across the studies. Overall,
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SCS developed in 123 of 1205 patients (10.2%). In all, 87 of these cases were iatrogenic
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(7.2%), whereas 38 were idiopathic (3.1%). Among all patients, 2 presented with both
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iatrogenic and idiopathic SCS. (Hudgins et al., 1998) Regarding routine image follow-up, 4
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papers, representing 355 (29.4%) patients, described postoperative image follow-up for all
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patients, whereas 5 other papers did not. Total SCS incidence in the routine image follow-up
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group was significantly higher than that described in papers that did not report postoperative
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imaging (p = 0.01).
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Iatrogenic SCS
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Among 726 patients who had manipulated normal patent sutures, 87 (11.9%) developed iatrogenic SCS. In 4 studies reporting sagittal synostosis correction, bi-coronal and lambdoid
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sutures were easily manipulated to various extents. There were controversial results with
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regard to SCS in the lambdoid suture. Seruya et al. performed extensive manipulation of
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normal lambdoid sutures, including craniectomy of the sutural site and sutural movement,
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and found that 93.6% of patients developed iatrogenic SCS in uni-lambdoid sutures. In
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contrast, Kuang et al. conducted less extensive surgery at the lambdoid suture (compared to
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that performed by Seruya et al.), and found that only 13.5% of patients developed lambdoid
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SCS. In a pooled analysis of these 2 studies, the extensiveness of the surgical manipulation at
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the lambdoid suture was significantly associated with the incidence of iatrogenic lambdoid
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SCS (odds ratio = 93.86, 95% confidence interval 20.9−421.5, p = 0.00). The 2 remaining
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studies did not report use of image work-ups in their patient groups, and found 0.6% and 6.1%
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ACCEPTED MANUSCRIPT iatrogenic SCS at the coronal sutures, respectively. This low iatrogenic SCS incidence was
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also found in other primary craniosynostosis papers that did not report routine imaging
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follow-up (Table 5). After the correction of metopic synostosis, bi-coronal iatrogenic SCS
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was reported as 3 patients in 2 studies (Hudgins et al., 1998; Esmaeli et al., 2014). With the
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exception of 2 patients who had both iatrogenic and idiopathic SCS, 9 patients with
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iatrogenic SCS (10.3%) underwent secondary operations for SCS correction.
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Idiopathic SCS
Among a total of 38 patients who developed idiopathic SCS, 32 (84.2%) developed SCS
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in the primary sagittal synostosis, whereas in 4 (10.5%) cases SCS occurred in the primary
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metopic synostosis. The most common suture in which idiopathic SCS developed was bi-
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coronal (n = 32, 84.2%), followed by sagittal (n = 4, 10.5%), and uni-coronal (n = 1, 2.6%).
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There was 1 uni-coronal synostosis patient who developed secondary pancraniosynostosis
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postoperatively. We did not find any evidence in the literature for isolated idiopathic SCS in
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lambdoid sutures except the aforementioned secondary pancraniosynostosis. Regarding
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surgery-related factors, most patients with idiopathic SCS (n = 36, 94.7%) underwent open
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craniectomies. However, 2 patients who underwent endoscopic craniectomies also developed
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idiopathic SCS. A total of 33 (86.8%) idiopathic SCS patients underwent primary synostosis
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correction before 6 months of age. In all, 15 (39.4%) idiopathic SCS cases were detected
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before 18 months postoperatively based on various signs and symptoms. In particular, 2
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studies (representing 28 idiopathic SCS cases) performed postoperative imaging follow-up; in
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these studies, most cases of idiopathic SCS were diagnosed based on imaging. With the
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exception of 28 cases, there were postoperative head shape deformities in most cases. These
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changes were the initial suspicion signs for SCS. Signs and symptoms of increased
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intracranial pressure (IICP) such as headache and papilledema developed in 18 idiopathic
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SCS patients. Finally, 10 (26.3%) of all patients with idiopathic SCS underwent secondary
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surgeries with the goal of decompressing IICP, or correcting head morphology (Table 6).
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Pathogenesis and characteristics of iatrogenic SCS
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DISCUSSION
There are several possible hypotheses regarding the mechanism underlying iatrogenic
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SCS. The most plausible hypothesis suggests that SCS forms when normal patent sutures
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separate from the underlying dura. Usually, surgery or other intervention disrupts normal
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suture anatomy during cranial vault reconstruction. This manipulation interrupts the signaling
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mechanism in the dura that maintains normal patent sutures, and weakens potential
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stimulation of calvarial growth by pulsatile forces from the brain (Seruya et al., 2013).
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Ultimately, this leads to SCS development (Arnaud et al., 2009; Adamo and Pollack, 2010;
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Cetas et al., 2013). According to this study, the dura detachment theory is acceptable because
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most manipulated normal patent sutures in our patients eventually closed, although the extent
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of closure varied. Furthermore, the result of pooled analysis revealed that the more extensive
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surgical manipulation of normal sutures including separation from the underlying dura,
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fracture or craniectomy, and relocation of normal sutures increased the incidence of
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iatrogenic SCS in 2 follow-up studies representing 49 cases of iatrogenic lambdoid SCS (p <
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0.001) (Kuang et al., 2013; Seruya et al., 2013). This fact supports the hypothesis that it arises
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from the detachment of normal sutures from the underlying dura, premature fusion of normal
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sutures, and interruption of normal suture growth.
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Regarding the influence of fixation technique on iatrogenic SCS, with the recent advent
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of the resorbable osteosynthesis system, a variety of plates and meshes have become widely 9
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concept that these biodegradable osteosynthesis materials form a membrane that guides bone
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regeneration, we usually cover the major part of osteotomy lines with several meshes to
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further stabilize bone fragments and provoke bone regeneration between the bony gaps as
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previously reported in the literature. Interestingly, we observed that most patients who
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received extensive osteosynthesis with meshes showed complete iatrogenic SCS, whereas in
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2 patients who received only limited osteosynthesis with absorbable plates, partial iatrogenic
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SCS was reported. Although an analysis by fixation technique and iatrogenic SCS could not
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be performed because of the lack of specific data on fixation technique type used for
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osteosynthesis in the literature review and the small sample size of the present study, we
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assumed that extensive fixation techniques using mesh could be a risk factor for iatrogenic
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SCS; further studies related to this issue are required in the future.
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The literature is not conclusive and demonstrates conflicting data regarding whether
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certain suture types are more prone to develop iatrogenic SCS if a normal suture is insulted.
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Seruya et al. reported that lambdoid sutures have a higher propensity to develop iatrogenic
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SCS than do coronal sutures. In contrast, Kuang et al. found that iatrogenic SCS developed
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more commonly at the coronal suture than it did at the lambdoid suture (Kuang et al., 2013;
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Seruya et al., 2013). It is difficult to determine which suture is more likely to develop
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iatrogenic SCS by simply comparing the incidence of iatrogenic SCS. There are several
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important factors that should be considered, including the architectural differences between
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sutures. In addition, it is important to consider the differential degree of surgical manipulation
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at each suture. Therefore, a controlled study that considers these factors is needed to further
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investigate the incidence of iatrogenic SCS.
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Interestingly, the rate of secondary surgeries for the correction of iatrogenic SCS was
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approximately 10%. This was much lower than that for idiopathic SCS (26.3%) in the pooled 10
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our experience, even if iatrogenic SCS developed at 100% of manipulated suture sites,
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normal growth was frequently observed, and secondary corrective surgeries were not often
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required. These findings may be attributable to the craniectomy gap adjacent to the fused
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suture, and the role it played in maintaining the intracranial space and minimizing the effect
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of iatrogenic SCS.
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Pathogenesis and characteristics of idiopathic SCS
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There are several, controversial theories regarding the pathogenesis of idiopathic SCS. One hypothesis involves intrinsic suture pathology and an abnormal signal from the cranial
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base that spreads to the calvarium based on genetic or metabolic causes (Moss, 1975).
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Therefore, when the underlying abnormal cranial base remains, either recurrent synostosis
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may develop after correction, or late onset SCS may occur in a previously open suture. This
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theory seems to apply to syndromic craniosynostosis because of the involvement of the
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midface and the high incidence of both recurrent synostosis and SCS. This hypothesis also
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explains some, but not all, cases of idiopathic SCS. We suspect that there is compensatory
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brain growth toward the area of increased dead space, which is caused by primary synostosis
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correction. An abrupt decrease and delay in brain growth perpendicular to the primary
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synostosis may subsequently cause premature suture fusion. In particular, after correction of
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bi-coronal synostosis, during which the antero-posterior (AP) dimension of the cranial vault
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was increased, there was delayed compensatory internal brain growth in the bi-temporal
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direction. Subsequently, sagittal idiopathic SCS could develop. A similar concept has been
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suggested in the literature describing post−ventricular shunting SCS. Decreased intracranial
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volume resulted in over-drainage of the cerebrospinal fluid. Alternatively, delayed internal
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ACCEPTED MANUSCRIPT brain growth after shunting could lead to collapse of the cranial vault with apposition, or
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overriding sutures and subsequent synostosis (Shuster et al., 1995; Park et al., 2009). In our
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study, idiopathic SCS developed in the sagittal suture in 3 patients who underwent surgery to
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widen the AP dimension. We did not detect idiopathic SCS in the bi-coronal suture because of
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frequent surgical manipulation of this suture during bi-temporal widening surgery. However,
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pooled analysis demonstrated 32 (84.2%) cases of idiopathic SCS in the bi-coronal suture in
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patients who underwent all bi-temporal widening surgery for sagittal synostosis correction.
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There may be few or no cases of idiopathic SCS after distraction osteogenesis, during which
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the cranium is gradually expanded postoperatively, allowing a slow expansion of the brain
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and less dead space between the brain and cranium. There are currently no studies addressing
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the development of idiopathic SCS after DO procedures for the correction of non-syndromic
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synostosis. Therefore, further study in this area is needed.
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SCS identification on imaging follow-up
With the advancement of 3D photography in recent years, the use of follow-up CT
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imaging during postoperative periods has come under increasing scrutiny. Because most of
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the reasons for a secondary surgery were poor appearance and intracranial pressure increase,
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CT may be likely to be abandoned in many craniofacial centers for follow-up. Of course, we
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agree that unnecessary radiation and examinations should be avoided; however, it is not
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possible to identify iatrogenic and idiopathic SCS without documentation of suture patency
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using preoperative and postoperative imaging. According to pooled analysis, 2 studies that
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reported pre- and postoperative CT scans found that more than 80% of patients who
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underwent coronal suture manipulation developed iatrogenic SCS (Kuang et al., 2013; Seruya
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et al., 2013). In addition, of all idiopathic SCS cases, 70% were diagnosed through routine
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ACCEPTED MANUSCRIPT imaging follow-up. The detection of idiopathic SCS is particularly important with regard to
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prognosis; 30% of idiopathic SCS cases required subsequent corrective surgeries in the
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pooled analysis. Fortunately, there are now low-radiation techniques that are available. We
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advocate a protocol of prospective routine radiographic follow-up with low-dose radiation
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after primary cranial vault repair for non-syndromic synostosis, and this ought to be used
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judiciously to provide pertinent information for patient care. However, there is still no
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consensus regarding how often and for how long radiologic follow-up should be performed.
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The interval and period of imaging follow-up should be determined based on time to develop
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SCS. According to the aforementioned hypothesis, idiopathic SCS develops early and is
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sensitive to volume changes in the intracranial environment. In this study, idiopathic SCS was
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discovered in 3 patients at postoperative CT follow-up before 18 months, which is the period
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of postoperative cranial stabilization, as suggested by Barone and Jimenez et al. (2011)
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However, the pooled analysis data revealed a similar incidence of idiopathic SCS diagnosed
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before and after 18 months. This discrepancy may be explained by the fact that some prior
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studies used routine imaging, whereas others did not. Further objective studies are needed to
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clarify these findings.
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Our findings should be interpreted in the light of several limitations. Although we tried to include only non-syndromic synostosis, there is a slight possibility that syndromic patients
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were not totally excluded from the pooled analysis. Furthermore, large prospective studies or
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systematic reviews are required to substantiate our conclusions.
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CONCLUSION To the best of our knowledge, this is the first study that not only characterizes SCS for all
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types of non-syndromic craniosynostosis, but also specifically classifies SCS into iatrogenic
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and idiopathic types. The results of this study provide insight into the fate of sutures in 13
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patients with non-syndromic synostosis and subsequent synostosis correction.
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Arnaud E, Capon-Degardin N, Michienzi J, Di Rocco F, Renier D: Scaphocephaly part II: secondary coronal synostosis after scaphocephalic surgical correction. J Craniofac Surg
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20 Suppl 2: 1843-1850, 2009
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Cetas JS, Nasseri M, Saedi T, Kuang AA, Selden NR: Delayed intracranial hypertension after
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cranial vault remodeling for nonsyndromic single-suture synostosis. J Neurosurg
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Pediatr 11: 661-666, 2013
340 341
Esmaeli A, Nejat F, Habibi Z, El Khashab M: Secondary bicoronal synostosis after metopic craniosynostosis surgical reconstruction. J Pediatr Neurosci 9: 242-245, 2014 Hudgins RJ, Cohen SR, Burstein FD, Boydston WR: Multiple suture synostosis and
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increased intracranial pressure following repair of single suture, nonsyndromal
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craniosynostosis. Cleft Palate Craniofac J 35: 167-172, 1998
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Kuang AA, Jenq T, Didier R, Moneta L, Bardo D, Selden NR: Benign radiographic coronal
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synostosis after sagittal synostosis repair. J Craniofac Surg 24: 937-940, 2013
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Marucci DD, Johnston CP, Anslow P, Jayamohan J, Richards PG, Wilkie AO, et al:
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Implications of a vertex bulge following modified strip craniectomy for sagittal
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synostosis. Plast Reconstr Surg 122: 217-224, 2008
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Moss ML: Functional anatomy of cranial synostosis. Childs Brain 1: 22-33, 1975
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Park DH, Chung J, Yoon SH: The role of distraction osteogenesis in children with secondary 15
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craniosynostosis after shunt operation in early infancy. Pediatr Neurosurg 45: 437-445,
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2009
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Ridgway EB, Berry-Candelario J, Grondin RT, Rogers GF, Proctor MR: The management of sagittal synostosis using endoscopic suturectomy and postoperative helmet therapy. J
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Neurosurg Pediatr 7: 620-626, 2011
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Seruya M, Tan SY, Wray AC, Penington AJ, Greensmith AL, Holmes AD, et al: Total cranial vault remodeling for isolated sagittal synostosis: part I. Postoperative cranial suture
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patency. Plast Reconstr Surg 132: 602e-610e, 2013
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Shuster BA, Norbash AM, Schendel SA: Correction of scaphocephaly secondary to
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ventricular shunting procedures. Plast Reconstr Surg 96: 1012-1019, 1995 Yarbrough CK, Smyth MD, Holekamp TF, Ranalli NJ, Huang AH, Patel KB, et al: Delayed synostoses of uninvolved sutures after surgical treatment of nonsyndromic
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craniosynostosis. J Craniofac Surg 25: 119-123, 2014
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Figure 1. Manipulation of bi-coronal suture during surgical correction of sagittal synostosis.
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Figure 2. Manipulation of contralateral coronal suture during surgical correction of uni-
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coronal synostosis.
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Figure 3. Study attrition diagram.
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Figure 4. Preoperative 3D-CT image of sagittal synostosis (right) and iatrogenic secondary
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synostosis developed in bi-coronal suture after sagittal synostosis correction (left).
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Figure 5. Preoperative (right) and postoperative (left) 3D-CT image of patient number 11 that
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revealed idiopathic secondary synostosis in the sagittal suture after surgical correction of bi-
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coronal synostosis.
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Figure 6. Preoperative (right), postoperative (middle) 3D-CT, and intraoperative (left) image
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of patient number 17 who showed iatrogenic secondary bi-coronal synostosis and idiopathic
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secondary synostosis in the sagittal suture after surgical correction for metopic synostosis and
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intraoperative image of bone flap fixation.
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ACCEPTED MANUSCRIPT Table 1. Data extraction form Study characteristics Study name First author Published year
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Institution Patient number Kinds of primary craniosynostosis
Sagittal, bicoronal, unicoronal, metopic and lambdoid synostosis Routine image follow up (x-ray, CT scan)
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Time of primary surgery Before 6 months Kinds of surgery
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After 6 months Open craniectomy with/without cranial vault remodeling Open craniectomy with DO Endoscopic assisted Spring assisted
Presence of manipulated normal suture during surgery Kinds of SCS
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SCS number and incidence
Type of SCS Iatrogenic SCS Idiopathic SCS
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Sagittal, bicoronal, unicoronal, metopic and lambdoid SCS
Associated symptom of SCS
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Time interval to develop the SCS
Rate of secondary operation for correction of SCS
CT; computed tomography; DO, distraction osteogenesis; SCS, secondary craniosynostosis.
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n (%)
Sex 14 (82.3)
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Male Female
3 (17.6)
Kinds of craniosynostosis
8 (47)
Bi-coronal
3 (17.6)
SC
Sagittal
Uni-coronal
5 (29.4)
1 (5.8)
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Metopic Time at primary surgery <6 months after birth
4 (23.5)
>6 months after birth
13 (76.4)
Kinds of surgery
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Open craniectomy with cranial vault remodeling
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Open craniectomy and distraction osteogenesis
15 (88.2) 2 (11.7)
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Table 3. Presence of manipulated normal patent sutures and development of secondary craniosynostosis (SCS). Procedure for craniosynostosis correction
Kinds of primary synostosis
Location of normal suture
1
Sagittal
Modified pi craniectomy with barrel stave osteotomies
2
Sagittal
Modified pi craniectomy with barrel stave osteotomies
3
Sagittal
Modified pi craniectomy with barrel stave osteotomies
4
Sagittal
5
manipulated
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Patient no.
Origin iatrogenic SCS
of
Origin of idiopathic SCS
Uni-coronal
-
Bi-coronal
Bi-coronal
-
Bi-coronal
Uni-coronal
-
Modified pi craniectomy with barrel stave osteotomies
Bi-coronal
Bi-coronal
-
Sagittal
Modified pi craniectomy with barrel stave osteotomies
Bi-coronal
Bi-coronal
-
6
Sagittal
Modified pi craniectomy with barrel stave osteotomies
Bi-coronal
Bi-coronal
-
7
Sagittal
Modified pi craniectomy with barrel stave osteotomies
Bi-coronal
Bi-coronal
-
8
Sagittal
Modified pi craniectomy with barrel stave osteotomies
Bi-coronal
Bi-coronal
-
9
Bi-coronal
Fronto-orbital advancement with bone flap transposition
Partial sagittal
Partial sagittal
-
Bi-coronal
Fronto-orbital advancement with bone flap transposition
Partial sagittal
Partial sagittal
-
11
Bi-coronal
Fronto-orbital advancement with bone flap transposition
Partial sagittal
Partial sagittal
Sagittal
12
Uni-coronal
Fronto-orbital advancement with bone flap transposition
Contra-lateral uni-coronal
Uni-coronal
-
13
Uni-coronal
Fronto-orbital advancement with bone flap transposition
Contra-lateral uni-coronal
Uni-coronal
-
14
Uni-coronal
Contra-lateral uni-coronal
Uni-coronal
Partial sagittal
15
Uni-coronal
Distraction osteogenesis
None
-
-
16
Uni-coronal
Distraction osteogenesis
None
-
-
17
Metopic
Fronto-orbital advancement with bone flap transposition
Bi-coronal
Bi-coronal
Sagittal
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Fronto-orbital advancement with bone flap transposition
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10
SC
Bi-coronal
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Table 4
Age at primary surgery (mo)
Sex
11
Bi-coronal
Sagittal
M
10
14
Uni-coronal
Partial sagittal
F
13
17
Metopic
Sagittal
M
6
Cranial vault remodeling
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CT, computed tomography; F, female; M, male.
Kinds of surgery
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Location of SCS developed
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Patients Kinds of primary no. craniosynostosis
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Characteristics of patients with idiopathic secondary craniosynostosis (SCS). Interval to develop idiopathic SCS (CT) 12 months +
Cranial vault remodeling
+
Cranial vault remodeling
+
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Table 5. Characteristics of the 10 included studies.
Hudgins et al. (1997) Agrawal et al. (2006) Adamo et al. (2010) Seruya et al. (2013) Kuang et al. (2013) Esmaeli et al. (2014) Cetas et al. (2013)
Kinds of synostosis with SCS (n)
Presence of manipulated normal suture
Total SCS (%)
Iatrogenic SCS
Idiopathic SCS
Routine image follow-up
Retrospective
229
Open
Sagittal
Sagittal
No
24 (10.4%)
-
24 (10.4%)
Yes (x-ray)
Retrospective
87
Open
Sagittal
Sagittal
No
3 (3.4%)
-
3 (3.4%)
No
Retrospective
145
Open
All
3 (2.0%)
-
3 (2.0%)
N/S
121
Endoscopic
All
Case report
210
Open
All
Retrospective
42
Open
Retrospective
143
Retrospective
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Kinds of synostosis in total patients
Bicoronal(1), Metopic(2) Metopic(1) Sagittal(1) Metopic(1) Unicoronal(1)
No
2 (1.6%)
-
2 (1.6%)
N/S
Yes
2 (0.9%)
2 (0.9%)
2 (0.9%)
No
Sagittal
Sagittal
No
4 (9.5%)
4 (9.5%)
Yes (x-ray)
Open
Sagittal
Sagittal
Yes
1 (0.6%)
1 (0.6%)
-
No
47
Open
Sagittal
Sagittal
Yes
44 (93.6)*
44 (93.6%)
-
Yes (CT)
Retrospective
37
Open
Sagittal
Sagittal
Yes
33 (89%)†
33 (89%)
-
Yes (CT)
Case report
63
Open
Metopic
Metopic
Yes
2 (3.1%)
2 (3.1%)
-
No
Retrospective
81
Open
All
Sagittal
Yes
5 (6.1%)
5 (6.1%)
Yes
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Primary surgery
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Patient no.
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Arnaud et al. (2009) Marucci et al.
Design
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Study (year)
-
No
CT, computed tomography; N/S, not stated; SCS, secondary craniosynostosis. *This study reported the data of SCS incidence as right and left side in coronal and lambdoid suture each other, so total incidence of SCS cannot be extracted and the data in this table is the incidence of SCS in left lambdoid which is most highest value in that study. †This study reported additionally 5 (15%) patients with partial lambdoid synostosis.
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‡Among 5 SCS patients in this study, 2 patients were excluded because they had genetic mutation representing syndromic craniosynostosis.
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Table 6. Characteristics of iatrogenic secondary craniosynostosis (SCS). Manipulated normal patent sutures
Iatrogenic SCS (n, % of total patients in each study)
RI PT
Primary craniosynostosis
Adamo et al. (2010) Seruya et al. (2013)
Bi-coronal
Uni-coronal (n=1, %)
Contralateral coronal
Esmaeli et al. (2014) Hudgins et al. (1997)
Bi-coronal (n=2, 3.1%) Bi-coronal (n=1, 0.4%)
Hudgins et al. (1997)
Uni-coronal (n=1, 0.4%)
Kuang et al. (2013)
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Metopic (n=3, %)
Cetas et al. (2013)
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Bi-coronal and lambdoid
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Sagittal (n=83, %)
Bi-coronal (n=1, 0.6%) Uni-coronal (n=38, 81.9%) Uni-lambdoid (n=44, 93.6%) Bi-coronal (n=33, 89%) Lambdoid (n=5, 13.5%) Bi-coronal (n=5, 6.1%)
ACCEPTED MANUSCRIPT Table 7. Characteristics of 38 idiopathic secondary craniosynostosis (SCS) patients. Characteristics
N (%)
Location of SCS developed
Metopic Bi-coronal Uni-coronal Sagittal
4 (10.5%) 32 (84.2%) 1 (2.6%) 4 (10.5%)
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Pancranio Open craniectomy Endoscopic craniectomy <6 months
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Surgical method Age at the primary surgery
32 (84.2%) 1 (2.6%) 1 (2.6%)
RI PT
Kinds of primary craniosynostosis
Sagittal Bi-coronal Uni-coronal
>6 months Average time interval to develop the Before 18 months SCS postoperatively After 18 months
Associated symptoms and signs of IICP
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Rate of secondary operation for SCS
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IICP, increased intracranial pressure.
5 (13.1%) 15 (39.4%) 23 (60.5%)
Imaging diagnosis Craniofacial asymmetry Vertex bulging Decreased head circumference
28 (73.6%) 5 (13.1%) 3 (7.8%) 2 (5.2%)
Headache Papilledema IICP
9 (23.6%) 2 (5.2%) 7 (18.4%)
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Initial sign of idiopathic SCS
1 (2.6%) 36 (94.7%) 2 (5.2%) 33 (86.8%)
10 (26.3%)
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S1010-5182(17)30269-X
DOI:
10.1016/j.jcms.2017.08.009
Reference:
YJCMS 2754
To appear in:
Journal of Cranio-Maxillo-Facial Surgery
Received Date: 6 January 2017 Revised Date:
4 July 2017
Accepted Date: 11 August 2017
Please cite this article as: Kim SY, Shi H-J, Lim SY, Determining the fate of cranial sutures after surgical correction of non-syndromic craniosynostosis, Journal of Cranio-Maxillofacial Surgery (2017), doi: 10.1016/j.jcms.2017.08.009. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
ACCEPTED MANUSCRIPT Determining the fate of cranial sutures after surgical correction of non-syndromic craniosynostosis
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So Young Kim, M.D1., Hyung-Jin Shi2, So Young Lim, M.D3.
From the 1Department of Plastic and Reconstructive Surgery, Inje University Sanggye Paik
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hospital, Inje University School of Medicine, Seoul; the 3Department of Plastic Surgery,
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Samsung Medical Center, Sungkyunkwan University School of Medicine, Seoul; and Department of Neurosurgery, Samsung Medical Center, Sungkyunkwan University School
of Medicine, Seoul, Korea
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The authors have no conflicts of interest to declare.
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There were no funding sources for this study.
Corresponding author:
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So Young Lim, M.D., Ph.D.
Departments of Plastic and Reconstructive Surgery, Samsung Medical Center, Sungkyunkwan University School of Medicine, 81 Irwon-ro, Gangnam-gu, Seoul 06351, Korea. Tel.: +82-2-3410-2239; Fax: +82-2-3410-0036 E-mail: [email protected]
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Summary
2
Purpose: “Secondary craniosynostosis” (SCS) refers to a loss of sutures after corrective vault
4
reconstruction. There are no prior studies that comprehensively review SCS in various types
5
of non-syndromic craniosynostosis. We assessed idiopathic and iatrogenic SCS using 3-
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dimensional computed tomography (3D CT). We also performed a systematic review to
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estimate the overall incidence of SCS in each craniosynostosis type, and to characterize its
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clinical features.
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Materials and Methods: We retrospectively reviewed the CT images of patients who
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underwent surgical correction of craniosynostosis for all types of craniosynostosis between
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August 1999 and December 2015. A literature search of the Medline and Ovid databases was
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conducted in October 2016 using the search term “secondary craniosynostosis.”
13
Results: In our series, iatrogenic SCS was observed in all patients who had manipulated
14
normal patent sutures to variable extents. Three (17.6%) cases of idiopathic SCS developed
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on sagittal sutures, and were confirmed with a 12-month follow-up CT. In a pooled analysis
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of 10 articles, overall SCS developed in 123 of 1205 patients (10.2%). Iatrogenic SCS cases
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made up 87 of 1205 cases (7.2%), whereas 38 (3.1%) were idiopathic. Idiopathic SCS most
18
commonly developed at the bi-coronal suture (n = 32, 84.2%), followed by the sagittal suture
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(n = 4, 10.5%) and uni-coronal suture (n = 1, 2.6%).
20
Conclusion: This is the first review not only to describe SCS in all types of non-syndromic
21
craniosynostosis, but also to classify SCS into iatrogenic and idiopathic types based on the
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underlying pathogenesis.
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Keywords: secondary craniosynostosis, secondary synostosis
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INTRODUCTION
26
Regardless of the surgical method, the ideal result after synostosis correction is neo-
28
suture formation and maintenance of a craniectomy gap with minimal defects along the
29
craniotomy line. Unfortunately, however, several authors have reported synostosis of other
30
sutures that were previously patent before synostosis correction (Marucci et al., 2008; Arnaud
31
et al., 2009; Adamo and Pollack, 2010; Seruya et al., 2013). For example, a representative
32
case included newly developed coronal synostosis after extended sagittal strip craniectomy
33
with bilateral parietal wedge osteotomies for sagittal synostosis correction (Agrawal et al.,
34
2006; Cetas et al., 2013; Kuang et al., 2013; Seruya et al., 2013). In these studies, newly
35
developed synostoses were called secondary craniosynostosis (SCS). Secondary
36
craniosynostosis is defined as a closure in other sutures that were previously open after
37
corrective vault reconstruction. In children with syndromic synostosis, SCS occurred after the
38
primary surgery in 10.8-36.8% of cases due to an underlying genetic disorder frequently
39
related to the fibroblast growth factor receptor gene, which affects all parts of the cranium
40
(Esmaeli et al., 2014). In contrast, in patients with non-syndromic synostosis, the incidence of
41
SCS after primary surgical correction varied from a few case reports to more than 80%. We
42
hypothesize that the discrepancy in the incidence of SCS may be attributable to different
43
types of surgical treatment and the extent of surgery. In other words, it is possible that
44
previous studies reported mixed results by including both iatrogenic SCS caused by surgical
45
manipulation and idiopathic SCS considered as genuine SCS that developed postoperatively
46
despite non-surgical manipulation during primary surgery.
47
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In this study, we assessed all kinds of cranial suture patency following surgical correction
48
using follow-up 3-dimensional computed tomography (3D CT). We also identified both
49
iatrogenic and idiopathic SCS in 4 kinds of nonsyndromic synostoses. Furthermore, we 2
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performed a systematic review of previous literature regarding SCS to estimate the overall
51
incidence of SCS for each craniosynostosis type, and investigated the characteristics of
52
patients who might have had a bearing on both kinds of SCS.
54
MATERIALS AND METHODS
55
Patients and CT imaging for SCS
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After Institutional Review Board approval, a retrospective review was performed for
59
patients who underwent surgical correction for all kinds of craniosynostosis between August
60
1999 and December 2015. Patients were included if they underwent 3D craniofacial CT both
61
preoperatively and at least 12 months postoperatively to confirm the quality of re-ossification
62
in the craniectomy gap, and to evaluate overall cranial vault volume and morphology.
63
Patients were excluded if they had a syndromic craniosynostosis, did not have a postoperative
64
follow-up CT, or had a prior cranial vault reconstruction. Related demographics and surgical
65
data were reviewed from the medical records. The normal sutures that were manipulated
66
during surgery were identified through review of the intraoperative photographs. 3D CT scan
67
images not only provided an overview of which cranial sutures were patent versus closed, but
68
also revealed other signs of increased intracranial pressure, including copper beating. SCS
69
was identified by comparing pre- and postoperative CT images, and was classified into either
70
iatrogenic or idiopathic SCS. Iatrogenic SCS developed in the area of surgical manipulation,
71
whereas idiopathic SCS occurred in areas free of surgical manipulation.
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72 73
Surgical technique
74 3
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All surgical procedures were performed by our senior author and a neurosurgeon. We performed open osteotomy designs for synostosis correction, and fixation techniques with
77
resorbable plate osteosynthesis. Specifically, in early 2 cases around 2000, Biosorb (Bionx,
78
Tampere, Finland) plates were used, and then a variety of geometric plate and mesh panels
79
from several corporations, including Rapidsorb (Synthes, West Chester, PA, USA), Inion CPS
80
(Inion, Tampere, Finland), and LactoSorb (Walter Lorenz Surgical Inc, Jacksonville, FL),
81
were used and cut into multiple smaller elements as needed. For the surgical correction for
82
sagittal synostosis, we performed a modified pi craniectomy with barrel stave osteotomies of
83
the bi-temporal area. Bi-coronal sutures were manipulated with this procedure (Fig. 1). For
84
patients with bi-coronal/uni-coronal and metopic synostosis, fronto-orbital advancement with
85
or without transposition of the frontal bone flap was performed. For bi-coronal synostosis, the
86
anterior part of the sagittal suture was partially manipulated. In most cases of uni-coronal
87
synostosis, the previously patent contralateral coronal suture was manipulated (Fig. 2). In
88
metopic synostosis, bi-coronal sutures were involved in the surgical procedure. In a few cases,
89
distraction osteogenesis was used to focus on the areas of the skull with fused sutures in order
90
to minimize the extent of the procedure. Therefore, there were no manipulated normal patent
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sutures after distraction osteogenesis was complete. There were no cases of lambdoid
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synostosis in this series.
94 95 96
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Literature review of secondary craniosynostosis
A literature search of the Medline and Ovid databases was conducted in October 2016
97
using the search terms “secondary craniosynostosis,” “restenosis,” and “secondary operation.”
98
A manual search was also performed to identify additional, relevant papers. A total of 318
99
papers were obtained through this search. After excluding articles that were not related to 4
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101
reports that reflected the incidence of SCS were also included. Studies were excluded based
102
on predefined exclusion criteria (Fig. 3), which eventually yielded 10 papers for final analysis.
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The following data were extracted using a standardized data extraction form (Table 1). We
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reviewed the surgical methods established in each paper. We classified SCS based on 2 types,
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iatrogenic and idiopathic, according to the aforementioned definition. In addition, we
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investigated routine follow-up images (x-ray or CT scans). A pooled analysis of SCS
107
incidence was performed. Chi-square or Fisher exact, paired-samples t, and Mann-Whitney U
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tests were conducted. A p-values <0.05 were considered statistically significant. All statistical
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analyses were conducted using SPSS 19.0 (SPSS Inc., Chicago, IL, USA).
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RESULTS
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Clinical results
In our series, after excluding 3 patients due to a lack of postoperative CT and follow-up
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loss, 17 patients (14 boys and 3 girls) met inclusion criteria. There were 4 types of
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craniosynostosis, including 8 sagittal, 3 bi-coronal, 5 uni-coronal and 1 metopic synostosis.
118
Mean age at the time of surgery was 18 months (range, 6 months to 10 years), and 4 (23.5%)
119
patients underwent primary synostosis correction before 6 months of age. Most patients
120
underwent open craniectomies with cranial vault remodeling, and fixation using resorbable
121
sutural osteosynthesis. Distraction osteogenesis was performed in 2 patients with uni-coronal
122
synostosis (Table 2). Except for 2 cases of distraction osteogenesis, manipulated normal
123
patent sutures were confirmed in 15 patients intraoperatively. Table 3 details the involvement
124
of normal patent sutures for each patient. There were no major or permanent complications of
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surgery, including cerebrospinal fluid (CSF) leak, brain injury, infection, or hematoma. The mean follow-up period was 5.5 years. On postoperative CT scan (a minimum of 12 months to 10 years after surgery), iatrogenic SCS was observed in all patients who had
128
manipulated normal patent sutures. The extent of this iatrogenic SCS varied across patients.
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Among 9 patients with bi-coronal manipulation (8 in sagittal and 1 in metopic synostosis),
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uni-coronal SCS developed in 2 patients, and bi-coronal SCS in 7 (Fig. 4). All 3 patients with
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contralateral coronal manipulation for the correction of uni-coronal synostosis developed
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partial iatrogenic contralateral coronal SCS. Among 3 patients with partial sagittal
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manipulation for surgical correction of bicoronal synostosis, partial sagittal SCS developed in
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2 patients, whereas 1 patient developed complete sagittal SCS (even in the non-manipulated
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portion of the sagittal suture) (Fig. 5). Including this complete sagittal SCS, 3 cases (17.6%)
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of idiopathic SCS developed on the sagittal suture in this study, as confirmed with 12-month
137
follow-up CT (including 1 metopic shown in Fig. 6, and 1 uni-coronal and 1 bi-coronal
138
synostosis). Detailed patient-related characteristics and time to develop idiopathic SCS are
139
shown in Table 4. None of these 3 patients showed clinical signs of increased ICH and
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underwent a secondary operation. There was no evidence of iatrogenic or idiopathic lambdoid
141
SCS in this study.
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Systematic review of literature with pooled analysis
Overall SCS incidence by craniosynostosis type
146
Ten papers representing a total of 1205 patients were included in this SCS incidence
147
review (Hudgins et al., 1998; Agrawal et al., 2006; Marucci et al., 2008; Arnaud et al., 2009;
148
Adamo and Pollack, 2010; Cetas et al., 2013; Kuang et al., 2013; Seruya et al., 2013; Esmaeli
149
et al., 2014; Yarbrough et al., 2014). Six of the 10 papers, representing 585 patients, described 6
ACCEPTED MANUSCRIPT sagittal SCS synostosis, and 1 paper included metopic synostosis. In contrast, the remaining 3
151
papers described all different kinds of craniosynostosis. Most studies described open
152
craniectomy with cranial vault remodeling, except 1 study, which used an endoscopic assisted
153
procedure. However, synostosis correction extensiveness varied across the studies. Overall,
154
SCS developed in 123 of 1205 patients (10.2%). In all, 87 of these cases were iatrogenic
155
(7.2%), whereas 38 were idiopathic (3.1%). Among all patients, 2 presented with both
156
iatrogenic and idiopathic SCS. (Hudgins et al., 1998) Regarding routine image follow-up, 4
157
papers, representing 355 (29.4%) patients, described postoperative image follow-up for all
158
patients, whereas 5 other papers did not. Total SCS incidence in the routine image follow-up
159
group was significantly higher than that described in papers that did not report postoperative
160
imaging (p = 0.01).
M AN U
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150
161
163
Iatrogenic SCS
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162
Among 726 patients who had manipulated normal patent sutures, 87 (11.9%) developed iatrogenic SCS. In 4 studies reporting sagittal synostosis correction, bi-coronal and lambdoid
165
sutures were easily manipulated to various extents. There were controversial results with
166
regard to SCS in the lambdoid suture. Seruya et al. performed extensive manipulation of
167
normal lambdoid sutures, including craniectomy of the sutural site and sutural movement,
168
and found that 93.6% of patients developed iatrogenic SCS in uni-lambdoid sutures. In
169
contrast, Kuang et al. conducted less extensive surgery at the lambdoid suture (compared to
170
that performed by Seruya et al.), and found that only 13.5% of patients developed lambdoid
171
SCS. In a pooled analysis of these 2 studies, the extensiveness of the surgical manipulation at
172
the lambdoid suture was significantly associated with the incidence of iatrogenic lambdoid
173
SCS (odds ratio = 93.86, 95% confidence interval 20.9−421.5, p = 0.00). The 2 remaining
174
studies did not report use of image work-ups in their patient groups, and found 0.6% and 6.1%
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7
ACCEPTED MANUSCRIPT iatrogenic SCS at the coronal sutures, respectively. This low iatrogenic SCS incidence was
176
also found in other primary craniosynostosis papers that did not report routine imaging
177
follow-up (Table 5). After the correction of metopic synostosis, bi-coronal iatrogenic SCS
178
was reported as 3 patients in 2 studies (Hudgins et al., 1998; Esmaeli et al., 2014). With the
179
exception of 2 patients who had both iatrogenic and idiopathic SCS, 9 patients with
180
iatrogenic SCS (10.3%) underwent secondary operations for SCS correction.
RI PT
175
183
Idiopathic SCS
Among a total of 38 patients who developed idiopathic SCS, 32 (84.2%) developed SCS
M AN U
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SC
181
in the primary sagittal synostosis, whereas in 4 (10.5%) cases SCS occurred in the primary
185
metopic synostosis. The most common suture in which idiopathic SCS developed was bi-
186
coronal (n = 32, 84.2%), followed by sagittal (n = 4, 10.5%), and uni-coronal (n = 1, 2.6%).
187
There was 1 uni-coronal synostosis patient who developed secondary pancraniosynostosis
188
postoperatively. We did not find any evidence in the literature for isolated idiopathic SCS in
189
lambdoid sutures except the aforementioned secondary pancraniosynostosis. Regarding
190
surgery-related factors, most patients with idiopathic SCS (n = 36, 94.7%) underwent open
191
craniectomies. However, 2 patients who underwent endoscopic craniectomies also developed
192
idiopathic SCS. A total of 33 (86.8%) idiopathic SCS patients underwent primary synostosis
193
correction before 6 months of age. In all, 15 (39.4%) idiopathic SCS cases were detected
194
before 18 months postoperatively based on various signs and symptoms. In particular, 2
195
studies (representing 28 idiopathic SCS cases) performed postoperative imaging follow-up; in
196
these studies, most cases of idiopathic SCS were diagnosed based on imaging. With the
197
exception of 28 cases, there were postoperative head shape deformities in most cases. These
198
changes were the initial suspicion signs for SCS. Signs and symptoms of increased
199
intracranial pressure (IICP) such as headache and papilledema developed in 18 idiopathic
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ACCEPTED MANUSCRIPT 200
SCS patients. Finally, 10 (26.3%) of all patients with idiopathic SCS underwent secondary
201
surgeries with the goal of decompressing IICP, or correcting head morphology (Table 6).
202 203 204 205
Pathogenesis and characteristics of iatrogenic SCS
SC
206
RI PT
DISCUSSION
There are several possible hypotheses regarding the mechanism underlying iatrogenic
208
SCS. The most plausible hypothesis suggests that SCS forms when normal patent sutures
209
separate from the underlying dura. Usually, surgery or other intervention disrupts normal
210
suture anatomy during cranial vault reconstruction. This manipulation interrupts the signaling
211
mechanism in the dura that maintains normal patent sutures, and weakens potential
212
stimulation of calvarial growth by pulsatile forces from the brain (Seruya et al., 2013).
213
Ultimately, this leads to SCS development (Arnaud et al., 2009; Adamo and Pollack, 2010;
214
Cetas et al., 2013). According to this study, the dura detachment theory is acceptable because
215
most manipulated normal patent sutures in our patients eventually closed, although the extent
216
of closure varied. Furthermore, the result of pooled analysis revealed that the more extensive
217
surgical manipulation of normal sutures including separation from the underlying dura,
218
fracture or craniectomy, and relocation of normal sutures increased the incidence of
219
iatrogenic SCS in 2 follow-up studies representing 49 cases of iatrogenic lambdoid SCS (p <
220
0.001) (Kuang et al., 2013; Seruya et al., 2013). This fact supports the hypothesis that it arises
221
from the detachment of normal sutures from the underlying dura, premature fusion of normal
222
sutures, and interruption of normal suture growth.
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223
Regarding the influence of fixation technique on iatrogenic SCS, with the recent advent
224
of the resorbable osteosynthesis system, a variety of plates and meshes have become widely 9
ACCEPTED MANUSCRIPT used for cranial vault reshaping instead of metallic wire or titanium plates. Based on the
226
concept that these biodegradable osteosynthesis materials form a membrane that guides bone
227
regeneration, we usually cover the major part of osteotomy lines with several meshes to
228
further stabilize bone fragments and provoke bone regeneration between the bony gaps as
229
previously reported in the literature. Interestingly, we observed that most patients who
230
received extensive osteosynthesis with meshes showed complete iatrogenic SCS, whereas in
231
2 patients who received only limited osteosynthesis with absorbable plates, partial iatrogenic
232
SCS was reported. Although an analysis by fixation technique and iatrogenic SCS could not
233
be performed because of the lack of specific data on fixation technique type used for
234
osteosynthesis in the literature review and the small sample size of the present study, we
235
assumed that extensive fixation techniques using mesh could be a risk factor for iatrogenic
236
SCS; further studies related to this issue are required in the future.
M AN U
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225
The literature is not conclusive and demonstrates conflicting data regarding whether
238
certain suture types are more prone to develop iatrogenic SCS if a normal suture is insulted.
239
Seruya et al. reported that lambdoid sutures have a higher propensity to develop iatrogenic
240
SCS than do coronal sutures. In contrast, Kuang et al. found that iatrogenic SCS developed
241
more commonly at the coronal suture than it did at the lambdoid suture (Kuang et al., 2013;
242
Seruya et al., 2013). It is difficult to determine which suture is more likely to develop
243
iatrogenic SCS by simply comparing the incidence of iatrogenic SCS. There are several
244
important factors that should be considered, including the architectural differences between
245
sutures. In addition, it is important to consider the differential degree of surgical manipulation
246
at each suture. Therefore, a controlled study that considers these factors is needed to further
247
investigate the incidence of iatrogenic SCS.
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248
Interestingly, the rate of secondary surgeries for the correction of iatrogenic SCS was
249
approximately 10%. This was much lower than that for idiopathic SCS (26.3%) in the pooled 10
ACCEPTED MANUSCRIPT analysis despite a higher incidence of iatrogenic SCS (7.2%) than idiopathic SCS (3.1%). In
251
our experience, even if iatrogenic SCS developed at 100% of manipulated suture sites,
252
normal growth was frequently observed, and secondary corrective surgeries were not often
253
required. These findings may be attributable to the craniectomy gap adjacent to the fused
254
suture, and the role it played in maintaining the intracranial space and minimizing the effect
255
of iatrogenic SCS.
256 257
Pathogenesis and characteristics of idiopathic SCS
259
M AN U
258
SC
RI PT
250
There are several, controversial theories regarding the pathogenesis of idiopathic SCS. One hypothesis involves intrinsic suture pathology and an abnormal signal from the cranial
261
base that spreads to the calvarium based on genetic or metabolic causes (Moss, 1975).
262
Therefore, when the underlying abnormal cranial base remains, either recurrent synostosis
263
may develop after correction, or late onset SCS may occur in a previously open suture. This
264
theory seems to apply to syndromic craniosynostosis because of the involvement of the
265
midface and the high incidence of both recurrent synostosis and SCS. This hypothesis also
266
explains some, but not all, cases of idiopathic SCS. We suspect that there is compensatory
267
brain growth toward the area of increased dead space, which is caused by primary synostosis
268
correction. An abrupt decrease and delay in brain growth perpendicular to the primary
269
synostosis may subsequently cause premature suture fusion. In particular, after correction of
270
bi-coronal synostosis, during which the antero-posterior (AP) dimension of the cranial vault
271
was increased, there was delayed compensatory internal brain growth in the bi-temporal
272
direction. Subsequently, sagittal idiopathic SCS could develop. A similar concept has been
273
suggested in the literature describing post−ventricular shunting SCS. Decreased intracranial
274
volume resulted in over-drainage of the cerebrospinal fluid. Alternatively, delayed internal
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ACCEPTED MANUSCRIPT brain growth after shunting could lead to collapse of the cranial vault with apposition, or
276
overriding sutures and subsequent synostosis (Shuster et al., 1995; Park et al., 2009). In our
277
study, idiopathic SCS developed in the sagittal suture in 3 patients who underwent surgery to
278
widen the AP dimension. We did not detect idiopathic SCS in the bi-coronal suture because of
279
frequent surgical manipulation of this suture during bi-temporal widening surgery. However,
280
pooled analysis demonstrated 32 (84.2%) cases of idiopathic SCS in the bi-coronal suture in
281
patients who underwent all bi-temporal widening surgery for sagittal synostosis correction.
282
There may be few or no cases of idiopathic SCS after distraction osteogenesis, during which
283
the cranium is gradually expanded postoperatively, allowing a slow expansion of the brain
284
and less dead space between the brain and cranium. There are currently no studies addressing
285
the development of idiopathic SCS after DO procedures for the correction of non-syndromic
286
synostosis. Therefore, further study in this area is needed.
M AN U
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275
288 289
TE D
287
SCS identification on imaging follow-up
With the advancement of 3D photography in recent years, the use of follow-up CT
291
imaging during postoperative periods has come under increasing scrutiny. Because most of
292
the reasons for a secondary surgery were poor appearance and intracranial pressure increase,
293
CT may be likely to be abandoned in many craniofacial centers for follow-up. Of course, we
294
agree that unnecessary radiation and examinations should be avoided; however, it is not
295
possible to identify iatrogenic and idiopathic SCS without documentation of suture patency
296
using preoperative and postoperative imaging. According to pooled analysis, 2 studies that
297
reported pre- and postoperative CT scans found that more than 80% of patients who
298
underwent coronal suture manipulation developed iatrogenic SCS (Kuang et al., 2013; Seruya
299
et al., 2013). In addition, of all idiopathic SCS cases, 70% were diagnosed through routine
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ACCEPTED MANUSCRIPT imaging follow-up. The detection of idiopathic SCS is particularly important with regard to
301
prognosis; 30% of idiopathic SCS cases required subsequent corrective surgeries in the
302
pooled analysis. Fortunately, there are now low-radiation techniques that are available. We
303
advocate a protocol of prospective routine radiographic follow-up with low-dose radiation
304
after primary cranial vault repair for non-syndromic synostosis, and this ought to be used
305
judiciously to provide pertinent information for patient care. However, there is still no
306
consensus regarding how often and for how long radiologic follow-up should be performed.
307
The interval and period of imaging follow-up should be determined based on time to develop
308
SCS. According to the aforementioned hypothesis, idiopathic SCS develops early and is
309
sensitive to volume changes in the intracranial environment. In this study, idiopathic SCS was
310
discovered in 3 patients at postoperative CT follow-up before 18 months, which is the period
311
of postoperative cranial stabilization, as suggested by Barone and Jimenez et al. (2011)
312
However, the pooled analysis data revealed a similar incidence of idiopathic SCS diagnosed
313
before and after 18 months. This discrepancy may be explained by the fact that some prior
314
studies used routine imaging, whereas others did not. Further objective studies are needed to
315
clarify these findings.
SC
M AN U
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EP
316
RI PT
300
Our findings should be interpreted in the light of several limitations. Although we tried to include only non-syndromic synostosis, there is a slight possibility that syndromic patients
318
were not totally excluded from the pooled analysis. Furthermore, large prospective studies or
319
systematic reviews are required to substantiate our conclusions.
320 321 322
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CONCLUSION To the best of our knowledge, this is the first study that not only characterizes SCS for all
323
types of non-syndromic craniosynostosis, but also specifically classifies SCS into iatrogenic
324
and idiopathic types. The results of this study provide insight into the fate of sutures in 13
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patients with non-syndromic synostosis and subsequent synostosis correction.
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REFERENCES
327
Adamo MA, Pollack IF: A single-center experience with symptomatic postoperative calvarial
329
growth restriction after extended strip craniectomy for sagittal craniosynostosis. J
330
Neurosurg Pediatr 5: 131-135, 2010
332 333
Agrawal D, Steinbok P, Cochrane DD: Reformation of the sagittal suture following surgery for isolated sagittal craniosynostosis. J Neurosurg 105: 115-117, 2006
SC
331
RI PT
328
Arnaud E, Capon-Degardin N, Michienzi J, Di Rocco F, Renier D: Scaphocephaly part II: secondary coronal synostosis after scaphocephalic surgical correction. J Craniofac Surg
335
20 Suppl 2: 1843-1850, 2009
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Cetas JS, Nasseri M, Saedi T, Kuang AA, Selden NR: Delayed intracranial hypertension after
337
cranial vault remodeling for nonsyndromic single-suture synostosis. J Neurosurg
338
Pediatr 11: 661-666, 2013
340 341
Esmaeli A, Nejat F, Habibi Z, El Khashab M: Secondary bicoronal synostosis after metopic craniosynostosis surgical reconstruction. J Pediatr Neurosci 9: 242-245, 2014 Hudgins RJ, Cohen SR, Burstein FD, Boydston WR: Multiple suture synostosis and
EP
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TE D
336
increased intracranial pressure following repair of single suture, nonsyndromal
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craniosynostosis. Cleft Palate Craniofac J 35: 167-172, 1998
344
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Kuang AA, Jenq T, Didier R, Moneta L, Bardo D, Selden NR: Benign radiographic coronal
345
synostosis after sagittal synostosis repair. J Craniofac Surg 24: 937-940, 2013
346
Marucci DD, Johnston CP, Anslow P, Jayamohan J, Richards PG, Wilkie AO, et al:
347
Implications of a vertex bulge following modified strip craniectomy for sagittal
348
synostosis. Plast Reconstr Surg 122: 217-224, 2008
349
Moss ML: Functional anatomy of cranial synostosis. Childs Brain 1: 22-33, 1975
350
Park DH, Chung J, Yoon SH: The role of distraction osteogenesis in children with secondary 15
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craniosynostosis after shunt operation in early infancy. Pediatr Neurosurg 45: 437-445,
352
2009
353
Ridgway EB, Berry-Candelario J, Grondin RT, Rogers GF, Proctor MR: The management of sagittal synostosis using endoscopic suturectomy and postoperative helmet therapy. J
355
Neurosurg Pediatr 7: 620-626, 2011
356
RI PT
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Seruya M, Tan SY, Wray AC, Penington AJ, Greensmith AL, Holmes AD, et al: Total cranial vault remodeling for isolated sagittal synostosis: part I. Postoperative cranial suture
358
patency. Plast Reconstr Surg 132: 602e-610e, 2013
360 361
Shuster BA, Norbash AM, Schendel SA: Correction of scaphocephaly secondary to
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ventricular shunting procedures. Plast Reconstr Surg 96: 1012-1019, 1995 Yarbrough CK, Smyth MD, Holekamp TF, Ranalli NJ, Huang AH, Patel KB, et al: Delayed synostoses of uninvolved sutures after surgical treatment of nonsyndromic
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craniosynostosis. J Craniofac Surg 25: 119-123, 2014
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Figure 1. Manipulation of bi-coronal suture during surgical correction of sagittal synostosis.
366
Figure 2. Manipulation of contralateral coronal suture during surgical correction of uni-
368
coronal synostosis.
RI PT
367
369
Figure 3. Study attrition diagram.
SC
370 371
Figure 4. Preoperative 3D-CT image of sagittal synostosis (right) and iatrogenic secondary
373
synostosis developed in bi-coronal suture after sagittal synostosis correction (left).
M AN U
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374
Figure 5. Preoperative (right) and postoperative (left) 3D-CT image of patient number 11 that
376
revealed idiopathic secondary synostosis in the sagittal suture after surgical correction of bi-
377
coronal synostosis.
378
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Figure 6. Preoperative (right), postoperative (middle) 3D-CT, and intraoperative (left) image
380
of patient number 17 who showed iatrogenic secondary bi-coronal synostosis and idiopathic
381
secondary synostosis in the sagittal suture after surgical correction for metopic synostosis and
382
intraoperative image of bone flap fixation.
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ACCEPTED MANUSCRIPT Table 1. Data extraction form Study characteristics Study name First author Published year
RI PT
Institution Patient number Kinds of primary craniosynostosis
Sagittal, bicoronal, unicoronal, metopic and lambdoid synostosis Routine image follow up (x-ray, CT scan)
SC
Time of primary surgery Before 6 months Kinds of surgery
M AN U
After 6 months Open craniectomy with/without cranial vault remodeling Open craniectomy with DO Endoscopic assisted Spring assisted
Presence of manipulated normal suture during surgery Kinds of SCS
TE D
SCS number and incidence
Type of SCS Iatrogenic SCS Idiopathic SCS
EP
Sagittal, bicoronal, unicoronal, metopic and lambdoid SCS
Associated symptom of SCS
AC C
Time interval to develop the SCS
Rate of secondary operation for correction of SCS
CT; computed tomography; DO, distraction osteogenesis; SCS, secondary craniosynostosis.
ACCEPTED MANUSCRIPT Table 2 Patient demographics and surgery-related data. Variable
n (%)
Sex 14 (82.3)
RI PT
Male Female
3 (17.6)
Kinds of craniosynostosis
8 (47)
Bi-coronal
3 (17.6)
SC
Sagittal
Uni-coronal
5 (29.4)
1 (5.8)
M AN U
Metopic Time at primary surgery <6 months after birth
4 (23.5)
>6 months after birth
13 (76.4)
Kinds of surgery
TE D
Open craniectomy with cranial vault remodeling
AC C
EP
Open craniectomy and distraction osteogenesis
15 (88.2) 2 (11.7)
ACCEPTED MANUSCRIPT
Table 3. Presence of manipulated normal patent sutures and development of secondary craniosynostosis (SCS). Procedure for craniosynostosis correction
Kinds of primary synostosis
Location of normal suture
1
Sagittal
Modified pi craniectomy with barrel stave osteotomies
2
Sagittal
Modified pi craniectomy with barrel stave osteotomies
3
Sagittal
Modified pi craniectomy with barrel stave osteotomies
4
Sagittal
5
manipulated
RI PT
Patient no.
Origin iatrogenic SCS
of
Origin of idiopathic SCS
Uni-coronal
-
Bi-coronal
Bi-coronal
-
Bi-coronal
Uni-coronal
-
Modified pi craniectomy with barrel stave osteotomies
Bi-coronal
Bi-coronal
-
Sagittal
Modified pi craniectomy with barrel stave osteotomies
Bi-coronal
Bi-coronal
-
6
Sagittal
Modified pi craniectomy with barrel stave osteotomies
Bi-coronal
Bi-coronal
-
7
Sagittal
Modified pi craniectomy with barrel stave osteotomies
Bi-coronal
Bi-coronal
-
8
Sagittal
Modified pi craniectomy with barrel stave osteotomies
Bi-coronal
Bi-coronal
-
9
Bi-coronal
Fronto-orbital advancement with bone flap transposition
Partial sagittal
Partial sagittal
-
Bi-coronal
Fronto-orbital advancement with bone flap transposition
Partial sagittal
Partial sagittal
-
11
Bi-coronal
Fronto-orbital advancement with bone flap transposition
Partial sagittal
Partial sagittal
Sagittal
12
Uni-coronal
Fronto-orbital advancement with bone flap transposition
Contra-lateral uni-coronal
Uni-coronal
-
13
Uni-coronal
Fronto-orbital advancement with bone flap transposition
Contra-lateral uni-coronal
Uni-coronal
-
14
Uni-coronal
Contra-lateral uni-coronal
Uni-coronal
Partial sagittal
15
Uni-coronal
Distraction osteogenesis
None
-
-
16
Uni-coronal
Distraction osteogenesis
None
-
-
17
Metopic
Fronto-orbital advancement with bone flap transposition
Bi-coronal
Bi-coronal
Sagittal
M AN U
TE D
EP
Fronto-orbital advancement with bone flap transposition
AC C
10
SC
Bi-coronal
ACCEPTED MANUSCRIPT
Table 4
Age at primary surgery (mo)
Sex
11
Bi-coronal
Sagittal
M
10
14
Uni-coronal
Partial sagittal
F
13
17
Metopic
Sagittal
M
6
Cranial vault remodeling
AC C
EP
TE D
CT, computed tomography; F, female; M, male.
Kinds of surgery
SC
Location of SCS developed
M AN U
Patients Kinds of primary no. craniosynostosis
RI PT
Characteristics of patients with idiopathic secondary craniosynostosis (SCS). Interval to develop idiopathic SCS (CT) 12 months +
Cranial vault remodeling
+
Cranial vault remodeling
+
ACCEPTED MANUSCRIPT
Table 5. Characteristics of the 10 included studies.
Hudgins et al. (1997) Agrawal et al. (2006) Adamo et al. (2010) Seruya et al. (2013) Kuang et al. (2013) Esmaeli et al. (2014) Cetas et al. (2013)
Kinds of synostosis with SCS (n)
Presence of manipulated normal suture
Total SCS (%)
Iatrogenic SCS
Idiopathic SCS
Routine image follow-up
Retrospective
229
Open
Sagittal
Sagittal
No
24 (10.4%)
-
24 (10.4%)
Yes (x-ray)
Retrospective
87
Open
Sagittal
Sagittal
No
3 (3.4%)
-
3 (3.4%)
No
Retrospective
145
Open
All
3 (2.0%)
-
3 (2.0%)
N/S
121
Endoscopic
All
Case report
210
Open
All
Retrospective
42
Open
Retrospective
143
Retrospective
SC
RI PT
Kinds of synostosis in total patients
Bicoronal(1), Metopic(2) Metopic(1) Sagittal(1) Metopic(1) Unicoronal(1)
No
2 (1.6%)
-
2 (1.6%)
N/S
Yes
2 (0.9%)
2 (0.9%)
2 (0.9%)
No
Sagittal
Sagittal
No
4 (9.5%)
4 (9.5%)
Yes (x-ray)
Open
Sagittal
Sagittal
Yes
1 (0.6%)
1 (0.6%)
-
No
47
Open
Sagittal
Sagittal
Yes
44 (93.6)*
44 (93.6%)
-
Yes (CT)
Retrospective
37
Open
Sagittal
Sagittal
Yes
33 (89%)†
33 (89%)
-
Yes (CT)
Case report
63
Open
Metopic
Metopic
Yes
2 (3.1%)
2 (3.1%)
-
No
Retrospective
81
Open
All
Sagittal
Yes
5 (6.1%)
5 (6.1%)
Yes
M AN U
Yarbrough et al. (2014)
Primary surgery
TE D
(2008)
Patient no.
EP
Arnaud et al. (2009) Marucci et al.
Design
AC C
Study (year)
-
No
CT, computed tomography; N/S, not stated; SCS, secondary craniosynostosis. *This study reported the data of SCS incidence as right and left side in coronal and lambdoid suture each other, so total incidence of SCS cannot be extracted and the data in this table is the incidence of SCS in left lambdoid which is most highest value in that study. †This study reported additionally 5 (15%) patients with partial lambdoid synostosis.
ACCEPTED MANUSCRIPT
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‡Among 5 SCS patients in this study, 2 patients were excluded because they had genetic mutation representing syndromic craniosynostosis.
ACCEPTED MANUSCRIPT
Table 6. Characteristics of iatrogenic secondary craniosynostosis (SCS). Manipulated normal patent sutures
Iatrogenic SCS (n, % of total patients in each study)
RI PT
Primary craniosynostosis
Adamo et al. (2010) Seruya et al. (2013)
Bi-coronal
Uni-coronal (n=1, %)
Contralateral coronal
Esmaeli et al. (2014) Hudgins et al. (1997)
Bi-coronal (n=2, 3.1%) Bi-coronal (n=1, 0.4%)
Hudgins et al. (1997)
Uni-coronal (n=1, 0.4%)
Kuang et al. (2013)
AC C
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Metopic (n=3, %)
Cetas et al. (2013)
SC
Bi-coronal and lambdoid
M AN U
Sagittal (n=83, %)
Bi-coronal (n=1, 0.6%) Uni-coronal (n=38, 81.9%) Uni-lambdoid (n=44, 93.6%) Bi-coronal (n=33, 89%) Lambdoid (n=5, 13.5%) Bi-coronal (n=5, 6.1%)
ACCEPTED MANUSCRIPT Table 7. Characteristics of 38 idiopathic secondary craniosynostosis (SCS) patients. Characteristics
N (%)
Location of SCS developed
Metopic Bi-coronal Uni-coronal Sagittal
4 (10.5%) 32 (84.2%) 1 (2.6%) 4 (10.5%)
SC
Pancranio Open craniectomy Endoscopic craniectomy <6 months
M AN U
Surgical method Age at the primary surgery
32 (84.2%) 1 (2.6%) 1 (2.6%)
RI PT
Kinds of primary craniosynostosis
Sagittal Bi-coronal Uni-coronal
>6 months Average time interval to develop the Before 18 months SCS postoperatively After 18 months
Associated symptoms and signs of IICP
EP
Rate of secondary operation for SCS
AC C
IICP, increased intracranial pressure.
5 (13.1%) 15 (39.4%) 23 (60.5%)
Imaging diagnosis Craniofacial asymmetry Vertex bulging Decreased head circumference
28 (73.6%) 5 (13.1%) 3 (7.8%) 2 (5.2%)
Headache Papilledema IICP
9 (23.6%) 2 (5.2%) 7 (18.4%)
TE D
Initial sign of idiopathic SCS
1 (2.6%) 36 (94.7%) 2 (5.2%) 33 (86.8%)
10 (26.3%)
AC C
EP
TE D
M AN U
SC
RI PT
ACCEPTED MANUSCRIPT
AC C
EP
TE D
M AN U
SC
RI PT
ACCEPTED MANUSCRIPT
AC C
EP
TE D
M AN U
SC
RI PT
ACCEPTED MANUSCRIPT
AC C
EP
TE D
M AN U
SC
RI PT
ACCEPTED MANUSCRIPT
AC C
EP
TE D
M AN U
SC
RI PT
ACCEPTED MANUSCRIPT
AC C
EP
TE D
M AN U
SC
RI PT
ACCEPTED MANUSCRIPT