Outcome Analysis of Helmet Therapy for Positional Plagiocephaly Using a Three-Dimensional Surface Scanning Laser

Success Rates of Cranial Remolding Orthosis Treatment of Plagiocephaly Based on Initial Presentation

Introduction

Cranial remolding orthoses (CROs) are used to treat deformational plagiocephaly. Treatment outcomes vary widely depending on treatment timing and severity of the deformity. The relative impact of these factors on success rates is not well known.

Objective

This study aimed to quantify success rates of CRO treatment, based on age at initiation of treatment and the severity of cranial deformity.

Study Design

This is a retrospective cohort study of infants treated for positional plagiocephaly with a CRO.

Methods

A total of 300 infants with deformational plagiocephaly who were treated with a CRO were categorized into four groups by corrected age at initiation of orthotic treatment (<22 weeks, 22–25 weeks, 26–30 weeks, and >30 weeks) and into four groups by severity of their deformity (initial cranial vault asymmetry of 6–9 mm, 10–12 mm, 13–16 mm, and 17+ mm). Success rates were compared across the groups. A successful outcome was defined as achieving a final cranial vault asymmetry of 5 mm or less.

Results

The overall success rate for CRO treatment was 75%. However, success rates among the groups varied from 6% to 98%, depending on the severity and the age at initiation. Severity had a more significant effect on success rates than age at initiation. The age at initiation became more influential in determining the likelihood of success when the infant's deformity was severe.

Conclusions

The likelihood of achieving a successful treatment outcome with a CRO varies greatly depending on the severity of the deformity and corrected age at initiation of treatment, with severity having the greater impact.

Clinical Relevance

This study provides clinicians with treatment outcomes categorized by severity and corrected age at initiation to aid in setting appropriate expectations for treatment outcomes.

Helmet Therapy for Positional Plagiocephaly: A Systematic Review of the Tools Used to Diagnose, Offer Treatment Recommendations, and Assess Treatment Outcomes of the Condition

BACKGROUND

Positional plagiocephaly (PP) is an asymmetric deformation of the skull as a consequence of external forces acting on a normal and pliable skull. The prevalence of PP ranges between 19.6% and 46.6%. Treatment options for PP include repositioning, physical therapy, and helmet orthoses. Consensus regarding the treatment of PP remains elusive due to the condition's imprecise natural history, dissimilar diagnostic strategies, and unreliable data asserting treatments' efficacy. Our aim was to conduct a systematic review of the tools used to diagnose, suggest treatment strategies, and assess outcomes for PP.

METHODS

We used the Preferred Reporting Items for Systematic Reviews and Meta-Analyses guidelines to query a variety of databases. A total of 444 articles were imported into Covidence, a screening and data extraction tool for conducting systematic reviews.

RESULTS

After a series of screenings, 60 articles met inclusion criteria and were reviewed in detail. The information was entered into a data extraction list consisting of 16 variables in the categories of general information, diagnostic strategies, treatment modalities, and treatment outcomes. Most articles reported retrospective case series, which yielded level 4 evidence. Only one article reported the results of a randomized and blinded outcomes assessment trial. Such article yielded level 1 evidence and was rated as high quality for allocation, concealment, and blinding of personnel.

CONCLUSION

The strategies used to diagnose and classify PP are a disparate list of measures most of which have no parallels making it impossible to offer treatment recommendations and generate generalizable knowledge.

Cranial remolding orthosis for children with deformational skull deformities: A systematic review on the factors affecting success and duration of treatment

Deformational plagiocephaly, deformational brachycephaly, and deformational scaphocephaly are the most common types of skull deformities during the first year of life. Using a cranial remolding orthosis (CRO) can have an important role in achieving a satisfactory level of improvement in symmetry and proportion of the deformed skulls. However, there is no consensus on the most important parameters for the success or length of treatment with a CRO. In this study, we did a systematic literature review in PubMed, Scopus, Web of Science, and EMBASE on January 2023. Titles/abstracts of the found studies were screened by two independent reviewers. The Newcastle-Ottawa Scale was used to evaluate the quality of the included articles. The best evidence synthesis was considered to determine the strength of the reported factors. A total of 25 articles with an accumulated sample of 7594 participants were included. Nine predictive factors, including age at initiation of CRO treatment, CRO compliance, deformity severity, deformity type, torticollis, gestational age, gestational type, delivery method, and developmental delay, were considered for CRO treatment length or success. Moderate evidence suggests that CRO treatment length is linked to a patient's age at the start of treatment and the deformity severity. Moreover, treatment success is correlated with a patient's age at the start of treatment, CRO compliance, and deformity severity. Moderate evidence indicates that there is no relationship between the presence of torticollis and gestational age with CRO treatment success.

Predictive Value of Sonographic Parameters on the Effects of Cranial Molding Helmet Therapy in Infants with Positional Plagiocephaly

Positional plagiocephaly is a deformational cranial flattening frequently treated in pediatric neurosurgical practice. Positional maneuvers and orthotic helmet therapy are preferred therapeutic options for moderate-to-severe forms. Treatment response seems to be age-dependent. Nevertheless, predictive data are vague, and cost-efficiency might be a limiting factor for treatment. The purpose of this study was to investigate the early predictive value of sonographic parameters on the efficacy of orthotic helmet therapy through the assessment of changes in skull shape and correlation of the parameters with caliper cephalometry values and with age. A consecutive cohort of 49 patients < 10 months of age, undergoing orthotic helmet therapy for positional plagiocephaly, was recruited prospectively. The authors routinely assessed the patency of the lambdoid sutures by ultrasound and the following additional skull parameters were measured: suture width, adjacent full bone thickness, adjacent cortical bone thickness and occipital angle. Caliper cephalometric values, as well as demographic and clinical data were collected. Retrospective data analysis showed an inverse relation between both cortical and full skull bone thickness and early treatment efficacy, defined by a reduction in the occipital angle. The improvement of sonographic parameters correlated with the development of cranial caliper cephalometry values. In conclusion, the sonographic assessment of skull bone thickness is a safe and cost-effective tool to predict the early efficacy of orthotic helmet therapy in positional plagiocephaly and might, therefore, help the clinician to foresee the potential evolution of the deformity.

A Study on the Effectiveness of Helmet Therapy for Cranial Deformations According to Cranial Shape

BACKGROUND

To investigate the effects of helmet therapy on plagiocephaly, according to head circumference, cephalic index (CI), and skull height. Plagiocephaly is a condition in which the skull is congenitally asymmetrical or affected by acquired factors such as compression in the womb or the habit of sleeping on one side. Although there are numerous studies on the effectiveness of helmet therapy for plagiocephaly, research on its effectiveness on skull shape is lacking.

METHODS

We conducted a prospective study on 400 patients who underwent helmet therapy. The infants were enrolled and the therapy was explained to the caregiver when the child had positional plagiocephaly and had a cranial vault asymmetry (CVA) exceeding 10 mm or a CVA index (CVAI) exceeding 3.5%. The CVA and CVAI changes were compared to investigate the effectiveness of helmet therapy according to head circumference, CI, and skull height.

RESULTS

A significant treatment effect was observed for CI values between 90 and 103. The treatment effect was found to increase with greater skull height. However, no significant difference was observed in the effectiveness of helmet therapy according to head circumference.

CONCLUSIONS

According to the findings, the effectiveness of helmet therapy in children with positional plagiocephaly is greater for children with higher skulls and for those with CI values between 90 and 103; it is unrelated to head circumference. Based on these results, we can provide predictions of the effectiveness of helmet therapy to caregivers of children with positional plagiocephaly.

Frontiers in Three-Dimensional Surface Imaging Systems for 3D Face Acquisition in Craniofacial Research and Practice: An Updated Literature Review

Digitalizing all aspects of dental care is a contemporary approach to ensuring the best possible clinical outcomes. Ongoing advancements in 3D face acquisition have been driven by continuous research on craniofacial structures and treatment effects. An array of 3D surface-imaging systems are currently available for generating photorealistic 3D facial images. However, choosing a purpose-specific system is challenging for clinicians due to variations in accuracy, reliability, resolution, and portability. Therefore, this review aims to provide clinicians and researchers with an overview of currently used or potential 3D surface imaging technologies and systems for 3D face acquisition in craniofacial research and daily practice. Through a comprehensive literature search, 71 articles meeting the inclusion criteria were included in the qualitative analysis, investigating the hardware, software, and operational aspects of these systems. The review offers updated information on 3D surface imaging technologies and systems to guide clinicians in selecting an optimal 3D face acquisition system. While some of these systems have already been implemented in clinical settings, others hold promise. Furthermore, driven by technological advances, novel devices will become cost-effective and portable, and will also enable accurate quantitative assessments, rapid treatment simulations, and improved outcomes.

Predictive Factors of Outcomes in Helmet Therapy for Deformational Plagiocephaly and Brachycephaly

Deformational plagiocephaly and brachycephaly, or abnormal flattening of the infant skull due to external forces, are often managed with orthotic helmet therapy. Although helmet therapy is widely used, the factors that predict poor outcomes are not well characterized. In this study of over 140,000 patients who received helmet therapy, older age and greater severity at presentation, and noncompliance with treatment were each independently associated with worse craniometric and provider-reported outcomes. Each additional point of cranial vault asymmetry index or cephalic index at a presentation is associated with an increased likelihood of residual brachycephaly at completion [odds ratio (OR): 1.067; 95% Cl: 1.058-1.075; P <0.0001 and OR: 2.043; 95% CI: 2.021-2.065; P <0.0001, respectively], whereas each additional point of cranial vault asymmetry index at a presentation associated with increased likelihood of residual asymmetry at completion (OR: 2.148; 95% Cl: 2.118-2.179; P <0.0001). Patients were more likely to have residual brachycephaly or asymmetry with increasing age at treatment initiation (OR: 1.562; 95% CI: 1.524-1.600; P <0.0001 and OR: 1.673; 95% Cl: 1.634-1.713; P <0.0001, respectively, for each additional month of age at initiation). These results highlight a need for prompt referral for helmeting, especially in cases with severe features or when patients present late to care. Potentially modifiable factors are age at helmeting and compliance with treatment protocols, and consideration of these factors may be important for achieving success in some cases.

Positional Plagiocephaly and Craniosynostosis

Along with the decrease in sudden infant death syndrome due to the successful "Back to Sleep" Campaign, there was a reciprocal increase in cases of positional plagiocephaly (PP). The prevalence of PP significantly rose from approximately 5% to upward of 46% at age 7 months. Consequently, clinicians have seen a surge in the number of patients presenting with head shape abnormalities. Not only does this increase in patient volume pose a logistical problem to clinics, but it also poses a potential risk to patients with craniosynostosis, whose head shape anomalies are similar to a "needle in a haystack" of patients with more common PP. This review explores the causes, risk factors, and treatment options of PP and craniosynostosis, along with the differential of head shape anomalies based on phenotypic presentation. In doing so, we hope to provide pediatric care clinicians with the tools necessary to effectively evaluate and manage patients with head shape abnormalities. [Pediatr Ann. 2023;52(1):e10-e17.].

Three-Dimensional Quantification of Facial Asymmetry in Children with Positional Cranial Deformity

BACKGROUND

The extent of facial involvement in positional plagiocephaly is only little investigated so far. Investigation methods that take into account the challenging anatomical conditions and growth of infants' faces are desirable. In this study, the authors established a new three-dimensional photogrammetry quantification method evaluating pretherapeutic and posttherapeutic facial asymmetry in positional plagiocephaly. Furthermore, a facial asymmetry index was established and evaluated.

METHODS

Three-dimensional photographs of 100 children undergoing treatment with head orthoses were analyzed by constructing a standardized interindividual coordinate system. Defining landmarks, section planes, and point coordinates with a computer-aided design software, both sides of the faces were compared. Facial asymmetry was quantified by measuring differences between left and right sides and pretherapeutic and posttherapeutic changes in each patient. The facial asymmetry index was calculated by putting the absolute differences in relation with the coordinates of the nonaffected side.

RESULTS

Present results indicate that positional plagiocephaly results in a distinct facial asymmetry (range, -3.8 to 9.6 mm) in nearly all spatial directions and facial regions. Helmet therapy led to a significant reduction (p < 0.05) of intraindividual facial asymmetry (median change in facial asymmetry index, -1.9 to 3.1 percent). However, no correlation of the Cranial Vault Asymmetry Index and facial asymmetry (Spearman rank correlation coefficient, ρ = -0.09 to 0.47) has been seen. According to these results, severe occipital deformation does not necessarily provoke distinct facial asymmetry.

CONCLUSIONS

Present three-dimensional photogrammetry method allows the longitudinal quantification of facial involvement in positional plagiocephaly. Asymmetry has been determined in all facial regions. The facial asymmetry decreased through helmet therapy but was not eliminated completely.

The role of age on helmet therapy in deformational plagiocephaly and asymmetric brachycephaly

PURPOSE

This study aimed to investigate the effect of age at helmet therapy onset on treatment efficacy in moderate-to-severe deformational plagiocephaly (DP) and combined DP and asymmetrical brachycephaly (AB) in infants.

METHODS

Ninety-eight infants who were referred to our institution and who underwent helmet therapy between 2014 and 2018 were retrospectively reviewed. Patients with DP [cranial vault asymmetry index (CVAI) > 7% and DD > 10 mm] and AB [CVAI > 7% and cephalic ratio (CR) ≥ 94] were included. Pre- and post-treatment calvarial asymmetries (difference among DD, CVAI, and CR) were measured using 3D screening systems (SmartSoc and Omega Scanner 3D). Infants were classified according to age at treatment onset: group 1 (age, < 6 months) and group 2 (age, ≥ 6 months).

RESULTS

CVAI was statistically different between treatment onset and end in subgroups. Moreover, the regression of CVAI between groups DP1 (- 7.5% ± 1.2%) versus DP2 (- 5.4% ± 1.5%; p = 0.001) and groups AB1 (- 6.6% ± 1.4%) versus AB2 (- 4.4 ± 2.5; p = 0.0013) was statistically significant. CVAI was < 3.5% and CR was ≤ 89 (assumed as normal cranial shape) after treatment in 48%, 40%, 32%, and 6% of infants in groups DP1, DP2, AB1, and AB2, respectively.

CONCLUSION

These findings emphasize the efficacy of helmet therapy for DP and AB. Helmet is an appropriate treatment option particularly for infants with severe DP and AB, and early onset of helmet therapy before the age of 6 months is advised.

Positional cranial deformation in children: A plea for the efficacy of the cranial helmet in children

BACKGROUND

Cranial deformations have historically aroused the interest of people worldwide. One of the more debated points about positional plagiocephaly is the choice of the treatment. In this article, the senior author (CM) shares his experience on almost 30 years of use of the helmet molding therapy in children with deformation plagiocephaly.

METHODS AND POPULATION

We retrospectively and systematically reviewed the cases of 2188 patients (75% males and 25% females) presenting positional head deformity and treated between 1991 and 2013 with a cranial helmet. To assess the effectiveness of the helmet, we compared the cranial index in bilateral plagiocephaly and the Cranial Diagonals Difference (CDD) in unilateral plagiocephaly at the beginning and at the end of the treatment.

RESULTS

The cranial indexes ranged between 94.4% and 124.2% before the treatment and decreased significantly between 86.8% and 121.4% after the treatment (P<0.01). The CDD ranged between 0.3 cm and 4.5 cm with an average of 1.50±0.54 cm before the treatment and decreased significantly between 0.1 cm and 2.5 cm with an average of 0.72±0.37 cm after the treatment (P<0.01). For unilateral plagiocephaly, at the beginning of the treatment, 2.5% children presented a mild plagiocephaly, 19.6% a moderate plagiocephaly and 77.9% a severe plagiocephaly. At the end of the treatment, the deformation was classified as mild in 40.2% children, moderate in 44.3% children and severe in 15.5% children with significantly less children in the most severe subgroups (P<0.01) Facial symmetry pre-existed before the treatment in 13.7% of children. This rate was significantly increased at the end of the treatment to 66.7% (P<0.01). In only 8 cases (0.2%), the helmet therapy did not allow to obtain correct clinical results and a surgical posterior cranial remodeling was performed.

CONCLUSIONS

The results observed in this series confirms that cranial helmet is a simple and well tolerated alternative which bring satisfying results. Its success implies a good collaboration with parents and a management both by orthoptist, physiotherapist and doctor. Nevertheless, it remains many controversies in the literature concerning in particular long-term cosmetic and functional outcomes. A long-term multicentric prospective study could enable to remove doubts.

A Clinical Photographic Method to Evaluate the Need for Helmet Therapy in Deformational Plagiocephaly

PURPOSE

With an increase in positional plagiocephaly patients, various therapy methods have been researched and helmet therapy is the most widely used and effective treatment method. To devise a method that would allow medical professionals and patients' parents to more easily identify the shape and outcomes before and after the therapy.

METHODS

This study included 399 patients who had helmet therapy from November 2014 to February 2016. Patients wore a cast helmet for more than 20 hours per day. A cranial caliper was used to measure their head before they wore the helmet (prehelmet), once a month during outpatient visits, and 6 months after they stopped wearing the helmet (posthelmet). Clinical photographs were taken on a transparent acrylic sheet with a grid of 5-mm intervals to measure cranial vault asymmetry (CVA), cranial vault asymmetry index (CVAI), and symmetry ration (SR). The patients' photographs were then measured twice: first against the background without the grid and then against the background with the grid.

RESULTS

Average age at prehelmet was 20 weeks while their average therapy period was 12 weeks. Patients' prehelmet CVA was 13.3 mm, and their posthelmet CVA was 3.1 mm. Their prehelmet CVAI was 10.1%, and their posthelmet CVAI was 2.1% (P < 0.001). Their overall prehelmet and posthelmet SRs were 0.820 and 0.969, respectively (P < 0.001). In addition, the measurements based on clinical photographs with and without the grid were compared using Fleiss kappa. The results showed κ = 0.847 and 0.956 when the patient was mild, κ = 0.744 and 0.919 when it was moderate, and κ = 0.767 and 0.924 when it was severe (P < 0.001). In all 3 patients, the consistency was higher with the grid.

CONCLUSION

Since cast helmet manufacturing for positional plagiocephaly therapy does not require computed tomography scanning, there is no need to administer a sedative, nor does it pose any radiation exposure risk. Since the cast helmet is easier to manufacture and operate and is more cost effective, it could be used to treat more people. In addition, it would be useful for both medical professionals and patients' guardians to use clinical photographs with the acrylic sheet with the grid as a method to analyze shapes and outcomes before and after therapy, along with traditional CVA and CVAI.

Cranial growth in infants─A longitudinal three-dimensional analysis of the first months of life

PURPOSE

In the first months of life, any deviation from a physiological growth pattern can cause skull deformity. As there has not been any longitudinal three-dimensional (3D) study investigating the physiological growth of the infant skull, the aim of the present study was to acquire such data.

MATERIALS AND METHODS

We performed 3D stereophotogrammetric scans of 40 infants without cranial asymmetry at four regular 2-month intervals from the 4th to the 10th month of age. Six growth-related parameters (circumference, length, width, height, cephalic index [CI; width-length ratio] and total head volume) were used to analyse skull growth longitudinally.

RESULTS

With exception of the CI, all parameters showed significant increases, with maximum percentage growth from the 4th to the 6th month. The CI initially remained unchanged until the 6th month, before showing a significant reduction that continued throughout the study period. Male infants had larger heads than female infants, but a similar width-length ratio at all measurement times.

CONCLUSION

This prospective study is the first longitudinal 3D analysis to examine the physiological growth dynamics of infants' heads within the first months of life. Understanding patterns of skull growth in all three dimensions is important for gaining further insights into physiological and pathophysiological skull development.

Analysis of the correlation between deformational plagiocephaly and neurodevelopmental delay

BACKGROUND

Deformational plagiocephaly (DP) refers to cranial asymmetry resulting from uneven external forces. A strong association exists between DP and developmental delay. We investigated the effect of DP severity on developmental delay.

METHODS

Between 2010 and 2016, data from 155 patients with DP were reviewed retrospectively. Two indices were used to evaluate the deformation quantitatively: cranial index (CI) and cranial vault asymmetry index (CVAI). The Bayley Scales of Infant Development-II was used to evaluate the neurodevelopment of patients.

RESULTS

According to the CI of the study population, 2 patients showed scaphocephaly, 12 showed mesocephaly, and 141 showed brachycephaly. For CVAI, 10 patients showed values of <3.5, 10 patients showed mild deformity (3.5-6.25), 27 patients showed moderate deformity (6.25-8.75), and 108 patients showed severe deformity. The means of the mental development index (MDI) and psychomotor development index (PDI) were 91.69 ± 16.8 and 92.28 ± 17.59, respectively; after the exclusion of patients with confounding factors, the values were 96.26 and 92.9, respectively. The Spearman correlation coefficients between MDI and CI and CVAI were -0.019662 and 0.118916, respectively, whereas for PDI, the values were -0.195428 and -0.012386, respectively.

CONCLUSIONS

There was a statistically significant neurodevelopmental delay in patients with DP. However, accelerated neurodevelopment was also encountered in many patients. MDI was found to be more affected by multiple confounding factors than PDI, whereas PDI was only affected by congenital anomalies. There was no definitive relationship between the severity of DP and the degree of developmental delay in our study group.

Head Orthosis Therapy in Positional Plagiocephaly: Influence of Age and Severity of Asymmetry on Effect and Duration of Therapy

BACKGROUND

Only a few studies investigating the optimal time point at which to start orthotic treatment for deformational plagiocephaly take into account the severity of skull asymmetry. The present study performs a three-dimensional analysis of the effects of age and severity of asymmetry on the final outcome.

METHODS

A total of 144 patients with deformational plagiocephaly treated by molding orthosis were examined and divided into three age groups (group I, <24 weeks; group II, ≥24 to <32 weeks; and group III, ≥32 weeks) and two severity levels (mild to moderate, 30-degree cranial vault asymmetry ≥3 mm to ≤12 mm; and moderate to severe, 30-degree cranial vault asymmetry >12 mm). The extent of the reduction of asymmetry was analyzed using three-dimensional stereophotogrammetry.

RESULTS

Therapy with molding orthosis led to a significant reduction in asymmetry in all defined age groups. Efficacy of reduction decreased with increasing age. Successful treatment (cranial vault asymmetry index <3.5 percent) was achieved in 83, 69, and 40 percent of patients with mild to moderate asymmetry in groups I, II, and III, respectively; and in 50, 30, and 7 percent of patients with moderate to severe asymmetry in groups I, II, and III, respectively. The average duration of treatment increased from 18.6 weeks to 25.3 weeks (age groups I and III).

CONCLUSION

Age at the beginning of treatment and severity of asymmetry have a definite impact on the duration and effectiveness of molding orthosis therapy.

CLINICAL QUESTION/LEVEL OF EVIDENCE

Risk, II.

Relationship between starting age of cranial-remolding-orthosis therapy and effectiveness of treatment in children with deformational plagiocephaly

PURPOSE

The aim of this study was to investigate the optimal age for starting cranial-remolding-orthosis therapy in children with deformational plagiocephaly.

METHODS

Medical records of 310 patients with deformational plagiocephaly were retrospectively reviewed and the initial and final cranial vault asymmetry index (CVAI), age when starting therapy, duration of therapy, mean change of CVAI, improvement rate, and treatment success were analyzed. We compared outcomes according to the groups divided by ages starting therapy.

RESULTS

There were no significant differences in improvement rate and duration of cranial-remolding-orthosis therapy among patients starting therapy at the age of 3, 4, and 5 months. However, when starting therapy after the age of 6 months, the rates of CVAI improvement were significantly lower and the duration of therapy was significantly increased.

CONCLUSION

Considering the spontaneous resolution effect according to the head growth nature, the age 5 month is the optimal period to start cranial-remolding-orthosis therapy for deformational plagiocephaly.

Validity and intraobserver reliability of three-dimensional scanning compared with conventional anthropometry for children and adolescents from a population-based cohort study

BACKGROUND

Conventional anthropometric measurements are time consuming and require well trained medical staff. To use three-dimensional whole body laser scanning in daily clinical work, validity, and reliability have to be confirmed.

METHODS

We compared a whole body laser scanner with conventional anthropometry in a group of 473 children and adolescents from the Leipzig Research Centre for Civilization Diseases (LIFE-Child). Concordance correlation coefficients (CCC) were calculated separately for sex, weight, and age to assess validity. Overall CCC (OCCC) was used to analyze intraobserver reliability.

RESULTS

Body height and the circumferences of waist, hip, upper arm, and calf had an "excellent" (CCC ≥ 0.9); neck and thigh circumference, a "good" (CCC ≥ 0.7); and head circumference, a "low" (CCC < 0.5) degree of concordance over the complete study population. We observed dependencies of validity on sex, weight, and age. Intraobserver reliability of both techniques is "excellent" (OCCC ≥ 0.9).

CONCLUSION

Scanning is faster, requires less intensive staff training and provides more information. It can be used in an epidemiologic setting with children and adolescents but some measurements should be considered with caution due to reduced agreement with conventional anthropometry.

Plagiocephaly and Developmental Delay: A Systematic Review

OBJECTIVE

Deformational plagiocephaly (includes plagiocephaly and brachycephaly) is a common pediatric condition. Infants who present with altered head shape often experience developmental delay. It is uncertain how common developmental delay is in infants with plagiocephaly and how sustained this is, when present. This review explores the association between plagiocephaly and developmental delay to guide clinical practice.

STUDY DESIGN

A systematic review was conducted. MEDLINE, EMBASE, CINAHL, and PEDro databases were searched. Data from relevant studies were extracted regarding study: sample, follow-up, design, and findings. Methodological quality of each study was rated using a critical appraisal tool.

RESULTS

The search recovered 1315 articles of which 19 met the inclusion criteria. In the included studies, the children's ages ranged from 3 months to 10 years. Study limitations included selection bias, nonblinding of assessors, and reuse of the same study population for multiple papers. Most papers (11/19) rated "moderate" on methodological quality. A positive association between plagiocephaly and developmental delay was reported in 13 of 19 studies, including 4 of 5 studies with "strong" methodological quality. Delay was more frequently in studies with children ≤24 months of age (9/12 studies) compared with >24 months of age (3/7 studies). Motor delay was the most commonly affected domain reported in high-quality papers (5/5 studies).

CONCLUSION

This review suggests plagiocephaly is a marker of elevated risk of developmental delays. Clinicians should closely monitor infants with plagiocephaly for this. Prompt referral to early intervention services such as physiotherapy may ameliorate motor delays and identify infants with longer term developmental needs.

Sonographic Analysis of Changes in Skull Shape After Cranial Molding Helmet Therapy in Infants With Deformational Plagiocephaly

OBJECTIVES

-The purpose of this study was to investigate the changes in skull shape on sonography after cranial molding helmet therapy in infants with deformational plagiocephaly.

METHODS

-Twenty-six infants who were treated with cranial molding helmet therapy were recruited. Caliper and sonographic measurements were performed. The lateral length of the affected and unaffected sides of the skull and cranial vault asymmetry index were measured with calipers. The occipital angle, defined as the angle between lines projected along the lambdoid sutures of the skull, was calculated by sonography. The occipital angle difference and occipital angle ratio were also measured. All caliper and sonographic measurements were performed in each infant twice before and twice after treatment.

RESULTS

-The study group included 12 male and 14 female infants with a mean age ± SD of 6.2 ± 3.5 months. The mean treatment duration was 6.0 ± 2.5 months. The difference in lateral length before and after helmet therapy was significantly greater on the affected skull than the unaffected skull (16.7 ± 12.7 versus 9.0 ± 13.4 mm; P < .01). The difference in the occipital angle before and after helmet therapy was significantly greater on the affected skull than the unaffected skull (-5.7° ± 7.3° versus 4.2° ± 7.9°; P < .01). The cranial vault asymmetry index and occipital angle ratio were significantly reduced after helmet therapy (cranial vault asymmetry index, 9.3% ± 2.3% versus 3.5% ± 3.0%; occipital angle ratio, 1.07 ± 0.05 versus 1.01 ± 0.01; P < .05).

CONCLUSIONS

-These results suggest that occipital angle measurements using sonography, combined with cephalometry, could provide a better understanding of the therapeutic effects of cranial molding helmet therapy in infants with deformational plagiocephaly.

Prevalence and Consequences of Positional Plagiocephaly and Brachycephaly

The incidence of positional plagiocephaly and brachycephaly in infants has increased. Treatment options include physiotherapy and helmet therapy.No information exists on the prevalence, cosmetic, and psychological consequences of plagiocephaly and brachycephaly later in life. This study was performed to assess the prevalence and cosmetic relevance of plagiocephaly and brachycephaly, as well as its influence on quality of life in adolescence.The authors performed plagiocephalomety to assess cranial shape and used a questionnaire that included question about educational level, medical history, cosmetic appearance, and cranial shape. To evaluate quality of life, the authors used the KIDSCREEN-27 questionnaire.All data were analyzed using SPSS version 19.0 2010. The authors included 87 adolescents. The prevalence of plagiocephaly, defined as an oblique diameter difference index (ODDI) higher than 106%, was 10.3%; the prevalence of brachycephaly, defined as a cranial proportional index (CPI) higher than 95%, was 0%.There was no significant correlation between the level of the ODDI or CPI and the cosmetic assessment of cranial shape (P = 0.128/0.541). There was no significant correlation with the level of the ODDI (P = 0.428).There was no significant correlation between the level of the ODDI or CPI and the average T-value for quality of life using the KIDSCREEN quality-of-life questionnaire (P = 0.461/0.713). The prevalence of positional deformities in our population of adolescents, born after the "back to sleep" campaign, is low. There was no significant correlation between the presence of a cranial deformity and the cosmetic judgement and quality of life.

Effectiveness of conservative therapy and helmet therapy for positional cranial deformation

BACKGROUND

The authors investigated the effectiveness of conservative (repositioning therapy with or without physical therapy) and helmet therapy, and identified factors associated with treatment failure.

METHODS

A total of 4378 patients evaluated for deformational plagiocephaly and/or deformational brachycephaly were assigned to conservative (repositioning therapy, n = 383; repositioning therapy plus physical therapy, n = 2998) or helmet therapy (n = 997). Patients were followed until complete correction (diagonal difference <5 mm and/or cranial ratio <0.85) or 18 months. Rates of correction were calculated, and independent risk factors for failure were identified by multivariate analysis.

RESULTS

Complete correction was achieved in 77.1 percent of conservative treatment patients; 15.8 percent required transition to helmet therapy (n = 534), and 7.1 percent ultimately had incomplete correction. Risk factors for failure included poor compliance (relative risk, 2.40; p = 0.009), advanced age (relative risk, 1.20 to 2.08; p = 0.008), prolonged torticollis (relative risk, 1.12 to 1.74; p = 0.002), developmental delay (relative risk, 1.44; p = 0.042), and severity of the initial cranial ratio (relative risk, 1.41 to 1.64; p = 0.044) and diagonal difference (relative risk, 1.31 to 1.48; p = 0.027). Complete correction was achieved in 94.4 percent of patients treated with helmet therapy as first-line therapy and in 96.1 percent of infants who received helmets after failed conservative therapy (p = 0.375). Risk factors for helmet failure included poor compliance (relative risk, 2.42; p = 0.025) and advanced age (relative risk, 1.13 to 3.08; p = 0.011).

CONCLUSIONS

Conservative therapy and helmet therapy are effective for positional cranial deformation. Treatment may be guided by patient-specific risk factors. In most infants, delaying helmet therapy for a trial of conservative treatment does not preclude complete correction.

CLINICAL QUESTION/LEVEL OF EVIDENCE

Therapeutic, III.

Orthotic (helmet) therapy in the treatment of plagiocephaly

OBJECT

The goal of this study was to review the current literature on orthotic (helmet) therapy use in the treatment of deformational plagiocephaly.

METHODS

PubMed was used to search English articles using the medical subject headings "deformational plagiocephaly" and "orthosis," and "deformational plagiocephaly" and "helmet."

RESULTS

Forty-two articles were found. There were no Class I studies, 7 Class II studies, 1 Class III study, and 13 Class IV studies. Cranial orthoses have been shown to be effective in treating deformational plagiocephaly. It continues to be debated as to whether the statistical significance of treatment with cranial orthoses compared with conservative therapies is clinically significant. Children older than 12 months of age with deformational plagiocephaly may still benefit from orthotic therapy. The long-term effects of orthotic therapy are controversial.

CONCLUSIONS

There is a lack of Class I literature evidence supporting the use of helmet therapy in deformational plagiocephaly. There are controversies surrounding the use of orthotic therapy such as appropriate use, cost, use in older children, and long-term outcomes. Clinical indications for orthotic therapy need to be better defined with further research studies.

Efficacy of passive helmet therapy for deformational plagiocephaly: report of 1050 cases

OBJECT

There has been a tremendous increase in the incidence of deformational plagiocephaly in children throughout the world. Therapeutic options include observation, active counterpositioning, external orthotics, and surgery. The current treatment in the US is highly debated, but it typically includes external orthotic helmets in patients with moderate to severe plagiocephaly presenting between 4 and 10 months of age or in children with significant comorbidities limiting passive (no-pressure) therapy. The present study was designed to evaluate 3 key issues: 1) the accuracy of the Argenta classification in defining a progressive degree of severity, 2) identification of an upper age limit when treatment is no longer effective, and 3) the effectiveness of an off-the-shelf prefabricated helmet in correcting deformational plagiocephaly.

METHODS

An institutional review board-approved retrospective study was conducted of all patients at the authors' clinic in whom deformational plagiocephaly was assessed using the Argenta classification system over a 6-year period; the patients underwent helmet therapy, and a minimum of 3 clinic visits were recorded. Inclusion criteria consisted of an Argenta Type II-V plagiocephalic deformity. Patients' conditions were categorized both by severity of the deformity and by patients' age at presentation. Statistical analysis was conducted using survival analysis.

RESULTS

There were 1050 patients included in the study. Patients with Type III, IV, and V plagiocephaly required progressively longer for deformity correction to be achieved than patients with Type II plagiocephaly (53%, 75%, and 81% longer, respectively [p < 0.0001]). This finding verified that the Argenta stratification indicated a progressive severity of deformity. No statistically significant difference in the time to correction was noted among the different age categories, which suggests that the previously held upper time limit for correction may be inaccurate. An overall correction rate to Type I plagiocephaly of 81.6% was achieved irrespective of severity and degree of the original deformity. This suggests that an inexpensive off-the-shelf molding helmet is highly effective and that expensive custom-fitted orthoses may not be necessary. The patients in the older age group (> 12 months) did not have a statistically significant longer interval to correction than the patients in the youngest age group (< 3 months). The mean length of follow-up was 6.3 months.

CONCLUSIONS

Patients treated with passive helmet therapy in the older age group (> 12 months) had an improvement in skull shape within the same treatment interval as the patients in the younger age group (< 3 months). This study supports the use of passive helmet therapy for improvement in deformational plagiocephaly in infants from birth to 18 months of age and verifies the stratification of degree of deformity used in the Argenta classification system.

Comparison of helmet therapy and counter positioning for deformational plagiocephaly

OBJECTIVE

To compare effectiveness on correcting cranial and ear asymmetry between helmet therapy and counter positioning for deformational plagiocephaly (DP).

METHODS

Retrospective data of children diagnosed with DP who visited our clinic from November 2010 to October 2012 were reviewed. Subjects ≤10 months of age who showed ≥10 mm of diagonal difference were included for analysis. For DP treatment, information on both helmet therapy and counter positioning was given and either of the two was chosen by each family. Head circumference, cranial asymmetry measurements including diagonal difference, cranial vault asymmetry index, radial symmetry index, and ear shift were obtained by 3-dimensional head-surface laser scan at the time of initiation and termination of therapy.

RESULTS

Twenty-seven subjects were included: 21 had helmet therapy and 6 underwent counter positioning. There was no significant difference of baseline characteristics, head circumferences and cranial asymmetry measurements at the initiation of therapy. The mean duration of therapy was 4.30±1.27 months in the helmet therapy group and 4.08±0.95 months in the counter positioning group (p=0.770). While cranial asymmetry measurements improved in both groups, significantly more improvement was observed with helmet therapy. There was no significant difference of the head circumference growth between the two groups at the end of therapy.

CONCLUSION

Helmet therapy resulted in more favorable outcomes in correcting cranial and ear asymmetry than counter positioning on moderate to severe DP without compromising head growth.

Outcome analysis after helmet therapy using 3D photogrammetry in patients with deformational plagiocephaly: the role of root mean square

Deformational plagiocephaly (DP) is a multifactorial non-synostotic cranial deformity with a reported incidence as high as 1 in 7 infants in North America. Treatment options have focused on non-operative interventions including head repositioning and the use of an orthotic helmet device. Previous studies have used linear and two dimensional outcome measures to assess changes in cranial symmetry after helmet therapy. Our objective was to demonstrate improvement in head shape after treatment with a cranial molding helmet by using Root Mean Square (RMS), a measure unique to 3D photogrammetry, which takes into account both changes in volume and shape over time. Three dimensional photographs were obtained before and after molding helmet treatment in 40 infants (4-10 months old) with deformational plagiocephaly. Anatomical reference planes and measurements were recorded using the 3dMD Vultus(®) analysis software. RMS was used to quantify symmetry by superimposing left and right quadrants and calculating the mean value of aggregate distances between surfaces. Over 95% of the patients demonstrated an improvement in symmetry with helmet therapy. Furthermore, when the sample of infants was divided into two treatment subgroups, a statistically significant correlation was found between the age at the beginning of treatment and the change in the RMS value. When helmet therapy was started before 7 months of age a greater improvement in symmetry was seen. This work represents application of the technique of RMS analysis to demonstrate the efficacy of treatment of deformational plagiocephaly with a cranial molding helmet.

Complications associated with molding helmet therapy for positional plagiocephaly: a review

Molding helmet therapy is a widely accepted treatment for positional plagiocephaly that is generally considered to be low risk. Multiple large outcome studies have shown good results, but adverse events are rarely reported. The literature on helmet therapy was reviewed to clarify the clinical experience with associated complications. Although significant complications were extremely rare, there was a large degree of variability in detection of lesser problems such as minor skin irritation. Patients with a primarily brachycephalic morphology may be at higher risk for poorly fitting orthoses. Most reported complications are minor and self-limited. Maintenance of good helmet hygiene appears to be the most effective strategy for reducing or eliminating complications.

Treatment of deformational plagiocephaly and torticollis using a weight distribution ring: a report of three cases

Plagiocephaly, from the Greek 'plagios' (slanting) and 'kephale' (head), refers to a condition of an infant's head deformation by forces acting upon a malleable cranium. Marked plagiocephaly causes distress and stigma towards the baby and their family and has knock-on effects with craniofacial abnormalities, visual-field defects and delay in motor skills, and may also cause developmental difficulties. Current treatment methods have multiple drawbacks. This small, illustrated case series presents a novel, cost-effective, practical first-line treatment using a horseshoe-shaped gel head ring to redistribute pressure, allowing uniform growth and reshaping. Our early experience suggests that this method represents an effective treatment option with promising results so far.

Helmet treatment of deformational plagiocephaly: the relationship between age at initiation and rate of correction

BACKGROUND

The purpose of this study was to evaluate the relationship between age at initiation of helmet therapy for deformational plagiocephaly and the rate of correction.

METHODS

Infants treated for deformational plagiocephaly with a helmet orthosis between 2009 and 2010 were included. Patients were stratified prospectively by the age at which treatment was initiated: group 1, younger than 20 weeks (n = 26); group 2, 20 to 23.9 weeks (n = 59); group 3, 24 to 27.9 weeks (n = 82); group 4, 28 to 31.9 weeks (n = 62); group 5, 32 to 35.9 weeks (n = 45); group 6, 36 to 40 weeks (n = 29), and group 7, older than 40 weeks (n = 43). Pretreatment and posttreatment calvarial asymmetry was measured using direct anthropometry and reported as a transcranial difference.

RESULTS

Three hundred forty-six infants were included; initial transcranial difference was equivalent on all paired-group comparisons. Duration of helmet therapy positively correlated with age at initiation (r = 0.89, p < 0.05). The rate of change in transcranial difference correlated negatively with age at treatment onset (r = -0.88, p < 0.05): group 1, 0.93 mm/week; group 2, 0.64 mm/week; group 3, 0.59 mm/week; group 4, 0.56 mm/week; group 5, 0.41 mm/week; group 6, 0.42 mm/week; and group 7, 0.42 mm/week). At the conclusion of therapy, all groups had improved calvarial symmetry, albeit less completely in groups 6 and 7.

CONCLUSIONS

The correction rate of plagiocephaly with helmet therapy decreases with increasing infant age; after 32 weeks, there is a slow and relatively constant rate of change. Improvement can still be achieved in infants older than 12 months.

CLINICAL QUESTION/LEVEL OF EVIDENCE

Therapeutic, II.

Evidence-based care of the child with deformational plagiocephaly, part II: management

Non-synostotic deformational plagiocephaly (DP) is a common condition that affects as many as one in five infants in the first 2 months of life. The purpose of this article, the second in a two-part series, is to present a synthesis of the evidence related to management of deformational plagiocephaly and an evidence-based clinical decision tool for multidisciplinary management of DP. We systematically reviewed and graded the literature on management of DP from 2000 to 2011 based on level of evidence and quality. The evidence suggests that although many cases of DP will improve over time, conservative management strategies such as repositioning, physical therapy, and cranial molding devices can safely and effectively minimize the degree of skull asymmetry when implemented in the first year of life. Outcomes are best when the timing of diagnosis and severity of asymmetry guide decision making related to interventions and referrals for DP. Prevention and management of early signs of DP are best achieved in a primary care setting, with multidisciplinary management based on the needs of the child and the goals of the family.

Deformational plagiocephaly and orthotic treatment: indications and limitations

PURPOSE

As the incidence of deformational plagiocephaly (DP) has risen, so has the demand on clinicians to make appropriate treatment recommendations. While knowledge of risk factors and natural history continue to evolve, there is uncertainty and controversy regarding intervention approaches. The purpose of this report is to review current treatment approaches for DP, in particular the use of orthotic helmets.

METHODS

A narrative literature review was conducted to summarize current evidence supporting preventative measures and re-positional and orthotic interventions.

RESULTS

When started early at under 2 months of age, positional efforts and 'tummy time' can be effective in preventing and improving DP, but these strategies need to be better promoted to caregivers. The timing, severity and parental concerns as indicators for orthotic treatment are reviewed. Limitations discussed include high cost, lower level of evidence and poor understanding of long-term outcomes and caregiving implications.

CONCLUSION

For optimal outcome, current evidence supports use of repositioning in young infants and start of orthotic helmet treatment for infants with significant DP at 4-6 months. Further research is needed to better understand the parameters for use (stratified by age and severity), long-term outcomes and natural history and the impact on caregiving, as well as the cultural significance of head shape.

Outcome analysis of cranial molding therapy in nonsynostotic plagiocephaly

Background

It is known that nonsynostotic plagiocephaly does not spontaneously improve, and the craniofacial deformities that result from it. This study was conducted to analyze the effectiveness of helmet therapy for the nonsynostotic plagiocephaly patient, and to suggest a new treatment strategy based on this analysis.

Methods

A total of 108 pediatric patients who had undergone helmet therapy after being diagnosed with nonsynostotic plagiocephaly were included in this study. The patients were classified according to the initiation age of the helmet therapy, severity, and helmet wearing time. The treatment effect was compared using cranial vault asymmetry (CVA) and the cranial vault asymmetry index (CVAI), which were obtained from diagonal measurements before and after therapy.

Results

The discrepancy of CVA and CVAI of all the patients significantly decreased after helmet therapy. According to the initiation time of helmet therapy, the treatment effect was best at 5 months old or less. The helmet wearing time per day was proportional to the treatment effect up to 20 hours. In addition, the rate of the successful treatment (final CVA ≤5 mm) significantly decreased when the initiation age was 9.1 months or older and the treatment period was less than 7.83 months.

Conclusions

This study showed the effectiveness of the helmet therapy for nonsynostotic plagiocephaly patients. Based on analysis of this study, helmet therapy should be started at the age of 9 months or younger for 7.83 months or more, and the helmet wearing time should be more than 20 hours a day.

Prevalence of Positional Plagiocephaly in Teens Born after the “Back to Sleep” Campaign

Objectives. To determine the prevalence of positional plagiocephaly and brachycephaly in teenagers born after the “Back to Sleep” campaign but before orthotic helmet treatment became widely available and to provide long-term outcomes data on those children with plagiocephaly who were not treated with remolding therapy.

Study Design. Cross-sectional analysis.

Setting. Local high schools in the Minneapolis–St Paul Metro area.

Subjects and Methods. Subjects were selected if they attended participating high schools and were born after the Back to Sleep campaign began. Skull measurements, including transcranial diameter, length, and width, were taken. Overall facial appearance was inspected for any apparent abnormal characteristics. Cranial vault asymmetry and cephalic index were calculated for each participant. Plagiocephaly was diagnosed if cranial vault asymmetry was >1 cm. Brachycephaly was diagnosed if the cephalic index was >0.90.

Results. There were 1045 participants, ranging from 12 to 17 years old, with an average age of 15.7 years. The prevalence of plagiocephaly was 1.1%. The prevalence of brachycephaly was 1.0%. The overall prevalence of a deformational cranial abnormality was 2.0%. Of those who met diagnostic criteria of plagiocephaly or brachycephaly, 38.1% were noted to have abnormal facial characteristics.

Conclusions. The prevalence of plagiocephaly and brachycephaly in teenagers is significantly lower than the 20% to 48% prevalence found in infants in previous studies, suggesting most children will outgrow the condition without intervention. Additional studies are needed to determine which patients might benefit from treatment and which will likely have resolution without intervention, since treating all infants who meet criteria results in significant overtreatment.

What is the optimal time to start helmet therapy in positional plagiocephaly?

BACKGROUND

Although helmet therapy is widely accepted in the treatment of severe positional plagiocephaly, treatment regimens, especially regarding starting age, are controversial. This study investigated the importance of starting age to optimize the management of helmet therapy.

METHODS

Sixty-two infants with severe positional plagiocephaly were enrolled in this prospective longitudinal study. Twenty-four started helmet therapy before 6 months of age (group 1) and 38 were older than 6 months (group 2). Cranial diagonal measurements were taken. Resulting differences and Cranial Vault Asymmetry Index values were compared and categorized by age at initiation of therapy. The Mann-Whitney U test was used for statistical analysis.

RESULTS

Duration of therapy was significantly shorter in group 1 (14 weeks) compared with group 2 (18 weeks) (p = 0.013), with significantly better outcomes. The Cranial Vault Asymmetry Index in group 1 was reduced to a normal mean value less than 3.5 percent. Infants in group 2 did not achieve normal values (index value, 4.5 percent) (p = 0.021). The relative improvement in asymmetry was significantly better in group 1 (75.3 percent) compared with group 2 (60.6 percent) (p = 0.001). After 4 to 11 weeks of treatment, group 1 already showed a better absolute reduction (p < 0.001) and a better relative reduction (p = 0.002).

CONCLUSIONS

Optimal starting age for helmet therapy is months 5 to 6 of life, and early recognition of infants in need is essential. Delaying the onset of treatment significantly deteriorates the outcome. The still often-practiced regimen of starting helmet therapy after physiotherapy should be replaced by a combined therapy in severe cases.

CLINICAL QUESTION/LEVEL OF EVIDENCE

Therapeutic, II.

Three-dimensional photographic analysis of outcome after helmet treatment of a nonsynostotic cranial deformity

Cranial asymmetries due to nonsynostotic deformation of the skull have been reported with increasing frequency during the last decade. Conservative approaches using helmets and physiotherapy have been shown to be effective in their treatment. Traditionally, documentation has been carried out using anthropometric caliper measurements. The present study evaluates the use of a new three-dimensional photographic system in the improved validation of changes in head deformities. This prospective analysis introduces a new technique for digital anthropometric measurement. The study series comprised 181 children with nonsynostotic head deformities. Three-dimensional photographs were obtained before and after treatment with an orthotic helmet device. The oblique head diagonals and head width and length were measured from three-dimensional photographs using 3dMD customer software. The cranial vault asymmetry index, cranial vault asymmetry, and cranial index were compared before and after treatment. The measurements obtained on three-dimensional images were able to demonstrate significant improvement in early infant cranial deformity after treatment with an orthotic helmet. The cranial vault asymmetry index in plagiocephaly was reduced by 7.16%, and cranial vault asymmetry was reduced by 0.86 cm. The cranial index in brachycephaly decreased by 7.32%. In children with combined plagiocephaly and brachycephaly, the cranial vault asymmetry index improved by 5.77%, cranial vault asymmetry improved by 0.71 cm, whereas the cranial index changed by 5.48%. Three-dimensional photogrammetry can support treatment control in patients with deformational plagiocephaly. This new technology offers several advantages such as easy acquisition of images, detection of landmarks without patient movement, repeatable measurements without patient discomfort, and the opportunity for unbiased evaluation.

Treatment of Plagiocephaly with Helmet Molding Therapy: Do Actual Results Mimic Perception?

Purpose

Actual and perceived improvements from helmet molding therapy for deformational plagiocephaly are demonstrated here. Effective communication of these data by craniofacial teams can help avoid unrealistic expectations and inform parents of expected outcomes.

Methods

Parents of 61 patients with plagiocephaly were asked to rate their children's head shape and ear position before and after helmet therapy (a score of 1 being abnormal and 10 being normal). Topographic laser head scans for an aged-matched cohort of 91 patients with deformational plagiocephaly were acquired. Cephalic ratio, overall symmetry ratio, radial symmetry index, ear offset, and left and right oblique were recorded before and after molding. The cranial vault asymmetry index (CVSI) score was calculated.

Results

Parent ratings before and after molding, respectively, were head shape 2.99 ± 1.50 (mean ± SD) versus 7.88 ± 1.64 (p < .0001) and ear position 3.75 ± 2.5 versus 7.73 ± 2.34 (p < 0.0001). Measurements before and after molding were cephalic ratio 0.89 ± 0.07 versus 0.87 ± 0.08 (p < .0001), overall symmetry index 0.87 ± 0.05 versus 0.90 ± 0.04 (p < .0001), radial symmetry index 59.9 ± 26.9 mm versus 46.3 ± 25.1 mm (p < .0001), CVSI 7.2 ± 3.75 versus 4.8 ± 2.8 (p < .0001), and ear offset 5.7 versus 5.5 mm (p = .58).

Conclusions

Helmet molding produces reproducible changes in head shape. Despite relatively small actual changes on topographic laser imaging, parents perceive a large correction in head shape and ear position following helmet molding. Craniofacial teams can use these data and head scans before helmet molding to provide parents with realistic expectations for the outcome of their child's helmet molding therapy.