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Skull and scalp ultrasound in children: a review
Abstract
INTRODUCTION : An important task of modern pediatrics is to ensure radiation safety of diagnostic examinations, especially in young children. One of the options for reducing radiation exposure at the stages of screening diagnostics and dynamic monitoring is a wider use of ultrasound.
OBJECTIVE: To analyze the data of domestic and foreign literature on the possibilities of ultrasound examination of the cranial vault bones, cranial sutures and scalp in children.
MATERIALS AND METHODS : The literature search was performed in open Russian and English databases Medline, PubMed, Web of Science, RSCI, eLIBRARY using keywords and phrases: «skull ultrasound», «scalp ultrasound», «cranial sutures ultrasound», «point of care ultrasound», «pediatric POCUS» without limitation of retrospective depth.
RESULTS: Based on the literature data and our own long-term experience in the use of cranial ultrasonography in clinical practice, the indications and examination technique, as well as the key ultrasound signs of the most frequent types of pathology are described. Prospects of scalp and skull ultrasonography within PoCUS, FAST, including the use of portable sonoscopes based on smartphones and tablets are outlined.
CONCLUSION : Ultrasound of the skull and scalp is a quick, simple, affordable, harmless method of screening and monitoring the most frequent types of pathologies of the cranial vault bones, cranial sutures, and soft tissues of the scalp in children (for example, fractures, synostoses, neoplasms).
Neuro-POCUS (Point-of-Care Ultrasound in neurology) is the international abbreviation for a new strategic direction in neuromedicine. It provides the clinician with a unique opportunity to perform neuroimaging themselves during patient examination or surgical manipulation to solve specifi c practical problems. In the domestic literature, the term «clinical-sonographic examination» was proposed for this approach. This direction is of particular importance in screening diagnosis, monitoring and surgical navigation in the most frequent and dangerous structural intracranial changes (hematomas, tumors, cysts, hydrocephalus, etc.). For the development of Neuro-POCUS technologies, an international scientifi c group was established in 2022, according to the report of which the assessment of brain parenchyma is discussed in the framework of monitoring midline shift and third ventricle width and mainly using transcranial color-coded duplex sonography. A review of the literature and our own 30 years of research suggest that B-mode transcranial ultrasonography is the optimal option for brain imaging within Neuro-POCUS. The history, foundations and prospects of Neuro-POCUS are discussed.
Background
The European EPI-CT study aims to quantify cancer risks from CT examinations of children and young adults. Here, we assess the risk of brain cancer.
Methods
We pooled data from nine European countries for this cohort study. Eligible participants had at least one CT examination before age 22 years documented between 1977 and 2014, had no previous diagnosis of cancer or benign brain tumour, and were alive and cancer-free at least 5 years after the first CT. Participants were identified through the Radiology Information System in 276 hospitals. Participants were linked with national or regional registries of cancer and vital status, and eligible cases were patients with brain cancers according to WHO International Classification of Diseases for Oncology. Gliomas were analysed separately to all brain cancers. Organ doses were reconstructed using historical machine settings and a large sample of CT images. Excess relative risks (ERRs) of brain cancer per 100 mGy of cumulative brain dose were calculated with linear dose-response modelling. The outcome was the first reported diagnosis of brain cancer after an exclusion period of 5 years after the first electronically recorded CT examination.
Findings
We identified 948 174 individuals, of whom 658 752 (69%) were eligible for our study. 368 721 (56%) of 658 752 participants were male and 290 031 (44%) were female. During a median follow-up of 5·6 years (IQR 2·4–10·1), 165 brain cancers occurred, including 121 (73%) gliomas. Mean cumulative brain dose, lagged by 5 years, was 47·4 mGy (SD 60·9) among all individuals and 76·0 mGy (100·1) among people with brain cancer. A significant linear dose-response relationship was observed for all brain cancers (ERR per 100 mGy 1·27 [95% CI 0·51–2·69]) and for gliomas separately (ERR per 100 mGy 1·11 [0·36–2·59]). Results were robust when the start of follow-up was delayed beyond 5 years and when participants with possibly previously unreported cancers were excluded.
Interpretation
The observed significant dose-response relationship between CT-related radiation exposure and brain cancer in this large, multicentre study with individual dose evaluation emphasises careful justification of paediatric CTs and use of doses as low as reasonably possible.
Funding
EU FP7; Belgian Cancer Registry; La Ligue contre le Cancer, L'Institut National du Cancer, France; Ministry of Health, Labour and Welfare of Japan; German Federal Ministry of Education and Research; Worldwide Cancer Research; Dutch Cancer Society; Research Council of Norway; Consejo de Seguridad Nuclear, Generalitat de Catalunya, Spain; US National Cancer Institute; UK National Institute for Health Research; Public Health England.
Minor blunt head trauma (MHT) represents a common reason for presentation to the pediatric emergency department (ED). Despite the low incidence of clinically important traumatic brain injuries (ciTBIs) following MHT, many children undergo computed tomography (CT), exposing them to the risk associated with ionizing radiation. The clinical predictions rules developed by the Pediatric Emergency Care Applied Research Network (PECARN) for MHT are validated accurate tools to support decision-making about neuroimaging for these children to safely reduce CT scans. However, a few non-ionizing imaging modalities have the potential to contribute to further decrease CT use. This narrative review provides an overview of the evidence on the available non-ionizing imaging modalities that could be used in the management of children with MHT, including point of care ultrasound (POCUS) of the skull, near-infrared spectroscopy (NIRS) technology and rapid magnetic resonance imaging (MRI). Skull ultrasound has proven an accurate bedside tool to identify the presence and characteristics of skull fractures. Portable handheld NIRS devices seem to be accurate screening tools to identify intracranial hematomas also in pediatric MHT, in selected scenarios. Both imaging modalities may have a role as adjuncts to the PECARN rule to help refine clinicians’ decision making for children at high or intermediate PECARN risk of ciTBI. Lastly, rapid MRI is emerging as a feasible and accurate alternative to CT scan both in the ED setting and when repeat imaging is needed. Advantages and downsides of each modality are discussed in detail in the review.
Purpose of Review
The objective of this review is to document the advances in non-ionising imaging alternatives to CT for the head and neck.
Recent Findings
The main alternative to CT for imaging bone of the head and neck region is MRI, particularly techniques which incorporate gradient echo imaging (Black Bone technique) and ultra-short or zero-echo time imaging. Since these techniques can provide high resolution isometric voxels, they can be used to provide multi-planar reformats and, following post processing, 3D reconstructed images of the craniofacial skeleton. As expected, the greatest advancements in recent years have been focused on enhanced image processing techniques and attempts to address the difficulties encountered at air-bone interfaces.
Summary
This article will review the imaging techniques and recent advancements which are bringing non-ionising alternatives to CT imaging of the bone of the head and neck region into the realm of routine clinical application.
A dermoid cyst is a benign lesion that may occur in different parts of the body. A dermoid cyst of the subgaleal space over the anterior fontanelle is rather uncommon. We present a case of congenital dermoid cyst of the anterior fontanelle in a 3-month-old male infant, underscoring the value of ultrasonography in the diagnosis and highlighting the classical clinical, sonographic, surgical, and pathological findings.
Craniosynostosis is a premature closure of the skull sutures, manifested by deformation of the head requiring surgical treatment. An instrumental examination of the state of the cranial sutures is necessary for the differential diagnosis of craniosynostosis and benign positional deformities of the skull in infants. Traditionally, radiation methods, such as X-ray and computed tomography with three-dimensional reconstruction, are used for this purpose. Over the past two decades, we have accumulated a large amount of data on the high information content of the ultrasound method in assessing the state of the cranial sutures in children. Ultrasound examination is widely available, easy to perform, reproducible; it does not require sedation of the patient and does not carry radiation exposure, which is especially important when examining young children. A negative result of the study makes it possible to exclude the diagnosis of craniosynostosis, while the detection of suture fusion serves as an indication for referring the child to visit a surgeon and further examination. The ultrasound method should be more widely used as a screening method for detecting head deformity and suspicion of craniosynostosis in children of the first year of life.
Introduction
The optimal protocol for diagnostic workup of craniosynostosis and the role of specific imaging modalities remain controversial. Skull X-rays and 3-dimensional head CTs are options when physical exam is equivocal but involve ionizing radiation. Ultrasound has emerged as an alternative modality for visualization of cranial sutures, but its use is not widespread.
Methods
The authors performed a systematic review of the literature on the use of ultrasound for the diagnosis of craniosynostosis.
Results
A total of 12 studies involving 1062 patients were included. Overall, 300 patients (28.2%) were diagnosed with craniosynostosis. A total of 369 (34.7%) patients had their diagnosis (craniosynostosis vs. patent sutures) confirmed with another imaging modality in addition to ultrasound. Among studies, the specificity of ultrasound ranged from 86 to 100%, and the sensitivity from 71 to 100%.
Conclusions
Ultrasonography of cranial sutures is a feasible and accurate tool for the diagnosis of single-suture craniosynostosis when physical exam findings are insufficient. Although technical aspects of ultrasonography and its interpretation have an associated learning curve, ultrasound can achieve high sensitivity and specificity among patients with suspected craniosynostosis.
Purpose
Posterior plagiocephaly (PP) is a common clinical condition in pediatric age. There are two main causes of PP: postural plagiocephaly and craniosynostosis. Early diagnosis is important, as it prevents neurological complications and emergencies. Diagnosis in the past was often made late and with imaging tests that subjected the infant to a high radiation load. Suture ultrasound does not use ionizing radiation; it is easy to perform, allows an early diagnosis, and directs toward the execution of the cranial 3D-CT scan, neurosurgical consultation, and possible intervention. The aim of the study is to describe the high sensitivity and specificity of suture ultrasound for the differential diagnosis between plagiocephaly and craniosynostosis.
Methods
We reported our prospective experience and compared it with the data in the literature through a systematic review. The systematic review was conducted on electronic medical databases (PubMed, Embase, Cochrane Library, Scopus, and Web of Science) evaluating the published literature up to November 2020. According to Preferred Reporting Items for Systematic Reviews and Meta-ANALYSES (PRISMA statement), we identified 2 eligible studies. Additionally, according to AMSTAR 2, all included reviews have been critically rated as high quality. A total of 120 infants with abnormal skull shape were examined in NICU. All underwent clinical and ultrasound examination.
Results
Of the total, 105 (87.5%) had plagiocephaly and 15 dolichocephaly/scaphocephaly (12.5%). None of these had associated other types of malformations and/or neurological disorders. The synostotic suture was identified ultrasonographically in 1 infant and subsequently confirmed by 3D CT scan (100%).
Conclusion
Cranial sutures ultrasonography can be considered in infants a selective, excellent screening method for the evaluation of skull shape deformities as first technique before the 3D CT scan exam and subsequent neurosurgical evaluation. Cranial suture ultrasonography should be considered part of clinical practice especially for pediatricians.
Neural tube defects can be accurately diagnosed prenatally. Every effort must be made to get this and its associations with Craniolacunia right, especially in low‐resource settings. This case highlights the importance of three‐dimensional CT in diagnosing neonatal skull abnormalities. Neural tube defects can be accurately diagnosed prenatally. Every effort must be made to get this and its associations with Craniolacunia right, especially in low‐resource settings. This case highlights the importance of three‐dimensional CT in diagnosing neonatal skull abnormalities.
Dermoid cysts are benign congenital lesions that usually appear on the surface of the skull, mainly on the anterior fontanelle. Diagnosis is usually made in the first months of life by physical examination and imaging studies such as CT, MRI, or ultra sound (US) Doppler. It is important to distinguish it from other similar lesions that represent greater surgical complexity, morbidity, and mortality. In this work, we show the principle differential diagnoses, the diagnostic approach, and the surgical technique used in the resection of the dermoid cyst located over the anterior fontanelle.
Subgaleal lipoma is a benign tumor of adipose tissue. It should be suspected when a semi-spherical avascular mass with well-defined margins, iso- or hyperechoic in most cases, with thin internal echogenic lines parallel to the long axis of the tumor, is observed between the galea aponeurosis and periosteum of the cranial bone. We report a series of cases of three patients who underwent surgical lesion excision and whose histopathological examination findings confirmed the diagnosis of lipoma.
Main teaching point:
The presence of long continuous echogenic lines within a lens-shaped soft tissue mass located beneath the galea aponeurosis may suggest the diagnosis of subgaleal lipoma.
Background
Blunt head trauma is a common presentation to emergency departments (EDs). Identifying skull fractures in children is important as they are known factor of risk for traumatic brain injury (TBI). Currently, CT is the reference standard for diagnosing skull fractures and TBIs in children. Identifying skull fractures with point-of-care ultrasound (POCUS) may help risk-stratify children for TBI following blunt trauma. The purpose of this study is to evaluate the sensitivity, specificity, positive predictive value and negative predictive value of POCUS in identifying skull fractures in children.
Methods
A systematic search was performed on 17 July 2020 in Ovid Medline, Cochrane Library, Google Scholar, Web of Science and Embase. Prospective studies reporting skull fractures diagnosed with ultrasound in children younger than 18 years due to blunt head injury were included. Studies that did not confirm the fracture with CT were excluded. The quality of studies was evaluated using the QUADAS-2 tool. Data were extracted from the eligible studies to calculate outcomes such as sensitivity and specificity; when possible overall outcomes were calculated.
Results
Seven studies were included. All eligible studies included patients for whom the decision to perform a CT scan was made in advance. Overall, the included studies demonstrated low risk of bias or had minor concerns regarding risk of bias. The pooled data (n=925) demonstrated a sensitivity of 91%, specificity of 96%, positive predictive value of 88% and negative predictive value of 97%.
Conclusion
The included studies demonstrate minor methodological limitations. Overall, the evidence suggests that POCUS is a valid option for diagnosing skull fractures in children visiting the ED after blunt head injury.
Diagnostic and therapeutic interventions in children for traumatic brain injury, which is known as the most important complication in trauma, require special attention. This study aimed to evaluate the accuracy of point-of-care ultrasound (POCUS) in diagnosing skull fracture in children with closed head injury in comparison with computed tomography (CT) scan. The current prospective cross-sectional study was conducted on children (0–14 years old), who were referred to the emergency department of a general teaching hospital in Shiraz, southern Iran (January–March 2018), with close head injury and were suspected of bone fracture. The participants were selected using a convenience sampling. The results of POCUS performed by emergency medicine (EM) residents were compared with the results of CT scan, which was reported by radiologists and considered a gold standard. Then, diagnostic tests were calculated. A total of 168 children were enrolled, with the mean ± standard deviation age of 6.21 ± 3.99. The most affected areas in the skull were the frontal (34.5%) and occipital areas (33.3%). POCUS had a sensitivity and specificity of 81.8% (95%CI, 48.2–97.7%) and 100% (95%CI, 97.7–100%), respectively. Positive and negative predictive values were 100% and 98.7%, with an accuracy of 98.8% in comparison with CT scan in the diagnosis of skull fracture.
Conclusion: The results showed that POCUS with a portable ultrasonography machine, performed by the EM’s physicians, have high diagnostic precision and can be considered a tool in the management of patients with closed head injury.What is Known:
• Some studies have investigated the accuracy of ultrasound in diagnosing skull bone fractures in children with closed head injury, but before conducting this survey, no definite evidence recommended POCUS for skull fracture in children with closed head trauma in the ED.
What is New:
• POCUS with a portable ultrasonography machine, performed by the EM’s physicians, has high diagnostic precision and can be considered a tool in the management of patients with closed head injury.
Objective: Among children with minor head trauma, the incidence of skull fractures is increased especially in those under one year of age. Several studies investigated the association between skull fracture and traumatic brain injury. In the present study, we aimed to test the potential of ultrasonography in detecting linear skull fracture in pediatric patients with minor head trauma. Methods: Patients under the age of 18 years with minor head trauma who presented to the emergency units of Bozok University Faculty of Medicine or Ordu University Training and Research Hospital between March 1, 2019 and November 1, 2019 and were planned to undergo head CT by their responsible physicians were included in the present study. The exclusion criteria were a Glasgow Coma Scale (GCS) score <14, traumatic open skull deformity, depressed skull fracture, penetrating head trauma, and hemodynamic instability. Results: A total of 62 patients (%64,5 males) with a mean age of 7.29 years were included. The sensitivity and specificity of ultrasound in detection of fractures were %84.6 (% 95 CI: 65.13- 95.6) and % 94.4 (% 95 CI: 81.3-99.3), respectively. Conclusion: In conclusion, we suggest that the use of ultrasound before CT examination in patients with minor head trauma may be a helpful means to detect cranial fractures.
Introduction:
Head trauma is a common reason for emergency department visits worldwide; many of which involve young children. We sought to determine if head ultrasound (US), as a portable, fast and safe modality, can guide diagnosis and treatment of children in emergency settings.
Methods:
In this cross-sectional study, brain computed tomography (CT) scan and emergency head US were performed on head trauma children who were referred to the emergency departments of Firouzgar and Besat Hospitals, Tehran, Iran, from September 2018 to May 2019. The findings of the two modalities were separately evaluated, and used to estimate the diagnostic accuracy of US.
Results:
538 patients with the mean age of 5.6 ± 4.9 (0-18) years were studied (54.8% male). Sensitivity and specificity of bedside US in detection of hemorrhage were 85.71% (42.13%-99.64%) and 97.99% (94.23%-99.58%) for children below the age of 2. These measures were 80.00% (51.91%-95.67%) and 97.97% (94.88%-99.44%), respectively, for those between 2 and 6 years old and 46.67% (21.27%-73.41%) and 92.90% (87.66%-96.40%), respectively, for those above the age of 6. Sensitivity and specificity were 92.31% (84.01%-97.12%) and 95.87% (93.62%-97.50%), respectively, in diagnosing skull fractures. Cohen's kappa coefficient varied greatly for different findings, ranging from 0.363 to 0.825, indicating different agreement rates for each.
Conclusion:
Based on our findings, emergency US can play a greater role in the initial management of head trauma children, especially as a triage test.
Background:. Diagnostic imaging for craniosynostosis currently relies entirely on radiation images, but it has been estimated that a risk of cancer from diagnostic x-rays may exist. Use of ultrasound imaging has been reported, but very little has been written on normal findings of the cranial suture. Also, ultrasound diagnostic methods have not been established. To obtain images for the diagnosis of abnormal sutures in craniosynostosis, we investigated the normal ultrasonographic appearance of the suture. To establish screening methods for craniosynostosis, we prepared a 2-point method for simple evaluation and confirmed its usefulness.
Methods:. Ultrasonography was performed in infants with normal head, deformational plagiocephaly, and craniosynostosis. We focused on the measurement indices and decided on the order for making our observations. Furthermore, we developed an evaluation method (2-point method) and recorded our finding in a useful table.
Results:. We could clearly judge whether the cranial suture was patent or closed and were able to measure the suture width. Even for 2-year-old children, the width of the sutures at the points measured exceeded the echocardiographic resolution. By using the 2-point evaluation method, all the sutures could be inspected in about 2 minutes. Sensitivity was 100% and specificity was 95.1%.
Conclusions:. Our present studies showed that normal or abnormal suture can be clearly distinguished by ultrasound. By evaluating the fixed points instead of the whole line, it was possible to shorten the inspection time. Ultrasound screening by applying the 2-point method is very useful.
Paediatric skull lesions are commonly identified on imaging. They can be challenging to image, given their location and size, and often require several imaging modalities to narrow down the differential diagnosis. Accurate diagnosis of these lesions is paramount because the clinical therapy can vary tremendously. In this review, we provide a simple and systematic approach to clinical-radiological features of primary skull lesions. We highlight the imaging characteristics and differentiate pathologies based on imaging appearances. We also accentuate the role of cross-sectional imaging in lesion identification and management implications.
Calvarial lesions are often asymptomatic and are usually discovered incidentally during computed tomography or magnetic resonance imaging of the brain. Calvarial lesions can be benign or malignant. Although the majority of skull lesions are benign, it is important to be familiar with their imaging characteristics and to recognise those with malignant features where more aggressive management is needed. Clinical information such as the age of the patient, as well as the patient’s history is fundamental in making the correct diagnosis. In this article, we will review the imaging features of both common and uncommon calvarial lesions, as well as mimics of these lesions found in clinical practice.
Teaching Points
• Skull lesions are usually discovered incidentally; they can be benign or malignant.
• Metastases are the most frequent cause of skull lesions.
• Metastatic lesions are most commonly due to breast cancer in adults and neuroblastoma in children.
• Multiple myeloma presents as the classic “punched out” lytic lesions on radiographs.
• Eosinophilic granuloma is an osteolytic lesion with bevelled edges.
Background. Birth head trauma causing intracranial injury is one of the most common causes of neonatal mortality and morbidity. In case of suspected cranial fractures and intracranial hematomas, diagnostic methods involving radiation, such as x-ray radiography and computed tomography, are recommended. Recently, an increasing number of studies have highlighted the risk of cancer complications associated with computed tomography in infants. Therefore, diagnostic methods that reduce radiation exposure in neonates are important. One such method is ultrasonography (US).
Aim. We evaluated US as a non-ionizing radiation method for diagnosis of cranial bone fractures and epidural hematomas in newborns with cephalohematomas or other birth head traumas.
Material and methods. The study group included 449 newborns with the most common variant of birth head trauma: cephalohematomas. All newborns underwent transcranial-transfontanelle US for detection of intracranial changes and cranial US for visualization of bone structure in the cephalohematoma region. Children with ultrasonic signs of cranial fractures and epidural hematomas were further examined at a children’s hospital by x-ray radiography and/or computed tomography.
Results and discussion. We found that cranial US for diagnosis of cranial fractures and transcranial-transfontanelle US for diagnosis of epidural hematomas in newborns were highly effective. In newborns with parietal cephalohematomas (444 children), 17 (3.8%) had US signs of linear fracture of the parietal bone, and 5 (1.1%) had signs of ipsilateral epidural hematoma. Epidural hematomas were visualized only when US was performed through the temporal bone and not by using the transfontanelle approach. Sixteen cases of linear fractures and all epidural hematomas were confirmed by computed tomography.
Conclusion. The use of US diagnostic methods reduced radiation exposure in newborns with birth head trauma. US methods (transcranial-transfontanelle and cranial) can be used in screening for diagnosis and personalized monitoring of changes in birth head trauma as well as to reduce radiation exposure.
Purpose:
Skull radiography (SR) and Computed Tomography (CT) are still proposed as the first-line imaging choice for the diagnosis of craniosynostosis (CS) in children with abnormal head shape, but both techniques expose infants to ionizing radiation. Several studies shown that ultrasound may play an important role in the diagnosis of craniosynostosis. The aim of our study is to assess the diagnostic accuracy of cranial ultrasound scan (CUS) and confirm if it is a reliable first step imaging evaluation for the diagnosis of craniosynostosis in newborn.
Method:
A cohort of 196 infants (122/74 males/females), with a mean age of 4 months, clinically suspected to have abnormal closure of cranial sutures, were firstly examined by CUS and then referred to neuroradiologists to perform volumetric CT scan if the suspicion of stenosis was ecographically confirmed; otherwise, a routine follow-up and physical treatment was performed, to observe the evolution of the head shape.
Results:
Of the 196 children studied by CUS, only two had inconclusive studies due to age limitation (>12 months). Thirty children were diagnosed with cranial synostosis at CUS and verified by CT; all the CUS results were confirmed, except two cases, that were revealed as false positives in the starting phase of the study. Twelve patients with very prominent head deformity and negative CUS underwent CT, which confirmed the CUS results in all of them; one case of closure of both temporal sutures, not studied by CUS, was documented by CT. All the 148 children with poor clinical suspicion and negative CUS underwent just a prolonged clinical follow-up. In all of them, a progressive normalization of head shape was observed, and the craniosynostosis was excluded on a clinical base.
Conclusions:
CUS is a highly specific and sensitive imaging technique. In referral centers, expert hands can use it as a reliable first-step screening for infants younger than 1 year, suspected to have a craniosynostosis, thus avoiding unnecessary exposure to ionizing radiation. The "golden age" to obtain the best CUS results is under 6 months of life. Because the method is operator-dependent and there is a learning curve, a case centralization is advisable.
Background
Minimizing the ionizing radiation dose to children is fundamental to pediatric radiology. The most widely accepted imaging examination for evaluating craniosynostosis is computed tomography (CT) of the head, an examination that involves ionizing radiation. Objective
To determine if sonography of the cranial sutures is an adequate screening examination for the diagnosis of craniosynostosis in patients with abnormal skull shape. Materials and methodsA retrospective review of all cranial suture ultrasound (US) examinations performed during the course of a 3-year period (July 2012 – September 2015) was undertaken. Results were compared with clinical follow-up and/or head CT to evaluate the accuracy of this modality as a screening tool to determine the presence or absence of craniosynostosis. Fifty-two sonographic exams were adequate for inclusion. ResultsForty-five of the examinations did not reveal synostosis. In each of these instances, follow-up physical exam findings and/or CT imaging confirmed that no abnormal premature suture closure was present. US findings demonstrated synostosis in seven cases. CT exam or operative reports of these cases confirmed all seven findings of premature suture closure. Statistical analysis demonstrated a sensitivity of 100% (95% confidence interval [CI]: 56.1–100.0%), a specificity of 100% (95% CI: 90.2–100.0%), and a negative predictive value of 100% (95% CI: 90.2–100.0%). Conclusion
Cranial US is a reliable screening tool to rule out craniosynostosis in patients with abnormal head shape.
Background:
Radiography, typically the first-line imaging study for diagnosis of craniosynostosis, exposes infants to ionizing radiation. We aimed to compare the accuracy of cranial ultrasound (CUS) with radiography for the diagnosis or exclusion of craniosynostosis.
Methods:
Children aged 0 to 12 months who were assessed for craniosynostosis during 2011-2013 by using 4-view skull radiography and CUS of the sagittal, coronal, lambdoid, and metopic sutures were included in this prospective study. Institutional review board approval and parental informed consent were obtained. CUS and radiography were interpreted independently and blindly by 2 pediatric radiologists; conflicts were resolved in consensus. Sutures were characterized as closed, normal, or indeterminate. Correlation between CUS and radiography and interreader agreement were examined for each suture.
Results:
A total of 126 children (82 boys, 64.5%) ages 8 to 343 days were included. All sutures were normal on CUS and radiography in 115 patients (93.7%); craniosynostosis of 1 suture was detected in 8 (6.3%, 5 sagittal, 2 metopic, 1 coronal). In 3 cases the metopic suture was closed (n = 2) or indeterminate on CUS (n = 1) but normally closed on radiography. CUS sensitivity was 100%, specificity 98% (95% confidence interval 94%-100%). Reader agreement was 100% for sagittal, coronal, and lambdoid sutures (κ = 0.80); after consensus, disagreement remained on 3 metopic sutures.
Conclusions:
In this series, CUS could be safely used as a first-line imaging tool in the investigation of craniosynostosis, reducing the need for radiographs in young children. Additional assessment may be required for accurate assessment of the metopic suture.
Objective:
To determine the test performance characteristics for point-of-care ultrasound performed by clinicians compared with computed tomography (CT) diagnosis of skull fractures.
Methods:
We conducted a prospective study in a convenience sample of patients ≤21 years of age who presented to the emergency department with head injuries or suspected skull fractures that required CT scan evaluation. After a 1-hour, focused ultrasound training session, clinicians performed ultrasound examinations to evaluate patients for skull fractures. CT scan interpretations by attending radiologists were the reference standard for this study. Point-of-care ultrasound scans were reviewed by an experienced sonologist to evaluate interobserver agreement.
Results:
Point-of-care ultrasound was performed by 17 clinicians in 69 subjects with suspected skull fractures. The patients' mean age was 6.4 years (SD: 6.2 years), and 65% of patients were male. The prevalence of fracture was 12% (n = 8). Point-of-care ultrasound for skull fracture had a sensitivity of 88% (95% confidence interval [CI]: 53%-98%), a specificity of 97% (95% CI: 89%-99%), a positive likelihood ratio of 27 (95% CI: 7-107), and a negative likelihood ratio of 0.13 (95% CI: 0.02-0.81). The only false-negative ultrasound scan was due to a skull fracture not directly under a scalp hematoma, but rather adjacent to it. The κ for interobserver agreement was 0.86 (95% CI: 0.67-1.0).
Conclusions:
Clinicians with focused ultrasound training were able to diagnose skull fractures in children with high specificity.
Although CT scans are very useful clinically, potential cancer risks exist from associated ionising radiation, in particular for children who are more radiosensitive than adults. We aimed to assess the excess risk of leukaemia and brain tumours after CT scans in a cohort of children and young adults.
In our retrospective cohort study, we included patients without previous cancer diagnoses who were first examined with CT in National Health Service (NHS) centres in England, Wales, or Scotland (Great Britain) between 1985 and 2002, when they were younger than 22 years of age. We obtained data for cancer incidence, mortality, and loss to follow-up from the NHS Central Registry from Jan 1, 1985, to Dec 31, 2008. We estimated absorbed brain and red bone marrow doses per CT scan in mGy and assessed excess incidence of leukaemia and brain tumours cancer with Poisson relative risk models. To avoid inclusion of CT scans related to cancer diagnosis, follow-up for leukaemia began 2 years after the first CT and for brain tumours 5 years after the first CT.
During follow-up, 74 of 178,604 patients were diagnosed with leukaemia and 135 of 176,587 patients were diagnosed with brain tumours. We noted a positive association between radiation dose from CT scans and leukaemia (excess relative risk [ERR] per mGy 0·036, 95% CI 0·005-0·120; p=0·0097) and brain tumours (0·023, 0·010-0·049; p<0·0001). Compared with patients who received a dose of less than 5 mGy, the relative risk of leukaemia for patients who received a cumulative dose of at least 30 mGy (mean dose 51·13 mGy) was 3·18 (95% CI 1·46-6·94) and the relative risk of brain cancer for patients who received a cumulative dose of 50-74 mGy (mean dose 60·42 mGy) was 2·82 (1·33-6·03).
Use of CT scans in children to deliver cumulative doses of about 50 mGy might almost triple the risk of leukaemia and doses of about 60 mGy might triple the risk of brain cancer. Because these cancers are relatively rare, the cumulative absolute risks are small: in the 10 years after the first scan for patients younger than 10 years, one excess case of leukaemia and one excess case of brain tumour per 10,000 head CT scans is estimated to occur. Nevertheless, although clinical benefits should outweigh the small absolute risks, radiation doses from CT scans ought to be kept as low as possible and alternative procedures, which do not involve ionising radiation, should be considered if appropriate.
US National Cancer Institute and UK Department of Health.
The purpose of this study was to describe the normal sonographic appearance and measurement of normal major cranial sutures in neonates and infants.
High-resolution sonograms of sagittal, coronal, and lambdoid sutures were obtained for two autopsy specimens and correlated with histologic sections obtained at identical locations. Also, 50 neonates and infants (0-5 months old [corrected age]) who had normally shaped craniums underwent sonography of the brain that produced normal findings. These neonates and infants also underwent sutural sonograms. The width and thickness of each of the major cranial sutures (sagittal, coronal, and lambdoid) were measured, with mean values established. Measurements were analyzed with paired t tests for interobserver variability. Linear regression was used for correlation of measurements with age.
With a scan plane perpendicular to the suture line, sonograms revealed sutures as hypoechoic gaps between two hyperechoic bony plates. On sonograms, sagittal sutures had an end-to-end appearance instead of the beveled junction seen throughout most of the coronal and lambdoid sutures. In the 50 patients, sonograms revealed the mean width to be 0.89 +/- 0.35 mm (mean +/- SD) for coronal sutures. 0.93 +/- 0.28 mm for sagittal sutures, and 0.96 +/- 0.39 mm for lambdoid sutures. On sonograms, mean thickness was 1.97 +/- 0.54 mm for coronal sutures, 1.88 +/- 0.56 mm for sagittal sutures, and 2.49 +/- 0.86 mm for lambdoid sutures. We found no interobserver variability (p < or = .05). With linear regression analysis, we found no correlation between suture width or thickness and patient age (r = .01).
In our study, high-resolution sonography proved to be a reliable and inexpensive technique capable of defining cranial sutures. Preliminary normative data obtained for cranial suture width and thickness showed no correlation with age in our population group. The normative data obtained will allow recognition of abnormal sutures, particularly synostotic or diastatic sutures.
The purpose of this investigation is to elucidate the sonographic features of abnormal major cranial sutures.
Eight excised synostosed suture specimens were evaluated. The high-resolution sonographic appearance was correlated with the histological section, plain radiographs, CT and MRI. Diastatic and molded sutures were also evaluated with sonography and compared with the normal cranial suture appearance.
Synostosed sutures demonstrated one or more of the following features: (a) loss of echo-poor fibrous gap between bony plates (five sagittal and coronal synostoses); (b) irregular thickened inner sutural margin (three lambdoid synostoses); (c) loss of bevelled edge (one lambdoid synostosis); (d) asymmetric anterior fontanelle (one coronal synostosis). Cranial molding results in an overlap of echogenic bony plates. Sutural width (the distance between bony plates) is increased in cases of elevated intracranial pressure.
Sonography is an inexpensive, radiation-free modality which can confirm synostosis versus molding versus an underlying intracranial lesion as a cause of plagiocephaly. The high-resolution sonographic images also provide a relatively easy means to assess sutural width and may provide information in regard to increased intracranial pressure.
The neuroradiologic findings in the Chiari II malformation are well known. Luckenschadel (lacunar skull) is commonly seen in patients with Chiari II on plain film and with computed tomography (CT). However, the sonographic appearance of luckenschadel has not previously been described. paragraph signObjective. To evaluate the presence or absence of luckenschadel on neurosonograms from infants with myelomeningocele.
Twenty-one neurosonograms in patients with myelomeningocele were reviewed for the presence of an irregular inner calvarial table indicative of luckenschadel. The degree of irregularity was graded and compared with CT and plain film when available. The ventricular index was calculated from the ultrasound (US) studies and correlated with degree of luckenschadel using one-way analysis of variance.
Nine patients had marked findings of luckenschadel, nine had mild findings, and three had normal US exams. There was no correlation between the degree of sonographic luckenschadel and the ventricular index.
The finding of luckenschadel adds to the spectrum of abnormalities of the Chiari II malformation diagnosed by US.
Dermoids and epidermoids are defined as ectodermal inclusion cysts. The aim of this study was to evaluate the spontaneous natural behavior and the ultrasonographic appearance of calvarial dermoids and epidermoids.
The ultrasonographic image datasets of 100 consecutive children up to 4 years of age (52 females, 48 males; age range at first examination 1 week to 40 months, mean age 8.3 +/- 6.9 months) presenting with a firm palpable calvarial mass (103 lesions) were studied retrospectively. All ultrasound (US) examinations were performed using a 7- to 10-MHz linear transducer including B-mode and color Doppler sonography. US follow-up studies (up to 47 months) could be achieved in 30 patients with 33 lesions.
At first presentation, all 103 lesions demonstrated very similar US features: a round or oval configuration (diameter 3-18 mm), hypoechogenic, and homogeneous internal structures with a marked hyperechogenic superficial capsule, which were localized adjacent to or expanded into the osseous external calvarial table. No conspicuous flow signs on color Doppler were seen. In 33 lesions with US follow-up investigations, 49% showed variable signs of regression: reduction of size, increase of internal echogenicity, and decrease of demarcation. Eight lesions (24%) remained unchanged. A slight progression up to a maximum diameter of 17 mm but without any increase in osseous destruction was observed in the remainder (27%). There was no lesion with a complete destruction of the underlying bone and no intracranial extension in any of the cases.
Calvarial dermoids and epidermoids in infants and children show a benign natural behavior with spontaneous regression in a large number of cases. On US, they demonstrate uniform pathognomonic features enabling the correct diagnosis in any of those lesions. Thus, additional, mainly radiation burdening and sometimes misleading imaging techniques should be restricted. Surgical treatment protocols should be handled conservatively and lesions should be primarily followed-up clinically and by US.
Currently, there are no standards for examining patients with suspected craniosynostosis. CT of the brain with 3D skull reconstruction is a common approach to diagnose craniosynostosis in many hospitals. This technique in pediatric patients is associated with a high dose of ionizing radiation and prompts searching for other diagnostic methods.
Objective:
To generalize an experience of cranial suture ultrasound and compare diagnostic capabilities of various ultrasound devices.
Material and methods:
We retrospectively analyzed data of cranial suture ultrasound in 49 patients under the age of 14 months with a suspected craniosynostosis. All patients underwent expert-class ultrasound. Of these, 10 patients underwent middle-class ultrasound. Age of these patients ranged from 2 to 10 months.
Results:
According to ultrasound data, we have found 48 synostotic sutures in 42 patients. There were 2 inaccurate results among these 48 sutures. In both cases, expert-class ultrasound confirmed partial closure of cranial sutures while 3D CT revealed their complete closure. Sensitivity and specificity of technique were 95.8% and 100%, respectively. Both expert- and middle-class ultrasound revealed synostotic sutures in 10 children under 1 year old.
Conclusion:
Our data have shown that ultrasound of cranial sutures may be a first-line imaging technique. This method has high sensitivity and specificity in pediatric patients. Moreover, middle-class ultrasound devices may be used for diagnosis.
Context.—Primary skull lesions are rare in the pediatric population. The differential diagnosis of these lesions is broad and includes both congenital and acquired lesions. Previous studies of skull lesions in the pediatric population suggest that dermoid/epidermoid tumors are the most common childhood skull tumors.
Objective.—To review the clinicopathologic features of primary skull lesions identified within the pediatric population of an academic tertiary medical center.
Design.—A retrospective review of surgical pathology reports during a 25-year period identified 19 primary skull lesions occurring in the pediatric population. Lesions were excluded if they were of known soft tissue or intracranial origin with secondary calvarial involvement, or if they represented a metastasis from a known primary malignancy.
Results.—Nineteen primary skull lesions were identified in 11 male (58%) and 8 female (42%) patients, with a median age at diagnosis of 9.5 years. These lesions were usually benign and most commonly presented as a painless mass (n = 8). The lesions were located in the occipital bone (n = 7), frontal bone (n = 5), parietal bone (n = 2), and temporal bone (n = 1). Diagnoses included epidermoid/ dermoid cyst (n = 8), Langerhans cell histiocytosis (n = 6), intraosseous hemangioma (n = 2), osteoblastoma (n = 1), infantile myofibroma (n = 1), and fibroma (n = 1). Intracranial extension was identified in 1 case, and recurrence was found in only 2 cases.
Conclusions.—Epidermoid/dermoid cysts and Langerhans cell histiocytosis are the most commonly encountered skull lesions in the pediatric population at our institution. Intracranial extension of these lesions is rare, and recurrence is uncommon following complete surgical resection.
Background:
Head trauma is a common reason for evaluation in the emergency department. The evaluation for traumatic brain injury involves computed tomography, exposing children to ionizing radiation. Skull fractures are associated with intracranial bleed. Point-of-care ultrasound (POCUS) can diagnose skull fractures.
Objectives:
We performed a systematic review/meta-analysis to determine operating characteristics of POCUS skull studies in the diagnosis of fractures in pediatric head trauma patients.
Methods:
We searched PubMed, EMBASE, and Web of Science for studies of emergency department pediatric head trauma patients. Quality Assessment Tool for Diagnostic Accuracy Studies 2 was used to evaluate risk of bias. Point-of-care ultrasound skull study operating characteristics were calculated and pooled using Meta-DiSc.
Results:
Six studies of 393 patients were selected with a weighted prevalence of 30.84%. Most studies were at low risk of bias. The pooled sensitivity (91%) and specificity (96%) resulted in pooled positive likelihood ratio (14.4) and negative likelihood ratio (0.14). Using the weighted prevalence of skull fractures across the studies as a pretest probability (31%), a positive skull ultrasound would increase the probability to 87%, whereas a negative test would decrease the probability of a skull fracture to 6%. To achieve a posttest probability of a skull fracture of ~2% would require a negative skull ultrasound in a patient with only a pretest probability of ~15%.
Conclusions:
A POCUS skull study significantly increases the probability of skull fracture, whereas a negative study markedly decreases the probability if the pretest probability is very low.
Introduction:
The aim of this article was to provide an overview of ultrasound (US) techniques for the investigation of cranial sutures in infants.
Material and methods:
We first describe a high-resolution sonography technique and its limitations. We then analyze the reliability, effectiveness and role of ultrasonography in routine practice using a PubMed literature review.
Results:
Ten studies reported excellent correlations between ultrasonography and 3D-CT. Cranial US for the diagnosis of a closed suture had 100% sensitivity in 8 studies and 86-100% specificity before the age of 12 months. Negative findings mean imaging investigation can be stopped. If ultrasonography confirms diagnosis, neurosurgical consultation is required. Thus, 3D-CT can be postponed until appropriate before surgery.
Conclusion:
Cranial suture ultrasound is an effective and reliable technique for the diagnosis of craniosynostosis. It has many advantages: it is fast and non-irradiating, and no sedation is required. It should be used as first-line imaging in infants below the age of 8-12 months when craniosynostosis is clinically suspected.
Langerhans cell histiocytosis is a tumor-like condition characterized by idiopathic proliferation of Langerhans cells. The disease may involve the skeleton as well as other organs systems. Bone involvement may be solitary or multifocal. Unifocal osseous Langerhans cell histiocytosis may involve virtually any bone, with the calvarium being most frequently involved. Plain radiography, computed tomography and magnetic resonance imaging are the most used techniques for detection and characterization of the lesion. The use of ultrasound is less known, although it may be a valuable technique in detection and follow-up of superficially located lesions such as calvarial lesions. This case report describes an 8-year-old girl, in whom the lesion was initially detected by ultrasound. Furthermore, ultrasound was used to evaluate spontaneous resolution of the lesion. The knowledge of ultrasound characteristics may be important to avoid unnecessary radiation and gadolinium administration, particularly in a pediatric population.
Superficial palpable masses of the head and neck are common in the pediatric population, with the vast majority of the lesions ultimately proven to be benign. Duplex ultrasonography (US) has emerged as the first-line imaging modality for the evaluation of superficial pediatric masses. Without utilizing radiation, iodinated contrast material, or sedation and/or anesthesia, US provides a means for quick and cost-effective acquisition of information, including the location, size, shape, internal content, and vascularity of the mass. In this review, the US findings are described for a variety of common and uncommon pediatric head and neck masses diagnosed in our practice. Specifically, the entities covered include neonatal scalp hematoma, craniosynostosis, dermoid and epidermoid cysts, Langerhans cell histiocytosis, lymph nodes and their complications, fibromatosis colli, thyroglossal duct cyst, branchial cleft cyst, cervical thymus, congenital goiter, thyroid papillary carcinoma, parathyroid adenoma, hemangioma, lymphangioma, jugular vein phlebectasia, Lemierre syndrome, acute parotitis and parotid abscess, leukemia and/or lymphoma, neurogenic tumor, and rhabdomyosarcoma. Ultimately, in situations in which the head or neck mass is too large, deep, or hyperechoic to be fully assessed within the US field of view, or if malignancy or a high-flow vascular lesion is suspected, then further evaluation with cross-sectional imaging is warranted. Online supplemental material is available for this article. ©RSNA, 2018.
Objectives:
The aim of this study was to investigate the accuracy of bedside ultrasound (US) performed by emergency physicians for diagnosing skull fractures in children 0 to 4 years old compared with the accuracy of head computed tomography (CT). We also sought to investigate characteristics and precautions associated with US.
Methods:
This single-center prospective study involved children 0 to 4 years old who had a history of head trauma. Bedside US was performed by emergency medicine physicians, and the results were compared with CT scan interpretations provided by attending radiologists. The accuracy of US for the diagnosis of skull fractures was calculated, and the errors were reviewed.
Results:
A total of 87 patients were enrolled. Skull fracture was present in 13 patients (14.9%), according to CT. Bedside US had a sensitivity and specificity of 76.9% (95% confidence interval [CI], 46.0%-93.8%) and 100% (95% CI, 93.9%-100%), respectively. Overall positive predictive value was 100% (95% CI, 65.5%-100%), and negative predictive value was 96.1% (95% CI, 88.3%-99.0%). Three false-negative cases were observed.
Conclusions:
Bedside US performed by emergency medicine physicians with short focused US training is a useful tool for diagnosing skull fractures in children 0 to 4 years of age. However, there were 3 false-negative cases. A meticulous examination is needed in the area adjacent to the orbital wall and skull base.
Objectives:
To determine the accuracy of skull point-of-care ultrasound (POCUS) for identifying fractures in children younger than 2 years of age with signs of head trauma, and the ability of POCUS to identify the type and depth of fracture depression.
Study design:
This was a multicenter, prospective, observational study of children younger than 2 years of age with nontrivial mechanisms of injury and signs of scalp/skull trauma. Patients were enrolled if they underwent computed tomography (CT). Patients underwent clinical evaluation, in addition to a cranial POCUS in the emergency department (ED). From the POCUS examinations, we documented whether fractures were present or absent, their location, characteristics, and depth. POCUS and CT findings were compared to calculate the diagnostic accuracy.
Results:
We enrolled a convenience sample of 115 of 151 (76.1%) eligible patients. Of the 115 enrolled, 88 (76.5%) had skull fractures. POCUS had a sensitivity of 80 of 88 (90.9%; 95% CI 82.9-96.0) and a specificity of 23 of 27 (85.2%; 95% CI 66.3-95.8) for identifying skull fractures. Agreement between POCUS and CT to identify the type of fracture as linear, depressed, or complex was 84.4% (97 of 115) with a kappa of 0.75 (95% CI 0.70-0.84).
Conclusions:
POCUS performed by emergency physicians may identify the type and depth of fractures in infants with local physical signs of head trauma with substantial accuracy. Emergency physicians should consider POCUS as an adjunct to clinical evaluation and prediction rules for traumatic brain injuries in children younger than 2 years of age.
Objectives
The aim of this study was to report our experience with ultrasonography in our routine practice for the diagnosis of cranial deformity in infants.
Methods
We conducted a single-institution retrospective study of infants referred to our department because of skull deformity. We only included in this study infants having undergone both US and 3D-CT to ensure accurate comparisons. Each cranial suture was described as normal or closed (partial or complete closure). Sonography examination results were correlated with 3D-CT findings as a gold-standard.
Results
Forty infants were included with a mean age of 5.2 ± 4.9 months. Thirty had a craniosynostosis and 10 children had a postural deformity with normal sutures. Correlation between US and 3D-CT for the diagnosis of normal or closed suture had a specificity and a sensitivity of 100%. US examination for the diagnosis of complete or incomplete synostosis had a sensitivity of 100%.
Conclusions
Cranial US is an effective technique to make a positive or negative diagnosis of prematurely closed suture. US examination of sutures is a fast and non-radiating technique, which may serve as a first-choice imaging modality in infants with skull deformity.
Objective:
Medical radiation-induced cataracts, especially those resulting from head and neck CT studies, are an issue of concern. The current study aimed to determine the risk of cataract associated with repeated radiation exposure from head and neck CT.
Materials and methods:
This study used information from a random sample of 2 million persons enrolled in the nationally representative Taiwan National Health Insurance Research Database. Exposed cases consisted of patients with head and neck tumor 10-50 years old who underwent at least one CT between 2000 and 2009. The nonexposed control group was composed of subjects who were never exposed to CT studies but who were matched by time of enrollment, age, sex, history of coronary artery disease, hypertension, and diabetes.
Results:
There were 2776 patients in the exposed group and 27,761 matched subjects in the nonexposed group. The exposed group had higher overall incidence of cataracts (0.97% vs 0.72%; adjusted hazard ratio [HR], 1.76; 95% CI, 1.18-2.63). Further stratifying the number of CT studies in the exposed group into one or two, three or four, and five or more revealed that cataract incidence increased gradually with increasing frequency of CT studies (0.79%, 0.93%, and 1.45%, respectively) (p=0.001, adjusted for trend). Radiation exposure due to repeated head and neck CT studies was independently associated with an increased risk of developing cataracts when the cumulative CT exposure frequency involved more than four studies (adjusted HR, 2.12; 95% CI, 1.09-4.14).
Conclusion:
Repeated exposure to head and neck CT is significantly associated with increased risk of cataract.
The current study was performed to assess the diagnostic accuracy of ultrasound compared to CT scan as a gold standard in the diagnosis of craniosynostosis. 44 infants (17 girls) under 1 year old, clinically suspected to have craniosynostosis, were first sonographically examined by a pediatric radiologist and were later referred to another blinded pediatric radiologist to examine CT scan with 3D reconstructed images of skull. Sensitivity, specificity, positive and negative predictive values of ultrasound versus CT scan were 96.9%, 100%, 100%, and 92.3%, respectively. The high specificity of ultrasound helps to correctly rule out craniosynostosis in clinically suspected cases and thus, can prevent unnecessary exposure of healthy infants to CT scan ionizing radiation.
Langerhans cell histiocytosis (LCH) is an infrequent disorder of unknown origin associated with histiocytic proliferation. The bones' involvement (including cranial bones) is the most frequent manifestation of pediatric LCH. Imaging of skull LCH is based predominantly on conventional radiography, CT, scintigraphy, and sometimes MRI. The aim of the study was to investigate the role of sonography (US) in the diagnosis and monitoring of bone lesions in children with localized LCH of the skull.
Twenty-seven children (15 boys/12 girls, mean age 6.1 years) were diagnosed between 1991 and 2005 in the Department of Pediatrics at the Medical University of Gdansk, Poland. Fourteen children (52%) had localized LCH of the skull.
All lesions of the skull visible on CT were visualized on US examination. Overall, 30 focal lesions were revealed by US. The largest bone lesions were accompanied by changes within the adjacent soft tissues. CT revealed 26 lesions, the location and size of which corresponded to the lesions seen on US, but soft-tissue changes adjacent to the bony lesions were difficult to visualize.
The US appearance of focal LCH lesions in cranial bones in children is not pathognomonic, but is characteristic enough to suggest an initial diagnosis and to monitor the evolution of lesions during treatment. US should be considered an additional diagnostic tool for LCH of the skull. Although US of localized LCH cannot replace CT, it could reduce the number of follow-up CT examinations. © 2012 Wiley Periodicals, Inc. J Clin Ultrasound, 2013
Background:
Blunt head trauma is a common reason for medical evaluation in the pediatric Emergency Department (ED). The diagnostic work-up for skull fracture, as well as for traumatic brain injury, often involves computed tomography (CT) scanning, which may require sedation and exposes children to often-unnecessary ionizing radiation.
Objectives:
Our objective was to determine if bedside ED ultrasound is an accurate diagnostic tool for identifying skull fractures when compared to head CT.
Methods:
We present a prospective study of bedside ultrasound for diagnosing skull fractures in head-injured pediatric patients. A consecutive series of children presenting with head trauma requiring CT scan was enrolled. Cranial bedside ultrasound imaging was performed by an emergency physician and compared to the results of the CT scan. The primary outcome was to identify the sensitivity, specificity, and predictive values of ultrasound for skull fractures when compared to head CT.
Results:
Bedside emergency ultrasound performs with 100% sensitivity (95% confidence interval [CI] 88.2-100%) and 95% specificity (95% CI 75.0-99.9%) when compared to CT scan for the diagnosis of skull fractures. Positive and negative predictive values were 97.2% (95% CI 84.6-99.9%) and 100% (95% CI 80.2-100%), respectively.
Conclusions:
Compared to CT scan, bedside ultrasound may accurately diagnose pediatric skull fractures. Considering the simplicity of this examination, the minimal experience needed for an Emergency Physician to provide an accurate diagnosis and the lack of ionizing radiation, Emergency Physicians should consider this modality in the evaluation of pediatric head trauma. We believe this may be a useful tool to incorporate in minor head injury prediction rules, and warrants further investigation.
The objective of this study was to investigate feasibility and evaluate test characteristics of bedside ultrasound for the detection of skull fractures in children with closed head injury (CHI).
This was a prospective, observational study conducted in a pediatric emergency department of an urban tertiary care children's hospital. A convenience sample of children younger than 18 years were enrolled if they presented with an acute CHI, and a computed tomography (CT) scan was performed. Ultrasound was performed by pediatric emergency medicine physicians with at least 1 month of training in bedside ultrasound. Ultrasound interpretation as either positive or negative for the presence of skull fracture was compared with attending radiologist CT scan dictation. Test characteristics (sensitivity, specificity, and positive and negative predictive values) were calculated.
Forty-six patients were enrolled. The median age was 2 years (range, 2 months to 17 years). Eleven patients (24%) were diagnosed with skull fractures on CT scan. Bedside ultrasound had a sensitivity of 82% (95% confidence interval [CI], 48%-97%), specificity of 94% (95% CI, 79%-99%), positive predictive value of 82% (95% CI, 48%-97%), and negative predictive value of 94% (95% CI, 79%-99%).
Bedside ultrasonography can be used by pediatric emergency medicine physicians to detect skull fractures in children with acute CHI. Larger studies are needed to validate these findings. Future studies should investigate the role of this modality as an adjunct to clinical decision rules to reduce unnecessary CT scans in the evaluation of acute CHI in children.
Secondary to the increase in deformational plagiocephaly a growing number of infants with cranial deformity present to craniofacial teams. Computed tomography (CT) is diagnostic, but uses ionizing radiation. The purpose of this study was to evaluate ultrasound as a screening test for the patency of cranial sutures in scaphocephaly and occipital plagiocephaly. The cranial sutures of 54 infants with this cranial deformity were assessed by ultrasound. Sutures were read as patent or fused if a hypoechoic gap could or could not be demonstrated between the hyperechoic clavarial bones, respectively. Seven children suffered from true craniosynostosis of either the sagittal or the lambdoid suture. In five cases the ultrasound findings were diagnostic for a fused suture, in two cases the results were inconclusive. Forty-seven infants presented with deformational plagiocephaly. Ultrasound examination demonstrated patent sutures in 45 cases and was inconclusive in two cases. Sonography of the cranial sutures is a good screening tool to distinguish fused from patent cranial sutures in scaphocephaly and occipital plagiocephaly and avoids the radiation exposure associated with CT examinations.
Bedside ultrasound has become a diagnostic tool that is commonly used in the emergency department. In trained hands, it can be used to diagnose multiple pathologies. In this case series, we describe the utility of ultrasound in diagnosing skull fractures in pediatric patients with scalp hematomas.
To determine the clinical evolution of children with skull fractures as a result of a minor head trauma from a witnessed accidental fall that have been studied by transfontanellar ultrasound (TFUS).
Observational study for 2 years (2004-2006) of children up to 1 year of age who suffered a skull fracture after minor head trauma and for whom a TFUS was carried out as the first neuroimaging test to rule out intracranial injuries.
One hundred and twenty-three children were evaluated. The mean age was 5.7 months (SD 2.9) and the most common mechanism of injury was rolling off the bed. In seven (5.7%) patients, a computed tomography (CT) was eventually performed after TFUS; in two of these patients, this was because of the detection of possible intracranial alterations and in the others, it was because of a small fontanelle. Both patients with abnormal TFUS had a small epidural haematoma on the CT scan that did not need surgery. The clinical course for all patients was uneventful.
TFUS is a valid and reliable alternative to CT for minor head trauma in infants with skull fractures. Its innocuousness and cost-effectiveness in comparison with CT makes it a good choice in this situation.
Eighteen cases of a congenital cystic swelling located over the anterior fontanelle are described in Nigerian patients who were otherwise clinically normal, There was a female: male ratio of 2: 1. Radiologically and at operation, the cysts showed no evidence of intracranial connexion. Excision was curative.Of 14 cases which were histologically verified, all were dermoid cysts except one in which nerve tissue was present suggesting an encephalocele.Air cystography was the most useful diagnostic procedure.
Diagnosis of craniosynostosis is based on clinical aspects but may be difficult in some cases where characteristic features are missing and radiographic imaging is necessary. In this context near-field high-frequency ultrasound has been used to evaluate the sonographic characteristics of synostotic sutures and its potential confirming the correct diagnosis. Sutures of 26 infants, aged 2-7 months, were investigated by ultrasound (Siemens Elegra, 7.5 MHz linear scanner). Sonographic features of synostotic sutures were correlated to CT imaging and compared to the sonographic and histopathological findings of normal cranial sutures. Hyperechogenic bridging of sutures with or without ridging were the characteristic aspects of synostotic sutures. All 26 patients could be reliable diagnosed showing partial (n = 21) or total fusion (n = 5) of one or more sutures consisting with craniosynostosis. Length of synostosis was identified exactly by sonography and imaging found to enable a classification of ultrastructural details of bony and soft tissue next to the synostotic suture. Ultrasound is a less expensive, nonradiating and easy-to-handle tool ensuring the diagnosis of craniosynostosis. Sonography offers the potential to be a standard investigation for infants with head deformities suspecting a suture pathology and has been therefore integrated in our craniofacial outpatient clinic as a daily routine method.