Complications of Cancer Therapy in Children: A Comprehensive Review of Neuroimaging Findings.

ABSTRACT: Complications of cancer therapy in children can result in a spectrum of neurologic toxicities that may occur at the initiation of therapy or months to years after treatment. Although childhood cancer remains rare, increasing survival rates mean that more children will be living longer after cancer treatment. Therefore, complications of cancer therapy will most likely occur with increasing frequency.At times, it is very difficult to differentiate between therapeutic complications and other entities such as tumor recurrence, development of secondary malignancy, and infection (among other conditions). Radiologists often play a key role in the diagnosis and evaluation of pediatric patients with malignancies, and thus, awareness of imaging findings of cancer complications and alternative diagnoses is essential in guiding management and avoiding misdiagnosis. The aim of this review article is to illustrate the typical neuroimaging findings of cancer therapy-related toxicities, including both early and late treatment effects, highlighting pearls that may aid in making the appropriate diagnosis.

Complications of Cancer Therapy in Children: A Comprehensive Review of Body Imaging Findings.

ABSTRACT: Complications of cancer therapy in children can result in a spectrum of toxicities that can affect any organ system and result in a range of morbidity. Complications may occur at the initiation of therapy or years following treatment. Although childhood cancer remains rare, increasing survival rates means more children are living longer following their treatment. Radiologists often play an important role in the diagnosis and evaluation of these complications, and thus, awareness of their imaging findings is essential to guide management and avoid misdiagnosis. This second part of a 2-part review aims to illustrate the typical body imaging findings of cancer therapy-related toxicities, including both early and late treatment effects. The article also discusses the differential diagnosis of imaging findings, highlighting pearls and pitfalls in making the appropriate diagnosis.

Prenatal Diagnosis of Skeletal Dysplasias: What Can CT Do for You?

Skeletal dysplasias (SDs) are a heterogeneous group of heritable disorders that affect development of bone and cartilage. Because each SD is individually rare and because of the heterogeneity within and among disorders, prenatal diagnosis of a specific SD remains challenging. Molecular genetic diagnosis involves invasive testing, which some patients are not amenable to. Further, genetic analysis is time consuming, and results may not become available in time to make pregnancy management decisions. Low-dose fetal CT can aid in the prenatal evaluation of SDs. The main downside is the low but true risk of fetal radiation exposure. As such, fetal CT should only be performed when there is concern for a severe skeletal dysplasia and the diagnosis is in question after a detailed ultrasound or if molecular genetic testing is unavailable and when prenatal diagnosis may affect management or counseling. Fetal CT should be obtained after consultation with geneticists, maternal-fetal medicine specialists, and fetal radiologists, and sometimes orthopedic surgeons or neonatologists. The purpose of this study was to review the technique of and indications for fetal CT, as well as discuss fetal radiation risk. Illustrative cases will demonstrate when and how CT may be helpful in the diagnosis of SDs.

Making intussusception reductions easier: use of medical air in lieu of manual pump.

BACKGROUND: Pneumatic reduction of ileocolic intussusception is commonly performed with manual insufflators. The challenge of operating a handheld device while controlling the fluoroscope and monitoring the reduction could be obviated if the manual insufflation could be eliminated. OBJECTIVE: The aim in this retrospective study was to describe and evaluate the use of medical wall air in intussusception reduction. MATERIALS AND METHODS: We retrospectively reviewed all intussusception reductions over a period of years: from 2015 to 2018 using the manual insufflator and from 2018 to 2021 using medical air. We compared success rates, complication rates and time to reduction as documented on fluoroscopic image time stamps. Demographic data were obtained from the medical record. Attending radiologists and fluoroscopic technologists indicated their preference between methods, ease of use, perceived duration of reduction and perceived difference in success rates through an anonymous internal survey. RESULTS: There were 179 first reduction attempts in 167 patients (93 attempts during the period using the manual insufflator and 86 after converting to wall air). There was no difference in reduction duration (8:23 min for insufflation, 8:22 min for wall air, P=0.99) and no statistically significant difference in success rate (66.8% for insufflation and 79.1% for wall air, P=0.165). All survey respondents preferred the wall air method. The vast majority (93%) perceived that the wall air method was faster. CONCLUSION: Hospital wall air can be used to successfully reduce intussusceptions without incurring time burden or loss of effectiveness. The method leads to a perception of increased efficiency.

Early pulmonary complications related to cancer treatment in children.

In this review, we summarize early pulmonary complications related to cancer therapy in children and highlight characteristic findings on imaging that should be familiar to a radiologist reviewing imaging from pediatric cancer patients.

Five Years Later: Impact of a Focused Women in Radiology Program.

PURPOSE: Women are underrepresented in radiology and experience barriers to professional growth that can affect job satisfaction and career advancement. The authors hypothesized that a structured, intentional Women in Radiology (WiR) program would increase women faculty members' perceptions of workplace gender equity, satisfaction with pace of professional advancement, interest in research and teaching, and perceptions of work-life balance and mentorship opportunities. METHODS: Components and structure of a sustainable WiR program are described in detail. Baseline and summative 5-year surveys of women faculty members in the department were distributed. The primary outcome measure was perception of equitable access to professional development opportunities for women. The authors also assessed the impact of the WiR program on creating a departmental culture shift to improve career advancement for women. Secondary outcomes included WiR's impact on women's satisfaction with pace of professional advancement, mentorship opportunities, work-life balance, and interest in research and teaching. RESULTS: Compared with 5 years prior, more women faculty members now believe that there is equitable access to career advancement opportunities and that the formal WiR program has contributed to a positive culture shift in the department. Significant gains in women faculty members' satisfaction with pace of their professional advancement were demonstrated. During the study period, more women developed interest in teaching and research, served as mentors, and perceived improvements in work-life balance compared with baseline. CONCLUSIONS: A structured, intentional WiR program can contribute to improved workplace gender equity, career satisfaction for women, and a positive departmental culture shift to support the needs of women in radiology.

Lymphatic Anomalies in Children: Update on Imaging Diagnosis, Genetics, and Treatment.

Lymphatic anomalies comprise a spectrum of disorders ranging from common localized microcystic and macrocystic lymphatic malformations (LMs) to rare complex lymphatic anomalies, including generalized lymphatic anomaly, Kaposiform lymph-angiomatosis, central conducting lymphatic anomaly, and Gorham-Stout disease. Imaging diagnosis of cystic LMs is generally straightforward, but complex lymphatic anomalies, particularly those with multiorgan involvement or diffuse disease, may be more challenging to diagnose. Complex lymphatic anomalies are rare but associated with high morbidity. Imaging plays an important role in their diagnosis, and radiologists may be the first clinicians to suggest the diagnosis. Furthermore, radiologists are regularly involved in management given the frequent need for image-guided interventions. For these reasons, it is crucial for radiologists to be familiar with the spectrum of entities comprising complex lymphatic anomalies and their typical imaging findings. In this article, we review the imaging findings of lymphatic anomalies, including LMs and complex lymphatic anomalies. We discuss characteristic imaging findings, multimodality imaging techniques used for evaluation, pearls and pitfalls in diagnosis, and potential complications. We also review recently discovered genetic changes underlying lymphatic anomaly development and the advent of new molecularly targeted therapies.

Characterization of germinal matrix hemorrhage in extremely premature infants: recognition of posterior location and diagnostic pitfalls.

BACKGROUND: Traditionally, descriptions of germinal matrix hemorrhage (GMH), derived from observations in preterm and very preterm infants, indicate its location at the caudothalamic grooves. However, before the germinal matrix begins to recede at approximately 28 weeks' gestational age (GA), it extends along the floor of the lateral ventricles far posterior to the caudothalamic grooves. Germinal matrix-intraventricular hemorrhage (GMH-IVH) can occur along any site from which the germinal matrix has not yet involuted. Therefore, as current advances in neonatology have allowed the routine survival of extremely preterm infants as young as 23 weeks' GA, postnatal GMH-IVH can occur in previously undescribed locations. Hemorrhage in the more posterior GMH on head ultrasound, if unrecognized, may lead to errors in diagnosis and mislocalization of this injury to the periventricular white matter or lateral walls of the lateral ventricles instead of to the subependyma, where it is in fact located. OBJECTIVE: Our aim is to describe posterior GMH in extremely premature infants, including its characteristic imaging appearance and potential pitfalls in diagnosis. MATERIALS AND METHODS: Over a 5-year period, all consecutive extremely preterm infants of 27 weeks' GA or less who developed GMH-IVH of any grade were included. A consecutive group of 100 very preterm infants of 31 weeks' GA with a GMH-IVH of any grade served as controls. RESULTS: In 106 extremely preterm neonates (mean GA: 25 weeks, range: 23.1-26.6 weeks) with 212 potential lateral ventricular germinal matrix bleeding sites, 159 sites had bleeds. In 70/159 (44%), the GMH-IVH was located posterior to the caudothalamic grooves and the foramina of Monro, 52 (32.7%) were both anterior and posterior and 21 (13.2%) were exclusively anterior. In 16 ventricles with intraventricular hemorrhage, an origin site in the germinal matrix could not be determined. In the control population of very preterm infants, all hemorrhages were at the anterior caudothalamic grooves and 95% were grade I. CONCLUSION: Unlike the older very preterm and moderately preterm infants that form the basis of our GMH-IVH description and classification, the extremely preterm infants now routinely surviving have a more fetal pattern of germinal matrix distribution, which is reflected in a different distribution and size of germinal matrix injury. We report the postnatal occurrence of subependymal GMH-IVH in extremely preterm infants in these more primitive, posterior locations, its potential imaging pitfalls and sonographic findings.

Head Ultrasound Resistive Indices Are Associated With Brain Injury on Diffusion Tensor Imaging Magnetic Resonance Imaging in Neonates With Hypoxic-Ischemic Encephalopathy.

BACKGROUND: Neonatal hypoxic-ischemic encephalopathy (HIE) is associated with dysfunctional cerebral autoregulation. Resistive index (RI) measured in the anterior cerebral artery on transfontanellar head ultrasound is a noninvasive measure of blood flow and may indicate autoregulation dysfunction. We tested whether RI was associated with brain injury on diffusion tensor imaging magnetic resonance imaging (MRI). MATERIALS AND METHODS: Seventy-five neonates who underwent therapeutic hypothermia for HIE were enrolled. Resistive index values were obtained from head ultrasound performed at the end of therapeutic hypothermia. Apparent diffusion coefficient scalars were measured on MRIs performed before day of life 10. RESULTS: Lower RI was associated with lower apparent diffusion coefficient in the centrum semiovale, basal ganglia, thalamus, and posterior limb of the internal capsule. Combining RI and Apgar scores improved the ability to distinguish injury severity on MRI relative to either metric alone. CONCLUSIONS: Low RI correlated with worse brain injury on diffusion tensor imaging and may serve as an early marker of brain injury in cooled HIE neonates.

Gauging potential risk for patients in pediatric radiology by review of over 2,000 incident reports.

BACKGROUND: Incident reporting can be used to inform imaging departments about adverse events and near misses. OBJECTIVE: To study incident reports submitted during a 5-year period at a large pediatric imaging system to evaluate which imaging modalities and other factors were associated with a greater rate of filed incident reports. MATERIALS AND METHODS: All incident reports filed between 2013 and 2017 were reviewed and categorized by modality, patient type (inpatient, outpatient or emergency center) and use of sedation/anesthesia. The number of incident reports was compared to the number of imaging studies performed during that time period to calculate an incident report rate for each factor. Statistical analysis of whether there were differences in these rates between factors was performed. RESULTS: During the study period, there were 2,009 incident reports filed and 1,071,809 imaging studies performed for an incident report rate of 0.19%. The differences in rates by modality were statistically significant (P=0.0001). There was a greater rate of incident reports in interventional radiology (1.54%) (P=0.0001) and in magnetic resonance imaging (MRI) (0.62%) (P=0.001) as compared to other imaging modalities. There was a higher incident report rate for inpatients (0.34%) as compared to outpatient (0.1%) or emergency center (0.14%) (P=0.0001). There was a higher rate of incident reports for patients under sedation (1.27%) as compared to non-sedated (0.12%) (P=0.0001). CONCLUSION: Using incident report rates as a proxy for potential patient harm, the areas of our pediatric radiology service that are associated with the greatest potential for issues are interventional radiology, sedated patients, and inpatients. The areas associated with the least risk are ultrasound (US) and radiography. Safety improvement efforts should be focused on the high-risk areas.