Haemodynamic patterns in children with posttraumatic diffuse brain swelling. A preliminary study in 6 cases with neuroradiological features consistent with diffuse axonal injury

Diffusion Tensor Imaging as Neurologic Predictor in Patients Affected by Traumatic Brain Injury: Scoping Review

Background: Diffusion tensor imaging (DTI), a variant of Diffusion Weighted Imaging (DWI), enables a neuroanatomical microscopic-like examination of the brain, which can detect brain damage using physical parameters. DTI's application to traumatic brain injury (TBI) has the potential to reveal radiological features that can assist in predicting the clinical outcomes of these patients. What is the ongoing role of DTI in detecting brain alterations and predicting neurological outcomes in patients with moderate to severe traumatic brain injury and/or diffuse axonal injury? Methods: A scoping review of the PubMed, Scopus, EMBASE, and Cochrane databases was conducted according to the Preferred Reporting Items for Systematic Reviews and Meta-Analysis (PRISMA) guidelines. The aim was to identify all potentially relevant studies concerning the role of DTI in TBI. From an initial pool of 3527 publications, 26 articles were selected based on relevance. These studies included a total of 729 patients with moderate to severe TBI and/or diffuse axonal injury. DTI parameters were analyzed to determine their relationship with neurological outcomes post-TBI, with assessments of several brain functions and regions. Results: The studies included various DTI parameters, identifying significant relationships between DTI variations and neurological outcomes following TBI. Multiple brain functions and regions were evaluated, demonstrating the capability of DTI to detect brain alterations with higher accuracy, sensitivity, and specificity than MRI alone. Conclusions: DTI is a valuable tool for detecting brain alterations in TBI patients, offering enhanced accuracy, sensitivity, and specificity compared to MRI alone. Recent studies confirm its effectiveness in identifying neurological impairments and predicting outcomes in patients following brain trauma, underscoring its utility in clinical settings for managing TBI.

Diagnosis and Treatment of Severe Traumatic Brain Injury in Idiopathic Intracranial Hypertension Syndrome

OBJECTIVE

A topic of current research is the development of a new approach to the diagnosis and treatment of severe brain injury taking into consideration its main pathophysiological mechanism-idiopathic intracranial hypertension syndrome. The goal of this study was to identify Doppler patterns of unfavorable craniocerebral injury conditions to form a consistent algorithm of treatment measures to reduce secondary brain damage in patients with severe craniocerebral trauma.

METHODS

Transcranial Doppler imaging is a prospective method, which allows quick and noninvasive assessment of the intracerebral blood flow dynamics right at the patient's bedside. Due to the operator-dependent nature of this method, clinical interpretation can often be contradictory. As a result, no clear criteria for therapy correction have yet been formulated based on this neuroimaging method.

RESULTS

Analysis of the therapy performed allowed us to specify the options for the hyperosmolar solutions for the correction of idiopathic intracranial hypertension syndrome.

CONCLUSIONS

No statistically significant difference in effectiveness was shown between mannitol and hypertonic saline solutions.

Diffuse Axonal Injury Pattern Predicts Timing of In-Hospital Neurologic Recovery: A Retrospective Case Series

BACKGROUND

Diffuse axonal injury (DAI) is a devastating traumatic neurologic injury with variable prognosis. Although outcomes such as mortality have been described, the time course of neurologic progression is poorly understood. We investigated the association between DAI neuroanatomic injury pattern and neurologic recovery timing.

METHODS

A retrospective review of our institution's trauma registry identified patients diagnosed with DAI from 2017-2021. The neuroradiologist's review of a head computed tomography scan was used to score DAI severity. In-hospital neurologic examinations were reviewed, and the Glasgow Coma Scale (GCS) was calculated for all patients throughout the hospital stay. Categorical variables were analyzed using the Fisher exact test, and continuous variables were analyzed using the Kruskal-Wallis test.

RESULTS

Nineteen DAI patients (grade 1 = 8; grade 2 = 1; grade 3 = 10) were included (mean age 31 years, 79% male). Mean Rotterdam computed tomography score, Injury Severity Scale, and admission GCS were comparable across DAI grades. Mean time in days to follow commands was shorter for those with grade 1 DAI (9.3) compared with grade 2 (17 days) or grade 3 (19 days) DAI (P = 0.02). Throughout hospitalization, patients with grade 1 DAI had higher motor (P = 0.006), eye (P = 0.001), and total GCS (P = 0.011) scores compared with those with grade 2 or 3 DAI. At the time of discharge, total GCS and the frequency of command following was similar across DAI grades.

CONCLUSIONS

Patients with grade 1 DAI demonstrated the fastest short-term neurologic recovery, although final discharge neurologic examination was comparable across DAI grades. DAI classification can provide useful short-term prognostic information regarding in-hospital neurologic improvement.

Complex Pathophysiology of Abusive Head Trauma with Poor Neurological Outcome in Infants

Abusive head trauma (AHT) in infants, especially acute subdural hematoma, has an extremely poor outcome. The most decisive and important finding is the appearance of a widespread low-density area on head computed tomography. This phenomenon was traditionally thought to be caused by cerebral ischemia. However, many other pathophysiological abnormalities have been found to be intricately involved. Recent studies have found that status epilepticus and hyperperfusion injures are the major causes. Another serious problem associated with AHT is cardiopulmonary arrest (CPA). Many infants are reported to visit to the hospital with CPA, and its pathophysiology has not been fully elucidated. This paper examines the background of these pathological conditions and associated factors and elucidate the pathophysiological mechanisms resulting in poor outcomes in AHT. In addition to the intensity of assault on the head, the peculiar pathophysiological characteristics in infants, as well as the social background specific to child abuse, are found to be associated with poor outcome.

Decompressive craniectomy in children: single-center series and systematic review

BACKGROUND

Decompressive craniectomy (DC) is performed as a life-saving procedure in patients with intractably increased intracranial pressure after traumatic brain injury, bleeding, cerebral infarction, or brain swelling of other causes. However, the application of DC is as controversial in the pediatric population as it is in adults.

OBJECTIVE

To find factors influencing the outcome in pediatric patients who underwent DC because of sustained high intracranial pressure.

METHODS

Between April 2000 and December 2009, 34 pediatric patients (age 0-18 years) underwent DC. Patients were stratified according to the indication for DC. Outcome was assessed according to the modified Rankin Scale score at 6 months. MEDLINE was searched for published studies or reports of DC in pediatric patients to gain a larger population. Two reviewers independently extracted data.

RESULTS

Literature data, including the current series, revealed a total of 172 pediatric patients. Overall, a favorable outcome was achieved in 106 of 172 patients (62%). A favorable outcome was achieved in 25 of 36 patients without traumatic brain injury vs 81 of 136 patients with traumatic brain injury (69% vs 60%). Patients without signs of cerebral herniation had a better outcome than patients with unilateral or bilateral dilated pupils (73% vs 60% vs 45%, respectively).

CONCLUSION

The current data indicate that DC in children with traumatic or nontraumatic brain swelling might be warranted, regardless of the underlying cause. Despite mydriasis, a favorable outcome might be achieved in a significant number of pediatric patients. Nevertheless, careful individual decision making is needed for each patient, especially when signs of cerebral herniation have persisted for a long time.

Transcranial Doppler can predict intracranial hypertension in children with severe traumatic brain injuries

PURPOSE

The purpose of this study is to evaluate the accuracy of emergency Transcranial Doppler (TCD) to predict intracranial hypertension and abnormal cerebral perfusion pressure in children with severe traumatic brain injury (TBI).

PATIENTS AND METHODS

A descriptive and retrospective cross-sectional study was designed through data collected from medical records of children with severe TBI (Glasgow coma scale ≤ 8), admitted to a level I pediatric trauma center, between January 2000 and December 2005. Early TCD examination was performed upon admission, and TCD profiles were considered as altered using previously validated threshold values for diastolic velocity (<25 cm/s) and pulsatility index (>1.31) or when no-flow/backflow was detected. Invasive intracranial pressure (ICP) and cerebral perfusion pressure (CPP) monitoring were considered as the gold standard to measure intracranial hypertension (ICH). Statistical analyses compared TCD profiles to increased ICP (≥ 20 mmHg) and abnormal cerebral perfusion pressure (<50 mmHg) at admission.

RESULTS

Non-invasive TCD and ICP monitoring were performed in 117 severe head-injured children. Mean age was 7.6 ± 4.4 years, with a male prevalence (71%). Median initial Glasgow coma scale was 6. TCD had 94% of sensitivity to identify ICH at admission and a negative predict value of 95% to identify normal ICP at admission. Its sensitivity to predict abnormal cerebral perfusion pressure was 80%.

CONCLUSIONS

The high sensitivity of admission TCD to predict ICH and abnormal CPP after trauma demonstrates that TCD is an excellent first-line examination to determine those children who need urgent aggressive treatment and continuous invasive ICP monitoring.

Transcranial Doppler in children

Transcranial Doppler US, a non-invasive tool for evaluating the cerebral arteries, has evolved significantly during the last two decades. This review describes the practical procedure, and summarises and illustrates its established and "work-in-progress" indications in children. Indications for a transcranial Doppler US examination include, but are not limited to: (1) evaluation of cerebral blood flow velocities in the circle of Willis in patients with sickle cell anaemia to guide transfusion therapy; (2) diagnosis and follow-up of vasculopathy, such as moyamoya disease; (3) diagnosis and monitoring of acute cerebrovascular disorders in intensive care patients, in particular following traumatic brain injury, and during cardiovascular surgery; and (4) confirmation of a clinical diagnosis of brain death by documentation of cerebral circulatory arrest.

Pediatric central nervous system emergencies

This article summarizes current state-of-the-art techniques used in the management of pediatric neurologic emergencies. Solutions to challenges faced by the radiologist, including the selection of an appropriate modality for an individual patient, are discussed. Imaging appearances of specific entities are described with an emphasis on conditions unique to the pediatric population.

Cerebrovascular pathophysiology in pediatric traumatic brain injury

BACKGROUND

Traumatic brain injury (TBI) is the leading cause of traumatic morbidity and mortality in children. Although there is increasing information concerning TBI in adults and experimental animal models, relatively little is known regarding cerebrovascular pathophysiology specific to children.

MATERIALS

A review of the pertinent medical literature.

RESULTS

Systemic and cerebral hemodynamic factors such as hypotension, hypoxia, hyperglycemia, and fever are associated with poor outcome in pediatric TBI. Similarly, cerebral autoregulation is often impaired after TBI and may adversely affect outcome, especially if systemic hemodynamics are altered. Furthermore, CO2 vasoreactivity may be altered after pediatric TBI and lead to either cerebral ischemia or hyperemia.

CONCLUSIONS

Understanding the effect of pediatric TBI on the cerebral circulation is needed to potentially develop protocols to improve outcome in this vulnerable population. Specifically, changes in pediatric cerebrovascular physiology and pathophysiology, including CO2 vasoreactivity and pressure autoregulation, must be understood and their mechanism elucidated.