Faculty Bibliography

OBJECTIVE:To determine how sleep with central spindles alters the spatial distribution of interictal spike frequency in children with intractable focal seizures, and whether such children have spindles arising from the medial temporal region in addition to the frontal-central region. METHODS:Seventeen children (age: 7 months-17 years) were studied using extraoperative electrocorticography (ECoG). RESULTS:Overall spike frequency across the subdural electrodes was greater during sleep with central spindles compared to wakefulness. In 13 children showing at least 1 spike/min in an electrode, the spatial distribution of spike frequency was similar during wakefulness and sleep; in addition, the spike frequency was greater in the seizure onset zones compared to the non-onset areas, regardless of wakefulness or sleep. Spindles were identified in the medial temporal region during sleep with central spindles in all 17 children. CONCLUSION/CONCLUSIONS:Overall spike frequency may be increased by sleep with spindles, but the spatial distribution of spike frequency appears similar during wakefulness and sleep in children with intractable focal seizures. SIGNIFICANCE/CONCLUSIONS:Both awake and sleep ECoG may be useful to predict seizure onset zones in children with intractable focal epilepsy. Medial temporal spindles are present in some children with focal epilepsy.

PURPOSE/OBJECTIVE:To study the effects of intracranial subdural grid electrode placement and seizures on intracranial pressure (ICP) in children undergoing invasive EEG monitoring. METHODS:Sixteen children with pharmacoresistant epilepsy who underwent two-stage epilepsy surgery with subdural grid placement were included in the study. The ICP was recorded at baseline and with each seizure prospectively. A variety of seizure parameters including type of seizure, length of seizure, extent of seizure spread, and number of subdural grid electrodes inserted were analyzed retrospectively and correlated with the change in ICP. RESULTS:A total of 48 seizures in 16 children were studied. The mean baseline ICP correlated positively with age of the child. Generalized tonic-clonic seizures were associated with the highest rise in ICP. Similarly, ICP rise was associated with seizures involving more electrodes indicating a larger area of brain participating in the seizure. CONCLUSION/CONCLUSIONS:Seizures in general and generalized tonic-clonic seizures, in particular, increase ICP temporarily in patients who are undergoing invasive EEG monitoring with subdural grids.

PURPOSE/OBJECTIVE:To report the utility of positron emission tomography (PET) with alpha-[(11)C]methyl-L-tryptophan (AMT) for monitoring progression and response to treatment of an isolated optic pathway glioma (OPG) in a 16-year-old girl. PROCEDURES/METHODS:Positron emission tomography scanning of the brain was performed 20 minutes after intravenous administration of AMT. The AMT-PET images were reconstructed and examined for tumor uptake of the tracer in correlation with coregistered magnetic resonance images. RESULTS:The PET scan demonstrated increased uptake of AMT by OPG in a clinically symptomatic child whose magnetic resonance imaging (MRI) was inconclusive for morphological changes of the tumor. The tracer uptake was dramatically decreased on the images obtained after chemotherapy. Subsequently, AMT-PET revealed a new tumor lesion of increased AMT uptake when the patient developed vision problems and MRI showed no significant interval morphological changes. Significant vision improvement was observed after external beam radiotherapy for the newly identified tumor lesion. CONCLUSIONS:Positron emission tomography with alpha-[(11)C]methyl-L-tryptophan may be useful for monitoring progression and response to treatment of OPGs, which needs to be further investigated in a prospective study of more patients, including those with neurofibromatosis.

Positron emission tomography can be used to evaluate brain function following perinatal hypoxia. This case report demonstrates transient hypermetabolism in the basal ganglia detected by glucose metabolism positron emission tomography study in a newborn who suffered hypoxic-ischemic encephalopathy and developed dystonic cerebral palsy later. A scan repeated at 4 years of age showed severe hypometabolism in the lentiform nuclei and thalami. Transient hypermetabolism in the basal ganglia following perinatal hypoxia may be related to excitotoxic damage causing permanent neurological symptoms in the form of dystonic cerebral palsy. Thus, positron emission tomography can help predict this form of cerebral palsy in neonates.

BACKGROUND AND PURPOSE/OBJECTIVE:Impaired cortical venous outflow and abnormal deep venous collaterals are common in Sturge-Weber syndrome (SWS), but their relation to brain metabolism and function is poorly understood. In this study, advanced MR imaging techniques, such as susceptibility-weighted imaging (SWI) and diffusion tensor imaging (DTI), were applied in conjunction with positron-emission tomography (PET), to assess cortical and white matter structural abnormalities and their relation to cortical glucose metabolism and cognitive functions in children with unilateral SWS. MATERIALS AND METHODS/METHODS:Thirteen children (age, 1.5-10.3 years) with unilateral SWS underwent MR imaging with SWI and DTI, glucose metabolism PET, and comprehensive neuropsychologic assessment prospectively. The MR imaging and PET images were coregistered and cortical regions showing decreased glucose metabolism were compared with locations of SWI signal intensity abnormalities, changes in white matter water diffusion, and cognitive functions. RESULTS:SWI detected both cortical abnormalities (n=8) and deep transmedullary veins (n=9), including those in young children with no cortical SWI signal intensity changes. These veins were often located under cortex adjacent to hypometabolic regions. DTI showed abnormal water diffusion both under hypometabolic cortex and in adjacent white matter with collateral veins. Cognitive dysfunction was associated with abnormal water diffusion in the posterior white matter. CONCLUSIONS:Transmedullary venous collaterals can be detected early by SWI and persist in white matter adjacent to damaged cortex in children with SWS. Microstructural white matter damage extends beyond cortical abnormalities and may contribute to cognitive impairment. SWI and DTI can be incorporated into clinical MR imaging acquisitions to objectively assess microstructural abnormalities at different stages of SWS.

PURPOSE OF REVIEW/OBJECTIVE:In this review we discuss recent advances in the neuroimaging of patients with tuberous sclerosis complex (TSC), highlighting its application in improving clinical management, particularly in the case of intractable epilepsy. RECENT FINDINGS/RESULTS:Progress in structural and functional imaging has led to further characterization of the brain lesions in TSC. New magnetic resonance imaging techniques that can delineate the extent of structural brain abnormalities in TSC have been developed. Diffusion tensor imaging unveils the microstructural abnormalities of the brain lesions and of the morphologically normal appearing white matter in TSC. It can potentially identify the epileptogenic zone. Positron emission tomography scanning with 2-deoxy-2-[18F]fluoro-D-glucose can assess the full extent of functional brain abnormalities in TSC. The use of alpha [11C] methyl-L-tryptophan positron emission tomography scanning has proven to be a useful tool in the identification of epileptogenic tubers and has improved the outcome of surgery for epilepsy in TSC. SUMMARY/CONCLUSIONS:Major advances of neuroimaging in TSC have shown evidence of widespread structural and functional brain abnormalities. In TSC patients with intractable epilepsy, new neuroimaging modalities can now provide an accurate assessment of the epileptogenic zone, thereby permitting improved identification of patients who can have good seizure outcome following surgery for epilepsy.

An important goal of software development in the medical field is the design of methods which are able to integrate information obtained from various imaging and nonimaging modalities into a cohesive framework in order to understand the results of qualitatively different measurements in a larger context. Moreover, it is essential to assess the various features of the data quantitatively so that relationships in anatomical and functional domains between complementing modalities can be expressed mathematically. This paper presents a clinically feasible software environment for the quantitative assessment of the relationship among biochemical functions as assessed by PET imaging and electrophysiological parameters derived from intracranial EEG. Based on the developed software tools, quantitative results obtained from individual modalities can be merged into a data structure allowing a consistent framework for advanced data mining techniques and 3D visualization. Moreover, an effort was made to derive quantitative variables (such as the spatial proximity index, SPI) characterizing the relationship between complementing modalities on a more generic level as a prerequisite for efficient data mining strategies. We describe the implementation of this software environment in twelve children (mean age 5.2 +/- 4.3 years) with medically intractable partial epilepsy who underwent both high-resolution structural MR and functional PET imaging. Our experiments demonstrate that our approach will lead to a better understanding of the mechanisms of epileptogenesis and might ultimately have an impact on treatment. Moreover, our software environment holds promise to be useful in many other neurological disorders, where integration of multimodality data is crucial for a better understanding of the underlying disease mechanisms.

UNLABELLED:The rate of incorporation of exogenous amino acids into brain proteins is indicative of the protein synthesis rate (PSR). The objective of this study was to assess the effect of plasma concentrations of leucine and large neutral amino acids (LNAAs) on the unidirectional uptake rate constant (Kcplx) of l-[1-(11)C]-leucine in the brain and to estimate the amino acid pool recycled from tissue. METHODS:Twenty-seven healthy adult volunteers (11 men and 16 women; age range, 20-50 y) underwent dynamic l-[1-(11)C]-leucine PET with arterial blood sampling. Data were analyzed with a standard 2-tissue-compartment model yielding the unidirectional uptake rate of plasma leucine into tissue (Kcplx = K(1)k(3)/(k(2) + k(3))) and the fraction of leucine originating from exogenous sources (lambda = k(2)/(k(2) + k(3))). PSR in brain was calculated as PSR = [Kcplx/lambda] x leucine. RESULTS:The mean plasma concentration of the sum of all LNAAs was 13% higher in men (981 +/- 86 micromol/L) than in women (850 +/- 76 micromol/L, P = 0.012), whereas the plasma leucine concentration was found to be similar in both sexes (men, 64 +/- 20 micromol/L; women, 58 +/- 21 micromol/L, P = 0.57). The whole-brain value for lambda was determined to be 0.64 +/- 0.03 and did not show a sex difference (P = 0.66). Whole-brain Kcplx values were significantly higher in women (0.0162 +/- 0.0024) than in men (0.0121 +/- 0.0031, P = 0.011); however, after normalization of the Kcplx to a standard plasma concentration of the sum of all LNAAs (Kcplx'), the Kcplx' was similar between the sexes (P = 0.21), as was the PSR' (1.24 +/- 0.49 micromol/L/min in men; 1.29 +/- 0.62 micromol/L/min in women, P = 0.87). No relationship between plasma leucine and Kcplx (r = -0.13, P = 0.63) was observed. Finally, there was a significant correlation between the PSR and the Kcplx derived using Patlak graphical analysis (rho = 0.65, P < 0.001). CONCLUSION/CONCLUSIONS:We conclude that both the Kcplx macroparameter and the PSR are stable indices of brain protein synthesis and are appropriate measures for testing altered protein synthesis in neurologic disorders.

We used quantitative L-[1-(14)C]leucine autoradiography to study the maturation of cerebral protein synthesis metabolism in kittens, starting at birth and through postnatal age (P) 180 days as well as in adult cats. We found that at birth most brain structures show protein synthesis (nmol/min/g; lCPS(leu)) rates already within the range of adult values (with some exceptions; e.g., the hippocampus and putamen). Likewise, most structures show a transient developmental peak during which the rates climb to levels higher than in adulthood. This peak often occurred at P60, but in some regions lasted from P30 to P90. Therefore, there is some regional heterogeneity in the maturation of brain protein synthesis. These results are compared with our previous findings on the maturation of cerebral glucose utilization and oxidative metabolism. We discuss the meaning of these maturational profiles in terms of time course of morphological development and of maturation of behavior in the cat. Correlations with findings in other mammalian species are also discussed.