Determination of radioiodine activity in charcoal cassettes

Sampling of radioiodine in air is accomplished by passing an air sample through an activated charcoal cassette. A mathematical model was developed, which assumes that radioiodine distribution along the cassette axis can be expressed by an exponential function. The model was validated experimentally for cassettes used for air sampling of radioiodine production boxes. There is a good agreement between the measurements and model predictions. Furthermore, when breakthrough occurs, the model can be used to estimate the activity that passed through the cassette unabsorbed.     

Transcranial magnetic stimulation and environmental enrichment enhances cortical excitability and functional outcomes after traumatic brain injury

Background

Therapeutic strategies for traumatic brain injury (TBI) in the last three decades have failed to show significant benefit in large scale studies. Given the multitude of pathological mechanisms involved in TBI, strategies focusing on multimodality regimen have gained interest as promising future interventions.

Reduced basal activity and increased functional homogeneity in sensorimotor and striatum of a Parkinson's disease rat model: a functional MRI study

Functional neuro-imaging studies of Parkinson's disease (PD) patients and animal models show inconsistent cortical responses to sensory stimulation: some present increased sensorimotor cortex activation contradicting classical basal ganglia-cortex circuitry models, whereas others show decreased activation. As functional neuro-imaging activation is defined as the signal difference between stimulation ON and stimulation OFF, reduced 'activation' can point to either increased neuronal activity during stimulation ON or to decreased basal neuronal activity during stimulation OFF. A unique non-invasive method that uses the temporal and the spatial variances of functional magnetic resonance imaging signal is employed here to compare basal neuronal activity levels and 'functional homogeneity' between groups. Based on the assumption that the temporal variance reflects average neuronal activity, the variance of activity within a predefined region is defined as the region's 'functional homogeneity', which is assumed to estimate neuronal synchronization. Comparison of temporal and spatial variances of the sensorimotor cortex and the striatum in the 6-hydroxydopamine (6-OHDA) PD rat model and a control rat group show bilaterally decreased temporal and spatial variances in the 6-OHDA rat group, suggesting bilateral reduction of basal neuronal activity levels together with an increase in local neuronal synchronization in line with classical basal ganglia-cortex circuit models.     

Enhanced calcium release in the acute neuronopathic form of Gaucher disease

Gaucher disease is an inherited metabolic disorder caused by defective activity of the lysosomal enzyme, glucocerebrosidase, resulting in accumulation of the lipids, glucosylceramide (GlcCer), and glucosylsphingosine (GlcSph). Little is known about the mechanism leading from lipid accumulation to disease, particularly in the acute and subacute neuronopathic forms of Gaucher disease, types 2 and 3, respectively. Recent work from our laboratory has shown, in animal models, that GlcCer enhances agonist-induced calcium release from intracellular stores via the ryanodine receptor, which results in neuronal cell death. We now test whether calcium release is altered in human brain tissue obtained post-mortem from Gaucher disease patients. Agonist-induced calcium release via the ryanodine receptor was significantly enhanced (P < 0.05) in brain microsomes from the acute neuronopathic form of Gaucher disease (type 2) (43 +/- 6% of the calcium in microsomes) compared to the subacute (type 3) (27 +/- 3%) and the non-neuronopathic (type 1) (28 +/- 6%) forms, and controls (18 +/- 3%), and correlated with levels of GlcCer accumulation. These findings suggest that defective calcium homeostasis may be a mechanism responsible for neuropathophysiology in acute neuronopathic Gaucher disease, and may potentially offer new therapeutic approaches for disease management.     

The interference of medical radionuclides with occupational in vivo gamma spectrometry

Radiation workers undergo routine monitoring for the evaluation of external and internal radiation exposures. The monitoring of internal exposures involves gamma spectrometry of the whole body (whole body counting) and measurements of excreta samples. Medical procedures involving internal administration of radioactive radionuclides are widely and commonly used. Medical radionuclides are typically short-lived, but high activities are generally administered, whereas occupational radionuclides are mostly long-lived and, if present, are found generally in relatively smaller quantities. The aim of the present work was to study the interference of some common medical radionuclides (201Tl, 9mTc, 57Co, and 131I) with the detection of internal occupational exposures to natural uranium and to 137Cs. Workers having undergone a medical procedure with one of the radionuclides mentioned above were asked to give frequent urine samples and to undergo whole body and thyroid counting with phoswich detectors operated at the Nuclear Research Center Negev. Urine and whole body counting monitoring were continued as long as radioactivity was detectable by gamma spectrometry. The results indicate that the activity of medical radionuclides may interfere with interpretation of occupational intakes for months after administration.     

Establishing schedules for repeated doses of strontium and for concurrent chemotherapy in hormone-resistant patients with prostate cancer: measurement of blood and urine strontium levels

Strontium-89 (Sr-89) alone or with concurrent chemotherapy has a role in the treatment of patients with prostate cancer (PCP). The schedules for repeated doses of Sr-89 or for concurrent chemotherapy is undetermined. The objective of this study was to measure the effective half-life (Te) of Sr-89 using a detector available in a nuclear research facility. Blood and urine samples obtained from PCP treated with Sr-89 (Metastron, Amersham, U.K.) were measured for radioactivity with a High Pure Germanium (HPGe) detector in a gamma spectrometry system (Eurisys, France). Twenty-five urine and 22 blood samples were obtained from 8 patients during a period of 160 days after Metastron injection. Sr-89 radioactivity levels in blood and urine were quite low (<8.2 x 10(-3) microCi/mL) in all patients after 21 days, whereas Sr-85 (available in 0.5% of Metastron) urine and, to a lesser extent, blood radioactivity levels were moderately high and could be detected up to 160 days. Based on Sr-85 urine levels, the calculated Sr-89 Te ranged from 9.6 to 20.7 days. Sr-89 Te can be routinely calculated in PCP based on HPGe detection of Sr-85 radioactivity levels in urine. This measurement can establish schedules for either repeated doses of Sr-89 or concurrent chemotherapy.     

Bilateral overactivation of the sensorimotor cortex in the unilateral rodent model of Parkinson's disease - a functional magnetic resonance imaging study

Functional magnetic resonance imaging (fMRI) is used to investigate the basal ganglia (BG)-cortex circuit using a rat model of Parkinson's disease (PD). The model involves a unilateral destruction of the right substantia nigra by intranigral injection of the dopaminergic neurotoxin 6-hydroxydopamine. Volume of cortical activity was measured by the blood oxygenation level-dependent contrast method while applying electrical forepaw stimulation. The main findings are the following. (i) Contrary to the predictions of the classic model but in line with recent experimental results (positron emission tomography, fMRI and electrophysiology), an increased cortical activity in the sensorimotor cortex of PD rats compared with sham-operated or normal rats was found. (ii) A diffuse neuronal activity at large cortical areas that were not related directly to the stimulation used, was observed. (iii) No difference was found between the lesion and the nonlesion hemispheres when the left or the right forepaw was stimulated; both cortices show significant overactivation of the sensorimotor cortices in addition to diffuse cortical activation. The last finding could be explained by either corticocortical connections or by bilateral BG-cortex connections. These finding suggest that the mutual influence of the two hemispheres is important in the pathophysiology of the BG-cortex circuit and might be crucial in predicting treatments.     

Endoscopic cellular microscopy for in vivo biomechanical assessment of tendon function

This study explores a novel method to quantify in vivo soft tissue biomechanics from endoscopic confocal fluorescence microscope images of externally loaded biological tissues. A custom algorithm based on normalized cross-correlation is used to track fluorescently labeled cells within soft tissue structures as they deform. Cellular displacements are subsequently reduced to tissue strains by deriving the spatial gradient of the spline smoothed cellular displacement field. The relative performance of the tracking method is verified using a synthetic dataset with known underlying deformation. In biological application of the method, tissue strains are measured in the Achilles tendon of an anesthetized mouse. Over repeated trials, structural strain in the tendon (i.e., the relative change in distance between cells located at view field extremes) is 20.3+/-3.1%, thus establishing the reproducibility of the loading protocol. Analysis of local tendon tissue strains reveal primary engineering strains in the tissue to range from 5 to 55%, signifying a highly inhomogeneous strain state, with complex relative motions of neighboring tendon substructures. In summary, the current work establishes a baseline for a promising experimental method, and demonstrates its technical feasibility.     

Ultrasound-based nonviral gene delivery induces bone formation in vivo

Nonviral gene delivery is a promising, safe, therapeutic tool in regenerative medicine. This study is the first to achieve nonviral, ultrasound-based, osteogenic gene delivery that leads to bone tissue formation, in vivo. We hypothesized that direct in vivo sonoporation of naked DNA encoding for the osteogenic gene, recombinant human bone morphogenetic protein-9 (rhBMP-9) would induce bone formation. A luciferase plasmid (Luc), encoding rhBMP-9 or empty pcDNA3 vector mixed with microbubbles, was injected into the thigh muscles of mice. After injection, noninvasive sonoporation was applied. Luc activity was monitored noninvasively, and quantitatively using bioluminescence imaging in vivo, and found for 14 days with a peak expression on day 7. To examine osteogenesis in vivo, rhBMP-9 plasmid was sonoporated into the thigh muscles of transgenic mice that express the Luc gene under the control of a human osteocalcin promoter. Following rhBMP-9 sonoporation, osteocalcin-dependent Luc expression lasted for 24 days and peaked on day 10. Bone tissue was formed in the site of rhBMP-9 delivery, as was shown by micro-computerized tomography and histology. The sonoporation method was also compared with previously developed electrotransfer-based gene delivery and was found significantly inferior in its efficiency of gene delivery. We conclude that ultrasound-mediated osteogenic gene delivery could serve as a therapeutic solution in conditions requiring bone tissue regeneration after further development that will increase the transfection efficiency.