In-vivo signatures of neurodegeneration in isolated rapid eye movement sleep behaviour disorder.

BACKGROUND AND PURPOSE: Isolated rapid eye movement sleep behaviour disorder (iRBD) is a parasomnia, recently recognized as a risk factor for progression to Parkinson's disease, dementia with Lewy body and multiple system atrophy. Biomarker studies in iRBD are relevant due to lack of evidence in this condition. The identification of biomarkers able to predict progression to synucleinopathy diseases is critical for iRBD. Fluorodeoxyglucose-positron emission tomography (FDG-PET) imaging might provide information about ongoing neurodegenerative processes. In the present study, we tested for presence of brain hypometabolism patterns as biomarkers of neurodegeneration in single iRBD individuals. METHODS: We recruited 37 subjects with polysomnography-confirmed iRBD, with neuropsychological assessment and available FDG-PET scan. Images were analysed with a validated statistical parametric mapping procedure, providing individual hypometabolism maps. RESULTS: According to the neuropsychological evaluation, 22 subjects with iRBD had normal cognition and 15 subjects showed impairments, particularly in visuoperceptive/visuospatial and memory domains. One-fifth of the cases were impaired on the Qualitative Scoring of Pentagon Test. In 32 iRBD cases, FDG-PET statistical parametric maps revealed significant cerebral hypometabolism, namely in the occipital lobes (n = 5), occipital and cerebellar regions (n = 13), occipitoparietal regions (n = 13) and a selective cerebellar hypometabolism (n = 1). Five cases had normal FDG-PET scans. CONCLUSIONS: These imaging findings indicate that brain neurodegenerative processes are present and already detectable in iRBD. The different hypometabolism patterns in the single individuals may reflect specific early pathophysiological events due to the underlying synucleinopathy, with a specific neural vulnerability for the occipital cortex that might pre-date a risk of progression towards dementia with Lewy body.

Evaluation of an optimized [18 F]fluoro-deoxy-glucose positron emission tomography voxel-wise method to early support differential diagnosis in atypical Parkinsonian disorders.

BACKGROUND AND PURPOSE: Atypical Parkinsonian disorders (APD) frequently overlap in clinical presentations, making the differential diagnosis challenging in the early stages. The present study aimed to evaluate the accuracy of the [18 F]fluoro-deoxy-glucose positron emission tomography Statistical Parametric Mapping (SPM) optimized procedure in supporting the early and differential diagnosis of APD. METHODS: Seventy patients with possible APD were retrospectively included from a large clinical cohort. The included patients underwent [18 F]fluoro-deoxy-glucose positron emission tomography within 3 months of the first clinical assessment and a diagnostic follow-up. An optimized SPM voxel-wise procedure was used to produce t-maps of brain hypometabolism in single subjects, which were classified by experts blinded to any clinical information. We compared the accuracy of both the first clinical diagnosis and the SPM t-map classifications with the diagnosis at follow-up as the reference standard. RESULTS: At first diagnosis, 60% of patients were classified as possible APD (progressive supranuclear palsy, corticobasal degeneration, dementia with Lewy bodies, multiple system atrophy) and about 40% as APD with uncertain diagnosis, providing 52% sensitivity, 97% specificity and 86% accuracy with respect to the reference standard. SPM t-map classification showed 98% sensitivity, 99% specificity and 99% accuracy, and a significant agreement with the diagnosis at follow-up (P < 0.001). CONCLUSIONS: The SPM t-map classification at entry predicted the second diagnosis at follow-up. This indicates its significantly superior role for an early identification of APD subtypes, particularly in cases of uncertain diagnosis. The use of a metabolic biomarker at entry in the instrumental work-up of APD may shorten the diagnostic time, producing benefits for treatment options and support to the patients.

Natural surfactant and hyperoxic lung injury in primates. II. Morphometric analyses.

Diffuse lung injury is accompanied by low compliance and hypoxemia with histological evidence of endothelial and alveolar epithelial cell disruption. The histological effects of treatment of an acute diffuse lung injury with a natural surfactant product were evaluated in a primate model because surfactant function and content have been shown to be abnormal in diffuse lung injury in both animals and humans. Ten baboons were ventilated with 100% O2 for 96 h, and 5 were given an aerosol of natural porcine surfactant. Physiological and biochemical measurements of the effects of hyperoxia and surfactant treatment are presented in a companion paper. After O2 exposure, lungs were fixed and processed for quantitative electron microscopy. The responses to O2 included epithelial and endothelial cell injuries, interstitial edema, and inflammation. The hyperoxic animals treated with surfactant were compared with the untreated animals; the treatments altered neutrophil distribution, fibroblast proliferation, and changes in the volumes of type I epithelial cells and endothelial cells. Surfactant-treated animals also had decreased lamellar body volume density in type II epithelial cells and preservation of endothelial cell integrity. These changes suggest complex effects of natural surfactant on the pulmonary response to hyperoxia, including protection against epithelial and endothelial cell destruction as well as significant interstitial inflammation and fibroblast proliferation. We conclude that natural surfactant treatment of hyperoxic lung injury in primates resulted in partial protection of epithelial and endothelial cells but also increased the accumulation of fibroblasts in the lung.

Natural surfactant and hyperoxic lung injury in primates. I. Physiology and biochemistry.

Surfactant dysfunction contributes to the pathophysiology of adult respiratory distress syndrome (ARDS), and we hypothesized that surfactant treatment would improve experimental ARDS produced by continuous exposure to hyperoxia. Twelve healthy male baboons (10-15 kg) were anesthetized, paralyzed, and mechanically ventilated with 2.5 cmH2O positive end-expiratory pressure (PEEP) for 96 h. Baboons were divided into three groups: 1) the O2 group (n = 5) received 100% O2, 2) the surfactant group (n = 5) received 100% O2 and aerosolized porcine surfactant, and 3) a control group (n = 2) was ventilated at fractional concentration of inspired O2 of 0.21 for 96 h to control for effects of anesthesia and mechanical ventilation. Hemodynamic parameters were obtained every 12 h, and ventilation-perfusion (VA/Q) distribution was measured daily by multiple inert gas elimination technique. PEEP was increased once or twice daily to 10 cmH2O for 30 min to study its effects on measurements of VA/Q. At the end of experiments, lungs were obtained for biochemical analysis. Prolonged hyperoxia resulted in progressive worsening in VA/Q, hemodynamic deterioration, severe lung edema, and altered surfactant metabolism. Surfactant administration increased disaturated phosphatidylcholine in lavage fluid but did not improve lung edema or gas exchange. In the surfactant group, however, the addition of 10 cmH2O PEEP resulted in a greater degree of shunt reduction than did 2.5 cmH2O PEEP (47 vs. 31% in the O2 group, P < 0.05). We conclude that aerosolized porcine surfactant did not prevent pulmonary O2 injury in baboons, but it potentiated the shunt-reducing effect of PEEP.

The pulmonary surfactant system.

Surfactant's importance is underscored by the severe morbidity of deficiency states--primary, as in neonatal respiratory distress syndrome, or secondary, as in ARDS. Current knowledge of surfactant synthesis and metabolism is reviewed. Clinically, the effectiveness of exogenous surfactant in RDS has prompted investigation of its administration in ARDS.