Effect of Disturbances of Zinc and Copper on the Physical and Mental Health Status of Patients with Alcohol Dependence.

The concentrations of copper and zinc in the tissues of alcohol-addicted people can significantly correlate with the variables describing their mental state. Studies on the homeostasis of zinc in alcohol-dependent patients have often been characterized by low hypozincemia detection. This may be caused by a low content of zinc in blood serum (1%) compared to the average zinc level in the body. Unfortunately, most authors have identified extracellular zinc in their studies. In the available literature, data on the level of copper in patients suffering from alcohol dependence are inconsistent. Our study included 100 alcohol-addicted patients (the study group) and 50 healthy subjects (the control group). Mental state was measured using appropriate psychometric scales. We used inductively coupled plasma mass spectrometry (ICP-MS) to determine copper and zinc content. Our results confirm the purposefulness of the use of zinc concentration in erythrocytes as a diagnostic parameter for low zinc status in alcohol-dependent patients. Alcohol-dependent patients with reduced concentrations of zinc in erythrocytes/copper in blood plasma differed significantly from alcohol-dependent patients with normal concentrations in terms of clinical parameters. With regard to zinc in blood plasma and copper in erythrocytes, this situation has not been found. The clinical symptoms of hypozincemia and copper deficiency in patients addicted to alcohol usually relate to disorders in central nervous system functioning, and they result in a decreased quality of physical and mental life.

Brain iron accumulation in Wilson disease: a post mortem 7 Tesla MRI - histopathological study.

AIMS: In Wilson disease (WD), T2/T2*-weighted (T2*w) MRI frequently shows hypointensity in the basal ganglia that is suggestive of paramagnetic deposits. It is currently unknown whether this hypointensity is related to copper or iron deposition. We examined the neuropathological correlates of this MRI pattern, particularly in relation to iron and copper concentrations. METHODS: Brain slices from nine WD and six control cases were investigated using a 7T-MRI system. High-resolution T2*w images were acquired and R2* parametric maps were reconstructed using a multigradient recalled echo sequence. R2* was measured in the globus pallidus (GP) and the putamen. Corresponding histopathological sections containing the lentiform nucleus were examined using Turnbull iron staining, and double staining combining Turnbull with immunohistochemistry for macrophages or astrocytes. Quantitative densitometry of the iron staining as well as copper and iron concentrations were measured in the GP and putamen and correlated with R2* values. RESULTS: T2*w hypointensity in the GP and/or putamen was apparent in WD cases and R2* values correlated with quantitative densitometry of iron staining. In WD, iron and copper concentrations were increased in the putamen compared to controls. R2* was correlated with the iron concentration in the GP and putamen, whereas no correlation was observed for the copper concentration. Patients with more pronounced pathological severity in the putamen displayed increased iron concentration, which correlated with an elevated number of iron-containing macrophages. CONCLUSIONS: T2/T2*w hypointensity observed in vivo in the basal ganglia of WD patients is related to iron rather than copper deposits.

Brain metal accumulation in Wilson's disease.

INTRODUCTION: Brain metal accumulation is suggested in the pathogenesis of numerous neurodegenerative disorders. In Wilson's disease (WD), only copper has been examined. The aim of the present study was to evaluate the copper, iron, manganese, and zinc concentrations in autopsy tissue samples from the brains of WD patients. METHODS: The study material consisted of 17 brains (12 WD patients, 5 controls) obtained at autopsy. Samples were taken from four different regions of each brain: frontal cortex, putamen, pons, and nucleus dentatus. The copper, manganese, and zinc content were determined using inductively coupled plasma mass spectrometry, and iron was assessed using flame atomic absorption spectroscopy. The results were analyzed according to select clinical variables. RESULTS: Copper content was increased homogenously in all investigated structures of the WD brains compared to controls (41.0 ± 18.6 µg/g vs.5.4 ± 1.8 µg/g; P<0.01). The mean concentrations of iron, manganese, and zinc were similar in WD and controls, but the iron level in the nucleus dentatus was higher in WD compared to controls (56.8 ± 14.1 µg/g vs. 32.6 ± 6.0 µg/g; P<0.05). Gender, age, and type and duration of WD treatment did not impact brain metals storage, but some correlations between the duration of the disease and copper and iron accumulation were observed. CONCLUSIONS: During the course of WD, copper accumulates equally in different parts of the brain. Zinc and manganese do not seem to be involved in WD pathology, but increased levels of iron were found in the nucleus dentatus. Thus, additional studies of brain iron accumulation in WD are needed.