Tissue digestion for aluminum determination in experimental animal studies

Four different procedures for the determination of aluminum in tissues by atomic absorption spectrometry (AAS) were investigated. They consisted of conventional acid digestion carried out before and after sample drying, associated or not with fat extraction. Drying was carried out in a conventional oven at 65 °C for 24 h. For fat extraction, different solvents and solvent mixtures were investigated considering both extraction yield and sample adequacy for further AAS measurement. Acid digestion was carried out with pure HNO₃ or with its mixture with HClO₄. After digestion, aluminum was measured by graphite furnace atomic absorption spectrometry. Tissues were collected from Al-exposed and nonexposed mice. The results indicated that drying the sample prior to digestion is advantageous as the amount of acid necessary can be significantly reduced. This procedure does not contribute to increase the aluminum level in the samples providing that careful measures to avoid contamination are taken, as the same procedures carried out without taking any precautions to avoid contamination produced imprecise results. Finally, aluminum was not found in the fatty fraction of any sample, even in exposed mice, demonstrating that aluminum does not accumulate in this part of the tissues.     

铝参与神经原纤维缠结形成的实验研究

目的探讨铝与神经原纤维缠结(NFTs)形成之间的相关性。方法选用16只雌性ICR小鼠,分为正常对照组与染铝组(200mg/kg.bw,染铝8个月)。组织荧光双重染色法观察铝与NFTs在小鼠大脑新皮层神经元内的定位。West-ern blot法半定量检测新皮层内tau蛋白及其磷酸化水平。结果组织荧光染色表明NFTs阳性荧光表达随铝阳性荧光增强而增强,两者分布呈对应关系;Western blot结果显示长期铝暴露导致tau蛋白水平下降(P<0.01,与对照组相比),但磷酸化水平升高(P<0.01,与对照组相比)。结论铝参与大脑新皮层神经元内NFTs形成与累积过程,tau蛋白的过度磷酸化可能是其成因之一。     

Urine levels of aluminum after drinking tea

A microwave-assisted acid digestion procedure coupled with a graphite furnace atomic absorption method has been applied in the determination of aluminum (Al) in urine to verify the correlation of free forms of Al in tea infusions and urinary excretion of Al. Significant urinary Al excretion has been found in 24-h urine of four volunteers after tea drinking. However, the difference in amount of Al excretion in urine between the consumption of Oolong (black tea) and Long-Jin (green tea), each of them with unique Al contents and species, was not significant. These findings indicated that the high levels of free Al species in tea infusions did not result in significant change in urinary excretion of the metal, possibly owing to the transformation by ligands present in food and the gastrointestinal tract (GIT). However, it could not be assumed that there was no big difference in absorption of the metal in the human body if fractions of consumed Al retained in the body or excreted by bile or feces were considered.     

Determination of aluminum levels in the kidney,liver, and brain of mice treated with aluminum hydroxide

In the present study, aluminum (Al) accumulation has been examined after aluminum loading in mice. The kidney, liver, and brain aluminum levels for mice that had been treated orally with aluminum hydroxide for 105 d and for the control group were determined using graphite furnace atomic absorption spectrophotometry (GFAAS) following an acid digestion. Matrix modifier consisted of 2% Triton X-100 and 2% Mg (NO₃)₂. Al loaded mice showed a significant increase in tissue aluminum levels, relative to the control group.     

Phosphate and pepsin adsorptions by a new boehmite compound and aluminum hydroxide

A new microcrystalline compound of aluminum oxide hydroxide (tentatively named PT-A) was synthesized in the hope of providing a better phosphate adsorbent for future clinical use than the currently marketed aluminum hydroxide gels (ALG). An X-ray diffraction study demonstrated a boehmite structure in PT-A but an amorphous structure in ALG. PT-A was more stable in pH change than ALG; in elution tests in artificial gastric and intestinal solutions, aluminum ion eluted from PT-A was maximally 10% of the amount from ALG at pH 1.2; and was undetectable at pH 6.8, at which point ALG still showed some aluminum elution. Phosphate-adsorbing efficacy of PT-A and ALG in vitro was about the same at pH 1.2; however, it was four times greater in PT-A than in ALG at pH 6.8, indicating that PT-A will be effective in the intestine. PT-A also adsorbed pepsin but the amount was at most the same or much less than that adsorbed by ALG, which depended on pH in solution.     

Highly sensitive analytical method for aluminum movement in soybean root through lumogallion staining

We present highly sensitive aluminum detection method in root using fluorescent lumogallion. Roots treated with 100 μM AlCl₃ including 0.2 mM CaCl₂ (pH 4.5) were stained for 60 min with 10 μM lumogallion fluorescence solution and fluorescence from aluminum complex in root was observed under confocal laser microscope. There was a good correlation between the intensity of fluorescence and aluminum content. When the amount of aluminum lost during each step in staining process was measured, it was found that about 10% of aluminum was lost only at staining stage. Through lumogallion staining method, aluminum accumulation especially at an early stage of aluminum treatment in root was shown. At the beginning (2 hr), aluminum began to be accumulated in root cap. After 4 hr treatment, the aluminum distribution was spread to about 3 mm from root apex in the root cap and outer cortex. When aluminum was found in the outer cortex in 3–5 mm from the root apex, the viability was tended to be decreased in the same area (6 hr). At the same time, aluminum amount in meristem was increased. However the comparison of lumogallion staining method with that of morin, which has been widely used to detect aluminum in root, the sensitivity of lumogallion method was found to be much higher.     

菌根真菌对酸铝胁迫的响应

酸性环境中活性铝浓度升高可能抑制菌根真菌生长,为探讨酸性条件下菌根真菌对活性铝的响应机制,以拟青霉(Simplicillium sp.,Si)、细长孢霉(Mortierella elongate,Me)、木霉菌(Trichoderma spp.,Tr)、瓶头霉(Phialocephala,Ph)和葡萄状穗霉(Stachybotrys chartarum,Sc)5种菌根真菌为供试材料,采用PDA液体培养基单种纯培养以pH值为5.5设定3个Al3+浓度梯度,分别为对照(0 mmol·L^-1)、低铝(0.2 mmol·L^-1)和高铝(1.0 mmol·L^-1),研究酸性条件下不同活性铝浓度对菌根真菌的生物量、有机酸分泌以及N、P、K含量等的影响。结果表明:(1)除拟青霉(Si)外,其他菌株均不同程度受活性铝浓度影响,Si生物量随活性铝浓度增加而增加,低铝时比对照增加了238%(P<0.05),而细长孢霉(Me)、木霉菌(Tr)、瓶头霉(Ph)和葡萄状穗霉(Sc)生物量均降低,其中,Ph和Sc分别比对照降低了38.1%和72.5%(P<0.05)。(2)5种菌根真菌分泌有机酸存在显著性差异,Si、Me、Tr和Sc的H+分泌量在高铝浓度时均低于对照,对Si产生显著性差异(P<0.05);仅Me分泌草酸,对照的分泌量是高铝时的1.12倍。(3)5种菌根真菌N、P、K含量随不同活性铝浓度胁迫存在显著性差异,Si和Sc的P、K含量随活性铝浓度增加而显著增加(P<0.05);Me和Ph的N含量随活性铝浓度增加而显著降低(P<0.05),Me的P、K含量分别在低铝和高铝时达到峰值,Tr和Ph的N、P、K含量在低铝时达到峰值而在高铝时受到抑制。(4)Si、Me和Tr受酸铝影响不显著,属耐酸铝型菌株,Ph和Sc属酸铝敏感型菌株。本工作可为天山雪岭云杉森林更新与幼苗存活问题研究的深入开展提供基础依据。     

Genetic influences on tissue deposition of aluminum in mice

Aluminum is a known neurotoxin and has been suggested to play a role in the development of Senile Dementia of the Alzheimer's Type. The relationship between aluminum exposure and senile dementia cannot be a simple one, however, as not all exposure results in neurotoxic manifestations. To determine if there are genetic differences in susceptibility to moderate aluminum exposure, 16 mice of five inbred strains were divided into two groups. The control group was fed a purified diet containing all known requirements for mice; the experimental group was fed the same diet supplemented with 260 mg Al/kg diet for 28 d. Analysis of brains, livers, and tibias for aluminum concentrations revealed strain differences in response to dietary treatment. The most notable results occurred in the DBA/2 and C3H/2 strains, with brain aluminum levels higher in the experimental groups. In contrast, A/J, BALB/c, and C57BL/6 strains showed no differences in brain aluminum in response to dietary treatment. These findings suggest that there are genetic differences in the permeability of the blood brain barrier and lend support to the hypothesis that variability in aluminum toxicity may be, in part, genetically determined.     

Aluminum speciation studies in biological fluids. Part 7. A quantitative investigation of aluminum(III)-malate complex equilibria and their potential implications for aluminum metabolism and toxicity.

As a nonessential element, aluminum may be toxic at both environmental and therapeutic levels, depending on ligand interactions. Dietary acids that normally occur in fruits and vegetables and commonly serve as taste enhancers are good ligands of the Al(3+) ion. Malic acid is one of these and also one of the most predominant in food and beverages. The present paper reports an examination of its potential influence on aluminum bioavailability through speciation calculations based on Al(III)-malate complex formation constants especially determined for physiological conditions. According to the results obtained, malate appears to be extremely effective in maintaining Al(OH)(3) soluble over the whole pH range of the small intestine under normal dietary conditions. In addition, two neutral Al(III)--malate complexes are formed whose percentages are maximum from very low malate levels. When aluminum is administered therapeutically as its trihydroxide, the amount of metal neutralized by malate peaks as its solubility pH range regresses to its original limits in the absence of malate. The enhancing effect of malate towards aluminum absorption is therefore virtually independent of the aluminum level in the gastrointestinal tract. The presence of phosphate in the gastrointestinal juice is expected to limit the potential influence of malate on aluminum absorption. Under normal dietary conditions, phosphate effectively reduces the fraction of aluminum neutralized by malate but without nullifying it. Aluminum phosphate is predicted to precipitate when aluminum levels are raised as with the administration of aluminum hydroxide, but a significant amount of neutral aluminum malate still remains in solution. Even therapeutic aluminum phosphate is not totally safe in the presence of malate, even at low malate concentrations. As plasma simulations predict that no compensatory effect in favor of aluminum excretion may be expected from malate, simultaneous ingestion of malic acid with any therapeutic aluminum salt should preferably be avoided.     

Functional and morphological changes in cultured neurons of rat cerebral cortex induced by long-term application of aluminum.

Aluminum is an environmental neurotoxin and a suspected risk factor for Alzheimer's disease. The neurotoxicity of aluminum on cultured neurons of rat cerebral cortex was investigated using an assay system for synapse formation and immunohistochemistry. The frequency of spontaneous oscillations of intracellular Ca2+, which is correlated to the number of synapses, was decreased after exposure to 100 microM of aluminum chloride for 22 days. Long-term application of aluminum (48 days) caused aggregation of cell bodies and fasciculation of processes. Processes and cell bodies were strongly stained by antibody to tau protein, which is one of the main components of Alzheimer's neurofibrillary tangles. It is suggested that the characteristics of the degeneration of cultured neurons induced by aluminum show some similarities to the pathology observed in brains with Alzheimer's disease.     

Impairment of motor coordination in mice after ingestion of aluminum chloride

The mechanisms of aluminum (Al) neurotoxicity is of increasing interest. Al compounds are known to produce neurological and behavioral abnormalities in some mammalian species. The present study was designed to determine the effects of Al chloride on the skilled motor performance in mice on the rota-rod treadmill. Al chloride, depending on the duration of treatment, produced an impairment of the motor coordination ability in mice.     

Chelating effect of novel pyrimidines in a model of aluminum intoxication

Long time ago aluminum (Al) was considered as a non-toxic element and its use had no restrictions. However, over the last two decades, scientific publications have indicated that Al is a toxic element. In line with this, aluminum accumulation in the organism is associated with a variety of human pathologies. Efficient therapeutics approach to treat Al intoxication are still not available, but there is a consensus that chelation therapy is the procedure to be used. However, the development of new chelating agents are highly desirable to improve the efficacy of the treatment of Al intoxication. The present study evaluates the chelating effect of two novel pyrimidines: 4-tricloromethyl-1-H-pyrimidin-2-one (THP) and (4-methyl-6-trifluoromethyl-6-pyrimidin-2-il)-hydrazine (MTPH) in a mice model of aluminum intoxication and compares their efficacy with those of desferrioxamine (DFO), a classical agent used for treat Al accumulation. The animals were exposed to aluminum by gavage (0.1 mmol aluminum/kg/day) 5 days/week for 4 weeks. At the end of this period, DFO was injected i.p. and the novel pyrimidines were given by gavage at 0.2 mmol/kg/day for five consecutive days. Aluminum concentration in tissues (brain, liver, kidney and blood) was determined by graphite furnace atomic absorption spectroscopy (GFAAS). The results showed that when administered by gavage, aluminum accumulated in the brain, kidney and liver of mice. MTPH was able to decrease aluminum levels in aluminum plus citrate animal groups, whereas THP was inefficient for this purpose. However, the novel pyrimidines used in this study were unable to surpass the aluminum chelating property of DFO. Thus, new studies must be performed utilizing other chelating agents which can decrease aluminum toxicity.     

The effect of aluminum chloride on some steps of heme biosynthesis in rats after oral exposure

Certain disturbances in heme biosynthesis induced by aluminum chloride were examined. The experiment was performed on female rats that received AlCl₃ orally at the dose 100 mg Al/kg daily for 21 d. The effects of aluminum on the activity of delta-aminolevulinic acid synthetase (ALA-S), dehydratase (ALA-D), and heme oxygenase (O.H.) were observed on 3, 7, 14, and 21 d in liver and kidneys of rats. Also the activity of ALA-D in blood and the concentration of delta-aminolevulinic acid (ALA-U) in urine were observed. Orally administered aluminum caused increase in the activity of ALA-D in the liver and blood, and parallel decrease of ALA-U in urine (r=−0.85) of rats. Aluminum chloride also induced an increase of ALA-S and O.H. in the liver but not in the kidneys. The changes of the enzymes activity participating in heme biosynthesis after administration of aluminum may be correlated with anemia and iron metabolism in rats.     

Effect of aluminum exposure on pteridine metabolism

Occupational and environmental aluminum (Al) exposure cause serious health problems by interaction with biological systems. Al is one of the most documented metals because its cellular targets are unclear biochemical processes and membranes of organisms. The major aim of the present study was to investigate the alteration of serum and urine aluminum in occupational exposure and to observe whether the metal exposure could cause any changes in pteridine-pathway-related critical compounds such as urinary neopterin and biopterin and blood dihydropteridine reductase (DHPR). In this study, determination of the metal concentrations was carried out in Al-exposed workers (n=23) and healthy volunteers (n=18) by using a tomic absorption spectrometer. DHPR enzyme activity and levels of neopterin and biopterin were detected by spectrophotometric and high-performance liquid chromatographic methods, respectively. It was found that occupational exposure to the metal led to a statistically significant increase in serum Al levels compared to the controls (p<0.05). At the same time, urinary neopterin and biopterin concentrations of the exposed group were higher than nonexposed subjects (both p<0.05). The correlations among Al levels and DHPR activity, magnesium concentration in serum and urine, working years, smoking status, and age were evaluated.     

Studies of aluminum in rat brain

The effects of high aluminum concentrations in rat brain were studied using¹⁴C autoradiography to measure the uptake of [¹⁴C]2deoxy-d-glucose ([¹⁴C]2dG) and microbeam proteon-induced X-ray emission (microPIXE) with a 20-μm resolution to measure concentrations of magnesium, aluminum, potassium, and calcium. The aluminum was introduced intracisternally in the form of aluminum tartrate (Al-T), and control animals were given sodium tartrate (Na-T). The¹⁴C was administered intravenously. The animals receiving Al-T developed seizure disorders and had pathological changes, which included cerebral cortical atrophy. The results showed that there was a decreased uptake of [¹⁴C]2dG in cortical regions in which increased aluminum levels were measured, i.e., there was a correlation between the aluminum in the rat brain and decreased brain glucose metabolism. A minimum detection limit of about 16 ppm (mass fraction) or 3×10⁹ Al atoms was obtained for Al under the conditions employed.     

Exploration of the ability of Coleus blumei to accumulate aluminum

In this study, the capacity of an ornamental species (Coleus blumei) to extract and accumulate aluminum was evaluated. The analyzed parameters were amount of soluble aluminum, radical growth, tolerance rate, bioaccumulation factor, and tissues aluminum concentration. The main limiting factor for aluminum accumulation is the availability of the metal. However, Coleus blumei can grow and accumulate up to 1445.7 mg kg(-1) of aluminum dry base. This plant can play an important role in the treatment of polluted water with metals, since it can grow in conditions with a pH of around 4.8. The aluminum tolerance rate showed for this plant ranged between 18.8% and 25%. Therefore, this species behaves as a non-accumulator, even though the bioaccumulation factor was 3098.5 L kg(-1).     

Dynamic pathways of selenium metabolism and excretion in mice under different selenium nutritional statuses

The selenoprotein, cellular glutathione peroxidase (cGPx), has an important role in protecting organisms from oxidative damage through reducing levels of harmful peroxides. The liver and kidney in particular, have important roles in selenium (Se) metabolism and Se is excreted predominantly in urine and feces. In order to characterize the dynamics of these pathways we have measured the time-dependent changes in the quantities of hepatic, renal, urinary, and fecal Se species in mice fed Se-adequate and Se-deficient diets after injection of (82)Se-enriched selenite. Exogenous (82)Se was transformed to cGPx in both the liver and kidney within 1 h after injection and the synthesis of cGPx decreased 1 to 6 h and continued at a constant level from 6 to 72 h after injection. The total amount of Se associated with cGPx in mice fed Se-deficient diets was found to be less than in mice fed Se-adequate diets. This finding indicated that cGPx synthesis was suppressed under Se-deficient conditions and did not recover with selenite injection. Excess Se was associated with selenosugar in liver and transported to the kidney within 1 h after injection, and then excreted in urine and feces within 6 h after injection. Any excess amount of Se was excreted mainly as a selenosugar in urine.     

High dietary aluminum affects the response of rats to silicon deprivation

Antagonistic interactions between silicon and aluminum occur in living organisms. Thus, an experiment was performed to ascertain whether high dietary aluminum would accentuate the signs of silicon deprivation in rats and conversely whether silicon deprivation would accentuate the response to high dietary aluminum. The experiment was factorially arranged with two variables: silicon as sodium metasilicate, 0 or 40 μg/g diet, and aluminum as aluminum citrate, 0 or 500 μg/g diet. After 9 wk, body weights and plasma urea nitrogen were higher and plasma concentrations of threonine, serine, glycine, cystine, and methionine were lower in silicon-adequate than silicon-deprived rats. High dietary aluminum significantly decreased plasma phenylalanine. An interaction between aluminum and silicon affected plasma triglyceride, cholesterol, and phosphorus concentrations. High dietary aluminum decreased these variables when silicon was absent from the diet, but increased them when silicon was present. Skull iron and silicon concentrations were decreased and iron and zinc concentrations in the femur were increased by the addition of 500 μg Al/g diet. High dietary aluminum decreased tibia density in silicon-adequate rats, but increased tibial density in silicon-deprived rats. The findings indicate that in rats, high dietary aluminum can affect the response to silicon deprivation and dietary silicon can affect the response to high dietary aluminum.     

Distribution of aluminum in different brain regions and body organs of rat

In the present study, an attempt has been made to investigate the distribution of aluminum in different regions of brain and body organs of male albino rats, following subacute and acute aluminum exposure. Aluminum was observed to accumulate in all regions of the brain with maximum accumulation in the hippocampus. Subcellular distribution of aluminum indicated that there was maximum localization in the nucleus followed by cytosolic, microsomal, and mitochondrial deposition. Elution profile of cytosolic proteins on G-75 Sephadex column revealed a substantial amount of aluminum bound to high-mol-wt protein fraction. Aluminum was also seen to compartmentalize in almost all the tissues of the body to varying extents, and the highest accumulation was in the spleen.     

The distribution of aluminum into and out of the brain

The extent, rate and possible mechanism(s) by which aluminum enters and is removed from the brain are presented. Introduction of Al into systemic circulation as Al.transferrin, the predominant Al species in plasma, resulted in about 7 x 10(-5) of the dose in the brain 1 day after injection. This brain Al entry could be mediated by transferrin-receptor-mediated endocytosis (TfR-ME). When Al.citrate, the predominant small molecular weight Al species in blood plasma, is introduced systemically, Al rapidly enters the brain. The rate of Al.citrate brain influx suggests a more rapid process than mediated by diffusion or TfR-ME. The question has been raised: "Is the brain a 'one-way sink' for aluminum?". Clinical observations are a basis for this suggestion. Rat brain 26Al concentrations decreased only slightly from 1 to 35 days after systemic 26Al injection, in the absence or presence of the aluminum chelator desferrioxamine, suggesting prolonged brain Al retention. However, studies of brain and blood extracellular Al at steady state, using microdialysis, suggest brain Al efflux exceeds influx, suggesting carrier-mediated brain Al efflux. The predominant brain extracellular fluid Al species is probably Al.citrate. The hypothesis that brain Al efflux, presumably of Al.citrate, is mediated by the monocarboxylate transporter was tested and supported. Although some Al that enters the brain is rapidly effluxed, it is suggested that a fraction enters brain compartments within 24 h from which it is only very slowly eliminated.