Nicotine: Alcohol Reward Interactions

It is well established that the continued intake of drugs of abuse is reinforcing—that is repeated consumption increases preference. This has been shown in some studies to extend to other drugs of abuse; use of one increases preference for another. In particular, the present review deals with the interaction of nicotine and alcohol as it has been shown that smoking is a risk factor for alcoholism and alcohol use is a risk factor to become a smoker. The review discusses changes in the brain caused by chronic nicotine and chronic alcohol intake to approach the possible mechanisms by which one drug increases the preference for another. Chronic nicotine administration was shown to affect nicotine receptors in the brain, affecting not only receptor levels and distribution, but also receptor subunit composition, thus affecting affinity to nicotine. Other receptor systems are also affected among others catecholamine, glutamate, GABA levels and opiate and cannabinoid receptors. In addition to receptor systems and transmitters, there are endocrine, metabolic and neuropeptide changes as well induced by nicotine. Similarly chronic alcohol intake results in changes in the brain, in multiple receptors, transmitters and peptides as discussed in this overview and also illustrated in the tables. The changes are sex and age-dependent—some changes in males are different from those in females and in general adolescents are more sensitive to drug effects than adults. Although nicotine and alcohol interact—not all the changes induced by the combined intake of both are additive—some are opposing. These opposing effects include those on locomotion, acetylcholine metabolism, nicotine binding, opiate peptides, glutamate transporters and endocannabinoid content among others. The two compounds lower the negative withdrawal symptoms of each other which may contribute to the increase in preference, but the mechanism by which preference increases—most likely consists of multiple components that are not clear at the present time. As the details of induced changes of nicotine and alcohol differ, it is likely that the mechanisms of increasing nicotine preference may not be identical to that of increasing alcohol preference. Stimulation of preference of yet other drugs may again be different –representing one aspect of drug specificity of reward mechanisms.     

酒精性肺疾病的临床研究及进展

酒精对全身器官均有损害,随着研究的深入,酒精性肺疾病逐渐被人们重视。基于酒精的挥发性和肺脏的丰富血供,酒精可以通过支气管循环从纤毛上皮进入到气道,汽化的酒精还可以沉积回气道随呼气再次被释放,这种重复循环使局部气道上皮细胞持续暴露于高浓度酒精下。酒精在肺脏的代谢分为氧化和非氧化代谢两种途径,氧化代谢产物乙醛可引起氧化应激,并产生大量的ROS和自由离子。酒精可影响肾素-血管紧张素系统,提高血管紧张素II水平,并引起内皮细胞应激。酒精还可降低肺脏内还原型谷胱甘肽含量,损害机体先天性和获得性免疫功能。本文将阑述酒精在肺脏的代谢途径及代谢产物对肺脏的损害,其引起重要的应激反应对肺脏均造成损害,是发生肺炎、慢性阻塞性肺疾病、急性呼吸窘迫征等肺疾病的重要因素之一。作者通过酒精对肺脏的作用机制,总结最新的治疗措施。     

Biological effects and metabolic interactions after chronic and acute administration of 4-methylpyrazole and ethanol to rats

4-Methylpyrazole in a dose producing an inhibition of alcohol dehydrogenase of about 60% was given alone or in combination with ethanol (10%) as sole drinking fluid to growing rats in periods up to 38 weeks. No effects were observed on the weight curves. Hematologic analyses showed normal values for blood and bone marrow. Studies of liver function with transaminase, bilirubin and albumin did not reveal any functional changes. Kidney function was normal as judged by creatinine and normal electrolytes. Electronmicroscopy of liver, kidney, and heart did not reveal any changes related to treatment. Combined treatment of ethanol and 4-methylpyrazole caused an increase of the microsomal drug-metabolizing activity. Chronic administration of ethanol and 4-methylpyrazole indicated that there is a mutual interaction in the metabolism of ethanol and 4-methylpyrazole, leading to a higher concentration of both ethanol and 4-methylpyrazole in the blood. Acute experiments, where alcohol dehydrogenase is saturated with ethanol, indicated a much slower elimination of 4-methylpyrazole. Administration of ethanol and 4-methylpyrazole in acute experiments showed a lower concentration of 4-hydroxymethylpyrazole in the blood indicating that ethanol interferes with the 4-methylpyrazole- and/or 4-hydroxymethyl-pyrazole-metabolizing enzymes. The present investigation has shown that the acute and chronic toxicity of 4-methylpyrazole alone or in combination with ethanol is minimal at doses that are effective in blocking ethanol metabolism in the rat. Because of its low toxicity and powerful inhibitory capacity, 4-methylpyrazole should be a potential tool for experimental clinical investigation of alcohol metabolism and its effects. 4-Methylpyrazole is also a potential therapeutic agent in methanol or ethylene glycol poisoning.     

Early and late changes in the metabolic pattern of the working myocardial fibres and Purkinje fibres of the human heart under ischaemic and inflammatory conditions: An enzyme histochemical study

Summary In this communication, the results of an enzyme histochemical study on the working myocardial fibres and Purkinje fibres of the atrioventricular conducting system of the human heart under ischaemic and inflammatory conditions are presented. The material was selected from patients showing changes which could be classified in three major groups: (1) early changes due to acute ischaemia either in the myocardial fibres or in the conducting system or in both; (2) chronic ischaemic changes due to cardiovascular insufficiency, such as old infarction, or coronary arteriosclerosis or both; and (3) inflammatory conditions such as myocarditis.The activity and location of about 20 enzymes that play a role in the aerobic and anaerobic pathways of energy metabolism were examined. The activity and location of some hydrolytic enzymes and the glycogen and lipid content were also studied.The most important findings were an obvious depletion of the glycogen reserves under acute ischaemic changes in both types of fibre. This was associated with a transient or permanent reduction in activity of many enzymes that play a role in aerobic and anaerobic metabolism. Further, there was an instantaneous and persistent increase in the activity of the NADPH-regenerating enzymes of the pentose phosphate pathway and of glyceraldehyde-3-phosphate dehydrogenase, the rate-limiting enzyme of glycolysis under ischaemic conditions. Chronic ischaemic changes were characterized by a gradual long-term increase in the activity of many anaerobic glycolytic enzymes. Moreover, there was an absence of activity of acetylcholine esterase immediately after the onset of infarction in the fibres of the conducting system. Lastly, a slight increase in lipid content was found in the hypertrophic chronic ischaemic fibres and in old infarcted areas. Cardiac fibres in inflamed areas showed a marked increased activity of the pentose phosphate shunt enzymes and a less pronounced increased activity of most anaerobic and hydrolytic enzymes. In contrast to the cardiac fibres in infarcted areas, the fibres in inflamed areas did not reveal a decrease or absence of activity of aerobic enzymes such as succinate dehydrogenase.     

Energy Stores Are Not Altered by Long-Term Partial Sleep Deprivation in Drosophila melanogaster

Recent human studies reveal a widespread association between short sleep and obesity. Two hypotheses, which are not mutually exclusive, might explain this association. First, genetic factors that reduce endogenous sleep times might also impact energy stores, an assertion that we confirmed in a previous study. Second, metabolism may be altered by chronic partial sleep deprivation. Here we address the second assertion by measuring the impact of long-term partial sleep deprivation on energy stores using Drosophila as a model. We subjected flies to long-term partial sleep deprivation via two different methods: a mechanical stimulus and a light stimulus. We then measured whole-body triglycerides and glycogen, two important sources of energy for the fly, and compared them to un-stimulated controls. We also measured changes in energy stores in response to a random circadian clock shift. Sex and line-dependent alterations in glycogen and/or triglyceride levels occurred in response to the circadian clock shift and in flies subjected to a single night of sleep deprivation using light. Thus, consistent with previous studies, our findings suggest that acute sleep loss and changes to the circadian clock can alter metabolism. Significant changes in energy stores were also observed when flies were subjected to chronic sleep loss via the mechanical stimulus, although not the light stimulus. Interestingly, mechanical stimulation resulted in the same change in energy stores even when it was not associated with sleep deprivation, suggesting that the changes are caused by stress rather than sleep loss. These findings emphasize the importance of taking stress into account when evaluating the relationship between sleep loss and metabolism.     

Ethanol treatment alters beta-endorphin metabolism by purified synaptosomal plasma membranes

Ethanol administration has been shown to affect beta-endorphin (beta-E) levels in most brain areas. Chronic ethanol treatment has also lead to changes in the levels of Met- and Leu-enkephalin which may be due to recent finding that enkephalin A activity is significantly altered. To determine if proteolytic enzymes responsible for beta-E metabolism at the pSPM are also altered, we studied the effect of chronic ethanol (7% v/v; 8 days) administration on in vitro central beta-E metabolism in male C57/BL mice. Purified SPM was time-course incubated with beta-E (20 microM) for 30-120 min and subjected to HPLC analyses for determination of beta-endorphin and related fragments. Chronic ethanol significantly reduced the half-life for beta-E at the pSPM (T1/2 = 50/min) versus controls (T1/2 = 100.4 min). Chronic ethanol also caused significant accumulation of the behaviorally active alpha- and gamma-type endorphins formed at the pSPM. These results suggest that chronic ethanol treatment leads to an increase in the activity of peptidases responsible for beta-E metabolism at pSPM leading to an increased formation of both alpha- and gamma-type endorphins which may affect alcohol related behaviors.     

Effects of modulation of glycerol kinase expression on lipid and carbohydrate metabolism in human muscle cells.

Glycerol is taken up by human muscle in vivo and incorporated into lipids, but little is known about regulation of glycerol metabolism in this tissue. In this study, we have analyzed the role of glycerol kinase (GlK) in the regulation of glycerol metabolism in primary cultured human muscle cells. Isolated human muscle cells exhibited lower GlK activity than fresh muscle explants, but the activity in cultured cells was increased by exposure to insulin. [U-(14)C]Glycerol was incorporated into cellular phospholipids and triacylglycerides (TAGs), but little or no increase in TAG content or lactate release was observed in response to changes in the medium glycerol concentration. Adenovirus-mediated delivery of the Escherichia coli GlK gene (AdCMV-GlK) into muscle cells caused a 30-fold increase in GlK activity, which was associated with a marked rise in the labeling of phospholipid or TAG from [U-(14)C]glycerol compared with controls. Moreover, GlK overexpression caused [U-(14)C]glycerol to be incorporated into glycogen, which was dependent on the activation of glycogen synthase. Co-incubation of AdCMV-GlK-treated muscle cells with glycerol and oleate resulted in a large accumulation of TAG and an increase in lactate production. We conclude that GlK is the limiting step in muscle cell glycerol metabolism. Glycerol 3-phosphate is readily used for TAG synthesis but can also be diverted to form glycolytic intermediates that are in turn converted to glycogen or lactate. Given the high levels of glycerol in muscle interstitial fluid, these finding suggest that changes in GlK activity in muscle can exert important influences on fuel deposition in this tissue.     

Differences in hepatic and metabolic changes after acute and chronic alcohol consumption.

Hepatic metabolism of ethanol to acetaldehyde by the alcohol dehydrogenase pathway is associated with the generation of reducing equivalents as NADH. Conversely, reducing equivalents are consumed when ethanol oxidation is catalyzed by the NADPH dependent microsomal ethanol oxidizing system. Since the major fraction of ethanol metabolism proceeds via alcohol dehydrogenase and since the oxidation of acetaldehyde also generates NADH, an excess of reducing equivalents is produced. This explains a variety of effects following acute ethanol administration, including hyperlactacidemia, hyperuricemia, enhanced lipogenesis and depressed lipid oxidation. To the extent that ethanol is oxidized by the alternate microsomal ethanol oxidizing system pathway, it slows the metabolism of other microsomal substrates. Following chronic ethanol consumption, adaptive microsomal changes prevail, which include enhanced ethanol and drug metabolism, and increased lipoprotein production. Severe hepatic lesions (alcoholic hepatitis and cirrhosis) develop after prolonged ethanol consumption in baboons. These injurious alterations are not prevented by nutritionally adequate diets and can therefore be ascribed to ethanol rather than to dietary inadequacy.     

Differential Phosphorylation of GluN1-MAPKs in Rat Brain Reward Circuits following Long-Term Alcohol Exposure

The effects of long-term alcohol consumption on the mitogen-activated protein kinases (MAPKs) pathway and N-methyl-D-aspartate-type glutamate receptor 1 (GluN1) subunits in the mesocorticolimbic system remain unclear. In the present study, rats were allowed to consume 6% (v/v) alcohol solution for 28 consecutive days. Locomotor activity and behavioral signs of withdrawal were observed. Phosphorylation and expression of extracellular signal-regulated protein kinase (ERK), c-Jun N-terminal kinase (JNK), p38 protein kinase and GluN1 in the nucleus accumbens, caudate putamen, amygdala, hippocampus and prefrontal cortex of these rats were also measured. Phosphorylation of ERK, but not JNK or p38, was decreased in all five brain regions studied in alcohol-drinking rats. The ratio of phospho/total-GluN1 subunit was reduced in all five brain regions studied. Those results suggest that the long-term alcohol consumption can inhibits GluN1 and ERK phosphorylation, but not JNK or p38 in the mesocorticolimbic system, and these changes may be relevant to alcohol dependence. To differentiate alcohol-induced changes in ERK and GluN1 between acute and chronic alcohol exposure, we have determined levels of phospho-ERK, phospho-GluN1 and total levels of GluN1 after acute alcohol exposure. Our data show that 30 min following a 2.5 g/kg dose of alcohol (administered intragastrically), levels of phospho-ERK are decreased while those of phospho-GluN1 are elevated with no change in total GluN1 levels. At 24 h following the single alcohol dose, levels of phospho-ERK are elevated in several brain regions while there are no differences between controls and alcohol treated animals in phospho-GluN1 or total GluN1. Those results suggest that alcohol may differentially regulate GluN1 function and ERK activation depending on alcohol dose and exposure time in the central nervous system.     

Zinc Supplementation or Regulation of its Homeostasis: Advantages and Threats

To accomplish its multifunctional biological roles, zinc requires precise homeostatic mechanisms. There are efficient mechanisms that regulate zinc absorption from the alimentary tract and its excretion by the kidney depending on the organism demands. The regulatory mechanisms of cellular zinc inflow, distribution, and zinc outflow are so efficient that symptoms of zinc deficiency are rare, and symptoms connected with its massive accumulation are even more rare. The efficiency of homeostatic mechanisms that prevent zinc deficiency or excessive zinc accumulation in the organism is genetically conditioned. It seems that an essential element of zinc homeostasis is the efficiency of zinc transmembrane exchange mechanisms. Intracellular free zinc concentration is higher than in extracellular space. Physiologically, the active outflow of zinc ions from the cell depends on the increase of its concentration in extracellular space. The ion pumps activity depends on the efficiency by which the cell manages energy. Considering the fact that zinc deficiency accelerates apoptosis and that excessive zinc accumulation inside cells results in a toxic effect that forces its death brings about several questions: Is intensification and acceleration of changes in zinc metabolism with age meaningful? Is there a real zinc deficiency occurring with age or in connection with the aforementioned pathological processes, or is it just a case of tissue and cell redistribution? When discussing factors that influence zinc homeostasis, can we consider zinc supplementation or regulation of zinc balance in the area of its redistribution? To clarify these aspects, an essential element will also be the clear understanding of the nomenclature used to describe changes in zinc balance. Zinc homeostasis can be different in different age groups and depends on sex, thus zinc dyshomeostasisrefers to changes in its metabolism that deviate from the normal rates for a particular age group and sex. This concept is very ample and implies that zinc deficiency may result from a low-zinc diet, poor absorption, excessive loss of zinc, zinc redistribution in intra- and extracellular compartments, or a combination of these factors that is inadequate for the given age and sex group. Such factor or factors need to be considered for preventing particular homeostasis disorders (or dyshomeostasis). Regulation of zinc metabolism by influencing reversal of redistribution processes ought to be the main point of pharmacologic and nonpharmacologic actions to reestablish zinc homeostasis. Supplementation and chelation are of marginal importance and can be used to correct long-term dietary zinc deficiency or zinc poisoning or in some cases in therapeutic interventions. In view of its biological importance, the problem posed by the influence of zinc metabolism requires further investigation. To date, one cannot consider, for example, routine zinc supplementation in old age, because changes of metabolism with age are not necessarily a cause of zinc deficiency. Supplementation is warranted only in cases in which deficiency has been established unambiguously. An essential element is to prevent sudden changes in zinc metabolism, which lead to dyshomeostasis in the terms defined here. The primary prophylaxes, regular physical activity, efficient treatment of chronic diseases, are all elements of such prevention.     

Changes in hepatic dolichol and dolichyl monophosphate caused by treatment of rats with inducers of the endoplasmic reticulum and peroxisomes and during ontogeny

Rats were treated with various inducers of the endoplasmic reticulum and peroxisomes and the properties and distributions of dolichol and dolichyl phosphate analyzed. The treatment of rats with carcinogenic agents 2-acetylaminofluorene, N-nitrosodiethylamine and 3-methylcholanthrene and with the compounds such as phenobarbital, terpentine, cholestyramine and di(2-ethylhexyl)phthalate have all caused changes in the microsomal or lysosomal contents of dolichol to various extents, but only the latter group influenced dolichyl-P concentration. Shortly after birth, the hepatic content of dolichyl-P reaches the adult level, whereas the level of the free alcohol is low at birth but increases continuously thereafter. Incorporation of [3H]mevalonate into dolichol was also dependent on factors other than de novo synthesis, e.g., the pool size. Rates of glycosylation reactions dependent on dolichyl-P exhibit considerable changes but are independent of the existing levels of lipid intermediate. GDP-mannosyl transferase activity increases greatly with birth, but the enzyme activity returns to the adult level within a day after birth. These results demonstrate that structural and functional modifications induced with drugs can greatly influence the content and distribution of dolichol which are independent of the existing levels of dolichyl-P.     

Stevioside counteracts the alpha-cell hypersecretion caused by long-term palmitate exposure

Long-term exposure to fatty acids impairs beta-cell function in type 2 diabetes, but little is known about the chronic effects of fatty acids on alpha-cells. We therefore studied the prolonged impact of palmitate on alpha-cell function and on the expression of genes related to fuel metabolism. We also investigated whether the antihyperglycemic agent stevioside was able to counteract these effects of palmitate. Clonal alpha-TC1-6 cells were cultured with palmitate in the presence or absence of stevioside. After 72 h, we evaluated glucagon secretion, glucagon content, triglyceride (TG) content, and changes in gene expression. Glucagon secretion was dose-dependently increased after 72-h culture, with palmitate at concentrations >or=0.25 mM (P< 0.05). Palmitate (0.5 mM) enhanced TG content of alpha-cells by 73% (P< 0.01). Interestingly, stevioside (10(-8) and 10(-6) M) reduced palmitate-stimulated glucagon release by 22 and 45%, respectively (P< 0.01). There was no significant change in glucagon content after 72-h culture with palmitate and/or stevioside. Palmitate increased carnitine palmitoyltransferase I (CPT I) mRNA level, whereas stevioside enhanced CPT I, peroxisome proliferator-activated receptor-gamma, and stearoyl-CoA desaturase gene expressions in the presence of palmitate (P<0.05). In conclusion, long-term exposure to elevated fatty acids leads to a hypersecretion of glucagon and an accumulation of TG content in clonal alpha-TC1-6 cells. Stevioside was able to counteract the alpha-cell hypersecretion caused by palmitate and enhanced the expression of genes involved in fatty acid metabolism. This indicates that stevioside may be a promising antidiabetic agent in treatment of type 2 diabetes.     

Regulation of catalytic activity of acid phosphatase by lipids in a reverse micellar system

The influence of biomembrane lipids on the catalytic activity of a peripheral membrane enzyme, acid phosphatase (AP), was studied in a reverse micellar system. It was found that the interaction of AP with lipids led to a number of kinetic effects depending on lipid nature on enzyme function. The observed effects might be caused by the formation of lipoprotein complexes as well as by the influence of lipids on structure and properties of the micellar matrix. The results are important for clear understanding of molecular mechanisms of regulation of the catalytic activity of the membrane-associated enzyme in vivo. These data can also be used as a physicochemical basis for application of AP in medical fields as a diagnostic tool for diseases caused by changes in lipid metabolism, e.g. urinary, orthopedic, and allergic diseases.     

Modulation of xenobiotic metabolism and oxidative stress in chronic streptozotocin-induced diabetic rats fed with Momordica charantia fruit extract

We studied the long-term effects of streptozotocin-induced diabetes on tissue-specific cytochrome P450 (CYP) and glutathione-dependent (GSH-dependent) xenobiotic metabolism in rats. In addition, we also studied the effect of antidiabetic Momordica charantia (karela) fruit-extract feeding on the modulation of xenobiotic metabolism and oxidative stress in rats with diabetes. Our results have indicated an increase (35-50%) in CYP4A-dependent lauric acid hydroxylation in liver, kidney, and brain of diabetic rats. About a two-fold increase in CYP2E-dependent hepatic aniline hydroxylation and a 90-100% increase in CYP1A-dependent ethoxycoumarin-O-deethylase activities in kidney and brain were also observed. A significant increase (80%) in aminopyrene N-demethylase activity was observed only in rat kidney, and a decrease was observed in the liver and brain of diabetic rats. A significant increase (77%) in NADPH-dependent lipid peroxidation (LPO) in kidney of diabetic rats was also observed. On the other hand, a decrease in hepatic LPO was seen during chronic diabetes. During diabetes an increased expression of CYP1A1, CYP2E1, and CYP4A1 isoenzymes was also seen by Western blot analysis. Karela-juice feeding modulates the enzyme expression and catalytic activities in a tissue- and isoenzyme-specific manner. A marked decrease (65%) in hepatic GSH content and glutathione S-transferase (GST) activity and an increase (about two-fold) in brain GSH and GST activity was observed in diabetic rats. On the other hand, renal GST was markedly reduced, and GSH content was moderately higher than that of control rats. Western blot analyses using specific antibodies have confirmed the tissue-specific alterations in the expression of GST isoenzymes. Karela-juice feeding, in general, reversed the effect of chronic diabetes on the modulation of both P450-dependent monooxygenase activities and GSH-dependent oxidative stress related LPO and GST activities. These results have suggested that the modulation of xenobiotic metabolism and oxidative stress in various tissues may be related to altered metabolism of endogenous substrates and hormonal status during diabetes. The findings may have significant implications in elucidating the therapeutic use of antidiabetic drugs and management of Type 1 diabetes in chronic diabetic patients.     

ALCOHOL DEHYDROGENASE ACTIVITY IN RAT BRAIN AND LIVER

Abstract— A significant level of alcohol dehydrogenase activity has been demonstrated in the soluble fraction of rat brain. The pH optimum, kinetic properties and response to inhibitors are similar to those of liver alcohol dehydrogenase. The nutritional state of the animal, such as that associated with feeding or fasting, appeared to have no effect on the levels of the alcohol dehydrogenase activities in either liver or brain. A cerebral mechanism for the metabolism of ethanol may be involved in local biochemical adjustments in tissues during exposure to alcohol and may play a significant role in the pathogenesis of the neural disorders which can accompany chronic alcohol ingestion or acute withdrawal.     

First pass metabolism of ethanol--a gastrointestinal barrier against the systemic toxicity of ethanol

Both in men and rats, most of the ethanol ingested at a low dose is metabolized before it reaches the systemic circulation. Oxidation of ethanol (mainly in the stomach) accounts for the bulk of this effect. This "first pass" metabolism (FPM) may be viewed as a barrier which protects against the systemic toxicity of ethanol. This barrier can be overcome by large doses of ethanol. Its efficiency is also reduced by a decrease in gastric alcohol dehydrogenase (ADH) activity secondary to chronic alcohol consumption.     

Hypoxia regulates glutamate metabolism and membrane transport in rat PC12 cells

We investigated the effect of hypoxia on glutamate metabolism and uptake in rat pheochromocytoma (PC12) cells. Various key enzymes relevant to glutamate production, metabolism and transport were coordinately regulated by hypoxia. PC12 cells express two glutamate-metabolizing enzymes, glutamine synthetase (GS) and glutamate decarboxylase (GAD), as well as the glutamate-producing enzyme, phosphate-activated glutaminase (PAG). Exposure to hypoxia (1% O(2)) for 6 h or longer increased expression of GS mRNA and protein and enhanced GS enzymatic activity. In contrast, hypoxia caused a significant decrease in expression of PAG mRNA and protein, and also decreased PAG activity. In addition, hypoxia led to an increase in GAD65 and GAD67 protein levels and GAD enzymatic activity. PC12 cells express three Na(+)-dependent glutamate transporters; EAAC1, GLT-1 and GLAST. Hypoxia increased EAAC1 and GLT-1 protein levels, but had no effect on GLAST. Chronic hypoxia significantly enhanced the Na(+)-dependent component of glutamate transport. Furthermore, chronic hypoxia decreased cellular content of glutamate, but increased that of glutamine. Taken together, the hypoxia-induced changes in enzymes related to glutamate metabolism and transport are consistent with a decrease in the extracellular concentration of glutamate. This may have a role in protecting PC12 cells from the cytotoxic effects of glutamate during chronic hypoxia.     

l-carnitine: Nutrition,pathology, and health benefits

Carnitine is a medically needful nutrient that contributes in the production of energy and the metabolism of fatty acids. Bioavailability is higher in vegetarians than in people who eat meat. Deficits in carnitine transporters occur as a result of genetic mutations or in combination with other illnesses such like hepatic or renal disease. Carnitine deficit can arise in diseases such endocrine maladies, cardiomyopathy, diabetes, malnutrition, aging, sepsis, and cirrhosis due to abnormalities in carnitine regulation. The exogenously provided molecule is obviously useful in people with primary carnitine deficits, which can be life-threatening, and also some secondary deficiencies, including such organic acidurias: by eradicating hypotonia, muscle weakness, motor skills, and wasting are all improved l-carnitine (LC) have reported to improve myocardial functionality and metabolism in ischemic heart disease patients, as well as athletic performance in individuals with angina pectoris. Furthermore, although some intriguing data indicates that LC could be useful in a variety of conditions, including carnitine deficiency caused by long-term total parenteral supplementation or chronic hemodialysis, hyperlipidemias, and the prevention of anthracyclines and valproate-induced toxicity, such findings must be viewed with caution.     

Lactational alcohol exposure elicits long-term immune deficits and increased noradrenergic synaptic transmission in lymphoid organs

Increasing evidence suggests that the sympathetic nervous system plays an important role in immunomodulation. While chronic alcohol consumption has been associated with immune deficits, the effects of exposure to alcohol during early postnatal life on subsequent immunocompetence and activity of sympathetic neurons in lymphoid organs are not known. This study examined the long-term effects of lactational alcohol consumption on cellular immune responses and noradrenergic synaptic transmission in lymphoid and other organs of the young adult C57BL/6 mouse. The data show that exposure to alcohol via the mother's milk was associated with long-term deficits in cellular immunity, including suppression of the local graft vs host and contact hypersensitivity responses. The animals also displayed enhanced noradrenergic synaptic transmission and decreased beta-adrenoceptor density selectively in lymphoid organs. These neuroimmune changes are particularly striking since body weight-gain of the suckling pups was normal and their blood alcohol concentration was considerably lower than that of the alcohol-consuming dam. This suggests an increased sensitivity of the nascent immune and nervous systems during the critical period of early postnatal development.     

解酒护肝饮解酒及对急慢酒精性肝损伤的保护作用

为了评价解酒护肝饮解酒效果及其对急、慢性酒精性肝损伤保护作用机制,本研究通过建立醉酒模型,确定致醉剂量;通过醉酒睡眠实验比较解酒护肝饮解酒特性;通过测定醉酒小鼠血乙醇含量的变化,研究解酒护肝饮对乙醇代谢的影响;通过建立急慢性酒精性肝损伤模型,测定AST、ALT、SOD活性,GSH、MDA水平,HE染色切片观察肝组织形态学的变化。研究发现小鼠最佳致醉剂量为11 m L/kg;与模型组比较,解酒护肝饮高(HD)、中剂量组(MD)均可延长醉酒时间、缩短醒酒时间(p<0.05),高、中剂量组可降低酒精灌胃后2 h、3 h时间点血乙醇含量(p<0.05);与模型组比较,急慢性酒精肝损伤模型各剂量组均能显著降低血清AST、ALT活性(p<0.05),急性酒精性肝损伤模型中,各剂量组肝组织SOD、GSH水平上升(p<0.05),MDA水平下降(p<0.05),而在慢性酒精性肝损伤模型肝组织中,低剂量组(LD)的SOD、GSH及MDA水平没有统计学差异;病理切片观察可见,急慢性酒精肝损伤模型高、中、低剂量组均能显著改善肝组织因乙醇而导致的肝损伤,并且高、中剂量组效果较好。本研究表明解酒护肝饮可显著延长醉酒时间,缩短醒酒时间,降低血乙醇的含量,对酒精诱导的肝损伤有较好的保护作用。