Expression pattern, ethanol-metabolizing activities, and cellular localization of alcohol and aldehyde dehydrogenases in human large bowel: association of the functional polymorphisms of ADH and ALDH genes with hemorrhoids and colorectal cancer

Alcohol dehydrogenase (ADH) and aldehyde dehydrogenase (ALDH) are principal enzymes responsible for metabolism of ethanol. Functional polymorphisms of ADH1B, ADH1C, and ALDH2 genes occur among racial populations. The goal of this study was to systematically determine the functional expressions and cellular localization of ADHs and ALDHs in human rectal mucosa, the lesions of adenocarcinoma and hemorrhoid, and the genetic association of allelic variations of ADH and ALDH with large bowel disorders. Twenty-one surgical specimens of rectal adenocarcinoma and the adjacent normal mucosa, including 16 paired tissues of rectal tumor, normal mucosae of rectum and sigmoid colon from the same individuals, and 18 surgical mixed hemorrhoid specimens and leukocyte DNA samples from 103 colorectal cancer patients, 67 hemorrhoid patients, and 545 control subjects recruited in previous study, were investigated. The isozyme/allozyme expression patterns of ADH and ALDH were identified by isoelectric focusing and the activities were assayed spectrophotometrically. The protein contents of ADH/ALDH isozymes were determined by immunoblotting using the corresponding purified class-specific antibodies; the cellular activity and protein localizations were detected by immunohistochemistry and histochemistry, respectively. Genotypes of ADH1B, ADH1C, and ALDH2 were determined by polymerase chain reaction-restriction fragment length polymorphisms. At 33 mM ethanol, pH 7.5, the activity of ADH1C*1/1 phenotypes exhibited 87% higher than that of the ADH1C*1/*2 phenotypes in normal rectal mucosa. The activity of ALDH2-active phenotypes of rectal mucosa was 33% greater than ALDH2-inactive phenotypes at 200 μM acetaldehyde. The protein contents in normal rectal mucosa were in the following order: ADH1 > ALDH2 > ADH3 ≈ ALDH1A1, whereas those of ADH2, ADH4, and ALDH3A1 were fairly low. Both activity and content of ADH1 were significantly decreased in rectal tumors, whereas the ALDH activity remained unchanged. The ADH activity was also significantly reduced in hemorrhoids. ADH4 and ALDH3A1 were uniquely expressed in the squamous epithelium of anus at anorectal junctions. The allele frequencies of ADH1C*1 and ALDH2*2 were significantly higher in colorectal cancer and that of ALDH2*2 also significantly greater in hemorrhoids. In conclusion, ADH and ALDH isozymes are differentially expressed in mucosal cells of rectum and anus. The results suggest that acetaldehyde, an immediate metabolite of ethanol, may play an etiological role in pathogenesis of large bowel diseases.     

Alcohol and aldehyde dehydrogenase

The enzymes mainly responsible for ethanol degradation in humans are liver alcohol dehydrogenases (ADH) and aldehyde dehydrogenases (ALDH). Polymorphisms occur in both enzymes, with marked differences in the steady-state kinetic constants. The Km-values for ethanol of ADH isoenzymes relevant for alcohol degradation range from 49 microM to 36 microM, and the Vmax-values from 0.6 to 10 U/mg. Expression of an inactive form of the ALDH2 isoenzyme, the so-called Oriental variant, results in impaired acetaldehyde metabolizing capacity. The differences in ethanol and acetaldehyde metabolizing activities of allelic enzyme forms may be responsible in part for the large variation in the alcohol metabolism rate in humans. Interindividual differences in the isoenzyme pattern may contribute to the genetically determined predisposition for excessive alcohol intake.     

Inhibition of human alcohol and aldehyde dehydrogenases by acetaminophen: Assessment of the effects on first-pass metabolism of ethanol

Acetaminophen is one of the most widely used over-the-counter analgesic, antipyretic medications. Use of acetaminophen and alcohol are commonly associated. Previous studies showed that acetaminophen might affect bioavailability of ethanol by inhibiting gastric alcohol dehydrogenase (ADH). However, potential inhibitions by acetaminophen of first-pass metabolism (FPM) of ethanol, catalyzed by the human ADH family and by relevant aldehyde dehydrogenase (ALDH) isozymes, remain undefined. ADH and ALDH both exhibit racially distinct allozymes and tissue-specific distribution of isozymes, and are principal enzymes responsible for ethanol metabolism in humans. In this study, we investigated acetaminophen inhibition of ethanol oxidation with recombinant human ADH1A, ADH1B1, ADH1B2, ADH1B3, ADH1C1, ADH1C2, ADH2, and ADH4, and inhibition of acetaldehyde oxidation with recombinant human ALDH1A1 and ALDH2. The investigations were done at near physiological pH 7.5 and with a cytoplasmic coenzyme concentration of 0.5 mm NAD⁺. Acetaminophen acted as a noncompetitive inhibitor for ADH enzymes, with the slope inhibition constants (K_is) ranging from 0.90 mm (ADH2) to 20 mm (ADH1A), and the intercept inhibition constants (K_ii) ranging from 1.4 mm (ADH1C allozymes) to 19 mm (ADH1A). Acetaminophen exhibited noncompetitive inhibition for ALDH2 (K_is = 3.0 mm and K_ii = 2.2 mm), but competitive inhibition for ALDH1A1 (K_is = 0.96 mm). The metabolic interactions between acetaminophen and ethanol/acetaldehyde were assessed by computer simulation using inhibition equations and the determined kinetic constants. At therapeutic to subtoxic plasma levels of acetaminophen (i.e., 0.2–0.5 mm) and physiologically relevant concentrations of ethanol (10 mm) and acetaldehyde (10 μm) in target tissues, acetaminophen could inhibit ADH1C allozymes (12–26%) and ADH2 (14–28%) in the liver and small intestine, ADH4 (15–31%) in the stomach, and ALDH1A1 (16–33%) and ALDH2 (8.3–19%) in all 3 tissues. The results suggest that inhibition by acetaminophen of hepatic and gastrointestinal FPM of ethanol through ADH and ALDH pathways might become significant at higher, subtoxic levels of acetaminophen.     

Research on alcohol metabolism among Asians and its implications for understanding causes of alcoholism

Research into the causes of alcoholism is a relatively recent scientific endeavor. One area of study which could lead to better understanding of the disease is the possibility of a genetic predisposition to alcoholism. Recent work has demonstrated that people have varying complements of enzymes to metabolize alcohol. Current knowledge is examined about the influence of various ethanol metabolizing enzymes on alcohol consumption by Asians and members of other ethnic groups. The two principal enzymes involved in ethanol oxidative metabolism are alcohol dehydrogenase (ADH) and aldehyde dehydrogenase (ALDH). ADH is responsible for the metabolism of ethanol to acetaldehyde. ALDH catalyzes the conversion of acetaldehyde to acetate. The different isozymes account for the diversity of alcohol metabolism among individuals. An isozyme of ADH (beta 2 beta 2) is found more frequently in Asians than in whites, and an ALDH isozyme (ALDH2), although present in Asians, often is in an inactive form. The presence of an inactive form of ALDH2 is thought to be responsible for an increase in acetaldehyde levels in the body. Acetaldehyde is considered responsible for the facial flushing reaction often observed among Asians who have consumed alcohol. A dysphoric reaction to alcohol, producing uncomfortable sensations, is believed to be a response to deter further consumption. Although the presence of an inactive ALDH2 isozyme may serve as a deterrent to alcohol consumption, its presence does not fully explain the levels of alcohol consumption by those with the inactive isozyme. Other conditions, such as social pressure, and yet undetermined biological factors, may play a significant role in alcohol consumption.     

A physiologically based model for ethanol and acetaldehyde metabolism in human beings.

Pharmacokinetic models for ethanol metabolism have contributed to the understanding of ethanol clearance in human beings. However, these models fail to account for ethanol's toxic metabolite, acetaldehyde. Acetaldehyde accumulation leads to signs and symptoms, such as cardiac arrhythmias, nausea, anxiety, and facial flushing. Nevertheless, it is difficult to determine the levels of acetaldehyde in the blood or other tissues because of artifactual formation and other technical issues. Therefore, we have constructed a promising physiologically based pharmacokinetic (PBPK) model, which is an excellent match for existing ethanol and acetaldehyde concentration-time data. The model consists of five compartments that exchange material: stomach, gastrointestinal tract, liver, central fluid, and muscle. All compartments except the liver are modeled as stirred reactors. The liver is modeled as a tubular flow reactor. We derived average enzymatic rate laws for alcohol dehydrogenase (ADH) and acetaldehyde dehydrogenase (ALDH), determined kinetic parameters from the literature, and found best-fit parameters by minimizing the squared error between our profiles and the experimental data. The model's transient output correlates strongly with the experimentally observed results for healthy individuals and for those with reduced ALDH activity caused by a genetic deficiency of the primary acetaldehyde-metabolizing enzyme ALDH2. Furthermore, the model shows that the reverse reaction of acetaldehyde back into ethanol is essential and keeps acetaldehyde levels approximately 10-fold lower than if the reaction were irreversible.     

Association of alcohol dehydrogenase 2 and aldehyde dehydrogenase 2 genotypes with fasting plasma glucose levels in Japanese male and female workers

AIMS: The objective was to clarify the effect of alcohol dehydrogenase 2 (ADH2) and aldehyde dehydrogenase 2 (ALDH2) genotypes on the diabetic risk in Japanese workers. METHODS: At the time of mandatory health checkup, the ADH2 and ALDH2 genotypes, as well as fasting plasma glucose (FPG) levels, body mass index (BMI), smoking habit, and weekly alcohol intake, were examined in 492 men and 183 women working at motor vehicle dealerships. RESULTS: In using two-way analysis of variance to manipulate ADH2 and ALDH2 genotypes and alcohol intake (>70 g/week for men and >35 g/week for women), the FPG level after the adjustment for age, BMI, smoking habit, and another genotype was significantly higher in the men with ADH2*1/1 genotype than in those with the other genotypes, but there was no significant difference in the FPG level between the men with and without ALDH2*1/1 genotype. In contrast, the women with ALDH2*1/1 genotype had significantly lower FPG levels than those with the other genotypes, but there was no significant difference in the FPG level between the women with and without ADH2*1/1 genotype. Also, a significant interaction between ethanol intake and ALDH2 genotypes was seen only in the women. CONCLUSIONS: These findings suggest that genotypes of ADH2 and ALDH2 can modify the diabetic risk, irrespective of amounts of alcohol consumed. Also, there may be sex differences in the effect of these enzyme genotypes on glucose metabolism.     

Pooled analysis of alcohol dehydrogenase genotypes and head and neck cancer: a HuGE review

Possession of the fast metabolizing alleles for alcohol dehydrogenase (ADH), ADH1B*2 and ADH1C*1, and the null allele for aldehyde dehydrogenase (ALDH), ALDH2*2, results in increased acetylaldehyde levels and is hypothesized to increase the risk of head and neck cancer. To examine this association, the authors undertook a Human Genome Epidemiology review on these three genes and a pooled analysis of published studies on ADH1C. The majority of Asians had the fast ADH1B*2 and ADH1C*1 alleles, while the majority of Caucasians had the slow ADH1B*1/1 and ADH1C*1/2 genotypes. The ALDH2*2 null allele was frequently observed among Asians, though it was rarely observed in other populations. In a pooled analysis of data from seven case-control studies with a total of 1,325 cases and 1,760 controls, an increased risk of head and neck cancer was not observed for the ADH1C*1/2 genotype (odds ratio = 1.00, 95% confidence interval: 0.81, 1.23) or the ADH1C*1/1 genotype (odds ratio = 1.14, 95% confidence interval: 0.92, 1.41). Increased relative risks of head and neck cancer were reported for the ADH1B*1/1 and ALDH2*1/2 genotypes in several studies. Recommendations for future studies include larger sample sizes and incorporation of relevant ADH and ALDH genes simultaneously, as well as other genes. These considerations suggest the potential for the organization of a consortium of investigators conducting studies in this field.     

Individual susceptibility and alcohol effects:biochemical and genetic aspects

The large interethnic and interindividual variability in alcohol-induced toxic effects comes from a combination of genetic and environmental factors, influencing ethanol toxicokinetics. The hepatic enzymatic systems involved in ethanol metabolism are alcohol dehydrogenase (ADH), aldehyde dehydrogenase (ALDH) and microsomal P4502E1 (CYP2E1). ADH oxidizes ethanol to acetaldehyde, which is very efficiently oxidized to acetate by ALDH. About 10% of moderate quantities of ethanol is metabolised by CYP2E1; the percentage increases when ADH is saturated. During ethanol metabolism reactive oxygen species and hydroxyethyl radicals are generated, causing oxidative stress, responsible for most ethanol-induced liver damage. For their critical role in detoxifying radicals, glutathione S-transferase are gaining attention in the etiology of alcoholism. All these enzymes have been shown to be polymorphic, giving rise to altered phenotypes. For this reason recent studies have looked for a correlation between metabolic variability and differences in alcohol abuse-related effects.     

Effect of acute ethanol drinking on alcohol metabolism in subjects with different ADH and ALDH genotypes

The effect of different amounts of orally ingested ethanol on plasma alcohol dehydrogenase (ADH) and erythrocyte aldehyde dehydrogenase (ALDH), as well as on the blood ethanol and acetaldehyde levels, was examined in healthy nonalcoholic subjects. The genotypes at ADH2 and ALDH2 locus were identified in enzymatically amplified blood DNA by hybridization with allele-specific oligonucleotides. While the Japanese subject was found to be genotypically heterozygous for both ADH2 and ALDH2, the Caucasian subjects were genotypically homozygous normal for these alleles. A faster ethanol elimination associated with a higher blood acetaldehyde level was observed in the Japanese subject as compared to Caucasian subjects. However, no significant change in ADH and ALDH enzyme activities was detected as the result of acute ethanol intake.     

Expression and activities of class IV alcohol dehydrogenase and class III aldehyde dehydrogenase in human mouth

Alcohol dehydrogenase (ADH) and aldehyde dehydrogenase (ALDH) are the principal enzymes responsible for the oxidation of ingested ethanol in humans. To study these two enzymes in surgical specimens of attached gingiva and tongue, we have examined the isozyme patterns by agarose isoelectric focusing and determined the enzyme activities. Class IV μ-ADH, class III χ-ADH, and class III ALDH₃ were detected in the oral mucosa tissues. Gingival μ-ADH exhibited a pH optimum for ethanol oxidation at 10 and the K_m value for ethanol (pH 7.5) was estimated to be 27 mM. At pH 7.5 and 30°C, the ADH activities in the gingiva and tongue samples were determined to be 90.0 ± 5.8 (mean ± SE; n = 24) and 50.6 ± 5.1 (n = 3) nmol/min/g tissue (at 33 mM ethanol), and 138 ± 11 and 55.1 ± 4.7 nmol/min/g tissue (at 500 mM ethanol), respectively. The ALDH activities at 20 mM acetaldehyde were determined to be 169 ± 19 and 50.3 ± 8.1 nmol/min/g tissue for the gingiva and tongue, respectively. We conclude that ethanol can be significantly metabolized in human attached gingiva and lingual mucosa by μ-ADH. The result also suggests that, due to lacking activity of low K_m ALDH₂ and ALDH₁, cytotoxic metabolite acetaldehyde may be involved in the etiology of alcohol-related oral injury.     

醛、醇脱氢酶基因多态性与三氯乙烯药疹样皮炎易感性的关系

目的研究醛脱氢酶、醇脱氢酶基因多态性与三氯乙烯药疹样皮炎易感性的关系。方法应用聚合酶链反应-限制性片段长度多态性(PCR-RFLP)方法,比较108例三氯乙烯药疹样皮炎病人和145例健康三氯乙烯接触工人醛脱氢酶2(ALDH2)、醇脱氢酶2(ADH2)和醇脱氢酶3(ADH3)的基因多态性分布,并计算相对危险度(OR)。结果ADH2和ADH3基因型分布在病人与接触对照工人中无显著性差异;ALDH2变异型基因(ALDH2*1/*2+ALDH2*2/*2)频率在病人中显著低于接触对照工人(分别为27·8%和43·4%,P=0·011),使三氯乙烯药疹样皮炎的危险性显著降低(OR=0·50,95%CI=0·29~0·85)。结论高活性ALDH2可能是导致三氯乙烯药疹样皮炎个体易感性差异的原因之一。     

Lack of aldehyde dehydrogenase ameliorates oxidative stress induced by single-dose ethanol administration in mouse liver.

Polymorphism of aldehyde dehydrogenase 2 (ALDH2), denoted ALDH2*2, is far more common in East Asian countries. Acetaldehyde, an intermediate metabolite of ethanol, is metabolized very slowly in people who have ALDH2*2, as the mutated ALDH2 lacks acetaldehyde metabolizing activity. On the other hand, it is well established that metabolism of ethanol causes oxidative stress in liver tissue. To examine the consequences of this polymorphism on ethanol-induced oxidative stress in liver tissue, we conducted a study using Aldh2 knockout mice. Aldh2+/+ and Aldh2-/- mice were orally administered ethanol at a dose of 5g/kg body weight. Levels of malondialdehyde, an indicator of oxidative stress, and glutathione, a key antioxidant, in liver tissue were analyzed 0-24h after administration. Levels of malondialdehyde were significantly lower in Aldh2-/- mice than in Aldh2+/+ mice at 12h after injection, while levels of glutathione were higher in Aldh2-/- mice than in Aldh2+/+ mice at 6 and 12h after injection. Our results suggest that a lack of ALDH ameliorates ethanol-induced oxidative stress in liver tissue.     

Regulation of Alcohol and Acetaldehyde Metabolism by a Mixture of Lactobacillus and Bifidobacterium Species in Human

Excessive alcohol consumption is one of the most significant causes of morbidity and mortality worldwide. Alcohol is oxidized to toxic and carcinogenic acetaldehyde by alcohol dehydrogenase (ADH) and further oxidized to a non-toxic acetate by aldehyde dehydrogenase (ALDH). There are two major ALDH isoforms, cytosolic and mitochondrial, encoded by ALDH1 and ALDH2 genes, respectively. The ALDH2 polymorphism is associated with flushing response to alcohol use. Emerging evidence shows that Lactobacillus and Bifidobacterium species encode alcohol dehydrogenase (ADH) and acetaldehyde dehydrogenase (ALDH) mediate alcohol and acetaldehyde metabolism, respectively. A randomized, double-blind, placebo-controlled crossover clinical trial was designed to study the effects of Lactobacillus and Bifidobacterium probiotic mixture in humans and assessed their effects on alcohol and acetaldehyde metabolism. Here, twenty-seven wild types (ALDH2*1/*1) and the same number of heterozygotes (ALDH2*2/*1) were recruited for the study. The enrolled participants were randomly divided into either the probiotic (Duolac ProAP4) or the placebo group. Each group received a probiotic or placebo capsule for 15 days with subsequent crossover. Primary outcomes were measurement of alcohol and acetaldehyde in the blood after the alcohol intake. Blood levels of alcohol and acetaldehyde were significantly downregulated by probiotic supplementation in subjects with ALDH2*2/*1 genotype, but not in those with ALDH2*1/*1 genotype. However, there were no marked improvements in hangover score parameters between test and placebo groups. No clinically significant changes were observed in safety parameters. These results suggest that Duolac ProAP4 has a potential to downregulate the alcohol and acetaldehyde concentrations, and their effects depend on the presence or absence of polymorphism on the ALDH2 gene.     

酒精代谢酶基因型在日本双生子中的分布

目的为预防酒精相关性疾病发生,调查了酒精代谢酶控制基因在日本双生子中的分布。方法以饱和酚法提取ＤＮＡ,应用限制性片段长度多态性分析技术检测了９２个日本双生子的酒精脱氢酶２（ＡＤＨ２）和乙醛脱氢酶２（ＡＬＤＨ２）基因型,根据基因型差异筛选敏感个体。结果ＡＤＨ２和ＡＬＤＨ２基因分布符合Ｈａｒｄｙｗｅｉｎｂｅｒｇ等式。ＡＤＨ２基因的３种基因型分别是ＡＤＨ２１／ＡＤＨ２１（１．１％）、ＡＤＨ２１／ＡＤＨ２２（４４．６％）和ＡＤＨ２２／ＡＤＨ２２（５４．３％）。ＡＬＤＨ２的基因型分别为ＡＬＤＨ２１／ＡＬＤＨ２１（４１．３％）、ＡＬＤＨ２１／ＡＬＤＨ２２（３９．１％）和ＡＬＤＨ２２／ＡＬＤＨ２２（１９６％）。ＡＤＨ２和ＡＬＤＨ２基因频率分别为０．２５５、０．７４５和０６０９、０３９１。结论异常纯合的ＡＤＨ２基因和纯合的ＡＬＤＨ２基因占优势。个体携有ＡＤＨ２１／ＡＤＨ２２和ＡＬＤＨ２１／ＡＬＤＨ２１、ＡＤＨ２２／ＡＤＨ２２和ＡＬＤＨ２１／ＡＬＤＨ２１者可视为敏感个体。     

Gene-environmental interactions in alcohol-related health problems--contributions of molecular biology to behavior modifications

High alcohol sensitivity among Asians is mainly due to a genetic polymorphism in the low Km aldehyde dehydrogenase (ALDH2) gene. Strong correlations between the ALDH2 genotype and alcohol sensitivity or alcohol drinking habits have been reported. Another prevalent polymorphism in the alcohol dehydrogenase beta-subunit (ADH2 gene) among Asians appears to modify skin flushing reactions after exposure to ethanol but does not influence alcohol drinking behavior. Both the ADH2 and ALDH2 genotypes have been significantly correlated with the risk of alcoholism. In a Japanese occupational population, a gene-environment interaction of the ALDH2 genotype and daily hassles scores for development of problem drinking behavior was observed. Habitual drinkers with the ALDH2*1/*2 genotype had higher frequencies of sister-chromatid exchange in cultured lymphocytes and higher 8-OHdG levels in polymorphonuclear leukocytes than those with the ALDH2*1/*1 genotype. Alcoholics and heavy drinkers with the ALDH2*1/*2 genotype have been shown to have significantly elevated risks for esophageal and multiple cancers in upper digestive organs than those with the ALDH2*1/*1 genotype. In Japan, bronchial asthma patients with the ALDH2*1/*2 genotype have been shown to have a significantly elevated risk for experiencing alcohol-induced asthma compared with the ALDH2*1/*1 genotype. Providing services to determine these genotypes would be of great help for each individual to make a plan for tailor-made health promotion.     

Properties of rat retina alcohol dehydrogenase

The rat eye fraction, including retina, pigment epithelium and choroid, contains an alcohol dehydrogenase (ADH) isoenzyme that is not present in rat liver. Starch gel electrophoresis of retina ADH shows an anodic band that can be visualized by activity staining, using either ethanol or pentanol as substrates. Ethanol is a poor substrate (Km: 336 mM, at pH 10.0) for the purified retina ADH which prefers long chain, 2-unsaturated and aromatic alcohols. The enzyme has a pH optimum of 10.0 for ethanol oxidation and it is inhibited by 4-methylpyrazole (KI: 10 microM). Electrophoretic and kinetic properties clearly differentiate the retina ADH from the hepatic cathodic ADH isoenzymes and from an anodic chi-ADH-like form that we have also detected in rat liver. At the pH and ethanol concentrations found "in vivo," retina ADH can oxidize ethanol to an appreciable extent. The subsequent production of acetaldehyde and redox change may be responsible for visual disorders during alcohol intoxication.     

Blood pressure, levels of serum lipids, liver enzymes and blood glucose by aldehyde dehydrogenase 2 and drinking habit in Japanese men

Objectives The association of blood pressure and levels of serum lipids, liver enzymes, blood glucose and aldehyde dehydrogenase 2 (ALDH2) with drinking habit was examined in Japanese men. Methods The subjects were 264 men aged 39 to 80 years who were classified into the ALDH2 deficiency or sufficiency group using the ethanol patch test and the Tokyo University ALDH2 Phenotype Screening Test. A self-administered questionnaire including drinking habit was used. Blood pressure and the levels of biochemical markers in groups with ALDH2 sufficiency, ALDH2 deficiency and drinking habit were compared using multiple regression models for adjusting age, smoking habit, physical exercising habit and body mass index. Results The levels of serum high-density lipoprotein cholesterol, triglycerides, aspartate aminotransferase (AST) and gamma-glutamyl transpeptidase (γ-GTP) were significantly higher in current drinkers of 20 g of ethanol or more per day than in nondrinkers of the ALDH2 sufficiency group. The levels of serum AST and γ-GTP in current drinkers of 20 g of ethanol or more per day, and fasting blood sugar in current drinkers of less than 20 g of ethanol per day were significantly higher than those in nondrinkers of the ALDH2 deficiency group. Conclusions These results suggest that alcohol consumption increases the levels of serum lipids and liver enzymes in ALDH2-sufficient individuals and liver enzymes and blood glucose levels in ALDH2-deficient individuals.     

以葛根提取物和藤茶粉为主要材料的配方的醒酒功能研究

目的 探讨并比较以葛根提取物和藤茶粉为主要材料的两种天然产物配方对急性酒精中毒小鼠乙醇脱氢酶（ADH）和乙醛脱氢酶（ALDH）活性的影响。方法 将18～22 g SPF级雄性KM小鼠随机分为AL[A配方低剂量：470mg/（kg·bw）]、AH[A配方高剂量：1 400 mg/（kg·bw）]、BL[B配方低剂量：400 mg/（kg·bw）]、BH[B配方高剂量：1 200 mg/（kg·bw）]、空白对照组、模型对照组、阳性对照组[海王金樽：1 500 mg/（kg·bw）]共7组,A、B配方组和阳性对照组按照受试物对应剂量灌胃14 d,模型对照组和空白对照组灌胃双蒸水[灌胃剂量：20 ml/（kg·bw）],第15 d除空白组外其余组灌胃52°白酒[灌胃剂量：22 ml/（kg·bw）]后观察翻正反射消失时间;酒精灌胃后的1、2和3 h分别进行眼眶取血检测血乙醇、乙醛含量变化趋势;取肝脏测定ADH和ALDH活性以及HE染色观察肝脏病理变化。结果 AH、BL、BH组ADH活性高于模型组（P=0.002;P=0.003;P=0.003）;A、B高低剂量ALDH活性高于模型组（P<...