乳酸生成

To promote the body's absorption of minerals in the large intestine by bacterial fermentation to generate L-lactic acid, can be dissolved calcium, magnesium, iron and other minerals, to promote the body's absorption of minerals; experiments confirmed that the prime factor Bifidobacterium absorption rate of calcium 70.8%.

促进人体对矿物质的吸收在大肠内被细菌发酵生成L-乳酸，可以溶解钙、镁、铁等矿物质，促进人体对矿物质的吸收；实验证实，黄金双歧因子促进钙的吸收率达70.8%。

To promote the body's absorption of minerals in the large intestine by bacterial fermentation to generate L-lactic acid, can be dissolved calcium, magnesium, iron and other minerals, to promote the body's absorption of minerals; experiment confirmed that the gold Bifidus factor promoting calcium absorption rate 70.8%.

促进人体对矿物质的吸收在大肠内被细菌发酵生成L-乳酸，可以溶解钙、镁、铁等矿物质，促进人体对矿物质的吸收；实验证实，黄金双歧因子促进钙的吸收率达70.8%。

These results show the level of diacetyl produced in Enterobacter aerogenes UV-3 would be dependent on the nonenzymatic oxidative decarboxylation of ALA.

通过主要代谢酶的酶学性质分析，确定产气肠杆菌突变株UV-3积累丁二酮的代谢途径是由α-乙酰乳酸的非酶氧化直接生成。

After developing 48 hours, hepatocytes enters 2.0 mM t-butyl hydroperxide or 2.0 mM diamide to induced cell blebbing. The samples collected at 0, 15, 30, 60 minutes to analyze cell about membrane protein thiol deletion; the leakage of lactate dehydrodenase; the change of glutathione; the lipid peroxidation; the variation of actin and tubulin, and use Confocal fluorescent microscope to observe the change of actin and tubulin in rat hepatocytes.

肝细胞在48小时培养后，分别加入2.0mM t-buty1 hydroperoxide或2.0 mM diamide诱发细胞膜小泡生成，并分别於0、15、30、60分钟取样，分析细胞膜硫醇流失程度；乳酸去氢□渗漏；□胱甘□浓度变化；脂质过氧化；肌动蛋白与管蛋白变化；并利用雷射共轭焦萤光显微镜观察肝细胞中肌动蛋白及管蛋白的变化。

In every group, rabbits were subdivided into experimental and control subgroups. 2 Rabbits were bullets injected followed by continuous injected with 13C labeled leucine, glucose, and lactic acid; 3 Blood were drewed before and 150, 160, 170, and 180 min after the initiation of isotopes injection for material analysis; 4 Exhale gas were collected every 5 min in the first 30 min followed by every 30 min there after for material analysis; 5 After centrifuge in low temp the supernatant of the blood samples were collected and went through axon and anon exchange column treatment; 6 Treated blood sample was used for 13C labeled leucine, glucose lactic acid examination through mass spectrograph; 7 The exhale gas was collected for 13CO2 exam through gas-phase mass spectrograph; 8 CO2 total production rate (V13CO2), body various substances production, oxidation speed, and substances metabolic percentage all can be calculated through equations provided by references below; 9 Data was processed through student t test.

分亮氨酸、葡萄糖和乳酸三组各取健康新西兰兔16只，每组再分为高代谢脓毒症组和对照组两部分，建模方法同第一部分；2）三组分别先静脉弹丸式推注再持续灌注13C标记的亮氨酸、葡萄糖和乳酸；3）灌注前抽取动脉血作为背景值，灌注达150，160，170和180min分别抽取动脉血2ml用于质谱分析；4）实验开始后前30min中每5min收集呼出气一次，随后每30min收集呼出气一次，用于气相质谱分析；5）血样经过低温离心取上清液，过阳离子及阴离子交换树脂，再经衍生化处理；6）处理过的血样进入气相色谱－质谱仪，测量其13C标记的亮氨酸、葡萄糖和乳酸丰度；7）实验兔的呼出气通过13CO2气相质谱分析仪测定其中的13CO2丰度（E13CO2）；8）利用文献提供的公式算出CO2总生成率（V13CO2）以及机体各物质的通量、氧化速率以及物质代谢百分比等；9）数据分析处理采用t检验。

The esterifying effects of monascus, daqu and rhizopus strain on single acid (acetic acid, caproic acid, lactic acid, butyric acid) and mixed acid (acetic acid,caproic acid,lactic acid, and butyric acid mixed together according to the ratio of 1∶1∶1∶1) were studied.

对红曲霉、大曲以及根霉菌对单一酸（乙酸、己酸、乳酸、丁酸）和混合酸（四大酸按1∶1∶1∶1混合）的酯化效果进行了研究，结果表明，红曲霉能促进己酸、丁酸及混合酸与乙醇的酯化作用，生成的酯类物质均为己酸乙酯，而且酯化能力极强；大曲能促进己酸、丁酸及混合酸与乙醇的酯化作用，生成的酯类物质均为己酸乙酯，并且能促进乙酸与乙醇的酯化生成乙酸乙酯；根霉能促进己酸和混合酸与乙醇的酯化作用，生成少量的己酸乙酯和乳酸乙酯。

The main gluconeogenic precursor in kidney is thought to be lactate; however, less is emphasized enantiomerically. L-lactate is a glycolysis end-product, but D-lactate is formed after detoxification of methylglyoxal, which is the main source of advanced glycation end-products.

乳酸为肾脏糖质新生的主要来源，其含有一不对称碳，故具有D-、L-乳酸两种镜相异构物，而D-、L-乳酸两者之生成相当不同，L-乳酸是糖解作用之终产物，D-乳酸为体内一醣化终产物(advanced glycation end-products)─甲基乙二醛进行去毒化反应所生成，目前缺乏对乳酸镜像异构物与肾脏糖质新生间相关的探讨。

Hydrothermal reactions makes water a Bronsted base-acid and act as an effective catalyst and the metal ions represent Lewis base character. The conversion process occurs in a very complex network of parallel, consecutive and equilibrium reactions, and the last step being the catalyzed Cannizzaro-type reaction of pyruvaldehyde to lactic acid.

nsted酸碱并具有一定的催化作用，金属离子在水热催化降解丙酮醛生成乳酸中表现出Lewis碱的特性，能与丙酮醛生成金属复合物，最终生成乳酸，此反应过程符合Cannizzaro反应特性。

The distribution partition of mass metabolic flux of high-level glucose between lactate production pathway and tricarboxylic acid cycle was 90% and 10%, with the ratio of ATP production 20% and 60%, respectively.

结果表明：当葡萄糖浓度较高时，葡萄糖在乳酸生成途径和TCA循环的代谢通量分配比例分别为90%和10%，ATP生成的比例分别为20%和60%，说明葡萄糖大部分经糖酵解途径生成乳酸，而进入TCA循环的少量部分则提供大部分的能量生成。

Principle:Lactate was dehydrogenated to pyruvate at the action of lactate dehydrogenase,at the same time NAD~+ received H~+ to yield NADH.According to the absorbance variances of NADH at 340 nm,the lactate level in supernatant of platelets was calculated.

原理：乳酸在乳酸脱氢酶作用下脱氢生成丙酮酸，同时NAD~+接受H~+生成NADH，根据NADH在340nm处的吸光度变化来计算血小板上清中乳酸的含量。

lactic acidosis：乳酸酸中毒

2.4.1 乳酸酸中毒的发病机制 乳酸酸中毒(lactic acidosis)是严重休克的代谢标志. 休克是组织氧供与需求之间的失衡,组织缺氧后,丙酮酸氧化减少,乳酸生成增多. 葡萄糖代谢生成丙酮酸后,不能进入线粒体的三羧酸循环,在胞浆中生成乳酸,

glycolytic pathway：酵解途径

一、糖酵解途径(glycolytic pathway) 糖酵解途径是指细胞在胞浆中分解葡萄糖生成丙酮酸(pyruvate)的过程,此过程中伴有少量atp的生成. 在缺氧条件下丙酮酸被还原为乳酸(lactate)称为糖酵解. 有氧条件下丙酮酸可进一步氧化分解生成乙酰coa进入三羧酸循环,

phosphoglycerate mutase：磷酸甘油酸变位酶

在磷酸甘油酸变位酶(phosphoglycerate mutase)催化下3-磷酸甘油酸C3-位上的磷酸基转变到C2位上生成2-磷酸甘油酸. 此反应是可逆的. 氧供应不足时从糖酵解途径生成的丙酮酸转变为乳酸. 缺氧时葡萄糖分解为乳酸称为糖酵解(glycolysis),

narcosis：麻醉

PaCO2 > 80mmHg,抑制呼吸中枢,可出现CO2麻醉(narcosis)(1)乳酸酸中毒:乳酸酸中毒(Lactc Acidosis)可见于各种原因引起的缺氧,其发病机制是缺氧时糖酵解过程加强,乳酸生成增加,因氧化过程不足而积累,导致血乳酸水平升高.

lactification：乳酸生成 乳酸形成

lactiferousgland 乳腺 | lactification 乳酸生成 乳酸形成 | lactifuge 回乳剂 止乳药

lactification：乳酸形成

lactification 乳酸生成 | lactification 乳酸形成 | lactifuge 止乳药

lactification：乳酸生成

lactiferous 输送乳汁的 | lactification 乳酸生成 | lactification 乳酸形成

lactifuge：回乳剂 止乳药

lactification 乳酸生成 乳酸形成 | lactifuge 回乳剂 止乳药 | lactigenous 泌乳的

Lactobacilli：乳酸杆菌

它们是如何转化成游离甙元的呢?研究认为,这主要是体内微生物酶的作用,使得这些葡萄糖甙发生了水解,生成异黄酮甙元和葡萄糖. 与大豆异黄酮糖甙酶解有关的肠道微生物有,乳酸杆菌(Lactobacilli)、假细菌(Bacteroides)双歧杆菌(Biofidobacteria).

Leuconostoc：明串球菌属

除明串球菌属(leuconostoc)外还有数种乳酸杆菌属于此类. 在微生物的同质乳酸发酵中,通过糖酵解途径由糖类生成丙酮酸,经乳酸脱氢酶作用形成乳酸. 在微生物链球菌中制造L(+)-乳酸,而乳酸杆菌制造D(-)-乳酸,也有两种乳酸均能制造的等等.