在氢氧化铝凝胶灭活寨卡病毒疫苗中甲醛残留量的测定方法

<正>建立了一种简便测定氢氧化铝凝胶配制的灭活寨卡病毒疫苗中甲醛残留量的方法,以用于药品质量评价。甲醛与2,4-二硝基苯肼(DNPH)反应,衍生产物用高效液相色谱检测,检测波长为360 nm。衍生化反应可在高效液相色谱中2 mL样品管进行样品直接分析。该方法已根据国际药品注册协调会议Q2指南得到充分验证。氢氧化铝凝胶质量浓度达     

改良2, 4-二硝基苯肼法测定脑内源甲醛

内源甲醛代谢失衡所造成的脑慢性损伤被认为是衰老过程中记忆丢失的危险因素之一,因此,有必要准确测定脑内不同区域甲醛的含量为相关研究提供参考.作者通过2,4-二硝基苯肼(2,4-DNPH)偶联高效液相色谱(UV-HPLC),测定了家猪脑额叶、顶叶、颞叶、枕叶、海马、小脑、脑干内源甲醛含量(75.5～83.4μmol/kg).采用10%三氯乙酸处理脑组织匀浆(pH=1.0),不但可以避免蛋白质及其他分子的干扰,还可以省略现有方法中的萃取步骤,且提高了测试的灵敏度(P<0.05).该方法的回收率约95.96%～102.04%,相对标准偏差(n=5)小于10%.结果表明,改良2,4-DNPH法用于脑内源甲醛的测定,其操作简便、可信度高.     

高效液相色谱测定车间空气中的甲醛

将盛有 DNPH 液的气泡吸收瓶,吸收车间空气中甲醛.2,4-二硝基苯肼和醛定量反应形成二硝基苯腙.Shimadu ODS(φ4.6×150mm)柱上分离,紫外检测器(360nm)测定.以保留时间定性、峰面积定量.本法线性回归方程相关系数大于0.999,变异系数0.48%,最低检出浓度为0.17mg/m~3.     

反相高效液相色谱法测定石榴皮多酚类物质方法的建立及分析

建立了同时测定石榴皮多酚中绿原酸、表儿茶素、鞣花酸和槲皮素含量的反相高效液相色谱方法。采用色谱柱Hypersil ODS2(250 mm×4.6 mm,5μm),其流动相为乙腈-0.4%磷酸溶液(体积比17∶83),流速为1.0m L/min,检测波长310 nm,柱温为30℃。建立安石榴甙测量方法,色谱柱为Hypersil ODS2(250 mm×4.6 mm,5μm);流动相为甲醇-2%冰醋酸(体积比7∶93);体积流量为1.0 m L/min;检测波长为232 nm;柱温25℃。结果表明:绿原酸、表儿茶素、鞣花酸、槲皮素和安石榴甙在一定浓度范围内与峰面积呈良好的线性关系,其平均回收率分别为100.66%(RSD=2.06%)、100.05%(RSD=0.58%)、100.05%(RSD=0.51%)、99.51%(RSD=1.22%)和99.79%(RSD=0.52%)。此结果说明反相高效液相色谱可用于测定石榴皮多酚类物质。     

交联透明质酸凝胶中交联剂的HPLC测定

目的建立交联透明质酸钠凝胶中交联剂二乙烯基砜(DVS)残留量的测定方法。方法用高效液相色谱法测定DVS残留量,色谱条件为:色谱柱为C8(4.6mm×250mm),流动相为25mmol/L磷酸二氢钾溶液(pH3.0)-乙腈(90∶10),检测波长为210nm。结果DVS在1~50μg/g范围内线性关系良好(r=0.9997),平均回收率98.4%,RSD为1.02%。结论用高效液相色谱法测定交联透明质酸钠凝胶中DVS残留量,方法准确、可靠,可用于产品质量控制。     

一种测定蛹虫草中虫草酸含量的酶标仪微量反应方法

研究和建立一种基于酶标仪-96孔板高通量测定虫草酸含量的检测方法,并对该方法进行性能评价。以酶标仪为检测仪器,在96孔板内按照设定反应条件微量加入样品和试剂进行显色反应,利用酶标仪测定吸光度值并计算虫草酸含量。通过检测精密度、重复性、回收率,并与分光光度计法进行比较,综合评价该方法的准确度、精确度。结果表明,测定数据具有较高的精密度（样品CM1的RSD值0.829%;样品CM2的RSD值1.772%)、重复性（标准样品B40的RSD值2.061%;样品CM2 的RSD值1.599%)、回收率（平均回收率99.24%,RSD值3.666%）,测定结果与分光光度法检测结果无显著差异(P>0.05)。结果表明,酶标仪微量法测定准确、重复性好,并可大大减少样品和试剂的用量,该方法方便、快捷、高效,可以替代分光光度法用于虫草酸含量的测定。     

HPLC法同时测定鸡矢藤中熊果酸和齐墩果酸的含量

目的:建立高效液相色谱法同时测定鸡矢藤中熊果酸和齐墩果酸的含量。方法:色谱柱为DiamonsilTM C18(250×4.6 mm,5滋m),流动相为甲醇-0.05mol.L-1磷酸溶液(93∶7)为流动相,检测波长210 nm,进样量10滋L。结果:熊果酸在21.28滋g.mL-1～212.8滋g.mL-1范围内线性关系良好(r=0.9997),平均回收率为97.79%(RSD=1.30%);齐墩果酸在24.02滋g.mL-1～240.2滋g.mL-1范围内线性关系良好(r=0.9996),平均回收率为98.36%(RSD=1.11%)。结论:该方法简便、灵敏、准确,可用于鸡矢藤药材的质量评价。     

变色酸-分光光度法测定丝氨酸含量

建立了变色酸-分光光度法测定丝氨酸含量的方法。丝氨酸在一定的pH条件下经高碘酸钠氧化后能与变色酸发生发应,产物在570 nm处有最大吸光值,且吸光值与丝氨酸的含量呈一次线性关系。结果表明,丝氨酸在0-1.0 g.L-1范围内呈良好的线性关系(r=0.9973),平均加样回收率为100.30%,RSD为1.11%。将测量结果与高效液相测量结果做比较,两种方法的相符率达到99%至101%。变色酸-分光光度法操作简便,结果准确。     

高效液相法测定香菇菇柄麦角甾醇的含量

采用高效液相色谱法(High performance liquid chromatography,HPLC)建立了测定菇柄麦角甾醇的含量测定方法。确定提取过程中皂化剂的种类和醇碱比后,将样品皂化,萃取后蒸干溶剂,乙醇定容测定。采用Phe-nomenex-C18色谱柱,V(流动相甲醇)∶V(水)=98∶2,流速1.0 mL/min,检测波长282 nm。结果表明:麦角甾醇线性回归方程为Y=9E+9×106X-8919.9(X:质量浓度,mg/mL),R2=0.998 9,0.01~0.30 mg/mL范围内线性关系良好,回收率为97.31%~101.95%。与紫外分光光度法所测结果比较,HPLC法测定菇柄中麦角甾醇含量灵敏、快速、准确,适用菇柄中麦角甾醇的含量测定。     

HPLC法同时测定鸡矢藤中熊果酸和齐墩果酸的含量

目的：建立高效液相色谱法同时测定鸡矢藤中熊果酸和齐墩果酸的含量。方法：色谱柱为DiamonsilTM C18（250×4.6 mm,5滋m）,流动相为甲醇-0.05mol.L-1磷酸溶液（93∶7）为流动相,检测波长210 nm,进样量10滋L。结果：熊果酸在21.28滋g.mL-1～212.8滋g.mL-1范围内线性关系良好（r=0.9997）,平均回收率为97.79%（RSD=1.30%）;齐墩果酸在24.02滋g.mL-1～240.2滋g.mL-1范围内线性关系良好（r=0.9996）,平均回收率为98.36%（RSD=1.11%）。结论：该方法简便、灵敏、准确,可用于鸡矢藤药材的质量评价。     

C1 metabolism and the Calvin cycle function simultaneously and independently during HCHO metabolism and detoxification in Arabidopsis thaliana treated with HCHO solutions

Formaldehyde (HCHO) is suggested to be detoxified through one‐carbon (C1) metabolism or assimilated by the Calvin cycle in plants. To further understand the function of the Calvin cycle and C1 metabolism in HCHO metabolism in plants, HCHO elimination and metabolism by Arabidopsis thaliana in HCHO solutions was investigated in this study. Results verified that Arabidopsis could completely eliminate aqueous HCHO from the HCHO solutions. Carbon‐13 nuclear magnetic resonance (¹³C‐NMR) analysis showed that H¹³CHO absorbed by Arabidopsis was first oxidized to H¹³COOH. Subsequently, a clear increase in [U‐¹³C]Gluc peaks accompanied by a strong enhancement in peaks of [2‐¹³C]Ser and [3‐¹³C]Ser appeared in Arabidopsis. Pretreatment with cyclosporin A or L‐carnitine, which might inhibit the transport of ¹³C‐enriched compounds into chloroplasts and mitochondria, caused a remarkable decline in yields of both [U‐¹³C]Gluc and [3‐¹³C]Ser in H¹³CHO‐treated Arabidopsis. These results suggested that both the Calvin cycle and the C1 metabolism functioned simultaneously during HCHO detoxification. Moreover, both functioned more quickly under high H¹³CHO stress than low H¹³CHO stress. When a photorespiration mutant was treated in 6 mm H¹³CHO solution, formation of [U‐¹³C]Gluc and [2‐¹³C]Ser was completely inhibited, but generation of [3‐¹³C]Ser was not significantly affected. This evidence suggested that the Calvin cycle and C1 metabolism functioned independently in Arabidopsis during HCHO metabolism.     

生物催化甲醛生成L-木糖

在当今不可再生资源日益消耗的情形下,利用生物合成的技术,将甲醛转变成糖类,具有重要意义。该过程最重要的是找到一个合适的催化剂组合来实现甲醛的二聚反应。在最近的研究中,报道发现了一种乙醇醛合酶(Glycolaldehyde synthase,GALS)可以催化这一反应,将其与D-果糖-6磷酸醛缩酶(D-fructose-6-phosphate aldolase,FSA)组合使用,即"一锅酶"法,可以利用甲醛合成L-木糖,并且转化率可达64%。这一过程的实现也为合成其他糖的反应提供了参考。     

Crystal structure of formaldehyde dehydrogenase from Pseudomonas putida: the structural origin of the tightly bound cofactor in nicotinoprotein dehydrogenases

Formaldehyde dehydrogenase from Pseudomonas putida (PFDH) is a member of the zinc-containing medium-chain alcohol dehydrogenase family. The pyridine nucleotide NAD(H) in PFDH, which is distinct from the coenzyme (as cosubstrate) in typical alcohol dehydrogenases (ADHs), is tightly but not covalently bound to the protein and acts as a cofactor. PFDH can catalyze aldehyde dismutations without an external addition of NAD(H). The structural basis of the tightly bound cofactor of PFDH is unknown. The crystal structure of PFDH has been solved by the multiwavelength anomalous diffraction method using intrinsic zinc ions and has been refined at a 1.65 A resolution. The 170-kDa homotetrameric PFDH molecule shows 222 point group symmetry. Although the secondary structure arrangement and the binding mode of catalytic and structural zinc ions in PFDH are similar to those of typical ADHs, a number of loop structures that differ between PFDH and ADHs in their lengths and conformations are observed. A comparison of the present structure of PFDH with that of horse liver ADH, a typical example of an ADH, reveals that a long insertion loop of PFDH shields the adenine part of the bound NAD(+) molecule from the solvent, and a tight hydrogen bond network exists between the insertion loop and the adenine part of the cofactor, which is unique to PFDH. This insertion loop is conserved completely among the aldehyde-dismutating formaldehyde dehydrogenases, whereas it is replaced by a short turn among typical ADHs. Thus, the insertion loop specifically found among the aldehyde-dismutating formaldehyde dehydrogenases is responsible for the tight cofactor binding of these enzymes and explains why PFDH can effectively catalyze alternate oxidation and reduction of aldehydes without the release of cofactor molecule from the enzyme.     

甲基营养微生物的甲醛代谢途径及其在环境生物技术中的应用

甲醛是一种毒性很高的一碳化合物,甲基营养菌是一类能在有高浓度甲醛的环境中生存的微生物,它们体内有多种降解甲醛的氧化途径和将甲醛转化为细胞组分的同化途径。丝氨酸途径和酮糖单磷酸途径是同时存在于甲基营养型细菌中的两种甲醛同化途径,木酮糖单磷酸途径是甲基营养型酵母菌中独有的甲醛同化途径。为了充分挖掘甲基营养型微生物在环境生物技术中的潜在应用价值,最近有很多研究尝试利用甲基营养微生物的细胞及其甲醛代谢途径关键酶开发甲醛污染检测方法和生物治理技术,对这方面的研究进展进行综述。     

Kinetic Studies of Formaldehyde Binding in Tissue

Specimens of rabbit liver were fixed for various periods up to 6 days in buffered ¹⁴C-formaldehyde. Binding of the isotope reached a plateau after fixation for approximately 24 hr; the half-maximal binding level was reached after approximately 100 min. Formaldehyde binding at 37 C was faster than at 25 C, and faster at pH 7.0 than at pH 4.0. During rinsing of the fixed tissue in water for up to 26 days there was a progressive decrease in isotope content to 10-20% of the pre-rinse level, indicating that formaldehyde fixation is a reversible process.     

Urea formaldehyde insulating foams: a risk for health?

Summary In 1983, the media brought out articies expressing serious concerns as to the use of Urea Formaldehyde Foam Insulation (UFFI). The emission of formaldehyde vapours within UFF insulated homes was held responsible for ?serious health problems?. A major controversy then started, with on the one hand several consumer associations, and on the other, the UFFI raw materials producing companies, while government departments concerned were called upon to intervene. On careful consideration of facts, it clearly appeared that the number of health-related incidents that could be charged to UFFI was much smaller than uncontrolled rumour would indicate, and that the effects of formaldehyde, although very unpleasant, fortunately did not have the degree of severity reported. Establishing a dialogue between the parties involved seemed possible and a mutually acceptable solution, safegarding the interests of all concerned, within reach... UFFI could be used in homes provided it be implemented by skilled professionals who would accept to redress duly established insulation defects. Unfortunately, the anti-UFFI press campaign had ruined the image of the product in the mind of potential users. Industry gradually withdrew from the market. As for customers with defect ridden homes, they had no redress possibility left to them... Six years have elapsed since then, and it should now be possible to review the issue with a fresh and dispassionate mind, while assessing the causes and effects of the polemics of the past. UFFI is no longer used in France and may well not be for a long time yet, unless of course the value of an effective low cost insulation material well suited to existing buildings, is eventually rediscovered. In any event, it is unquestionably interesting to draw a lesson from this typical example and try to find better approaches to similar situations particularly in the housing sector, in order to best meet the requirements of all concerned.     

内源性甲醛异常蓄积与记忆衰退

近期,本实验室报道了内源性甲醛浓度与认知功能损伤程度之间的关系(Neurobiol Aging,2011,32(1):31-41).观察到转基因痴呆小鼠(APP、APP/PS1)及衰老加速型(SAMP8)小鼠脑内甲醛浓度较对照组显著升高.参照痴呆鼠脑内甲醛浓度,实验人员对正常成年小鼠进行注射,导致其视觉空间记忆能力减退.注射甲醛消除剂可以降低老龄大鼠体内甲醛浓度、减少APP痴呆模型小鼠脑内的老年斑,且能观察到记忆功能的改善.临床观察显示,老年痴呆患者尿甲醛浓度与认知功能损伤程度之间呈正相关.甲醛的过量蓄积造成脑慢性损伤,可能是散发性老年记忆衰退的机制之一.     

甲醛氧化途径关键酶重组蛋白的生化特性及固定化酶吸收甲醛效果研究

甲醛脱氢酶(formaldehyde dehydrogenase,ADH)与甲酸脱氢酶(formate dehydrogenase,FDH)是甲醛氧化途径的两个关键酶.恶臭假单胞菌(Pseudomonas putida)的PADH是一种不依赖谷胱甘肽可以把游离甲醛直接氧化为甲酸的脱氢酶,博伊丁假丝酵母菌(Candida boidinii)的FDH在有NAD+存在时可以把甲酸氧化为二氧化碳.以基因组DNA为模板用PCR方法,从P.putida中扩增出PADH基因的编码区(padh),从C.boidinii中扩增出FDH的编码区(fdh),然后亚克隆到pET-28a(+)中分别构建这两个基因的原核表达载体pET-28a-padh和pET-28a-fdh,转化大肠杆菌,利用IPTG诱导重组蛋白PADH和FDH的表达.通过优化条件使重组蛋白的表达量占菌体总蛋白的70%以上,通过亲和层析法纯化出可溶性PADH和FDH重组蛋白.对重组蛋白的生化特性分析结果表明:PADH在最适反应温度50℃的活性为1.95 U/mg;FDH在最适反应温度40℃的活性为0.376 U/mg.所表达的重组蛋白与之前报道过的相比,具有更好的热稳定性和更广的温度适应范围.将PADH、FDH两个重组蛋白及辅因子NAD+固定到聚丙烯酰胺载体基质上,对固定化酶甲醛吸收效果的初步分析结果显示固定化酶对空气中的甲醛有一定的吸收效果,说明这两种酶被固定后具有开发成治理甲醛污染环保产品的潜力.     

Maize glutathione-dependent formaldehyde dehydrogenase cDNA: a novel plant gene of detoxification

We have previously shown that intact plants and cultured plant cells can metabolize and detoxify formaldehyde through the action of a glutathione-dependent formaldehyde dehydrogenase (FDH), followed by C-1 metabolism of the initial metabolite (formic acid). The cloning and heterologous expression of a cDNA for the glutathione-dependent formaldehyde dehydrogenase from Zea mays L. is now described. The functional expression of the maize cDNA in Escherichia coli proved that the cloned enzyme catalyses the NAD⁺- and glutathione (GSH)-dependent oxidation of formaldehyde. The deduced amino acid sequence of 41 kDa was on average 65% identical with class III alcohol dehydrogenases from animals and less than 60% identical with conventional plant alcohol dehydrogenases (ADH) utilizing ethanol. Genomic analysis suggested the existence of a single gene for this cDNA. Phylogenetic analysis supports the convergent evolution of ethanol-consuming ADHs in animals and plants from formaldehyde-detoxifying ancestors. The high structural conservation of present-day glutathione-dependent FDH in microorganisms, plants and animals is consistent with a universal importance of these detoxifying enzymes.     

甲醛导致细胞周期异常的浓度选择性

一定浓度的甲醛可以引起蛋白质的异常修饰、功能丧失、细胞死亡。虽然甲醛的细胞毒性已见报道,但甲醛影响神经细胞周期及其分子机制等尚不明确．本文采用不同浓度甲醛与神经母细胞瘤细胞系SH-SY5Y共孵育,观察到甲醛对细胞周期的影响取决于甲醛的浓度．当甲醛浓度([FA])≤0.1 mmol/L(细胞培养48 h),细胞周期与对照相比,无显著性差异．当甲醛浓度增加(0.1 mmol/L <[FA]≤0.2 mmol/L),S期和G2/M期细胞比例显著增加;当[FA] = 0.3 mmol/L时,细胞增殖被显著抑制,大量细胞滞留在S期(46.28%),G2/M期细胞仅占16.05%．将细胞同步到G2/M期,用0.1～0.3 mmol/L甲醛孵育,尽管G2/M期细胞都有一定程度的减少,但S期细胞显著增加;将细胞同步化到S期,与0.1 mmol/L甲醛孵育,则G2/M期细胞有一定程度的减少;与0.3 mmol/L甲醛孵育,表现为G2/M细胞显著减少,S期细胞极度增加．在相同条件下,Sprague-Dawley (SD)大鼠原代皮层神经元,也表现出G2/M期细胞比例随甲醛浓度升高而降低,S期细胞比例随之增加的现象．当0.1 mmol/L≤[FA]≤0.2 mmol/L时,细胞出现明显的早期或晚期凋亡;当[FA]≥0.3 mmol/L时,DNA损伤明显,细胞出现凋亡和部分坏死．以上结果提示,低浓度甲醛(0.1 mmol/L≤[FA]≤0.2 mmol/L)主要通过引起DNA超甲基化而抑制S期DNA的合成,高浓度甲醛([FA]≥0.3 mmol/L)则造成DNA的损伤,从而影响细胞周期的进程．