聚N-异丙基丙烯酰胺无胶筛分毛细管电泳分离DNA片段

采用0．5％～6％聚N-异丙基丙烯酰胺作为筛分介质,对ФX174／Hae Ⅲ酶切DNA片段毛细管电泳分离进行了研究,结果表明其筛分效果差,信噪比低。然而,添加适量甘露醇可以显著改善分离效率。在3％聚N-异丙基丙烯酰胺中添加2％～6％甘露醇可以取得较好的分离结果,并对甘露醇改善筛分能力的机制进行了探讨。     

毛细管电泳中葡萄糖-羟丙基甲基纤维素体系分离脱氧核糖核酸

葡萄糖作为羟丙基甲基纤维素（Hydroxpropylmethyl cellulose,HPMC)筛分体系的添加剂,可以改善该体系在低浓度时分离脱氧核糖核酸（DNA）的能力。研究了硼酸浓度和pH值对葡萄糖－羟丙基甲基纤维素体系分离性能的影响;并将葡萄糖与其它添加剂如甘油、甘露醇对分离的影响作了比较,葡萄糖特有的环状结构使得其对羟丙基甲基纤维素体系分离能力的提高更为显著。     

含有金纳米粒子的筛分介质对不同长度DNA片段的毛细管电泳分离

探讨了含有金纳米粒子(GNPs)的筛分介质在毛细管电泳(CE)中对不同长度DNA片段的分离.以聚环氧乙烷(PEO)-金纳米粒子(GNPs)-TBE为CE筛分介质,用涂层的毛细管柱(37 cm×75 μm,有效长度27 cm)分离DNA Marker D和1 kbp DNA Ladder Marker标准DNA片段,考察了CE过程中各参数(如筛分介质质量浓度、分离电压、温度和筛分介质pH值)对不同长度DNA片段分离的影响.对比了新型筛分介质与不含GNPs的PEO-TBE筛分介质的分离效果,并将新型筛分介质用于实际样品的检测.结果表明,在筛分介质中添加GNPs后能够改进CE的分离效果,且分离时间短.方法较适于分离较宽范围的DNA片段.     

基于纤维素衍生物的毛细管无胶筛分电泳及其应用

毛细管无胶筛分电泳近年来取得了很大进展。本文综述了以纤维素衍生物作为筛分介质的毛细管无胶筛分电泳的研究进展,包括筛分理论,筛分体系模式,以及它在DNA、蛋白质分离方面的应用。     

无胶筛分毛细管电泳分离盐生盐杆菌DNA片段

 由羟乙基纤维素和聚吡咯烷酮混合组成筛分介质 ,在涂敷聚硅氧烷的毛细管柱上 ,研究了LambdaDNA/EcoRⅠ +HindⅢ片段分离的最佳条件。实验表明 ,混合筛分介质与单一的羟乙基纤维素筛分介质相比 ,改变了筛分介质的孔径大小 ,抑制了毛细管壁对DNA的吸附 ,从而改善了分离 ,并首次在同一条件下将所含的 13个片段完全分离。方法简便、快速 ,曾应用于两组盐生盐杆菌DNA片段的分离及其碱基对数目的推测。     

毛细管电泳无胶筛分介质分离DNA的机理

快速、高效而灵敏的分离技术对于DNA的分析是至关重要的。使用无胶筛分介质的毛细管电泳是最重要的DNA分离技术之一，通常使用无交联的高分子溶液作为无胶筛分介质。本文在介绍高分子溶液理论的基础上，综述了DNA在毛细管电泳无胶筛分介质（缠结溶液和稀溶液）中的分离机理，主要包括Ogston筛分模型、各种修正的爬行模型、瞬态缠结偶合机理及其改进机理等。     

毛细管电泳无胶筛分介质分离DNA的机理

快速、高效而灵敏的分离技术对于DNA的分析是至关重要的。使用无胶筛分介质的毛细管电泳是最重要的DNA分离技术之一,通常使用无交联的高分子溶液作为无胶筛分介质。本文在介绍高分子溶液理论的基础上,综述了DNA在毛细管电泳无胶筛分介质(缠结溶液和稀溶液)中的分离机理,主要包括Ogston筛分模型、各种修正的爬行模型、瞬态缠结偶合机理及其改进机理等。     

毛细管电泳-限制性片段长度多态性快速检测胃癌组织中P53基因点突变的方法

为建立毛细管电泳快速高效检测小于70bp双链DNA的方法。对毛细管电泳过程中的各参数进行了考察,最终得到最佳分离体系(筛分介质浓度8%,添加剂甘露醇浓度8%,pH6.5,温度15℃,电场强度275V/cm),并将该体系用于临床59例胃癌患者肿瘤组织基因248位、249位密码子点突变情况的检测,30min之内同时检测了两个密码子位点的突变情况,实现了35bp和40bpDNA片段的基线分离,且分离度较高(1.642),初步建立了快速、高分辨诊断胃癌的方法。     

用于毛细管电泳DNA分离的合成聚合物*

毛细管电泳的无胶筛分方法在DNA片段分离、DNA 测序方面取得了显著的成绩并已成功应用于人类基因组计划.该法是在毛细管柱中充入一定浓度和组成的线性高分子溶液,利用其对样品组分电泳迁移时的阻滞作用,按分子量大小对DNA等生物大分子进行筛分分离分析.因此,聚合物筛分介质的类型、组成和性质会显著影响分离效果.近年来,由于受到基因组计划的影响,出现了许多用于DNA片段分离和DNA测序的水溶性高分子聚合物,并取得很大进展.本文按照均聚物和共聚物的分类,综述了作为筛分介质的各种合成聚合物及其应用效果,并简要介绍了有关的筛分理论和分离的评价指标.     

毛细管电泳无胶筛分介质分离DNA的机理

快速、高效而灵敏的分离技术对于DNA的分析是至关重要的.使用无胶筛分介质的毛细管电泳是最重要的DNA分离技术之一,通常使用无交联的高分子溶液作为无胶筛分介质.本文在介绍高分子溶液理论的基础上,综述了DNA在毛细管电泳无胶筛分介质(缠结溶液和稀溶液)中的分离机理,主要包括Ogston筛分模型、各种修正的爬行模型、瞬态缠结偶合机理及其改进机理等.     

Mannitol influence on the separation of DNA fragments by capillary electrophoresis in entangled polymer solutions

A new kind of sieving matrix is presented in this paper to allow satisfactory separation of DNA fragments in a relatively low viscous solution. When a certain amount of mannitol was added to cellulose solution not concentrated enough to separate PGEM-3Zf(+)/HaeIII standards well, a polymer solution with low viscosity but with very good separation effects was obtained. The separation result of this sieving buffer was comparable with those using highly concentrated cellulose solutions. The sieving ability of solutions with different cellulose concentrations and different amounts of mannitol has been investigated. It was proved that 0.5% was the minimum hydroxypropylmethylcellulose (HPMC) concentration that could be used to separate DNA fragments satisfactorily. HPMC solutions with a concentration of less than 0.5% could not separate the standard DNA fragments even in the presence of mannitol. It was found that 6% was the optimized mannitol concentration because either more or less mannitol will lead a decrease of resolution. The principle of the positive influence of mannitol has also been discussed.     

Electrophoretic separation of DNA using a new matrix in uncoated capillaries

A new separation matrix, consisting of polymer poly(N-isopropylacrylamide) (PNIPAM) and small molecule additive mannitol, was used for double-stranded (ds) DNA and plasmid DNA separation by capillary electrophoresis. The matrix had a low viscosity, which made it very easy to handle. The additive mannitol dramatically enhanced the sieving performance of PNIPAM in TBE buffer. The optimal mannitol concentration 6% in polymer solution, was determined with the consideration of both speed and resolution. A resolution of 0.95 was achieved on the separation of 271/281 bp in the phiX174/HaeIII digest by using 1.5% PNIPAM + 6% mannitol, while the supercoiled, linear and nicked conformers of lambda plasmid were separated in 1% PNIPAM + 6% mannitol, demonstrating the potential use of this new matrix for effective DNA separations. The dramatic impact of mannitol on sieving performance of PNIPAM solution was investigated. pH dependent self-coating ability of PNIPAM was revealed. The presence of mannitol in TBE buffer decreased the pH of the buffer, which led to more efficient self-coating ability of PNIPAM probable due to the formation of hydrogen bonds between PNIPAM molecules and silanol groups at the silica wall.     

Rapid authentication of ginseng species using microchip electrophoresis with laser-induced fluorescence detection

Ginseng is one of the most expensive Chinese herbal medicines and the effectiveness of ginseng depends strongly on its botanical sources and the use of different parts of the plants. In this study, a microchip electrophoresis method coupled with the polymerase chain reaction (PCR)–short tandem repeats (STR) technique was developed for rapid authentication of ginseng species. A low viscosity hydroxypropyl methylcellulose (HPMC) solution was used as the sieving matrix for separation of the amplified STR fragments. The allele sizing of the amplified PCR products could be detected within 240 s or less. Good reproducibility and accuracy of the fragment size were obtained with the relative standard deviation for the allele sizes less than 1.0% (n=11). At two microsatellite loci (CT 12, CA 33), American ginseng had a different allele pattern on the electropherograms compared with that of the Oriental ginseng. Moreover, cultivated and wild American ginseng can be distinguished on the basis of allele sizing. This work establishes the feasibility of fast genetic authentication of ginseng species by use of microchip electrophoresis.     

Electrophoretic migration behavior of DNA fragments in polymer solution

A newly developed polymer coil shrinking theory is described and compared with the existing entangled solution theory to explain electrophoretic migration behaviour of DNA in hydroxypropylmethylcellulose (HPMC) polymer solution in buffer containing 100 mM tris(hydroxymethyl)aminomethane 100 mM boric acid, 2 mM ethylenediaminetetraacetic acid at pH 8.3. The polymer coil shrinking theory gave a better model to explain the results obtained. The polymer coil shrinking concentration, Cs, was found to be 0.305% and the uniform entangled concentration, C+, 0.806%. The existence of three regions (the dilute, semidilute, and concentrated solution) at different polymer concentrations enables a better understanding of the system to guide the selection of the best conditions to separate DNA fragments. For separating large fragments (700/ 800 bp), dilute solutions (HPMC < 0.3%) should be used to achieve a short migration time (10 min). For small fragments (200/300 bp), concentrated solutions are preferred to obtain constant resolution and uniform separation. The best resolution is 0.6% HPMC due to a combined interaction of the polymer coils and the entangled structure. The possibility of DNA separation in semidilute solution is often neglected and the present results indicate that this region has a promising potential for analytical separation of DNA fragments.     

A design of nanosized PEGylated-latex mixed polymer solution for microchip electrophoresis

We report here advanced microchip electrophoresis using a nanoparticle doped polymer solution that enables greater separation of DNA. The proposed system is simple and effective without any new apparatus or complicated procedures. Various amounts and sizes (80 nm, 110 nm, and 193 nm) of polymer nanoparticle solutions (PEGylated-latex) were mixed with a conventional polymer solution for microchip electrophoresis. When a 0.49 wt% hydroxyl propyl methyl cellulose (HPMC) buffer solution was mixed with a 2.25 wt% 80 nm-PEGylated-latex a higher separation efficiency and a higher mobility of a wider molecular range of dsDNA (10 bp to 2 kbp) was achieved under low viscosity conditions (<5.5 cP) than in conventional 0.7% HPMC. The separation performance was dependent on the particle size and concentration. Furthermore, the effectiveness of the larger PEGylated-latex (193 nm) was not as high as the smaller one (80 to 110 nm). The observed separation improvement by polymer solution with latex-nanoparticles seems to derive from the balance between wider polymer mesh size and the structural obstacles of particles in the buffer.     

无胶筛分毛细管电泳分析几百个碱基对核酸的条件优化

通过正交设计实验综合分析了内充羟丙基甲基纤维素（ＨＰＭＣ）无胶筛分毛细管电泳中的分离场强、ＨＰＭＣ浓度、柱长度和柱内径对核酸分离的影响。结果表明,柱长度越长、柱内径越小、分离场强越小,分离效果越好。考虑实际情况,为能在短时间内使几百个碱基对的核酸得到有效分离,一般选择３７ｃｍ×７５μｍｉ．ｄ．的涂壁毛细管、柱内质量浓度为８ｇ／Ｌ的ＨＰＭＣ、场强为３２４Ｖ／ｃｍ的条件,并在此种条件下分析了ＡｐｏＢ１００基因的低浓度聚合酶链式反应（ＰＣＲ）扩增产物（７１０ｂｐ）。     

Anti-tack action of polyvinylpyrrolidone on hydroxypropylmethylcellulose solution

The anti-tack action of polyvinylpyrrolidone (PVP) on hydroxypropylmethylcellulose (HPMC) solution was elucidated using a probe test method. The influence of PVP of varying molecular weights at various PVP concentrations and solution temperatures on the tackiness of HPMC solution was studied. The viscosity, surface tension, cloud point and solution spectroscopy of HPMC solutions and glass transition temperature of HPMC films, with and without PVP, were investigated. The tackiness of HPMC solutions in response to the addition of PVP, at different concentrations of HPMC and using HPMC with varying contents of hydroxypropyl/methoxyl substitution, was also evaluated. PVP is a commonly used binder and adhesive. However, it reduced the tack of the HPMC solution when used at low concentrations, without affecting the state of hydration of HPMC. Lower molecular weight PVP was more effective as an anti-tack agent owing to suitable hydrodynamic size to intersperse among the HPMC chains. The degree of reduction in tack values was more pronounced for HPMC that showed a greater extent of interaction between polymer chains such as when high concentration of HPMC or low solution temperature was employed. This indicated that the tack reduction property of PVP relied on its ability to interact with the HPMC chains. The profile of reduction in tack values was affected by the contents of HPMC substitution and was a result of net reduction in the extent of hydrogen bonding between HPMC chains. It was significantly correlated to the changes of viscosity and surface tension of the HPMC solutions but not to the glass transition temperatures of the polymers prepared as solid films. The results suggested that the anti-tack action of PVP was attributed to its ability to interact with HPMC chains in the aqueous medium and consequently to reduce the extent of HPMC-HPMC bonding.     

Separation of double-stranded DNA fragments by capillary electrophoresis using polyvinylpyrrolidone and poly(N,N-dimethylacrylamide) transient interpenetrating network

A noncross-linked interpenetrating polymer network (IPN), consisting of poly(N,N-dimethylacrylamide) (PDMA) and polyvinylpyrrolidone (PVP, weight-average molecular weight M(w) = 1 x 10(6) g/mol) was synthesized by polymerizing N,N-dimethylacrylamide (DMA) monomers directly in PVP buffer solution and tested as a separation medium for double-stranded (ds)DNA analysis without further purification. Due to the incompatibility of PVP and PDMA, a simple solution mixture could incur a microphase separation and showed poor performance on dsDNA separation. However, a dramatic improvement was achieved by the formation of an IPN. We attributed the high sieving ability of IPN as due to an increase in the number of entanglements by the more extended polymer chains. Apparent viscosity studies showed that the IPN had a much higher viscosity than the simple mixture containing the same amount of PDMA and PVP. In 1 x Tris-borate-EDTA (TBE) buffer, the concentration ratio of PDMA and PVP had a great effect on the DNA separation. At optimal conditions, the 22 fragments in pBR322/HaeIII DNA were successfully separated within 15 min, with a resolution of better than 1.0 for 123/124 bp.     

Rapid and variable-volume sample loading in sieving electrophoresis microchips using negative pressure combined with electrokinetic force

A rapid and variable-volume sample loading scheme for chip-based sieving electrophoresis was developed by negative pressure combined with electrokinetic force. This was achieved by using a low-cost microvacuum pump and a single potential supply at a constant voltage. Both 12% linear polyacrylamide (LPA) with a high viscosity of 15000 cP and 2% hydroxyethylcellulose (HEC) with a low viscosity of 102 cP were chosen as the sieving materials to study the behavior and the versatility of the proposed method. To reduce the hydrodynamic resistance in the sampling channel, sieving material was only filled in the separation channel between the buffer waste reservoir (BW) to the edge of the crossed intersection. By applying a subambient pressure to the headspace of sample waste reservoir (SW), sample and buffer solution were drawn immediately from sample reservoir (S) and buffer reservoir (B) across the intersection to SW. At the same time, the charged sample in the sample flow was driven across the interface between the sample flow and the sieving matrix into the sieving material filled separation channel by the applied electric field. The injected sample plug length is in proportion with the loading time. Once the vacuum in SW reservoir was released to activate electrophoretic separation, flows from S and B to SW were immediately terminated by the back flow induced by the difference of the liquid levels in the reservoirs to prevent sample leakage during the separation stage. The sample consumption was about 1.7 x 10(2) nL at a loading time of 1 s for each cycle. Only 0.024 s was required to transport bias-free analyte to the injection point. It is easy to freely choose the sample plug volume in this method by simply changing the loading time and to inject high quality sample plug with non-distorted shape into the separation channel. The system has been proved to possess an exciting potential for improving throughput, repeatability, sensitivity and separation performance of chip-based sieving electrophoresis.