超滤操作说明书

EnglishIntroductionAmicon® Ultra-15 10K centrifugal filter devices provide fast ultrafiltration, with the capability for high concentration factors and easy concentrate recovery from dilute and complex sample matrices. Thevertical design and available membrane surface area provide fast sample processing, high sample recovery (typically greater than 90% of dilute starting solution), and the capability for 80-fold concentration. Typical processing time is 15 to 40 minutes. Solute polarization and subsequent fouling of the membrane are minimized by the vertical design, and a physical deadstop in the filter device prevents spinning todryness and potential sample loss. The concentrate is collected from the filter device sample reservoir using a pipettor, while the ultrafiltrate is collected in the provided centrifuge tube. The device can be spun in a swinging-bucket or fixed-angle rotor. Amicon® Ultra-15 10K devices are supplied non-sterile and are for single use only.Intended UseThe Amicon® Ultra-15 product line includes 5 different cutoffs (Molecular Weight Cutoff, MWCO), however, the Amicon® Ultra-15 10K device (10,000 MWCO) is the only device intended for in vitro diagnostic use. It can be used to concentrate serum, urine, cerebrospinal fluid, and other body fluids prior to analysis. For information on other Amicon® Ultra-15 cutoffs, go to and enter Amicon Ultra-15in the search box.User GuideAmicon ® Ultra-15 10K Centrifugal Filter Devicesfor volumes up to 15 mLUFC901008UFC901024UFC901096CVApplications●Concentration of biological samples containing antigens, antibodies, enzymes, nucleic acids(DNA/RNA samples, either single- or double-stranded), microorganisms, column eluates, andpurified samples●Purification of macromolecular components found in tissue culture extracts and cell lysates, removalof primer, linkers, or molecular labels from a reaction mix, and protein removal prior to HPLC●Desalting, buffer exchange, or diafiltrationMaterials SuppliedThe Amicon® Ultra-15 10K device is supplied with a cap, a filter device, and a centrifuge tube.Required Equipment●Centrifuge with swinging-bucket or fixed-angle rotor with wells/carriers that can accommodate50 mL tubesCAUTION: To avoid damage to the device during centrifugation, check clearance before spinning.●Pipettor with 200 microliter (μL) tip for concentrate recoverySuitabilityPreliminary recovery and retention studies are suggested to ensure suitability for intended use. See the “How to Quantify Recoveries” section.Shelf LifeShelf life is 3 years from date of manufacture. Refer to expiration date on package label.Rinsing Before UseThe ultrafiltration membranes in Amicon® Ultra-15 10K devices contain trace amounts of glycerine. If this material interferes with analysis, rinse the device with buffer or Milli-Q® water before use. If interference continues, rinse with 0.1 N NaOH followed by a second spin of buffer or Milli-Q® water. CAUTION: Do not allow the membrane in Amicon® Ultra filter devices to dry out once wet. If you are not using the device immediately after rinsing, leave fluid on the membrane until the device is used. How to Use Amicon® Ultra-15 Centrifugal Filter Devices1. Add up to 15 mL of sample (12 mL if using a fixed-angle rotor) to the Amicon® Ultra filter device.2. Place capped filter device into centrifuge rotor; counterbalance with a similar device.3. When using a swinging-bucket rotor, s pin the device at 4,000 × g maximum for approximately15–40 minutes.When using a fixed-angle rotor, orient the device with the membrane panel facing up and spin at 5,000 × g maximum for approximately 15–40 minutes.NOTE: Refer to Figure 1 and Table 1 for typical spin times.4. To recover the concentrated solute, insert a pipettor into the bottom of the filter device and withdrawthe sample using a side-to-side sweeping motion to ensure total recovery. The ultrafiltrate can be stored in the centrifuge tube.NOTE: For optimal recovery, remove concentrated sample immediately after centrifugation. Desalting or DiafiltrationDesalting, buffer exchange, or diafiltration are important methods for removing salts or solvents in solutions containing biomolecules. The removal of salts or the exchange of buffers can be accomplished in the Amicon® Ultra-15 device by concentrating the sample, then reconstituting the concentrate to the original sample volume with any d esired solvent. The process of “washing out” can be repeated until the concentration of the contaminating microsolute has been sufficiently reduced. See example below.1 mg/mL100 mMNaCl200 μL of75 mg/mLprotein inNaCl200 μL of75 mg/mLprotein inNaClAdd 14.8 mL of10 mM NaClor exchangebufferPerformanceFlow RateFactors affecting flow rate include sample concentration, starting vol u me, chemical nature of solute, relative centrifugal force, centrifuge rotor angle, membrane type, and temperature. Figure 1 and Table 1 can be used to estimate the time required to achieve a given volume of filtrate or concentrate. A typical spin time for a 15 mL sample is approximately 15 to 40 minutes. While most of the sample is filtered in the first 15 to 30 minutes of centrifugation, the lowest concentrate volume (100–150 μL) is reached after spinning for 15 to 40 minutes.Spin conditions: Swinging-bucket rotor (4,000 × g, 15 mL starting volume),or fixed-angle rotor, (5,000 × g, 12 mL starting volume), room temperature.Protein marker used: Cytochrome c, n=6.Table 1. Typical Concentrate Volume vs. Spin TimeSpin conditions: Room temperature.Protein marker used: Cytochrome c, n=6 (mean value of 3 membrane lots).Shaded volumes were used for the calculation of protein recovery in Table 3.Protein Retention and Concentrate RecoveryThe membranes used in Amicon® Ultra devices are characterized by a molecular weight cutoff (MWCO); that is, their ability to retain molecules above a specified molecular weight. Solutes with molecular weights close to the MWCO may be only partially retained. Membrane retention depends on the solute’s molecular size and shape. For most applications, molecular weight is a convenient parameter to use in assessing retention characteristics. For best results, use a membrane with a MWCO at least two times smaller than the molecular weight of the protein solute that one intends to concentrate. Refer to Table 2.Table 2. Typical Retention of Protein MarkersMarker/Concentration MolecularWeightDeviceMWCO% RetentionSwinging-bucket% RetentionFixed-angleSpin Time(min)α-Chymotrypsinogen (1 mg/mL)25,00010K> 95> 9530 Cytochrome c (0.25 mg/mL)12,400> 95> 9530 Vitamin B-12 (0.2 mg/mL)1,350< 5< 530 Spin Conditions: Swinging-bucket rotor (4,000 × g, 15 mL starting volume), or fixed-angle rotor, (5,000 × g,12 mL starting volume), room temperature, n=6 (mean value of 3 membrane lots).Factors that determine sample recovery include the nature of the protein solute relative to the device MWCO chosen, starting concentration, and concentration factor. Table 3 provides typical recoveries for Amicon® Ultra-15 10K device.Table 3. Typical Concentrate RecoveryConcentrate Concentration ConcentrateSpin Conditions: Swinging-bucket rotor (4,000 × g, 15 mL starting volume), or fixed-angle rotor, (5,000 × g,12 mL starting volume), room temperature, n=6 (mean value of 3 membrane lots). The shaded volumes were taken from Table 1.Maximizing Sample RecoveryLow sample recovery in the concentrate may be due to adsorptive losses, over-concentration, or passage of sample through the membrane.●Adsorptive losses depend upon solute concentration, its hydrophobic nature, temperature and timeof contact with filter device surfaces, sample composition, and pH. To minimize losses, removeconcentrated samples immediately after centrifugal spin.●If the starting sample concentration is high, monitor the centrifugation process in order to avoid over-concentration of the sample. Over-concentration can lead to precipitation and potential sample loss.●If the sample appears to be passing through the membrane, choose a lower MWCO Amicon® Ultra-15device.How to Quantify RecoveriesCalculate total recovery, percent concentrate recovery, and percent filtrate recovery using the method below. The procedure provides a close approximation of recoveries for solutions having concentrations up to roughly 20 mg/mL.NOTE: Appropriate assay techniques include absorption spectrophotometry, radioimmunoassay, refractive index, and conductivity.Direct Weighing ProcedureThe density of most dilute proteins is nearly equal to the density of water (i.e., 1 g/mL). Using this property, the concentrate and filtrate volumes can be quantified by weighing them and converting the units from grams to milliliters. This technique is valid only for solutions with concentrations of approximately20 mg/mL or less.1. Before use, separately weigh the empty filter device, the centrifuge tube, and an empty tube forconcentrate collection.2. Fill filter device with solution and reweigh.3. Assemble device and centrifuge per instructions.4. Collect the concentrate with a pipettor and dispense it into the preweighed concentrate collection tube.5. Remove the device from the centrifuge tube and weigh the centrifuge tube and concentrate collectiontube.6. Subtract weight of empty device/tubes to calculate weights of starting material, filtrate, andconcentrate.7. Assay the starting material, filtrate, and concentrate to determine solute concentration.8. Calculate recoveries using the weight/volume data and the measured concentrations as follows:% concentrate recovery = 100 × W c × C c W o × C o% filtrate recovery = 100 × W f × C f W o × C o% total recovery = % concentrate recovery + % filtrate recoveryW c = total weight of concentrate before assayW o = weight of original starting materialW f= weight of filtrateC c= concentrate concentrationC o= original starting material concentrationC f= filtrate concentrationSpecificationsMaximum initial sample volumeSwinging-bucket15.0 mLFixed-angle rotor12.0 mLTypical final concentrate volume 150–300 μLMaximum relative centrifugal forceSwinging-bucket rotor4,000 × gFixed-angle rotor5,000 × gActive membrane area7.6 cm2DimensionsFilter device in tube (capped)Length: 119 mm (4.7 in.)Diameter: 33.5 mm (1.3 in.) Filter deviceLength: 72.0 mm (2.8 in.)Diameter: 29.7 mm (1.2 in.) Materials of ConstructionFilter device Copolymer styrene/butadieneMembrane Ultracel® low binding regenerated cellulose Filtrate tube PolypropyleneFiltrate cap and liner PolyethyleneChemical CompatibilityAmicon® Ultra centrifugal devices are intended for use with biological fluids and aqueous solutions. Before use, check the sample for chemical compatibility with the device.Table 4. Chemical Compatibility of Amicon® Ultra Filter DevicesAcids Concentration Concentration Acetic acid ≤ 50%*Phosphoric acid ≤ 30% Formic acid ≤ 5%*Sulfamic acid≤ 3% Hydrochloric acid ≤ 1.0 M Sulfuric acid ≤ 3% Lactic acid ≤ 50%Trichloroacetic acid (TCA)≤ 10%* Nitric acid ≤ 10%Trifluoroacetic acid (TFA)≤ 30%* AlkalisAmmonium hydroxide ≤ 10%Sodium hydroxide ≤ 0.5 M Alcoholsn-Butanol ≤ 70%Isopropanol ≤ 70% Ethanol ≤ 70%Methanol ≤ 60% DetergentsAlconox® detergent ≤ 1%Sodium dodecyl sulfate (SDS)≤ 0.1% CHAPS detergent≤ 0.1%Tergazyme®detergent ≤ 1% Lubrol® PX detergent≤ 0.1%Triton® X-100 surfactant≤ 0.1% Nonidet™ P-40 surfactant≤ 2%Tween® 20 surfactant≤ 0.1% Sodium deoxycholate≤ 5%Organic solventsAcetone not recommended Ethyl acetate not recommended Acetonitrile ≤ 20%Formaldehyde ≤ 5% Benzene not recommended Pyridine not recommended Carbon tetrachloride not recommended Tetrahydrofuran not recommended Chloroform not recommended Toluene not recommended Dimethyl sulfoxide (DMSO)≤ 5%*MiscellaneousAmmonium sulfate Saturated Phenol≤ 1% Diethyl pyrocarbonate ≤ 0.2%Phosphate buffer (pH 8.2)≤ 1 M Dithiothreitol (DTT)≤ 0.1 M Polyethylene glycol≤ 10% Glycerine≤ 70%Sodium carbonate ≤ 20% Guanidine HCl ≤ 6 M Tris buffer (pH 8.2)≤ 1 M Imidazole≤ 100 mM Urea ≤ 8 M Mercaptoethanol≤ 0.1 M* Contact with this chemical may cause materials to leach out of the component parts. Solvent blanks are recommended to determine whether leachables represent potential assay interferences.Product Labeling SymbolsThe following table defines the symbols found on Amicon® Ultra-15 10K device labels.Product Ordering InformationThis section lists the catalogue numbers for Amicon® Ultra Ultrafiltration Devices. See the Technical Assistance section for contact information. You can purchase these products on-line at/products.* Amicon® Ultra-4 and -15 10K devices are for in vitrodiagnostic use. All other devices are for research use only.NoticeThe information in this document is subject to change without notice and should not be construed as a commitment by Merck Millipore Ltd. (“Millipore”) or an affiliate. Neither Merck Millipore Ltd. nor any of its affiliates assumes responsibility for any errors that may appear in this document.Technical AssistanceFor more information, contact the office nearest you. Up-to-date world-wide contact information is available on our web site at /offices. You can also visit the tech service page on our web site at /techservice.Standard WarrantyThe applicable warranty for the products listed in this publication may be found at/terms (“Conditions of Sale”).M Merck Millipore Ltd.Tullagreen,Carrigtwohill,Co. Cork, IrelandMade in IrelandThe M logo, Millipore, Amicon, Milli-Q, and Ultracel are registered trademarks of Merck KGaA, Darmstadt, Germany.All trademarks of third parties are the property of their respective owners.© 2014 EMD Millipore Corporation. Billerica, MA, U.S.A. All rights reserved.PR04318TR, Rev. B, English, 10/14。

废水回收系统手动操作规程一、 多介质过滤器系统手动操作1、开机：①检查多介质过滤器进水阀、上排阀是否已经开启。

②初排废水池絮凝层：开启提升泵，将废水池底部的絮凝层排去一些，尽可能的使其不进入到多介质过滤器。

初排时水显深黄色，待水较清时，即可结束排放。

排放时间约为3~4min。

③换水：打开多介质过滤器下部排水阀，关闭上排阀，使其正洗换水约5~6min摆布，在设备停运8小时以上，应该要做到这一步，少于8小时，可以只要2min摆布。

④出水：正洗换水完毕后，可开启多介质过滤器出水阀，关闭多介质过滤器下部排水阀。

设备转入正常运行状态。

（附注：关于多介质过滤器出水流量的确定，目前暂将进入废水池的流量确定为90m3/h，其絮凝剂与杀菌剂的投加也是按此流量来投加的。

由于多介质过滤器是全流量过流，于是其产水量也是90 m3/h。

此后的超滤、RO系统的各项流量数据均是以此为基础而得出的，在此也一并说明。

）2、停机：①打开多介质过滤器上部排水阀，关闭出水阀。

②停提升泵。

（注意：在手动操作状态下，多介质过滤器进水阀、上排阀在停机时，应为常开状态。

）3、多介质过滤器的反冲洗：其反冲洗的条件普通有两种：①压差法：当过滤器进出水压差到0.05~0.1MPa时，过滤器就应该要反冲洗了。

②定期法：可根据现场废水水质情况，定时冲洗过滤器。

根据现场的温度、水质情况，建设每运行12小时反冲洗一次。

③反冲的步骤：⑴气冲洗：先将过滤器的下部排水阀、上部排水阀打开，关进水阀、出水阀，将砂滤器中的水排至下视镜中部即可，关闭下排阀，然后打开多介质过滤器进气阀，并注意砂层气洗情况。

在此请注意进气阀一定要缓慢开户，否则压缩空气将极易破坏多介质过滤器的卵石垫层而引起漏砂现象。

气冲洗普通5分钟，完毕后关闭进气阀。

（气冲洗不一定每次反冲洗都要进行，可隔开几个周期气冲一次。

（2）水反冲洗：气冲洗完毕后，可进行水反冲洗。

检查上排阀是否已经开启，然后打开多介质过滤器反洗阀，阀门先稍稍打开一点，待启动多介质过滤器反冲洗泵后，再缓慢开大，在多介质过滤器上视镜底部看到膨胀的滤料层时，阀门不再开大。

PVDF中空纤维超滤膜产品技术手册目录第一章公司简介 (4)第二章超滤技术介绍 (5)2.1超滤的基本原理 (5)2.2超滤的特点 (5)2.3超滤的几个常用基本概念 (6)2.3.1纯水通量与产水流量 (6)2.3.2温度对产水流量的影响 (6)2.3.3临界流量与临界压力 (6)2.3.4跨膜压差 (6)2.3.5内压式过滤与外压式过滤 (7)2.3.6全量过滤与错流过滤 (7)第三章膜能（MONON）超滤膜的特点及性能参数 (8)3.1超滤膜的特点 (8)3.2超滤膜的主要性能参数 (8)3.3超滤膜的应用领域 (8)第四章柱式超滤膜组件的特点及性能参数 (9)4.1柱式超滤膜组件的特点 (9)4.2柱式超滤膜组件的型号及规格说明 (9)4.3MONON超滤膜组件的规格参数 (10)第五章超滤系统的设计 (12)5.1原水水质 (12)5.2预处理 (12)5.2.1超滤膜组件进水要求（设计基准值可以是一定范围） (12)5.3柱式超滤膜组件 (12)5.4配套反洗系统选型 (13)5.4.1反洗水箱 (13)5.4.2反洗水泵 (13)5.4.3（CEB）化学增强反洗加药泵（计量泵） (14)5.5超滤膜化学清洗系统选型设计 (14)5.5.1化学清洗水箱（一般要求清洗温度：25-35℃） (14)5.5.2化学清洗循环泵 (14)5.5.3保安过滤器 (15)5.5.4化学清洗药剂配方 (15)5.6气洗系统 (15)5.7控制系统 (15)第六章超滤系统的安装与操作 (17)6.1安装前的准备工作 (17)6.2柱式超滤膜组件的安装 (17)6.3超滤系统的首次启动 (17)6.3.1启动前的检查内容 (17)6.3.2首次启动顺序 (18)6.4日常启动 (18)6.5超滤膜系统的维护与保养 (19)6.6运行记录 (19)第七章超滤系统的维护与故障分析 (20)7.1超滤系统的维护 (20)7.1.1水泵 (20)7.1.2仪器仪表 (20)7.1.3自动阀门 (20)7.1.4超滤组件 (20)7.2超滤系统的故障分析 (20)第八章柱式超滤膜组件的贮存与运输 (21)8.1贮存 (21)8.2运输 (21)第九章技术支持和质量保证 (21)9.1技术支持 (21)9.2质量保证 (21)9.3买方义务 (22)9.4售后服务 (22)22-附录：超滤系统流程图 (23)第一章公司简介杭州膜能膜分离科技有限公司是专注于高抗污染系列滤膜产品的开发、生产、推广和应用集成服务的高新技术企业，也是国内首家集中空纤维膜和平板膜生产于一体的设计制造商。

超滤管使用方法和注意事项超滤管使用方法和注意事项1. 超滤管简介超滤管是一种常见的水处理设备，通过超滤膜的微孔来完成水的过滤和分离，能有效去除水中的悬浮物、细菌、等有害物质，提供清洁健康的饮用水。

2. 使用方法使用超滤管进行水处理时，需要按照以下步骤进行操作：2.1. 准备工作检查超滤管的材料是否完好无损，确保超滤膜没有破损或者老化。

清洁超滤管的外表面，避免灰尘和污垢进入系统。

2.2. 连接超滤管将超滤管连接到水源或者水处理设备的进水口，确保连接密切可靠，避免漏水或者渗水现象。

2.3. 启动超滤管打开进水阀门，让水缓慢进入超滤管。

水流进入的速度应逐渐增加，避免冲击超滤膜，影响使用寿命。

建议初始使用时水流速度不超过设计流量的50%。

2.4. 检查水质使用超滤管处理水后，可以通过对出水进行水质检测来确定过滤效果。

确保出水合格后，即可正常使用。

2.5. 定期清洗超滤管在长期使用后，会因为滤孔的阻塞而降低过滤效果。

建议定期进行清洗，可根据使用情况选择适当的清洗方法，如物理清洗、化学清洗等。

3. 注意事项在使用超滤管时，需要注意以下事项，以确保正常运行和延长使用寿命：3.1. 避免污水反渗透超滤管的用途是过滤净化水，不适合于处理污水。

避免将含有高浓度污染物的水进入超滤管，以避免超滤膜受损。

3.2. 避免干燥超滤管在不使用时，应保持湿润状态，避免超滤膜干燥。

如果长期不使用，建议拆卸超滤管并储存于水中，以保持滤膜的良好状态。

3.3. 防止冻裂在寒冷季节，超滤管需要采取防冻措施，避免超滤管因冻裂而损坏。

如果超滤管未受到寒冷天气的保护，可能会发生泄漏或者无法正常使用。

3.4. 防止化学腐蚀超滤管的材料通常对普通水质和化学品有较好的耐腐蚀性，但某些特殊化学物质可能对超滤膜有伤害。

在处理特殊水质时，需参考厂家提供的使用说明或者进行特殊预处理。

3.5. 定期维护和更换定期进行设备维护和超滤膜更换，是保证超滤管长期稳定运行的关键。

超滤系统操作维护手册一、超滤技术介绍1、超滤是什么在膜分离领域，按照分离精度划分有微滤（MF）、超滤（UF）、纳滤（NF）、反渗透（RO）四种分离过程。

其中，超滤（Ultrafiltration）：介于微滤和纳滤之间的一种膜过程，使用压力通常为0.02~0.3MPa，膜孔径在0.002~0.1μm，截留分子量约为1000~500,000道尔顿左右，超滤是一种能够将溶液进行净化、分离、浓缩的膜分离技术，超滤过程通常可以理解成与膜孔径大小相关的筛分过程，以膜两侧的压力差为驱动力，以超滤膜为过滤介质。

超滤膜可有效去除水中的悬浮物、胶体微粒、细菌和大部分病毒等，对有机物的去除率为20~60%，对小分子有机物和无机离子几乎不截留。

目前在饮用水、工业用水处理、饮料、环保、化工、冶金、食品等已得到广泛应用。

尤其在海水淡化、纯水、超纯水等生产中作为反渗透的预处理，确保反渗透及后续设备运行稳定。

2、超滤膜组件的结构形成目前市场上超滤膜有平板式、卷式、管式和中空纤维式四种结构型式，特点如下：平板式，其比表面积小，处理能力偏低，不适合工程放大。

卷式，不可反洗，且预处理要求高。

管式，装填密度低、单位体积内膜面积小，且能耗大。

中空纤维式，装填密度高，能耗低，通量大，寿命长，且可以反洗，在工程实际中用得比较多。

表 1 各种结构形式膜组件之间卷式中空管式平板式的比较比较项目填充密度（m2.m-3）200-800 1200 60 30-500组件结构复杂复杂简单很复杂膜更换方式组件组件膜或组件膜膜更换成本较高较高中低料液预处理高较高低低抗污染性中等一般非常好中等清洗效果一般至难易优良工程放大难易中中易难能耗低低高中投资较低低高较高内压式与外压式操作内外压中空纤维超滤膜应用特点中空纤维膜的操作形式分为内压式和外压式。

内压式操作，即原液先进入中空纤维内部，经过压力驱动，沿径向由内向外透过中空纤维膜成为渗透液，而浓缩液则留在中空纤维的内部，由另外一端流出；外压式操作，原液在中空纤维外侧流动，原液在压力差作用下由外向内透过中空纤维膜进入纤维内侧成为透过液，而浓缩液则汇集在中空纤维的外部。

超滤管(0.5ml, 100kDa MWCO, PES, Sartorius)产品编号 产品名称包装 FUF058-5pcs 超滤管(0.5ml, 100kDa MWCO, PES, Sartorius 分装) 5个/袋 FUF058-25pcs 超滤管(0.5ml, 100kDa MWCO, PES, Sartorius 分装) 25个/袋 FUF058-100pcs超滤管(0.5ml, 100kDa MWCO, PES, Sartorius 原装)100个/盒产品简介：本超滤管(0.5ml, 100kDa MWCO, PES, Sartorius)，Ultrafiltration Spin Columns (0.5ml, 100kDa MWCO, PES, Sartorius)，为赛多利斯Vivaspin ® 500原装进口或分装产品，原货号为VS0141/VS0142，是一种通过离心方式对液体样品进行浓缩、脱盐或缓冲液置换的一次性超滤装置。

本产品适合的最大样品体积为0.5ml ，截留分子量(Molecular Weight Cutoff, MWCO)为100,000 (即100kDa)，超滤管膜的材质为聚醚砜膜(polyethersulfone, PES) ，亲水性(Hydrophilic)。

本超滤管适合在1.5-2ml 离心机上使用。

超滤离心浓缩管(Ultrafiltration Spin Columns)，又称超滤离心管、超滤管或离心过滤器，常用于生物样品的浓缩。

本产品适合对水溶液进行超滤，对部分有机溶剂和酸碱溶液的化学兼容性见下表(2hr contact time)：Solutions PES Solutions PES Solutions PES Compatible pH range pH 1–9 Glycerine (70%) Ok Pyridine (100%) No Acetic Acid (25.0%) Ok Guanidine HCI (6M) Ok Sodium Carbonate (20%) Ok Acetone (10.0%) No Hydrocarbons, aromatic No Sodium Deoxycholate (5.0%) Ok Acetonitrile (10.0%) No Hydrocarbons, chlorinated No Sodium Dodecylsulfate(0.1M) Ok Ammonium Hydroxide(5.0%)?Hydrochloric Acid (1M) Ok Sodium Hydroxide (2.5M) NoAmmonium Sulphate(saturated) Ok Imidazole (300mM) Ok Sodium Hypochlorite(200ppm) OkBenzene (100%) No Isopropanol (70%) Ok Sodium Nitrate (1.0%) Ok n-Butanol (70%) ? Lactic Acid (5.0%) Ok Sulfamic Acid (5.0%) Ok Chloroform (1.0%) No Mercaptoethanol (1.0M) No Tetrahydrofuran (5.0%) No Dimethyl Formamide (10.0%) ? Methanol (60%) ? Toluene (1.0%) No Dimethyl Sulfoxide (5.0%) Ok Nitric Acid (10.0%) Ok Trifluoroacetic Acid (10%) OkEthanol (70.0%) Ok Phenol (1.0%) ? Tween ®20 (0.1%) OkEthyl Acetate (100%) No Phosphate Buffer (1.0M) Ok Triton ®X-100 (0.1%) Ok Formaldehyde (30%) Ok Polyethylene Glycol (10%) Ok Urea (8M) Ok Formic Acid (5.0%) Ok Ok = Acceptable; ? = Questionable; No = Not recommended赛多利斯Vivaspin ®500离心超滤管，简单快速，一步离心完成样品浓缩，起始样品体积可达500µl 。