| Description | Reactive oxygen species (ROS) are natural by-products of normal oxygen metabolism, including superoxide radicals, hydrogen peroxide, and their downstream products such as peroxides and hydroxides. Studies show that over 95% of ROS in organisms originate from mitochondria. An imbalance leading Reactive oxygen species (ROS) are natural by-products of normal oxygen metabolism, including superoxide radicals, hydrogen peroxide, and their downstream products such as peroxides and hydroxides. Studies show that over 95% of ROS in organisms originate from mitochondria. An imbalance leading to oxidative stress is associated with cell growth, proliferation, development, differentiation, aging, apoptosis, and many physiological and pathological processes. Under normal conditions, a balance exists between the intracellular antioxidant defense system and oxygen free radicals, maintaining ROS at low physiological levels. Under pathological conditions, this balance is disrupted, leading to excessive intracellular ROS levels. This can damage mitochondrial enzymes, lipids, and nucleic acids, causing oxidative stress. Additionally, ROS can attack mitochondrial DNA, causing oxidative damage that leads to structural and functional changes such as reduced mitochondrial ATP synthesis and disrupted mitochondrial membrane potential. Mitochondrial Reactive Oxygen Species (ROS) Production Rate Assay Kit (Fluorometric Method) provides a simple, sensitive, and rapid method for detecting mitochondrial ROS production rate. The principle utilizes the fluorescent probe DCFH-DA for ROS detection. DCFH-DA (2',7'-Dichlorodihydrofluorescein diacetate) diffuses across the mitochondrial membrane and is hydrolyzed by esterases inside the mitochondria to form non-fluorescent DCFH. DCFH is then oxidized by ROS to generate fluorescent DCF. The rate of increase in DCF fluorescence intensity is proportional to the rate of ROS production.M1492773Component96TStorageM1492773AExtraction Buffer60 mL×22-8℃M1492773BReagentⅠ50 mL2-8℃M1492773CReagent Ⅱ1.5 mL-20℃. Store in the dark.M1492773DReagent Ⅲ1EA2-8℃. Store in the dark.M1492773EReagent Ⅳ1EA2-8℃. Store in the dark.M1492773FReagent Ⅴ1EA2-8℃. Store in the dark.M1492773GReagent Ⅵ20 µL-20℃. Store in the dark.Note: It is recommended to perform preliminary experiments using 2-3 samples expected to have significant differences before formal testing.User-Provided Instruments and ConsumablesAdjustable pipettes and tipsHomogenizer, Low-temperature centrifuge, 96-well solid black or solid white microplateConstant temperature incubator, Multifunctional microplate readerExperimental Procedure1. Reagent PreparationReagent NameReagent PreparationPrecautionsExtraction BufferReady-to-use; equilibrate to room temperature before use.Store at 4°CReagentⅠReady-to-use; equilibrate to room temperature before use.Store at 4°CReagentⅡReady-to-useStore at -20°C protected from light.ReagentⅢPrepare before use: Dissolve contents for 96 tests in 6 mL Reagent I. Mix well.Unused dissolved Reagent III can be stored at 4°C protected from light for 1 month.ReagentⅣPrepare before use: Dissolve contents for 96 tests in 6 mL Reagent I. Mix well.Unused dissolved Reagent IV can be stored at 4°C protected from light for 1 month.ReagentⅤPrepare before use: Dissolve contents for 96 tests in 6 mL Reagent I. Mix well.Unused dissolved Reagent V can be stored at 4°C protected from light for 1 month.ReagentⅥReagent VI is somewhat irritating; personal protection is recommended during use.Working ReagentⅥPrepare before use: Dilute Reagent VI 300-fold with Reagent I according to the required volume.Diluted Working Reagent VI cannot be reused.2. Sample Preparation (Tissue/Cell Mitochondria Extraction)2.1 Weigh approximately 0.1 g of tissue or collect 5 million cells. Add 1 mL of Extraction Buffer and 10 µL of Reagent II. Homogenize on ice using a homogenizer. Centrifuge at 600 g, 4°C for 5 minutes. Collect the supernatant into a new centrifuge tube, discard the pellet.2.2 Centrifuge the supernatant again at 11,000 g, 4°C for 10 minutes. The pellet contains the extracted mitochondria.2.3 Discard the supernatant. Resuspend the pellet in 200 µL of Reagent I. Keep on ice for immediate assay.Notes:(1) Fresh samples are recommended. If not used immediately, samples can be stored at -80°C for one month.(2) Extracted mitochondrial samples must be assayed on the same day and should not be frozen.(3) For protein concentration determination, Aladdin B774074 Bradford Protein Assay Kit or B406195 Bradford Assay Solution (Ready-to-Use) [for Protein Determination] is recommended.3. Assay Steps3.1 Pre-heat the multifunctional microplate reader to 37°C. Set the fluorescence excitation wavelength to 488 nm and emission wavelength to 525 nm.3.2 Add reagents to a 96-well solid black or solid white microplate as follows:ReagentBlank Well (µL)Test Well (µL)Sample020ReagentⅠ200ReagentⅢ5050ReagentⅣ5050ReagentⅤ5050Working ReagentⅥ30303.3 Mix well. Incubate at 37°C protected from light for 15 minutes.3.4 After incubation, measure the fluorescence intensity over 10 minutes using the microplate reader (Ex/Em = 488/525 nm). Maintain the instrument temperature at 37°C. Record the fluorescence change over 10 minutes.Notes:(1) Fluorescence intensity changes must be measured at a constant 37°C over 10 minutes.(2) When mixing with a pipette, pipette gently to avoid generating bubbles.(3) Use solid black or white 96-well plates to prevent interference between adjacent wells. 4. Result Calculation 4.1 Data Processing Perform linear regression analysis on the sampled data points (fluorescence intensity vs. time) to calculate the regression coefficient, i.e., the slope (k) of the line. The actual mitochondrial ROS production rate equals the slope (k test ) from the linear regression of the sample's fluorescence intensity vs. time data points minus the slope (k blank ) from the linear regression of the background fluorescence intensity vs. time data points. k = (RFU 10min - RFU 0min ) / 600 (assuming time in seconds; 10 min = 600 s) 4.2 Activity Calculation Note: We provide both derived and simplified calculation formulas, which are equivalent. The simplified formulas in bold are recommended as the final calculation formulas. (1) Based on sample mass: (1) Based on sample mass: ROS Production Rate (RFU/s/g fresh weight) = (k test - k blank ) ÷ (V sample ÷ V total × W) = 100 × (k test - k blank ) (2) Based on sample protein concentration: ROS Production Rate (RFU/s/mg prot) = (k test - k blank ) ÷ (V sample ÷ V total × Cpr) = 10 × (k test - k blank ) ÷ Cpr (3) Based on cell count: ROS Production Rate (RFU/s/10⁴ Cells) = (k tes t - k blank ) ÷ (500 × V sample ÷ V total ) = (k test - k blank ) ÷ 50 Parameter Description: V sample : Sample volume added, 0.02 mL V total : Total resuspension volume of the sample, 0.2 mLCpr: Sample protein concentration, mg/mLW: Sample mass, 0.1 g500: Cell count, in units of 10⁴Precautions1.Biochemical reagents are generally irritating and biologically toxic. For your safety and health, please implement appropriate biosafety precautions throughout the experiment. Wear personal protective equipment such as lab coats, masks, gloves, and hair caps. Perform experiments in a fume hood or biosafety cabinet.2.This product is for scientific research use only. Not intended for clinical diagnosis... Read More | Inquire | FFPE DNA/RNA KitFixed Tissue DNA/RNA Extraction Kit Catalog number: F666120 (50 preps)Storage conditions: DNase I and 10×Reaction Buffer -20℃, Spin Columns DF and Spin Columns RS can be stored at room temperature for 2 months, 2-8℃ for 1 year, the rest of the components are stored FFPE DNA/RNA KitFixed Tissue DNA/RNA Extraction Kit Catalog number: F666120 (50 preps)Storage conditions: DNase I and 10×Reaction Buffer -20℃, Spin Columns DF and Spin Columns RS can be stored at room temperature for 2 months, 2-8℃ for 1 year, the rest of the components are stored at room temperature (15-30℃).Products Content:Products IntroductionThis kit is suitable for the effective purification of genomic DNA and total RNA from paraffin-embedded tissues, using specially optimized deparaffinizing agents and lysates to release DNA and RNA from tissue section samples, without the use of the organic reagent xylene, and without the need for overnight operation; the digested samples are incubated at higher temperatures to remove inhibitors caused by cross-linking, which can effectively improve nucleic acid yields and purity; and an optimized buffer system allows nucleic acids in the lysate to bind specifically to the adsorbent membrane, and inhibitors are effectively removed by a two-step rinsing procedure. The optimized buffer system enables the nucleic acids in the lysate to bind specifically to the adsorbent membrane, and the inhibitors are effectively removed by a two-step rinsing step, and finally eluted with low-salt buffer or water to obtain high purity DNA and RNA, and at the same time, equipped with a high-efficiency microsorbent column, the volume of the elution can be as low as 20 µl. The purified DNA and RNA can be directly used for PCR, Real-time PCR, SNP genotyping, STR genotyping, and so on. The purified DNA and RNA can be directly used for PCR, Real-time PCR, SNP genotyping, STR genotyping, second-generation sequencing, pharmacogenomics research and blot analysis.Self-contained reagent: anhydrous ethanolPre-experiment Preparation and Important Notes 1. After obtaining the sample, fix the sample as soon as possible, the fixation time of 14-24 hours is appropriate, too long a period of time will easily lead toDNA and RNA breaks, affecting downstream experiments. If the formaldehyde fixation time is too long or the sample is stored for too long(>1 year) is prone to compromise DNA integrity and failure to amplify long fragments.2. Ensure that samples are thoroughly dehydrated prior to embedding; residual formalin will inhibit Proteinase K action.3. Add 1.25 ml of Proteinase K Storage Buffer to Proteinase K to dissolve it, and store at -20℃. Do not leave the prepared Proteinase K at room temperature for a long period of time to avoid affecting its activity.4. Anhydrous ethanol should be added to Buffer RW2, Buffer GW1 and Buffer GW2 according to the label instructions on the vials before first use.5. Check Buffer GTL, Buffer GL and Buffer DS for crystallization or precipitation prior to use; if crystallization or precipitation occurs, redissolve Buffer GTL, Buffer GL and Buffer DS in a 37°C water bath.6. Preheat the water bath or thermostatic mixer to 56°C before starting the experiment.7. Use an ambient temperature centrifuge or set the centrifuge temperature to 25°C. Temperatures below 15°C may result in clogging of the adsorption column.8. To prevent RNase contamination, the following should be observed:1) Use RNase-free plastics and tips to avoid cross-contamination.(2) Glassware should be dry baked at 180°C for 4 hours before use, plasticware can be soaked in 0.5 M NaOH for 10 minutes, rinsed thoroughly with water and autoclaved.3) RNase-free water should be used to prepare the solution.(4) Operators wear disposable masks and gloves, and change gloves diligently during the experiment.procedureParaffin-embedded samples1. Trim off excess paraffin from the tissue block to expose the tissue and cut into 5-10 µm slices.2. Place approximately 1 x 1 cm2 slices (1-5 slices in total) in a centrifuge tube (supplied), add 500 µl of Buffer DS and vortex for 10 s. Briefly centrifuge the sample to the bottom of the tube. Centrifuge briefly to collect the sample at the bottom of the tube, incubate at 56°C for 3 minutes, remove from the water bath and allow to cool to room temperature before proceeding.Note: If the surface of the sample is exposed to air, discard the initial 2-3 slices without using them.3. Centrifuge at 12,000 rpm for 2 minutes and carefully discard the supernatant thoroughly without aspirating the precipitate. The residual dewaxing solution can be carefully removed with a small tip (10 µl).4. Add 180 µl of Buffer GTL and 20 µl of Proteinase K to the above tube and mix well with vortexing.5. Incubate at 56°C for 15 minutes, then place on ice for 3 minutes. Centrifuge at 12,000 rpm for 15 minutes at room temperature.6. Transfer the supernatant to a new 1.5 ml centrifuge tube for RNA extraction, taking care not to aspirate undigested tissue. Use the precipitate for DNA extraction. RNA extraction7. Take the supernatant obtained in step 6 and incubate at 80°C for 15 minutes.8. Add 320 µl of Buffer GL, mix by vortexing and shaking, then add 720 µl of anhydrous ethanol and mix immediately by vortexing and shaking.9. Add all of the resulting solution to the Spin Columns RS in the collection tube; if the solution cannot be added all at once, it may be transferred in several passes. centrifuge the column at 12,000 rpm for 1 minute, pour off the waste solution from the collection tube, and place the column back into the collection tube. Note: If the columns are clogged, the sample size may be too large and consideration should be given to reducing the number of starting sections to 1-2.Optional step: If genomic DNA is to be removed, the following steps can be followeda. Add 350 µl of Buffer RW1 to the column, centrifuge at 12,000 rpm for 1 minute, discard the waste solution, and place the column back into the collection tube.b. Preparation of DNase I mixture: Take 52 µl of RNase-Free Water and add 8 µl of 10×Reaction to it.Buffer and 20 µl DNase I (1 U/µl), mix well, and prepare a final volume of 80 µl of reaction solution.c. Add 80 µl of DNase I Mix directly to the adsorption column and incubate at 20-30°C for 15 minutes.d. Add 350 µl of Buffer RW1 to the column, centrifuge at 12,000 rpm for 1 minute, discard the waste solution, and return the column to the collection tube.Add 500 µl of Buffer RW2 to the adsorbent column, centrifuge at 12,000 rpm for 1 min, pour off the waste liquid in the collection tube, and put the adsorbent column back into the collection tube.11. Repeat step 10. centrifuge at 12,000 rpm for 2 minutes and pour off the waste liquid in the collection tube. Place the column at room temperature for 5 minutes.minutes to dry thoroughly.12. Place the column in a new RNase-free centrifuge tube and add 20-50 µl to the center of the column.RNase-Free Water, left at room temperature for 5 minutes, centrifuged at 12,000 rpm for 1 minute, and collected RNA solution, the-80°C for storage.DNA extraction7. Take the precipitate obtained in step 6 and add 180 µl Buffer GTL and 20 µl Proteinase K to the precipitate. VortexResuspend the precipitate for 15 seconds.8. Incubate at 56°C for 1 hour until the sample is completely dissolved. 90°C for 1 hour.Add 200 µl Buffer GL, vortex and shake to mix and then add 200 µl anhydrous ethanol, vortex and shake to mix thoroughly. Centrifuge briefly so that the solution on the wall of the tube collects at the bottom of the tube. Add all of the solution from step 9 to the Spin Columns DF in the collection tube, or transfer the solution in several passes. centrifuge at 12,000 rpm for 1 minute, pour off the waste solution from the collection tube, and return the column to the 10. collection tube.Note: If the adsorption column is clogged, the sample size may be too large and consideration should be given to reducing the number of starting sections to 1-2.11. Add 500 µl of Buffer GW1 to the adsorbent column and centrifuge at 12,000 rpm for 1 minute. Pour off the waste liquid from the collection tube and put the column back into the collection tube.12. Add 500 µl of Buffer GW2 to the adsorbent column and centrifuge at 12,000 rpm for 1 minute. Pour off the waste liquid from the collection tube and place the column back into the collection tube.Note: Step 12 may be repeated if further purity is required.13. Centrifuge at 12,000 rpm for 2 minutes and pour off the waste liquid in the collection tube. Leave the adsorption column at room temperature for 5 minutes to dry thoroughly. Note: The purpose of this step is to remove residual ethanol from the adsorbent column; ethanol residue will affect the subsequent enzymatic reaction. 14. Place the column in a new 1.5 ml centrifuge tube, add 20-50 µl Buffer EB to the center of the column, leave at room temperature for 5 minutes, centrifuge at 12,000 rpm for 1 minute, collect the DNA solution, and store at -20℃... Read More | DescriptionIt contains a set of six different heterogeneous palladium catalysts, useful for rapid screening of catalysis conditions. It is in sampler format with individual components packaged for multiple experiments and mini scale-up. The cost of the kit is less than the total cost of individual DescriptionIt contains a set of six different heterogeneous palladium catalysts, useful for rapid screening of catalysis conditions. It is in sampler format with individual components packaged for multiple experiments and mini scale-up. The cost of the kit is less than the total cost of individual components.Catalysis Screening Kits... Read More | Products contentN665730Component24 T96 TStorageN665730ATPS V50 144 µL576 µL-20℃. Avoid freeze/thaw cycle.N665730B5×FA Reaction Buffer144 µL576 µL-20℃. Avoid freeze/thaw cycle.N665730C2×HiFidelity PCR Mix600 µL2×1.2 mL-20℃. Avoid freeze/thaw Products contentN665730Component24 T96 TStorageN665730ATPS V50 144 µL576 µL-20℃. Avoid freeze/thaw cycle.N665730B5×FA Reaction Buffer144 µL576 µL-20℃. Avoid freeze/thaw cycle.N665730C2×HiFidelity PCR Mix600 µL2×1.2 mL-20℃. Avoid freeze/thaw cycle.N665730DPPM48 µL192 µL-20℃. Avoid freeze/thaw cycle.* This kit is suitable for human genomic DNA library construction with a starting template DNA input of 50 ng. We also have transposase library construction kits for human genomic DNA starting at 5 ng and 1 ng, so it is recommended to use different kits for different starting amounts of DNA in order to obtain higher quality libraries. Products IntroductionThis kit is developed for Illumina's high-throughput sequencing platform and provides the enzyme premix system and reaction buffer for genomic DNA library construction, including all components except PCR primers. Compared with the traditional library construction kits, this kit adopts the new transposase method for library construction, which can complete DNA fragmentation, end repair and junction reaction in one simple enzymatic reaction, significantly reducing the amount of template, reducing the number of experimental steps, and shortening the time of library construction; it adopts the high-fidelity DNA polymerase for library enrichment, and the preference-free PCR amplification can expand the coverage area of the sequence, which can be used for efficient and effective sequencing. The use of high-fidelity DNA polymerase for library enrichment and preference-free PCR amplification broadens the coverage area of the sequence and enables efficient preparation of DNA libraries for Illumina's second-generation sequencing platform. The kit is suitable for DNA libraries with a starting template of 50 ng, and all reagents in the kit have been subjected to strict quality control and functional validation to maximize the stability and reproducibility of library construction. Product Features ● DNA fragmentation and junction ligation in one step.● Ultra-fidelity amplification minimizes amplification-preferred steps.Provide your own instruments, kits and consumables1. Magnetic frame: DynaMagTM-2 is recommended.2. DNA purification and recovery kit: It is recommended to use DNA purification and recovery kit by magnetic bead method.3. Library PCR primer kits: transposase method for second-generation sequencing multi-sample primer kits are recommended. 4. Anhydrous ethanol, deionized water (pH between 7.0 and 8.0).5. Reaction tubes: It is recommended to use low adsorption PCR tubes and 1.5 ml centrifuge tubes. Tips: It is recommended to use high quality filter tips to prevent contamination of kits and library samples. Pre-experiment Preparation and Important Notes1. Avoid repeated freezing and thawing of reagents.2. PCR products are easily contaminated due to improper operation, resulting in inaccurate results. It is recommended to isolate the PCR reaction system preparation area from the PCR product purification area, and to use special pipettes to clean the experimental areas at regular intervals.3. Bead purification: the beads should be equilibrated to room temperature before use, all operations on the beads should be carried out at room temperature, 80% ethanol should be dispensed freshly, the beads should be rinsed and dried until the surface is free of liquid reflections and has a frosted appearance, insufficient drying of the beads will cause ethanol residue that will affect the subsequent experiments, and over-drying of the beads will affect the efficiency of DNA recovery.4. The kit is suitable for human genomic DNA library construction, if the DNA sample is a PCR product, it should be ensured that its length>.500 bp, since transposases do not work on DNA ends, it is recommended to extend the PCR product by 50-100 bp at each end of the PCR product to avoid low coverage of the ends for sequencing.Sample PreparationDNA purity requirements: A260/A280 = 1.8-2.0. Sample DNA: dissolve in ultrapure water. DNA Quantification: Too much or too little DNA will affect the quality of the library. It is recommended to use Nano to test the purity of the genomic DNA and then use Qubit to test the concentration of the genome (do not use any absorbance-based assay for template quantification).Schematic diagram of DNA banking processprocedureDNA fragmentation, junction reaction1. Add the following reagents to a 200 µl PCR tube: 2. Mix by gently blowing with a pipette and centrifuge briefly so that all components are collected at the bottom of the tube.3. Place the above PCR tubes in the PCR instrument with the hot cap on and program the reaction as follows:DNA should be purified immediately after the fragmentation reaction has been performed and the transposase is still in a high state of activity.to prevent smaller library fragments due to DNA over-fragmentation. Purification of fragmentation productsWe recommend the use of the Century Magnetic Bead Method DNA Purification and Recovery Kit.1. CMPure should be equilibrated at room temperature for 30 min after shaking and mixing before use.2. Add 50 µl of magnetic beads equilibrated to room temperature to the fragmentation product, vortex and shake for 5 seconds, then let stand at room temperature for 5 minutes.3. Centrifuge briefly, place the tube on a magnetic rack to separate the beads from the supernatant solution until the solution is clear (approximately 3-5 minutes), carefully aspirate the supernatant and discard, avoiding contact with the beads that have bound the target DNA. Note: Do not discard the beads.4. Continue to keep the centrifuge tube fixed on a magnetic rack and add 200 µl of freshly prepared 80% ethanol to the centrifuge tube and allow to stand at room temperature for 30 seconds, carefully discarding the supernatant.Note: When adding ethanol, the liquid must not be blown directly onto the beads.5. Repeat step 4.6. Keep the centrifuge tube fixed on a magnetic rack and leave to dry at room temperature until the surface of the beads is slightly cracked, then add 23 µlddH2O to solubilize.Note: Do not over-dry the beads as this may affect the elution efficiency.7. Remove the tube from the magnetic rack, vortex to completely resuspend the beads, and allow to stand at room temperature for 5 minutes. Centrifuge briefly, place the tube on the magnetic rack until the solution is clear, and transfer 21 µl of supernatant to a new 200 µl PCR tube.PCR amplification Add the following reagents to the 200 µl PCR tube: Mix by gently blowing with a pipette and centrifuge briefly so that all components are collected at the bottom of the tube.3. Place the above PCR tubes in the PCR instrument with the hot cap on and program the reaction as follows:Selective recovery of library DNA fragmentsIt is recommended to use CombiVision Magnetic Beads DNA Purification and Recovery Kit for selective recovery of DNA fragments. When different sizes of DNA fragments are required, the amount of magnetic beads to be used is different, please refer to the attached table for the specific amount of magnetic beads to be used (if other brands of magnetic beads are used, you need to find out the optimal amount of magnetic beads to be used on your own).Note: Amplification products can also be fragment length sorted and purified using the Gum Recovery Kit. If there is no special requirement for library length distribution, the amplification products can also be purified without selective recovery of DNA fragments as described on page 6 of the manual.1. CMPure should be equilibrated at room temperature for 30 min after shaking and mixing before use.2. Transfer the PCR product to a 1.5 ml centrifuge tube, rehydrate to 100 µl and add several volumes of magnetic beads equilibrated to room temperature, vortex for 5 seconds and let stand at room temperature for 5 minutes.3. Centrifuge briefly, place the tube on a magnetic rack to separate the beads from the supernatant until the solution is clear, and carefully aspirate the supernatant and transfer it to a new 1.5 ml centrifuge tube.Note: Do not discard the top clear.4. Add several volumes of magnetic beads to the supernatant, vortex and shake for 5 seconds, then let stand at room temperature for 5 minutes.5. Centrifuge briefly, place the tube on a magnetic rack to separate the beads from the supernatant until the solution is clear, carefully aspirate the supernatant and discard it, avoiding contact with the beads that have bound the target DNA.Note: Do not discard the beads.6. Continue to keep the centrifuge tube fixed on a magnetic rack and add 200 µl of freshly prepared 80% ethanol to the tube and allow to stand at room temperature for 30 seconds, carefully discarding the supernatant.Note: When adding ethanol, the liquid must not be blown directly onto the beads.7. Repeat step 6 once.8. Keep the centrifuge tube fixed on a magnetic rack and leave to dry at room temperature until the surface of the beads is slightly cracked, add 20 µl of ddH2O to solubilize.Note: Do not over-dry the beads as this may affect the elution efficiency.9. Remove the centrifuge tube from the magnetic rack, vortex and oscillate to completely resuspend the beads, and let stand at room temperature for 5 minutes. Leave brieflycentrifuge, place the tube on a magnetic rack until the solution is clear, and transfer the supernatant solution to a new centrifuge tube. Table: Suggested amount of magnetic beads for different segment selection recoveryLibrary DNA fragment purificationWe recommend the use of the Century Magnetic Bead Method DNA Purification and Recovery Kit.1. CMPure should be equilibrated at room temperature for 30 min after shaking and mixing before use.2. 50 µl of magnetic beads equilibrated to room temperature were added to the PCR product, vortexed and shaken for 5 seconds, and then left to stand at room temperature for 5 minutes.3. Centrifuge briefly, place the tube on a magnetic rack to separate the beads from the supernatant solution until the solution is clear (approximately 3-5 minutes), carefully aspirate the supernatant and discard it, avoiding contact with the beads that have bound the target DNA. Note: Do not discard the beads.4. Continue to keep the centrifuge tube fixed on a magnetic rack and add 200 µl of freshly prepared 80% ethanol to the centrifuge tube and allow to stand at room temperature for 30 seconds, carefully discarding the supernatant.Note: When adding ethanol, the liquid must not be blown directly onto the beads.5. Repeat step 4.6. Keep the centrifuge tube fixed on a magnetic rack and leave to dry at room temperature until the surface of the beads is slightly cracked, add 25 µl of ddH2O to solubilize.Note: Do not over-dry the beads as this may affect the elution efficiency.7. Remove the tube from the magnetic rack, vortex to completely resuspend the beads, and allow to stand at room temperature for 5 minutes. Centrifuge briefly, place the tube on the magnetic rack until the solution is clear, and transfer the supernatant solution to a new tube.Library quality controlDetermination of library concentrationIn order to obtain high-quality sequencing results, accurate quantification of DNA libraries is required, and the first recommendation is to use Real-timePCR methods are used for absolute quantification of DNA libraries. Additionally, fluorescent dye methods such as the Qubit method or the fluorescent dye picogreen method can be used; do not use quantification methods based on absorbance measurements here. The following approximate formula can be used to convert the molar concentration of the DNA library. Average total length of librariesApproximate conversion formula Library fragment distributionThe prepared DNA libraries can be detected by agarose gel electrophoresis or Agilent 2100 Bioanalyzer.Range of segment length distributions... Read More |