| Description | DescriptionUse in combination with the KitAlysis Bench Top Inertion Box (Z742064) or a glove box/glove bag to provide inert atmosphere for kit set-up.Designed to be used with KitAlysis High-Throughput Screening Kits.Components:24-Well Reaction BlockTorque ScrewdriverSmall screwdriver to easily DescriptionUse in combination with the KitAlysis Bench Top Inertion Box (Z742064) or a glove box/glove bag to provide inert atmosphere for kit set-up.Designed to be used with KitAlysis High-Throughput Screening Kits.Components:24-Well Reaction BlockTorque ScrewdriverSmall screwdriver to easily remove torqued screws after reaction is complete.10 Reaction Block Replacement Screws... Read More | Product content: Component G665666 200 preps Buffer P1 60ml Buffer P2 60ml Buffer E3 60ml Buffer PW (concentrate) 25ml Buffer EB 30ml RNase A (10 mg/ml) 600 µl Spin Columns DM 200 with Collection Tubes 200Product Introduction:This reagent kit is suitable for extracting 1-5 ml of Product content: Component G665666 200 preps Buffer P1 60ml Buffer P2 60ml Buffer E3 60ml Buffer PW (concentrate) 25ml Buffer EB 30ml RNase A (10 mg/ml) 600 µl Spin Columns DM 200 with Collection Tubes 200Product Introduction:This reagent kit is suitable for extracting 1-5 ml of bacterial solution. On the basis of alkaline lysis of cells, it efficiently and specifically binds plasmid DNA through a new silicon-based membrane. Each adsorption column can adsorb up to 40% µ The plasmid DNA of g is effectively removed with a special buffer system to effectively remove impurities such as proteins. The yield and purity of plasmids obtained from this kit are high, and the quality is stable. It is suitable for downstream experiments such as cell transfection, DNA sequencing, PCR, PCR based mutations, in vitro transcription, transformed bacteria, and endonuclease digestion.Self prepared reagents: anhydrous ethanol, isopropanol.Preparation and important precautions before the experiment:1. All components can be stably stored for 1 year in a dry, room temperature (15-30 ℃) environment. The adsorption column can be stored for a longer time at 2-8 ℃. 2.Buffer P1 with RNase A added can be stably stored for 6 months at 2-8 ℃. Before use, add RNase A to Buffer P1 (add all RNase A provided in the reagent kit), mix well, and store at 2-8 ℃. Before use, it is necessary to leave it at room temperature for a period of time, and then use it after returning to room temperature.3.Before the first use, anhydrous ethanol should be added to the Buffer PW according to the instructions on the reagent bottle label.4. Before use, please check if there is any crystallization or precipitation in Buffer P2 and Buffer E3. If there is any crystallization or precipitation, you can take a water bath at 37 ℃ for a few minutes to restore clarity.5. Note that Buffer P2 and Buffer E3 contain irritating substances. Please wear gloves when operating and immediately cover the lid after use.6.The amount and purity of plasmid extraction are related to factors such as bacterial culture concentration, strain type, plasmid size, and plasmid copy number.7. The maximum volume of Spin Columns DM is 750 µ l. If the sample volume is greater than 750 µ L can be added in batches.Operation steps:1. Take 1-5 ml of overnight cultured bacterial solution and add it to a centrifuge tube (provided). Centrifuge at 13000 rpm (~16200 × g) for 1 minute to collect bacteria, and try to discard all the supernatant as much as possible.2. Add 200 to the centrifuge tube containing bacterial sediment µ Buffer P1 (please check if RNase A has been added first), mix thoroughly with a pipette or vortex oscillator, and suspend bacterial precipitation.Attention: If the bacterial blocks are not thoroughly mixed, it will affect the cracking effect, resulting in low extraction amount and purity.3. Add 200 to the centrifuge tube µ Buffer P2, gently invert and mix 8-10 times to fully lyse the bacterial cells. At this point, the solution should become clear and viscous.Attention: Mix gently and do not shake vigorously to avoid interrupting genomic DNA and mixing genomic DNA fragments in the extracted plasmid. If the solution does not become clear, it indicates that the bacterial count may be too large and the lysis may not be complete. The bacterial count should be reduced or the dosage of P1, P2, E3, and isopropanol should be increased proportionally.4. Add 200 to the centrifuge tube µ Buffer E3, immediately invert and mix 8-10 times, at which point white flocculent precipitates appear. Centrifuge at 13000 rpm for 5 minutes.Attention: After adding Buffer E3, it should be mixed evenly immediately to avoid local precipitation.5. Add 260 to the spin columns DM that have been loaded into the collection tube µ After adding isopropanol, immediately add the supernatant collected in step 4 and mix it upside down.Attention: After adding isopropanol, immediately add the supernatant and mix well to avoid isopropanol dripping into the collection tube after being left for a long time. The maximum volume of the adsorption column is 750 µ l. If the sample volume is greater than 750 µ l. Isopropanol and the supernatant can be collected in a centrifuge tube (provided by oneself), mixed well, and passed through the column in batches.6.13000 rpm for 1 minute, discard the waste liquid in the collection tube, and place the adsorption column back into the collection tube.7. Add 400 to the adsorption column µ L Buffer PW (please check if anhydrous ethanol has been added first), centrifuge at 13000 rpm for 1 minute, and discard the waste liquid in the collection tube.8. Place the adsorption column in a new collection tube and add 50-100 to the middle of the adsorption membrane µ Centrifuge at 13000 rpm for 1 minute using buffer EB and collect the plasmid solution into a centrifuge tube- Store the plasmid at 20 ℃.Note: 1) To increase the efficiency of plasmid recovery, the obtained solution can be added back to the adsorption column, left at room temperature for 2-5 minutes, centrifuged at 13000 rpm for 2 minutes, and collected into a centrifuge tube.2) When the plasmid copy number is low or>10 kb, preheating the buffer EB in a water bath at 65-70 ℃ can increase the extraction efficiency... Read More | Product content:M665754Component25 TStorageM665754ATris-HCl, 1 mM, PH 8.01 mL-20℃. Avoid freeze/thaw cycleM665754BE. coli Poly(A) Polymerase, 5 U/µL15 µL-20℃. Avoid freeze/thaw cycleM665754C10×Poly(A) Polymerase Buffer80 µL-20℃. Avoid freeze/thaw Product content:M665754Component25 TStorageM665754ATris-HCl, 1 mM, PH 8.01 mL-20℃. Avoid freeze/thaw cycleM665754BE. coli Poly(A) Polymerase, 5 U/µL15 µL-20℃. Avoid freeze/thaw cycleM665754C10×Poly(A) Polymerase Buffer80 µL-20℃. Avoid freeze/thaw cycleM665754DATP, 10 mM15 µL-20℃. Avoid freeze/thaw cycleM665754ERT Primer, 25 µM90 µL-20℃. Avoid freeze/thaw cycleM665754F5×SuperRT Buffer120 µL-20℃. Avoid freeze/thaw cycleM665754GUltraPure dNTP Mix, 10 mM each30 µL-20℃. Avoid freeze/thaw cycleM665754HSuperRT, 200 U/µL15 µL-20℃. Avoid freeze/thaw cycleM665754IRNase-Free Water1 mL-20℃. Avoid freeze/thaw cycle Product Introduction:This kit uses the method of adding a poly (A) tail at the 3 'end of miRNA to give miRNA a Poly (A) tail, followed by reverse transcription using Oligo (dT) - Universal tag universal reverse transcription primers to synthesize the first stranded cDNA corresponding to miRNA. The miRNA cDNA first strand synthesis kit contains all the reagents required for the miRNA 3 'end Poly (A) tail modification process and the reverse transcription process after modification. This kit has a very high Poly (A) modification and reverse transcription efficiency, which can range from 1 ng-2 µ The first strand of cDNA corresponding to miRNA was effectively obtained from the total RNA of g. And the operation is simple and fast, which can be used to simultaneously detect multiple miRNAs from a synthesized cDNA reaction. This not only reduces errors and saves samples, but also achieves high-throughput detection.Note: This kit must be used in conjunction with the miRNA fluorescence quantitative detection kit.Self prepared experimental materials: 1 ng-2 µ Total RNA of g, or 0.1 ng-1 µ Small molecule RNA of g.Notes:To prevent RNase pollution, attention should be paid to the following aspects:1. Use plastic products and gun heads without RNase to avoid cross contamination.2. Glassware should be dry baked at a high temperature of 180 ℃ for 4 hours before use. Plastic containers can be soaked in 0.5 M NaOH for 10 minutes, thoroughly rinsed with water, and then sterilized under high pressure.3. The solution should be prepared using water without RNase.4. Operators should wear disposable masks and gloves, and change gloves frequently during the experiment.Usage:A. The process of miRNA adding Poly (A) tail:1.based on the amount of RNA used, dilute the total RNA of 10 mM ATP with 1 mM Tris (pH 8.0) according to the following formula: ATP dilution coefficient=5000/__ ngExample: If the initial amount of total RNA is 100 ng, then the ATP dilution coefficient is 5000/100=50. About to dilute ATP 50 times (1 µ 10 mM ATP plus 49 for l µ 1 mM Tris at pH 8.0.2. Add the following reagents to the pre cooled RNase free reaction tube in the ice bath to a total volume of 25 µ L. reagent 25 µlReaction system final concentration total RNA* X µl Up to 2 µg 10×Poly(A) Polymerase Buffer 2.5 µl 1× Diluted ATP in step "1" 1 µl / E. coli Poly(A) Polymerase, 5U/µl 0.5 µl 2.5 U RNase-Free Water up to 25 µl /*The total RNA used in the reaction must contain small molecule RNA.This process can also directly use small molecule RNA (recommended dosage of 2-5) µ L. Please determine the amount added based on the abundance of the target miRNA.3. Gently mix the above reaction solution and briefly centrifuge to collect the liquid at the bottom of the tube. Incubate at 37 ℃ for 15 minutes. After this process is completed, immediately proceed with the synthesis of the first strand cDNA or temporarily store it at -20 ℃. If long-term storage is required, it is recommended to store at -80 ℃.B. The process of synthesizing the first strand of modified miRNA cDNA:1. Add the reagents in the table below to the pre cooled RNase free reaction tube in the ice bath until the final volume reaches 20µl: reagent 20 µlReaction system The above Poly (A) reaction solution 4 µl UltraPure dNTP Mix ,10 mM each 1 µl RT Primer ,25 µM 3 µl 5×SuperRT Buffer 4 µl SuperRT ,200 U/µl 0.5 µl RNase-Free Water 7.5 µl2. Gently mix the above reaction solution and briefly centrifuge to collect the liquid at the bottom of the tube. Incubate at 42 ℃ for 50 minutes.3.85 ℃ for 5 minutes and terminate the reaction. The synthesized cDNA reaction solution can be directly used for fluorescence quantitative detection experiments or stored at -20 ℃ for future use... Read More | This kit is used to extract miRNAs from various animal tissues, plant tissues and cells. The extracted miRNA molecule is complete and high purity, which is suitable for various molecular biology experiments such as Northern blot, real timepcr, miRNA microarray chip, in situ hybridization, This kit is used to extract miRNAs from various animal tissues, plant tissues and cells. The extracted miRNA molecule is complete and high purity, which is suitable for various molecular biology experiments such as Northern blot, real timepcr, miRNA microarray chip, in situ hybridization, RNase protection assay, etcComposition:Scope of application:Nucleic acid extraction and purificationInstruction:1.Experimental preparation:1.1.All reagents were prepared with DEPC-treated solvents. Please use RNase-free tip and centrifuge tube to avoid RNA degradation by RNase during extraction.1.2.70 % ethanol, -20C pre-cooling.2.Operational procedure:There is a slight difference in the operation of miRNA extraction from different samples. The specific steps are as follows :【 Extraction of miRNA from animal tissues】1.Take 20-40 mg tissue, transfer to a pre-cooled mortar, and add liquid nitrogen to grind into powder.Please click below to describe the amount of organization used :①RNA-rich tissue ( e.g. liver ) : no more than 30 mg②Tissues with low RNA content ( e.g., muscle ) : no more than 100 mg③When the amount of tissue used was less than 20 mg : the amount of R-I, R-II and isopropanol used was halved.④When the amount of tissue used was more than 40 mg : the use of R-I, R-II and isopropanol increased proportionally.2.Add 400 ul Buffer R-I, repeatedly aspirate 8-10 times with a syringe equipped with a 21-25 needle, and transfer to a 1.5 m : centrifuge tube ( provided in the kit ). 3.Add 150 µl BufferR-1l, swirl for 15-30 s, centrifuge at 12,000 X g for 5 min. [ Centrifugation at 4 °C is recommended ] 4.Take the supernatant to 1.5ml centrifuge tube, add 180 u anhydrous ethanol, mix evenly.5.The preparation tube was placed in a 2 m : centrifuge tube ( provided in the kit ), the mixture in step 4 was transferred to the preparation tube, and 12,000 X g was centrifuged for 1 min. [ 1 Centrifugation at 4 °C is recommended ; 2 miRNA in the filtrate, pay attention to preserve the filtrate. ]6.Abandon the preparation tube, add 500µl isopropanol to the filtrate, and mix evenly.7.12,000Xg centrifuged for 10 min, discard the supernatant.8.Add 700µl 70 % ethanol ( pre-cooled at -20 °C ), centrifuged at 12,000Xg for 5min.9.The supernatant was discarded and dried at room temperature for 5-10 min.10.70 ul Buffer TE ( nucdease-free ) or RNase-free water was added to the centrifuge tube to elute miRNA.【 Extraction of miRNA from plant tissue 】1.Take 30-150 mg tissue, transfer to a pre-cooled mortar, and add liquid nitrogen to grind into powder.Please click below to describe the amount of organization used :①Plant leaves : usually 10-80 mg② Plant fiber tissue : usually 100-150 mg③When the amount of plant leaf tissue was less than 30 mg : the amount of R-I, R-II and isopropyl alcohol used was halved.④When the amount of plant leaf tissue was more than 80 mg : the use of R-I, R-II and isopropanol increased proportionally.⑤When the amount of plant fiber tissue was more than 150 mg : the use of R-I, R-II and isopropanol increased proportionally.2.Add 400 ul BufferR-I, use a syringe with a 21-25 needle to repeatedly suck 8-10 times, and transfer to a 1.5mI centrifuge tube ( provided in the kit ). 3.Add 150 ul Buffer R-1I, vortex oscillation 15-30 s, 12.000 x g centrifugation 5 min. [ Centrifugation at 4 °C is recommended ]4.Take the supernatant to 1.5ml centrifuge tube, add 180 mountain anhydrous ethanol, mix evenly.The preparation tube was placed in a 2 mI centrifuge tube ( provided in the kit ), the mixture in step 4 was transferred to the preparation tube, and 12.000 xg was centrifuged for 1 min. It is recommended to centrifuge at 4 °C ; 2 miRNA in the filtrate, pay attention to preserve the filtrate. ]Abandon the preparation tube, add 500µl isopropanol to the filtrate, and mix evenly.7.12,000xg high heart for 10 min, discard the supernatant.8.Add 700 ul 70 % ethanol ( -20 °C precooling ), 12,000 xg centrifuge for 5 min.9.The supernatant was discarded and dried at room temperature for 5-10 min.10.70 ul Buffer TE ( nucdease-free ) or RNase-free water was added to the centrifuge tube to elute miRNA.【miRNA extraction from cells】Steps 1-3 According to the different ways of cell culture, two experimental methods, a or b, can be selected.a. Suspension cultured animal cells or cell suspension obtained from petri dishes or culture flasks or freshly isolated animal tissue single cell suspension :1a.Collect 2X 10 * -1X 10 ' cells, centrifuge 2,000Xg for 5 min, discard the supernatant ;2a. Add 400 µl Buffer R-I, repeatedly draw 8-10 times with a syringe containing 21-25 needles, and transfer to a 1.5 mI centrifuge tube ( provided in the kit ) ;3a. Add 150µl Buffer R1I, vortex oscillation 15-30s, 12.000Xg centrifugal 5min. [ build at 4 °C centrifugal ].b. Cells cultured on 96-well L, 24-well, 12-well or 6-well plates :Cells were collected from 96-well, 24-well, 12-well or 6-well culture plates, and the medium was discarded as much as possible, and 400 u / well Buffer R-I was added to each well, and the pipette gun was used to blow up and down 8-10 times ;2b.Transfer the above cell suspension to a 1.5ml centrifuge tube ( provided in the kit ), and repeatedly draw 8-10 times with a syringe containing 21-25 needles ;3b. Add 150 µl Bufflr R-II, swirl for 15-30 s, centrifuge for 5 min at 12,000 × g. [ Recommended at 4 °C ]4.Take the supernatant to 1.5ml centrifuge tube, add 180 mountain anhydrous ethanol, mixing evenly.5.The preparation tube was placed in a 2 ml centrifuge tube ( provided in the kit ), the mixture in step 4 was transferred to the preparation tube, and centrifuged at 12.000 Xg for 1 min. [ 1 Centrifugation at 4 °C is recommended ; 2 miRNA in the filtrate, pay attention to preserve the filtrate. ]6.Abandon the preparation tube, add 500 u of isopropanol to the filtrate, and mix evenly.7.12,000Xg high heart for 10 min, discard the supernatant.8.Add 700µ70 % ethanol ( pre-cooled at − 20 °C ), centrifuged at 12,000 × g for 5 min.9.Abandon the supernatant, dry at room temperature for 5 - 10 min.10.70 ul Bufer TE ( nucdease-free ) or RNase-free water was added to the centrifuge tube to elute mRNA.3.Flow chartMatters needing attention:Buffer R-I contains irritating compounds, when operating to wear latex gloves and glasses, to avoid contamination of the skin, eyes and clothes, be careful not to inhale the nose and mouth. If the skin, eyes, to immediately rinse with a lot of water or saline, if necessary, seek medical advice... Read More | The fluorescent dye PKH67 is suitable for conventional cell membrane labeling. It is a green fluorescent dye that can track cells in vitro and in vivo. It labels cells by binding to the lipid components of the membrane structure. PKH67 has low cytotoxicity, low fluorescence background, high fat The fluorescent dye PKH67 is suitable for conventional cell membrane labeling. It is a green fluorescent dye that can track cells in vitro and in vivo. It labels cells by binding to the lipid components of the membrane structure. PKH67 has low cytotoxicity, low fluorescence background, high fat solubility, can easily penetrate cell membranes, and has strong and stable green fluorescence. PKH67-labeled cells can be used for in vitro and in vivo proliferation studies, and have the function of not staining neighboring cells. In the process of cell division and proliferation, the fluorescence intensity of PKH67 will gradually decrease as the cells divide. The labeled fluorescence can be evenly distributed to the two sub-generation cells, so its fluorescence intensity is half that of the parent cell. According to this feature, It can be used to detect cell proliferation, cell cycle estimation and cell division, etc. The fluorescence of PKH67-labeled cells is very uniform, and the fluorescence distribution of sub-generation cells after division is also more uniform. In the process of cell division and proliferation, PKH67-labeled fluorescence can be evenly distributed between the two sub-generation cells, and the fluorescence intensity becomes half of that of the parent cell. According to the difference in fluorescence intensity, the undivided cells can be detected by flow cytometry. One time (1/2 the fluorescence intensity), the second time (1/4 the fluorescence intensity), three times (1/8 the fluorescence intensity), and more divisions of cells. PKH67 can detect splits up to six times or even more. In addition to the detection of cell proliferation, PKH67 can also be used for in vitro tracking of cells. After labeling, the fluorescence expression is stable in the cell, and the positive labeling rate is over 98%. The labeled cells have good morphology, which can effectively observe the cells in vitro. Induce differentiation; or inject labeled cells into the body, it can effectively show the migration and differentiation of transplanted cells in living tissues. PKH67-labeled cells can be used for in vivo observation for as long as several weeks. It is often used for in vivo cell detection experiments and experiments to observe long-term cell activity using fluorescence electron microscope. PKH67 is less toxic and does not affect cell proliferation. This method is simple to operate, does not use radioactive isotopes, and poses no safety hazards. You can get the desired experimental data faster, more accurately and more safely.Due to the longer length of the charcoal tail, internal studies have shown that PKH67 is less transferred between cells than PKH2. In in vivo studies using PKH1 and PKH2, the fluorescence intensity will slowly lose. Since this is a behavioral characteristic of green cell linker dye rather than red cell linker dye, PKH67 will have similar properties. The correlation between the in vitro cell membrane retention of non-dividing cells and the in vivo fluorescence half-life reveals that the in vivo fluorescence half-life of PKH67 is 10-12 days. Other green cell linker dyes with similar half-lives have been used to monitor the transport of lymphocytes and macrophages in the body within one to two months. The results indicate that PKH67 can also be used for medium-term in vivo tracking studies.The dye can stably bind to the lipid region of the cell membrane and emit fluorescence, and is mainly used for cell labeling in vitro, cell proliferation research in vitro, and cell tracing research in vivo and in vitro. The fluorescence half-life of PKH67 in vivo is 10-12 days. Compared with PKH-67, PKH-26 has a longer half-life, and the half-life of PKH26 labeled on rabbit red blood cells is more than 100 days. Especially suitable for in vitro proliferation research and long-term in vivo cell tracking research. After PKH67 labels the cells, flow cytometry is usually used for cell proliferation detection.Kit components0.1ml kits: P266290A-0.1ml P266290B-10ml1ml kits: P266290A-1ml P266290B-60mlDyes with A suffix and diluents with B suffix are used togetherPKH67 labeled cells show green fluorescence, the fluorescence wavelength: λex=490 nm, λem=502 nm.Storage conditions: -20℃ protected from light, valid for 1 yearPrecautions●Staining concentration varies according to the type of cell and the number of cells in each well.● The prepared PKH67 mother liquor is very easy to dissolve. It is recommended to store in aliquots and freeze-dry at ≦-20℃.● PKH67 working solution should be prepared for immediate use, and cannot be prepared in advance, because PKH67 will decompose due to the absorption of water and affect the dyeing effect.● PKH67 is easily decomposed and will deteriorate quickly in the water solution. Please avoid contact with water during use of mother liquor. The working fluid is in contact with the water during the process of labeling the cells within the permitted time range.● PKH67 fluorescent dye is a DMSO solution. It will solidify and stick to the bottom, wall or cap of the tube at a lower temperature such as 4℃ and ice bath. After being taken out of the refrigerator, it will return to room temperature and become After the liquid is in the state, remove the cap from the bottom of the tube. It can be used after it has completely melted in a 37°C water bath.● The number of generations or time that can be traced after different cell types are marked is quite different. Please make a test based on the actual situation or reference documents.Instructions1. Staining solution preparation:(1) Take out the PKH67 reagent from the refrigerator, let it stand for a few minutes to room temperature, or after a 37°C water bath, leave the tube containing PKH67, and be sure to leave the tube for a few minutes before opening the lid to allow the reagent to fully fall into the tube The lid can only be opened after the bottom.(2) According to the number of cell samples to be tested, dilute the probe 10 times with the diluent, and then use a suitable solution (such as non-clear medium, HBSS or PBS) to dilute the PKH67 mother liquor 25 times to prepare a stain Work fluid. The best working solution concentration should be adjusted according to different cells and your own experimental system. Generally, the cells can be diluted 250 times according to the final concentration of the mother liquor in the kit. Some cells may need to increase the concentration appropriately.2. Cell staining(1) Resuspend the prepared cells to be tested in 100µl of staining solution to a cell concentration of about 107/ml. You can also perform in-situ staining, as long as the staining solution is enough to cover the cells.(2) Culture the cells at 2~8℃ for 15~30 minutes. The best culture time is different for different cells.It is recommended to incubate the labeled cells in the staining solution at 37°C for 5 minutes, and then at 4°C for 15 minutes.Low-temperature incubation can reduce the endocytosis of the dye by the cells, help the dye to label the plasma membrane, and reduce the possibility of the dye localizing to cytoplasmic vesicles.(3) After separation, remove the supernatant, collect the cells, wash the cells 1-2 times with PBS or non-clear medium, and finally add PBS or non-clear medium to resuspend the cells.(4) Take 500µl of cell suspension and test with flow cytometer. Ex/Em=490/502nm.(5) Subsequently, the cells can be cultured according to the normal culture method.(6) The labeling effect can be directly observed under a fluorescence microscope, or the cell proliferation can be detected by a flow cytometer after an appropriate period of culture, or used for cell fluorescence traces for other specific experimental purposes... Read More |