| Description | Glycogen is a macromolecular polysaccharide composed of glucose and serves as one of the primary storage forms of sugar. It is mainly stored in the liver and muscles as reserve energy, referred to as liver glycogen and muscle glycogen, respectively. Liver glycogen regulates blood glucose Glycogen is a macromolecular polysaccharide composed of glucose and serves as one of the primary storage forms of sugar. It is mainly stored in the liver and muscles as reserve energy, referred to as liver glycogen and muscle glycogen, respectively. Liver glycogen regulates blood glucose concentration; when blood sugar rises, glycogen can be synthesized in the liver, and when blood sugar decreases, liver glycogen is broken down into glucose to supplement blood sugar. Therefore, liver glycogen is crucial for maintaining the relative balance of blood glucose. Muscle glycogen is the storage form of sugar in muscles. During strenuous exercise that consumes large amounts of blood sugar, muscle glycogen cannot be directly broken down into blood sugar but must first decompose to produce lactic acid, which circulates to the liver via the bloodstream and is converted into liver glycogen and glucose through gluconeogenesis. Detection Principle: Glycogen is extracted using a strong alkaline extraction buffer. Under strong acidic conditions, it forms a blue compound with the anthrone chromogen, which has a characteristic absorption peak at 620 nm. Within a certain concentration range, the glycogen content is linearly related to the absorbance at 620 nm. The glycogen content in the sample can be calculated based on the standard curve. Detection Range: 0.003125 - 0.25 mg/mL Sensitivity: 0.003125 mg/mL Applicable Samples: Animal tissues, bacteria, cellsG1501748Component96TStorageG1501748AExtraction Buffer120 mL2-8℃G1501748BChromogen1EA2-8℃. Store in the dark.G1501748CStandard1 mL2-8℃Note: It is recommended to perform preliminary experiments using 2-3 samples expected to have significant differences before formal testing.User-Provided Instruments and Consumables1.Microplate reader or visible spectrophotometer (capable of measuring absorbance at 620 nm)2.Low-temperature centrifuge, Water bath3.96-well plate or micro glass cuvettes, Adjustable pipettes and tips, EP tubes4.Deionized water, Concentrated sulfuric acidExperimental Procedure1. Reagent PreparationReagent NameReagent PreparationPrecautionsExtraction BufferReady-to-use; equilibrate to room temperature before use.Store at 4°C. Corrosive; please take protective measures during handling.ChromogenFirst, dissolve the powder in 7.2 mL of deionized water. Then slowly add 28.8 mL of concentrated sulfuric acid. Mix thoroughly after complete dissolution.Store at 4°C protected from light; valid for one week. Toxic; please take protective measures during handling.StandardStore at 4°C.2. Standard Curve SetupDilute the 1 mg/mL standard with deionized water to prepare standard solutions of 0.25, 0.1, 0.05, 0.025, 0.0125, 0.00625, and 0.003125 mg/mL as shown in the table below.No.Standard VolumeDeionized Water Volume (µL)Concentration (mg/mL)Std.1100µL of 1mg/mL3000.25Std.2160µL of Std.12400.1Std.3200µL of Std.22000.05Std.4200µL of Std.32000.025Std.5200µL of Std.42000.0125Std.6200µL of Std.52000.00625Std.7200µL of Std.62000.003125Note: A standard curve must be prepared for each experiment. Diluted standard solutions are unstable and must be used within 4 hours.3. Sample PreparationNote: Fresh samples are recommended. If not used immediately, samples can be stored at -80°C for up to 1 month.3.1 TissuesWeigh 0.1 g of tissue and place it in a 10 mL test tube. Add 0.75 mL of Extraction Buffer. Boil in a water bath for 20 minutes (stopper the tube tightly to prevent water evaporation). Shake the tube every 5 minutes to mix thoroughly. After the tissue is completely dissolved, remove the tube and let it cool. Dilute to 5 mL with deionized water, mix well. Centrifuge at 8,000 g, 25°C for 10 minutes. Collect the supernatant for detection.3.2 Cells or BacteriaCollect 5 million bacteria or cells into an EP tube. Centrifuge and discard the supernatant. Add 0.75 mL of Extraction Buffer and disrupt the bacteria or cells by ultrasonication (power 200 W, ultrasonicate for 3 s, interval 10 s, repeat 30 times). Transfer to a 10 mL test tube. Boil in a water bath for 20 minutes (stopper the tube tightly to prevent water evaporation). Shake the tube every 5 minutes to mix thoroughly. Remove the tube and let it cool. Dilute to 5 mL with deionized water, mix well. Centrifuge at 8,000 g, 25°C for 10 minutes. Collect the supernatant for detection.Note: For protein concentration determination, Aladdin BCA Protein Quantification Kit (B665595) or Ready-to-Use BCA Protein Quantification Kit (R1491648) are recommended.4. Assay Steps4.1 Instrument Preparation: Preheat the microplate reader or visible spectrophotometer for at least 30 minutes. Set the wavelength to 620 nm. For visible spectrophotometers, zero the instrument with deionized water.4.2 Sample Assay: Add reagents sequentially to EP tubes as follows:ReagentBlank Tube (µL)Standard Tube (µL)Test Tube (µL)Sample0060Standard0600Deionized Water6000Chromogen2402402404.3 Mix well. Incubate in a 95°C water bath for 10 minutes (cap tightly to prevent evaporation). Cool. Transfer 200 µL to a 96-well plate or micro glass cuvette. Measure the absorbance at 620 nm, recorded as A blank, A standard, and A test. Calculate ΔA test = A test - A blank and ΔA standard = A standard - A blank. Note: It is recommended to perform preliminary experiments with 2-3 samples expected to have significant differences before formal testing. If ΔA test is less than 0.001, appropriately increase the sample amount. If ΔA test is greater than 1.5, dilute the sample further with deionized water (multiply the result by the dilution factor) or reduce the amount of sample used for extraction. 5. Result 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. 5.1 Standard Curve Plotting Plot the standard curve with standard concentration as the y-axis and ΔA standard as the x-axis (using concentration as the y-axis facilitates calculation). Substitute ΔA test into x to calculate y (mg/mL). 5.2 Sample Glycogen Content Calculation (1) Based on sample mass: Glycogen (mg/g) = 1.11 × (y × V sample ) ÷ (W × V sample ÷ V total ) × n = 5.55 × y ÷ W × n (2) Based on sample protein concentration: Glycogen (mg/mg prot) = 1.11 × (y × V sample ) ÷ (V sample × Cpr) × n = 1.11 × y ÷ Cpr × n (3) Based on bacterial or cell count: Glycogen (mg/10⁴) = 1.11 × (y × V sample ) ÷ (Bacterial or Cell Count × V sample ÷ V total ) × n = 5.55 × y ÷ Bacterial or Cell Count × n Parameter Description: 1.11: Constant for converting glucose content measured by this method to glycogen content (i.e., 100 µg glucose color developed with anthrone reagent is equivalent to that of 111 µg glycogen). V sample : Volume of test sample added to the reaction system, 0.06 mL. W: Sample mass, g. V total : Total volume of the sample extract, 5 mL. n: Dilution factor. Cpr: Sample protein concentration, mg/mL. Bacterial or Cell Count: In units of 10⁴ (ten thousands)6. Result PresentationTypical Standard Curve: y = 0.1746x + 0.0027, R² = 0.9961(The following data and curve are for reference only; users must establish their own standard curve based on their experiment.)Precautions1. It is recommended to perform preliminary experiments using 2-3 samples expected to have significant differences before formal testing.2. This product is for scientific research use only and is not intended for clinical diagnosis. For your safety and health, please wear a lab coat and disposable gloves during operation... Read More | Calcein AM /PI Double Staining Kitis utilized for simultaneous fluorescence staining of viable and dead cells. This kit contains Calcein-AM and Propidium Iodide (PI) solutions, which stains viable and dead cells, respectively(Fig. 1). Calcein-AM, an acetoxymethyl ester of calcein, is highly Calcein AM /PI Double Staining Kitis utilized for simultaneous fluorescence staining of viable and dead cells. This kit contains Calcein-AM and Propidium Iodide (PI) solutions, which stains viable and dead cells, respectively(Fig. 1). Calcein-AM, an acetoxymethyl ester of calcein, is highly lipophilic and cell membrane permeable. Though Calcein-AM itself is not a fluorescent molecule, the calcein generated from Calcein-AM by esterase in a viable cell emits a strong green fluorescence (excitationat 490 nm, emission at515 nm). Therefore, Calcein-AM only stains viable cells. On the other hand, PI, a nuclei staining dye, cannot pass through a viable cell membrane. It reaches the nucleus by passing through disordered areas of dead cell membrane, and intercalates with the DNA double helix of the cell to emit red fluorescence (excitation: 535 nm,emmision: 617 nm). Since both calcein and PI-DNA can be excited with 490 nm, simultaneous monitoring of viable and dead cells is possible with a fluorescence microscope. With 545 nm excitation, only dead cells can be observed (Fig. 1). Since optimal staining conditions differ from cell line to cell line, we recommend that a suitable concentration of PI and Calcein-AM be individually determined. Please note that PI is suspected to be highly carcinogenic;careful handling is required.Required Equipment and Materials:Microscope with 490 nm excitation filter and 530 nm emission filter;CO2incubator;10 µl and 200 µl adjustable pipettes, PBSSolution A (Calcein-AM);Solution B (PI) Storage Condition: -20oC ;Shipping Condition: blue ice.Application:Assay Procedure1)Add 2.5 µl Solution A and 12.5 µl Solution B to 5 ml PBS to prepare assay solution.*2)Wash the cell with PBS several times to remove residual esterase activity.3)Add 100uLof assay solution to200uL105~106CELLSsolution and incubate the mixture at 37oC for 15 min.4)Detect fluorescence using a fluorescence mircoscope with 490 nm excitationfor simultaneous monitoring of viable and dead cells.With 545 nm excitation, only dead cells can be observed.*The following steps may be necessary tooptimizethe suitable concentration of each reagent:1)Prepare dead cells by 10 min incubation in 0.1% saponin or 0.1-0.5% digitonin or by 30 min incubation in 70% ethanol.2)Stain dead cells with 0.1-10 µM PI solution to find a PI concentration that stains the nucleus only, not the cytosol.3)Stain dead cells with 0.1-10 µM Calcein-AM solution to find a Calcein-AM concentration that does not stain the cytosol. Then stainviable cells with that Calcein-AM solution to check whether the viable cell can be stained... Read More | Format:2-ComponentEnzyme:Horseradish peroxidase | Inquire | Product contentY666144Component50 TStorageY666144ABuffer P115 mLRTY666144BBuffer P215 mLRTY666144CBuffer N320 mLRTY666144DBuffer PS15 mLRTY666144EBuffer PB10 mLRTY666144FBuffer PW (concentrate)10 mLRTY666144GBuffer EB10 mLRTY666144HGlass Beads2 gRTY666144IRNase A (10mg/mL)150 µLRTY666144JSpin Product contentY666144Component50 TStorageY666144ABuffer P115 mLRTY666144BBuffer P215 mLRTY666144CBuffer N320 mLRTY666144DBuffer PS15 mLRTY666144EBuffer PB10 mLRTY666144FBuffer PW (concentrate)10 mLRTY666144GBuffer EB10 mLRTY666144HGlass Beads2 gRTY666144IRNase A (10mg/mL)150 µLRTY666144JSpin Columns DM with Collection Tubes50 setsRTProductsThis kit is improved on the basis of common alkaline lysis method, the glass beads can effectively break the yeast cell wall, the new silica matrix membrane and buffer system can efficiently and specifically bind the plasmid DNA, and at the same time can maximize the removal of proteins and other impurities, the whole process is convenient and fast, no need to use toxic and harmful reagents, and can be processed at the same time for multiple samples. In addition to yeast cells, it can also be used in E. coli. Plasmid DNA extracted with this kit can be used in various molecular biology experiments, such as ligation, transformation, sequencing and library screening.Self-contained reagents: β-mercaptoethanol, anhydrous ethanol.Pre-experiment Preparation and Important Notes1. All components can be stably stored in dry, room temperature (15-30℃) environment for 1 year, the adsorption column can be stored at 2-8℃ for a longer period of time, and Buffer P1 with RNase A can be stably stored at 2-8℃ for 6 months.2. Before the first use, add all the RNase A solution to Buffer P1, mix well, and store at 2-8℃.3. Anhydrous ethanol should be added to Buffer PW before first use according to the instructions on the reagent bottle label.4. Before use, please check whether Buffer P2 and Buffer N3 are crystallized or precipitated. If there is any crystallization or precipitation phenomenon, it can be clarified by taking a water bath at 37℃ for a few minutes to restore the clarity.5. Be careful not to touch Buffer P2 and Buffer N3 directly, and tighten the lid immediately after use.6. The amount of plasmid extracted is related to the yeast strain, plasmid copy number, culture conditions, etc. Usually, yeast plasmid copy number is very low, which is difficult to be detected by electrophoresis or spectrophotometer method.Procedure1. Take 1-5 ml of yeast culture (maximum 5×107 yeast cells, generally for Saccharomyces cerevisiae OD = 1.0, equivalent to 1-2×107 cells/ml) and add it to a centrifuge tube (self-provided), centrifuge for 30 seconds at 12,000 rpm (~13,400×g), collect the bacterial precipitate, and aspirate as much as possible to discard the supernatant.2. Add 250µl Buffer P1 to the bacterium (please check if RNase A has been added first) and resuspend the precipitate.3. Add 40mg of Glass Beads to the above mixture and vortex and shake for 10 minutes.4. Add 250 µl of Buffer P2 to the centrifuge tube, mix gently by turning up and down 6-8 times, and let stand at room temperature for 5-10 minutes, at which time the bacterial solution should become clear and viscous.Note: Mix gently, do not shake violently, so as not to interrupt the genomic DNA, resulting in genomic DNA fragments mixed in the extracted plasmid. If the solution does not become clear, it suggests that the amount of bacteria may be too large and the lysis is not complete, and the amount of bacteria should be reduced.5. Add 350 µl of Buffer N3 to the centrifuge tube and immediately mix gently up and down 6-8 times, at which point a white flocculent precipitate appears, and centrifuge at 12,000 rpm for 20 minutes.Note: Buffer N3 should be mixed immediately after addition to avoid localized precipitation.6. Column Equilibration: Add 200 µl of Buffer PS to the Spin Columns DM in the collection tube, 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.7. Add the supernatant from step 5 to the adsorbent column that has been loaded into the collection tube, taking care not to aspirate the precipitate.Note: The maximum volume of the adsorption column is 750 µl, and the solution is passed through the column in 2 times.8. Centrifuge at 12,000 rpm for 1 minute, pour off the waste liquid in the collection tube and place the adsorption column back into the collection tube.9. Add 150 µl Buffer PB 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.10. Add 750 µl Buffer PW to the adsorption column (please check that anhydrous ethanol has been added first), centrifuge at 12,000 rpm for 1 minute, and pour off the waste liquid in the collection tube.11. Place the column back into the recovery collection tube and centrifuge at 12,000 rpm for 2 minutes, pouring off the waste liquid. Leave the column at room temperature for several minutes to dry thoroughly.Note: The purpose of this step is to remove residual ethanol from the adsorption column; ethanol residue can interfere with subsequent enzymatic reactions (digestion, PCR, etc.).12. Place the adsorbent column in a new centrifuge tube, add 50-100 µl of Buffer EB to the center of the adsorbent membrane dropwise, let it stand at room temperature for a few minutes, centrifuge at 13,000 rpm for 1 minute, and collect the plasmid solution into the centrifuge tube. Store the plasmid at -20°C.Attention:1) To increase the recovery efficiency of the plasmid, the resulting solution can be reintroduced into the adsorbent column, left at room temperature for a few minutes, centrifuged at 13,000 rpm for 1 minute, and the plasmid solution collected into a centrifuge tube.2) When the plasmid copy number is low or >10 kb, Buffer EB is preheated at 65-70°C in a water bath, which can increase the extraction efficiency.3) Usually yeast plasmids have very low copy number and are difficult to detect by electrophoresis or spectrophotometry. If the extracted plasmid is to be used in the next step of the experiment, it is usually recommended to use 1-5µl of the plasmid as PCR template, and 5-10µl of the plasmid for transformation of E. coli.4) Commercial high transformation efficiency receptor cells should be used for transformation of E. coli... Read More |