| Description | Triglycerides (TG), also known as triacylglycerols, are fat molecules formed from three long-chain fatty acids and glycerol. They are the most abundant lipids in the human body. Most tissues can utilize the breakdown products of triglycerides for energy. Simultaneously, tissues like the liver and Triglycerides (TG), also known as triacylglycerols, are fat molecules formed from three long-chain fatty acids and glycerol. They are the most abundant lipids in the human body. Most tissues can utilize the breakdown products of triglycerides for energy. Simultaneously, tissues like the liver and adipose tissue can synthesize triglycerides. The enzymatic method for measuring TG is commonly used in biochemical assays due to its characteristics: 1. High sensitivity, accuracy, and precision; 2. Use of mild reaction conditions; 3. Simple operation; 4. Suitable for semi-automatic biochemical analyzers.Detection Principle: Triglycerides are hydrolyzed by lipoprotein lipase (LPL) into glycerol and free fatty acids. Glycerol is then phosphorylated by glycerol kinase (GK) and adenosine triphosphate (ATP) to form glycerol-3-phosphate (G-3-P). G-3-P is subsequently oxidized by glycerol-3-phosphate oxidase (GPO), producing hydrogen peroxide. The hydrogen peroxide, in the presence of peroxidase (POD), 4-aminoantipyrine (4-AAP), and phenol (collectively known as PAP), reacts to form a red-colored quinoneimine dye (Trinder reaction). The quinoneimine dye has a maximum absorption at 510 nm. The absorbance is directly proportional to the triglyceride concentration in the sample and can be measured using a microplate reader between 500-520 nm.This kit is used for the quantitative determination of triglyceride content in serum, cells, tissues, and other samples from humans or animals. This kit is intended for research use only and is not suitable for clinical diagnosis or other purposes.Component100TStorageBuffer Solution24 mL2-8℃. Store in the dark.Enzyme Reagent6 mL2-8℃. Store in the dark.Glycerol Standard (1.7 mmol/L)1 mL2-8℃User-Prepared Instruments and ReagentsddH₂O, Physiological Saline or PBSCentrifuge tubes or small test tubes, Water bath or incubatorMicroplate reader, 96-well plate, Semi-automatic biochemical analyzerExperimental Procedure1. Sample Preparation1.1 Serum, Plasma, Cerebrospinal Fluid SamplesSerum or plasma separated from the test sample should not be hemolyzed. Assay directly. If the concentration exceeds the linear range, dilute with physiological saline before assaying.1.2 Cell Samples(1) Take an appropriate amount of cells (generally recommended >10⁶), centrifuge at 1000 g for 10 min, discard the supernatant, keep the pellet.(2) Wash the pellet 1-2 times with PBS or physiological saline, centrifuge at 1000 g for 10 min, discard the supernatant, keep the pellet.(3) Add 200-300 µL of PBS or physiological saline to homogenize. Sonicate the cells on ice (power 300W, pulse 3-5s, interval 30s, repeat 3-5 times). Alternatively, homogenize manually. Do not centrifuge the prepared homogenate. Alternatively, lyse with 1-2% Triton X-100 on ice for 30-60 min. Do not centrifuge the prepared lysate.1.3 Tissue SamplesAccurately weigh an appropriate amount of tissue sample. Add physiological saline or PBS at a mass (g) to volume (mL) ratio of 1:9. Homogenize manually or mechanically on ice. Centrifuge at 2500-3000 g for 10 min. Collect the supernatant for assay.2. Preparation of GPO-PAP Working SolutionBefore use, mix the Buffer Solution and Enzyme Reagent at a 4:1 volume ratio. Mix well. Store at 4°C.3. TG Assay Steps using Microplate Reader3.1 Add reagents sequentially to the 96-well plate according to the table below. Mix thoroughly and incubate at 37°C in a water bath or incubator for 10 minutes.Reagent (µL)Blank WellStandard WellTest WellddH2O2.5//Glycerol Standard (1.7 mmol/L)/2.5/Test Sample//2.5GPO-PAP Working Solution2502502503.2 Measure the absorbance between 500-520 nm using the microplate reader. Zero the instrument with the blank well, then read the absorbance of the standard well and all test wells.4. TG Assay Steps using Semi-Automatic Biochemical Analyzer4.1 Instrument Parameter Settings:WavelengthTemperatureDelay TimeMeasurement TimeReagent BlankReaction TypeAspiration Volume510-550nm37℃2s2sYesEndpoint800µL4.2 Add reagents sequentially to tubes according to the table below. Mix thoroughly and incubate at 37°C in a water bath for 10 minutes.Reagent (µL)Blank TubeStandard TubeTest TubeddH2O10//Glycerol Standard (1.7 mmol/L)/10/Test Sample//10GPO-PAP Working Solution1000100010004.3 Zero the instrument with the blank tube, then read the absorbance of the standard tube and all test tubes.5. Calculation Formula5.1 For serum, plasma, and other liquid samples (Blank zeroed):TG (mmol/L) = (Absorbance of Test Well/Tube / Absorbance of Standard Well/Tube) × 1.7 mmol/L5.2 For cell, tissue, and other samples (Blank zeroed):TG (mmol/g prot) = (Absorbance of Test Well/Tube / Absorbance of Standard Well/Tube) × 1.7 mmol/L / Sample Protein Concentration (mg/mL)Reference Interval (Healthy Adults)Desirable range: < 1.7 mmol/L (< 150 mg/dL)Borderline high: 1.7 – 2.25 mmol/L (150 – 199 mg/dL)High: 2.26 – 5.64 mmol/L (200 – 499 mg/dL)Very high: ≥ 5.65 mmol/L (≥ 500 mg/dL)Precautions1. Avoid repeated freeze-thaw cycles for the low-temperature reagents mentioned above to prevent inactivation or decreased efficiency.2. The GPO-PAP Working Solution should be prepared immediately before use and is not suitable for long-term storage at 4°C.3. This method can be directly used to detect TG content in cerebrospinal fluid but cannot directly detect TG in urine, as untreated urine contains reducing substances that interfere with the peroxidase reaction.4. If test samples cannot be assayed immediately, they should be stored at 2-8°C and are stable for 3 days.5. The linear range of this method is up to 9.0 mmol/L. If the sample TG concentration is too high, results may be falsely low. Dilute the sample with physiological saline and re-assay, multiplying the result by the dilution factor.6. The working reagent should be protected from contamination by substances like glucose and cholesterol.7. The reagent is susceptible to oxidation by air, turning red. A blank measurement is necessary.8. For your safety and health, please wear a lab coat and disposable gloves during operation.9.Use the reagents as soon as possible after opening to prevent affecting subsequent experimental results... Read More | Description:Acetylcholinesterases (AChEs) are enzymes that hydrolyze the neurotransmitter acetylcholine (ACh) to acetate and choline. AChE is located at the synaptic cleft and functions to terminate synaptic transmission by catalyzing the breakdown of ACh allowing cholinergic neurons to Description:Acetylcholinesterases (AChEs) are enzymes that hydrolyze the neurotransmitter acetylcholine (ACh) to acetate and choline. AChE is located at the synaptic cleft and functions to terminate synaptic transmission by catalyzing the breakdown of ACh allowing cholinergic neurons to return to a resting state after activation. It is also found in membranes of red blood cells, motor and sensory fibers, muscles, nerves and central and peripheral tissues. Changes in AChE activity may result from exposure to certain insecticides, which act as cholinesterase inhibitors. Inhibitors of AChE are also used to treat certain conditions such as dementia.Acetylcholinesterase activity assay kit has been used to determine the activity of acetylcholinesterase in a rat organophosphate model and in brain tissue homogenates.Principle:Acetylcholinesterase can catalyze the hydrolysis of acetylcholine to choline, and the reaction of choline with disulfide p-nitrobenzoic acid to produce 5-merhydryl-nitrobenzoic acid (TNB). The product has a characteristic absorption peak at 412 nm, and the activity of acetylcholinesterase can be characterized by the change of light absorption valueThe Dilution Calculator EquationConcentration (start)xVolume (start)= Concentration (final)× Volume (final)This equation is commonly abbreviated as: C1V1 = C2V2... Read More | Products B669892Component50 TStorageB669892ABuffer RCL3×260 mL2-8℃B669892BBuffer GR25 mLRTB669892CBuffer GL25 mLRTB669892DBuffer GW1 (concentrate)13 mLRTB669892EBuffer GW2 (concentrate)15 mLRTB669892FBuffer GE15 mLRTB669892GProteinase K50 mgRTB669892HProteinase K Storage Buffer5 Products B669892Component50 TStorageB669892ABuffer RCL3×260 mL2-8℃B669892BBuffer GR25 mLRTB669892CBuffer GL25 mLRTB669892DBuffer GW1 (concentrate)13 mLRTB669892EBuffer GW2 (concentrate)15 mLRTB669892FBuffer GE15 mLRTB669892GProteinase K50 mgRTB669892HProteinase K Storage Buffer5 mLRTB669892ISpin Columns DL with Collection Tubes50 setsRTProductsThis kit is suitable for the extraction of total DNA, including genomic DNA, mitochondrial DNA and viral DNA, from fresh or frozen whole blood (blood samplestreated with anticoagulants such as citrate, EDTA or heparin), plasma, serum, haematocrit brown and yellow layers, bone marrow, cell-free body fluids, etc. Theproduct can process 1-5 ml of whole blood, and can be purified to obtain sizes rangingfrom 100bp to 50kb. The purified DNA is of high yield and good quality, with maximumremoval of proteins, pigments, lipids and other inhibitory impurities, and can bedirectly used in PCR, fluorescence quantitative PCR, enzyme digestion and SouthernBlot.Self-contained reagent: anhydrous ethanol.Pre-experiment Preparation and Important Notes1. Add 5ml Proteinase K Storage Buffer to Proteinase K to dissolve it, and storeit at -20℃. Do not leave the prepared Proteinase K at room temperature for a longtime, and avoid repeated freezing and thawing to avoid affecting its activity.2. Repeated freezing and thawing of the sample should be avoided, as this may resultin smaller DNA fragments and a decrease in the amount of extracted DNA. 3.This kit can extract up to 1-5 ml of whole blood samples, if you need to extracta large number of blood samples, please use the blood genome non-column extractionkit. 4. Anhydrous ethanol should be added to Buffer GW1 and Buffer GW2 according to theinstructions on the label of the reagent bottle before first use.5. Please check Buffer GL for crystallization or precipitation before use, if thereis any crystallization or precipitation, please put it in 56℃water bath to re-dissolve.6. If the downstream experiments are sensitive to RNA contamination, 4µl of DNaseFree RNase A (100mg/ml) can be added, RNase A is not provided in the kit, and canbe ordered separately from our company if needed.7. The Buffer RCL in the kit cannot be used further after turbidity.procedure1. Add 1-5 ml of blood sample to a centrifuge tube (supplied) and add 3 times thevolume of Buffer RCL and gently vortex or invert to mix.2. Centrifuge at 3000 rpm (~900 x g) for 10 minutes and carefully aspirate thesupernatant.3. Add 400 µl Buffer GR to the precipitate and resuspend the precipitate. Note: If the downstream assay is sensitive to RNA, add 4 µl of RNase A (100 mg/ml)solution, shake for 15 seconds, and leave at room temperature for 5 minutes.4. For 1-2 ml blood sample extraction, add 40µl Proteinase K to the above solutionand mix well; for 2-5 ml blood sample extraction, add 100µl Proteinase K to theabove solution and mix well.5. Add 400 µl of Buffer GL, mix upside down 15 times, and vigorously vortex andshake for at least 1 minute. Note: Do not add Proteinase K directly to Buffer GL.6. Incubate at 70°C for 10 minutes, during which time mixing was inverted severaltimes.Note: 1) If the solution is not completely clear, add appropriate amount of Proteinase K and incubate. Extend the incubation time until the solution is completely clear. 2) The yield of DNA has been maximized by 10 minutes of incubation, and continuedprolongation of the incubation time has no effect on DNA yield or purity.7. Add 400 µl of anhydrous ethanol and mix upside down 10 times. Centrifuge brieflyto concentrate the liquid on the walls and cap to the bottom of the tube.8. Add all of the solution obtained in the previous step to the Spin Columns DL inthe collection tube. If the solution cannot be added all at once, transfer it severaltimes. centrifuge at 12,000 rpm (~13,400 x g) for 1 minute, pour off the waste liquidfrom the collection tube, and put the column back into the collection tube.9. Add 500 µl of Buffer GW1 to the adsorption column (check that anhydrous ethanolis added before use), centrifuge at 12,000 rpm for 1 minute, pour off the waste liquidin the collection tube, and put the adsorption column back into the collection tube.Note: It is recommended that step 9 be repeated if the sample being extracted isthe blood genome of a species such as mice or monkeys from which hemoglobin isdifficult to remove.10. Add 500 µl Buffer GW2 to the adsorption column (check that anhydrous ethanolis added before use), centrifuge at 12,000 rpm for 1 minute, pour off the waste liquidin the collection tube, and put the adsorption column back into the collection tube.Note: Step 10 can be repeated if further DNA purity is required.11. Centrifuge at 12,000 rpm for 2 minutes and pour off the waste liquid in thecollection tube. Leave the adsorption column at room temperature for several minutesto dry thoroughly. Note: The purpose of this step is to remove residual ethanol from the adsorptioncolumn, which can interfere with subsequent enzymatic reactions (digestion, PCR,etc.)12. Place the adsorption column in a new centrifuge tube, add 50-200 µl of BufferGE or sterilized water to the middle of the adsorption column overhanging the column,leave it at room temperature for 2-5 minutes, centrifuge at 12,000 rpm for 1 minute,collect the DNA solution, and store the DNA at -20℃.Note: 1) If the downstream experiment is sensitive to pH or EDTA, you can use sterilized water for elution. The pH of the eluent has a great influence on theelution efficiency, if water is used as the eluent should ensure that its pH is7.0-8.5 (you can use NaOH to adjust the pH of the water to this range), and the elutionefficiency is not high when the pH is lower than 7.0.2) Incubation at room temperature for 5 minutes prior to centrifugation increasesyield.3) Re-elution with an additional 50-200 µl Buffer GE or sterilized water can increase the yield.4) If the final concentration of DNA is to be increased, the DNA eluate obtainedin step 12 can be re-spiked onto the adsorbent membrane and centrifuged at 12,000rpm. 1min; if the elution volume is less than 200µl, the final concentration of DNA canbe increased, but the total yield may be reduced. If the amount of DNA is less than1 µg, elution with 50 µl Buffer GE or sterilized water is recommended.5) Because DNA preserved in water is subject to acidic hydrolysis, for long-termstorage, it is recommended that it be eluted with Buffer GE and stored at -20℃... Read More | Ketone bodies, 3-hydroxybutyric acid (BOH) and acetoacetic acid (AcAc), are produced in the liver primarily from oxidation of fatty acids, and are normally present at low concentrations in urine and blood. Increased ketone concentrations in the blood may lead to metabolic acidosis, which has been Ketone bodies, 3-hydroxybutyric acid (BOH) and acetoacetic acid (AcAc), are produced in the liver primarily from oxidation of fatty acids, and are normally present at low concentrations in urine and blood. Increased ketone concentrations in the blood may lead to metabolic acidosis, which has been associated with diabetes, childhood hypoglycemia, growth hormone deficiency, alcohol or salicylate intoxication, and inborn errors of metabolism.Ketone Body Assay has been used to measure the release of ketone bodies in the human liver cancer cell line HepG2 culture medium... 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 |