A Nucleic Acid Extrator is an instrument specially used to extract nucleic acid molecules from biological samples. It can separate and purify DNA or RNA in cells or tissues for subsequent experimental operations or analysis. The working principle of the Dna Nucleic Acid Extrator is based on processes such as cell lysis, protein precipitation, and nucleic acid separation. First, the sample undergoes cell lysis, which ruptures the cell and nuclear membranes and releases the cell contents. Nucleic acid molecules are then purified by adding reagents such as protease to remove proteins and other organic matter from the sample. Finally, the purified nucleic acid molecules are separated from the solution through techniques such as centrifugation. The nucleic acid extraction instrument has the characteristics of high efficiency, automation and accuracy. Automated Nucleic Acid Extrator can process multiple samples in a short time and can extract nucleic acid molecules in the samples with high purity. In addition, it can also adapt to different types of samples and experimental operations of different scales, and has a certain degree of flexibility. Nucleic acid extraction instruments are widely used in fields such as molecular biology, genomics, and medical research. It provides scientific researchers with an efficient and reliable way to obtain pure nucleic acid molecules, and provides reliable prerequisites for subsequent experimental

Real-Time PCR Instrument offer several advantages compared to conventional PCR instruments. Some of the key advantages include: 1. Real-Time Monitoring: Real-time PCR instruments allow for the continuous monitoring of the amplification process as it happens. This means that amplification data can be collected throughout the entire cycling process, providing valuable insights into the kinetics of the reaction. It allows researchers to analyze and interpret the results in real-time, saving time and effort. 2. Quantification: Real-Time PCR instruments enable accurate quantification of the target DNA or RNA molecules in the sample. By using fluorescent dyes or probes that specifically bind to the amplified product, the instruments can measure the fluorescence signal in real-time and correlate it with the initial amount of the target molecule, allowing for precise quantification. 3. Sensitivity and Specificity: Real-time PCR instruments offer excellent sensitivity, allowing detection of very low levels of target molecules. They also provide high specificity, as the amplification and detection can be designed to target specific sequences, minimizing the chance of nonspecific amplification or detection of irrelevant molecules. 4. Speed: Real-time PCR instruments typically offer rapid cycling times, allowing for faster results compared to traditional PCR instruments. This is especially useful when handling large sample numbers or when time is a critical factor. PCR System Displa

DNA Analyzer Display The Classic 1616 Life Science Gene Test Blood Gene Count Analyzerr offers several advantages that make it a valuable tool in the field of life science research. 1. Accuracy: The analyzer provides highly accurate and reliable results, ensuring that the data collected is of high quality. This is crucial in life science research where precise measurements are required for accurate analysis and interpretation. 2. Speed and Efficiency: The Classic 1616 analyzer is designed to deliver quick results, allowing researchers to analyze a large number of samples in a short period of time. This saves time and increases productivity, enabling researchers to conduct experiments and analysis more efficiently. 3. Versatility: This analyzer is capable of analyzing a wide range of blood parameters, making it a versatile tool in life science research. It can measure various parameters such as blood cell counts, hemoglobin levels, and blood chemistry, providing a comprehensive analysis of blood samples. 4. User-friendly Interface: The analyzer features a user-friendly interface that is easy to operate, even for those with limited technical expertise. This reduces the learning curve and enables researchers to quickly adapt to the system, allowing them to focus more on the research itself.

The specifications of drug testing equipment can vary depending on the specific type of testing being conducted, as well as the intended use and industry requirements. However, here are some common specifications that are often considered: 1. Testing Method: Drug testing equipment can utilize various testing methods, such as urine analysis, saliva analysis, blood analysis, or hair analysis. Each method has its own set of specifications, including the sample collection process, detection window, and sensitivity to different drug types. 2. Analytes Detected: Drugs Instrument equipment is designed to detect specific substances or classes of drugs. The specification will include a list of the substances that the equipment is capable of detecting, such as commonly abused drugs like marijuana, cocaine, amphetamines, opioids, benzodiazepines, or prescription medications. Drug Testing Equipment Display 3. Sensitivity: Sensitivity refers to the ability of the drug testing equipment to accurately detect low concentrations of drugs in the specimen. Sensitivity is typically expressed as the cut-off level, which is the minimum amount of a drug that can be detected. Lower cut-off levels indicate higher sensitivity. 4. Testing Time: The testing time i

The Sanger sequencing instrument is a piece of laboratory equipment used for DNA sequencing. It is named after Frederick Sanger, the British scientist who invented the Sanger sequencing method, also known as the chain termination method. The Sanger sequencing instrument automates the sequencing process by performing the various steps required for DNA sequencing, such as DNA amplification, DNA denaturation, primer annealing, and extension. It allows researchers to determine the exact order of nucleotides in a DNA molecule, which is crucial for many biological studies, including genetic research, disease diagnosis, and forensic investigations. The instrument is equipped with a laser and fluorescent detectors to detect the different colored fluorophores attached to the terminating nucleotides during the sequencing reaction. These fluorophores emit light at different wavelengths when excited by the laser, and the instrument reads the emitted light to determine the identity of the nucleotide at each position in the DNA sequence. The Genetic Analyzer Forensic Dna Instrument is typically coupled with automated capillary electrophoresis, which separates the DNA fragments based on their size and charge. After sequencing, the instrument analyzes the electropherogram, a graphical representation of the DNA sequence, to determine the order of nucleotides. Molecular Biolab Equipment Display

A DNA analyzer is a device or instrument used to analyze and sequence DNA molecules. It is an essential tool in molecular biology and genetics research, forensic analysis, medical diagnostics, and other fields where the study of DNA is important. A DNA analyzer typically includes components such as a thermal cycler, which facilitates the polymerase chain reaction (PCR) to amplify specific DNA sequences, and a detection system to identify and measure the amplified DNA fragments. It may also have a capillary electrophoresis system or a sequencing module to determine the order of nucleotides in the DNA molecule. The analyzer's main function is to process DNA samples using various techniques, including fluorescence-based methods, enzymatic reactions, DNA sequencing, and fragment analysis. It provides researchers with information about the genetic makeup of an organism or individual, allowing them to study DNA variations, mutations, genetic markers, and other molecular characteristics. DNA analyzers come in different sizes and configurations. Some are large and stationary, requiring a dedicated laboratory space, while others are portable, allowing for on-site analysis in remote locations or field settings. Advances in technology have also led to the development of high-throughput DNA analyzers, capable of processing a large number of samples simultaneously, significantly increasing throughput and efficiency.

Recently, Mr. Wen, the Overseas Market Director of Nanjing Superyears Gene Technology Co., Ltd., and his delegation visited the Bangladesh Institute of Nuclear Agriculture (BINA). The purpose of this visit was to explore opportunities for collaboration in the field of agricultural technology and establish a strategic cooperation agreement. Bangladesh, being an agricultural powerhouse, faces significant challenges in terms of food security, improving agricultural productivity, and enhancing the quality of agricultural products. Nanjing Superyears Gene Technology Co., Ltd., as a leading genetic technology company in China, has been committed to agricultural technology innovation and addressing global agricultural challenges. Therefore, the collaboration between the two parties holds great potential for mutual complementarity and can contribute to the sustainable development of agriculture in Bangladesh. During the visit, Mr. Wen engaged in in-depth discussions and cooperation negotiations with the leadership and research teams of BINA. Both parties discussed key issues in the field of agriculture, particularly opportunities for collaboration in the development of new crop varieties, crop protection, and adaptation to agricultural climate change. It was mutually recognized that by combining the advanced technologies of Nanjing Superyears Gene Technology Co., Ltd. with the rich agricultural experience of BINA, innovative research can be conducted, and solutions can be provided to enhance Bangladesh's agricultural production capacity and food security.

As a supplier, we are excited to introduce our range of advanced equipment for Biochemical Analysis, Gene Sequencing, and Forensic Laboratories: At Superyears, we understand the critical role that cutting-edge technology plays in advancing research, diagnostics, and analysis in the fields of genetics, biochemistry, and forensics. That's why we offer a comprehensive range of state-of-the-art equipment specifically designed to meet the needs of Biochemical Analyzers, Gene Sequencers, and Forensic Laboratories. Our Biochemical Analyzers are equipped with the latest advancements in biochemical analysis technology. They provide accurate and rapid results for a wide range of applications, including clinical diagnostics, pharmacology, food safety, and environmental testing. With user-friendly interfaces and advanced automation features, these analyzers streamline the analysis process, saving both time and resources. In the field of gene sequencing and genomics, our Gene Sequencers are at the forefront of innovation. These sequencers utilize next-generation sequencing (NGS) technologies, delivering high-throughput, cost-effective, and accurate DNA and RNA sequencing results. Our gene sequencers are suitable for various applications, including human genetic research, agriculture and livestock breeding, microbial genomics, and personalized medicine. For forensic laboratories, we offer a range of specialized equipment tailored to meet the unique requirements of forensic analysis. Our forensic laboratory solutions include DNA extraction systems, DNA quantification and documentation instruments, genetic analyzers, and software for DNA profiling. These tools

The Sanger sequencing machine is a valuable tool in the field of molecular diagnosis. It is widely used for DNA sequencing, genotyping, and other genetic analysis applications. Here are some common uses and benefits of using a Sanger sequencing machine in molecular diagnosis: DNA sequencing: The Sanger sequencing machine is commonly used for DNA sequencing, which is crucial for understanding genetic variations and mutations. It helps in identifying the sequence of nucleotides in a DNA molecule, providing insights into genetic disorders, infectious diseases, and other genetic conditions. Genotyping: Sanger sequencing is widely used for genotyping, which involves analyzing variations in specific genes or regions of DNA. This allows for the identification of genetic markers associated with diseases or drug response, aiding in personalized medicine and targeted therapies. Identification of mutations: Sanger sequencing helps in detecting and characterizing mutations in DNA. It enables the identification of point mutations, insertions, deletions, or rearrangements in genes or regulatory regions. This information is critical in diagnosing genetic diseases and understanding disease mechanisms. Validation of genetic tests: Sanger sequencing is often used to validate the results of other genetic tests. It can confirm the presence or absence of specific mutations or variations detected by alternative methods, ensuring the accuracy and reliability of

The usage of a 5-channel thermocycler PCR real-time qPCR PCR involves the following steps: 1. Sample preparation: Extract DNA or RNA from the biological sample of interest. This can be done using various methods such as phenol-chloroform extraction, column-based purification, or magnetic bead-based purification. 2. Primer and probe design: Design specific primers and probes that will bind to the target sequence of interest. These primers and probes are typically designed using software tools that consider factors like melting temperature, GC content, and specificity. 3. PCR reaction setup: Prepare the PCR reaction mix by combining the DNA or RNA template, primers, probes, and other necessary components such as nucleotides, buffer, and polymerase. The reaction mix is then distributed into the wells of the PCR plate. 4. Thermocycling: Place the PCR plate into the 5-channel thermocycler, which can accommodate multiple samples simultaneously. The thermocycler will then go through a series of temperature cycles, including denaturation, annealing, and extension, to amplify the target DNA or RNA sequence. 5. Real-time monitoring: The 5-channel thermocycler is equipped with fluorescence detection capabilities. During each temperature cycle, the thermocycler detects the fluorescence emitted by the labeled probe as it binds to the amplified DNA or RNA. This allows for real-t

Thermocycler: A thermocycler is a laboratory instrument used to amplify DNA or RNA through the polymerase chain reaction (PCR) technique. It provides precise temperature control to facilitate the cycling of temperature required for DNA denaturation, primer annealing, and DNA extension. PCR (Polymerase Chain Reaction): PCR is a technique used to amplify a specific segment of DNA or RNA. It involves repeated cycles of heating and cooling to denature the DNA, anneal primers, and extend DNA strands using a DNA polymerase enzyme. PCR is widely used in various applications, including genetic research, diagnostics, forensics, and biotechnology. Real-Time PCR (qPCR): Real-time PCR, also known as quantitative PCR or qPCR, is a variation of PCR that allows for the quantification of DNA or RNA in real-time. It uses fluorescent dyes or probes to monitor the amplification of DNA or RNA during each cycle of PCR. Real-time PCR provides accurate and quantitative measurements of gene expression, viral load, or genetic variations. PCR Analyzer: A PCR analyzer is a device or instrument used to analyze the results of PCR reactions. It can detect and measure the amplified DNA or RNA products generated during PCR. PCR analyzers often include fluorescence detection systems, software for data analysis, and various features to automate and streamline the PCR analysis process. They are commonly used in research laboratories, clinical diagnostics, and other molecular biology applications.

Thermal cycler real-time PCR machines are used in various applications in research, clinical diagnostics, and forensic science. Some of the common applications of this machine are: 1. Gene expression analysis: Real-time PCR is used to measure the expression of genes in different samples. This helps in understanding the regulation of genes and their role in various diseases. 2. Pathogen detection: Real-time PCR is used to detect the presence of pathogens such as viruses, bacteria, and fungi in clinical samples. This helps in diagnosing infectious diseases. 3. Quantitative analysis: Real-time PCR is used to quantify the amount of DNA or RNA in a sample. This helps in determining the copy number of a gene or the viral load in a patient sample. 4. Mutation detection: Real-time PCR is used to detect mutations in genes that are associated with various diseases such as cancer. This helps in early diagnosis and treatment of the disease. 5. Forensic analysis: Real-time PCR is used in forensic science to analyze DNA samples from crime scenes. This helps in identifying suspects and solving crimes. Overall, the thermal cycler real-time PCR machine is a versatile tool that has revolutionized various fields of research a

Genetic testing equipment for STR (short tandem repeat) analysis is a powerful tool used in forensic science, paternity testing, and genetic research. Here are some of the features of genetic testing equipment for STR: 1. High accuracy: STR analysis equipment is highly accurate and reliable. It can detect even the smallest differences in DNA sequences, making it ideal for forensic investigations and paternity testing. 2. Automated processing: Many modern STR analysis systems are fully automated, which reduces the risk of human error and increases efficiency. The automation also allows for high-throughput processing of samples. 3. Multiplexing: STR analysis equipment can analyze multiple STR loci simultaneously, which saves time and resources. Multiplexing also increases the accuracy of the analysis, as more data points can be collected. 4. User-friendly software: STR analysis equipment often comes with user-friendly software that allows for easy data analysis and interpretation. The software can also generate reports and provide statistical analysis of the results. 5. Non-invasive sampling: Some STR analysis equipment allows for non-invasive sampling, such as using saliva or buccal swabs. This makes the testing process less invasive and more comfortable for the patient. 6. Portable: Some STR analysis equipment is portable, which allows for on-site testing in remote locations. This is particularly useful in forensic investigations where time is of the essence.

Superyears has conducted a free nucleic acid test for all employees: Yesterday afternoon, the Nanjing Epidemic Prevention and Control Press Conference announced that 17 positive cases of COVID-19 had been detected at Nanjing Lukou Airport. As a result, Jiangning District needed to quickly complete nucleic acid testing for more than 1.9 million pe