Congratulations! Nanjing Superyears Gene Technology Co., Ltd. won the Police Equipment Science and Technology Innovation Award held by the organizing committee of the 18th CHINA PUBLIC SECURITY EXPO (CPSE 2020-2021) #technology #innovation

Superyears 96-channel genetic analyzer achieved mass production. The Honor 1696 genetic analyzer can load up to 16 plates simultaneously, and the maximum throughput can achieve 3936 samples per day. Compatible with mainstream reagent consumables. Chinese and English operation interface, the operation process is more concise. Easy To Interact And Handy To Operate.

On 2nd December 2021, Nanjing Superyears Gene Technology Co., Ltd. delivered and debugged the brand-new product Classic 116 gene analyzer for the Second hospital of Shanxi Medical University formally and successfully. CLASSIC series (Classic 116) DNA sequence, known as the gold standard in the DNA testing industry, is our main product. The Classic 116 capillary electrophoreses gene analyzer supported with 16-Channel technology approved by CE, NMPA (Jiangsu Device Registration Approval No. 20202221294). The product provides a customized software interface that is easy to interact handy to operate, which can reflect the real-time operating status of the instrument, the use of consumables, and system maintenance information. Therefore, it can play an essential role in basic molecular genetic research. The Classic 116 genetic analyzer is also a handy tool, practically a work staple in various departments in the hospital, such as Gynecolog

A Thermal Cycler Real Time PCR System machine is a powerful tool used in various fields like molecular biology, genetics, microbiology, and medical diagnostics. Here are some common applications of a Thermal Cycler Real Time PCR machine: 1. **Gene Expression Analysis**: It is used to quantify gene expression levels in samples, providing insights into how genes are regulated under different conditions or in different tissues. 2. **Pathogen Detection**: Real-Time PCR can rapidly detect the presence of pathogens such as bacteria, viruses, and fungi in biological samples, making it invaluable in diagnostic microbiology. 3. **Genotyping and Mutation Analysis**: By detecting specific DNA sequences, this technology is used for genotyping studies to identify genetic variations and mutations associated with diseases or other traits. 4. **Viral Load Quantification**: Real Time PCR is often employed to measure the amount of viral RNA or DNA present in clinical samples, aiding in the monitoring and management of viral infections like HIV, hepatitis, and COVID-19. 5. **Pharmacogenomics**: It helps in studying how genetic variations in patients affect drug metabolism and response, assisting in personalized medicine approaches. 6. **Environmental Analysis**: Real Time PCR can be used to

DNA Analyzer Display Genetic Analyzer, gene sequencing, and MLPA (Multiplex Ligation-dependent Probe Amplification) are all crucial tools in genetic analysis, each serving distinct purposes. 1. **Genetic Analyzer:** A genetic analyzer is an instrument used to analyze DNA, RNA, and proteins. It's used in various fields such as molecular biology, medical diagnostics, and forensic science. These analyzers are instrumental in deciphering the genetic code, identifying mutations, and unraveling genetic variations. 2. **Gene Sequencing:** Gene sequencing is the process of determining the precise order of nucleotides within a DNA molecule. This technology is fundamental for understanding genetic variation, identifying disease-causing mutations, and studying the genetic basis of traits and diseases. It has applications in fields such as medicine, agriculture, and evolutionary biology. 3. **MLPA (Multiplex Ligation-dependent Probe Amplification):** MLPA is a method used to detect copy number changes and is particularly applicable in detecting deletions or duplications of one or more exons in specific genes. It can be especially useful for identifying genetic disorders and in cancer research, where the duplication or deletion of certain genes can be indicative of the presence or progression of the disease. In combination, these PCR Syste

PCR System Display The General 2215 Real Time PCR Machine, like other real-time PCR machines, is a versatile tool used in molecular biology for the amplification and quantification of specific DNA sequences. Here's a general guide on how to use it: 1. **Preparation**: - Ensure the machine is connected to a power source and turned on. - Program the machine using the appropriate software for your specific PCR assay. 2. **Sample Preparation**: - Prepare your DNA or RNA samples by isolating the genetic material of interest using standard molecular biology techniques. - Dilute your samples to ensure that the concentration falls within the linear range of the assay. 3. **Primer and Probe Design**: - Design and procure the specific primers and probes for the target DNA or RNA sequence. Ensure that these are specific to the sequence you wish to amplify. 4. **Setting Up the PCR Plate**: - Add your samples and controls to the wells of the PCR plate according to the designed assay, taking care to

RT-qPCR Instrument Display Real-time quantitative polymerase chain reaction (PCR System) is a powerful technique used in biochemistry and molecular biology to detect and quantify nucleic acids (DNA or RNA) in real time during the PCR process. This technique is widely used in various research fields, including genetics, microbiology, oncology, and diagnostics. In the context of a biochemistry analyzer, real-time qPCR can be utilized for a range of applications: 1. Gene Expression Analysis: Real-time qPCR is commonly used to analyze gene expression levels by quantifying the amount of specific RNA transcripts present in a sample. This is vital for understanding how genes are regulated under different conditions and in various tissues or cell types. 2. Pathogen Detection: Biochemistry analyzers equipped with Real-Time PCR capabilities are essential for the rapid and accurate detection of pathogens such as viruses, bacteria, and fungi. This is particularly crucial in clinical diagnostics, epidemiology, and environmental monitoring. 3. SNP Genotyping: Real-time qPCR is utilized to detect and distinguish single nucleotide polymorp

Gradient thermal cyclers are used in hospitals for various applications in PCR (Polymerase Chain Reaction) processes. The gradient feature allows users to test multiple annealing temperatures in a single run, which is particularly useful when optimizing PCR conditions for new primer sets or when dealing with samples with variable DNA quality. RT-qPCR Instrument Display Here are some specific use cases for gradient thermal cyclers in hospitals: 1. **Diagnostic Testing**: Hospitals use Real-Time PCR for diagnosing various infectious diseases such as COVID-19, influenza, tuberculosis, and others. The gradient feature allows for optimization of the PCR conditions, ensuring accurate and reliable results. 2. **Research and Development**: Hospitals often conduct research into new diagnostic markers for diseases, genetic testing, and drug resistance monitoring. Gradient PCR helps in identifying the ideal annealing temperature for specific primers, which is critical for successful PCR amplification. 3. **Quality Control**: Hospitals may use PCR for quality control of samples, such as ensuring the absence of contaminants in laboratory reagents, verifying the identity of cell lines, or detecting genetic mutations. 4. **Environm

The Display of DNA Analyzer The Genetic Analyzer Automatic three-stage indirect is a system used for genetic analysis and is commonly associated with processes related to DNA sequencing or genotyping. As the name implies, it operates in a three-stage process to enable a sophisticated and accurate examination of genetic material. Although the detailed usage may depend on the specific model and manufacturer, a typical workflow might involve the following stages: 1. **Sample Preparation**: In this stage, genetic material (usually DNA or RNA) is extracted from the biological sample, such as blood, tissue, or cultured cells. The extracted genetic material is then purified and prepared for analysis. 2. **Amplification and Labeling**: The prepared genetic material is then subjected to amplification and labeling processes. Amplification, often carried out using Polymerase Chain Reaction (PCR), increases the amount of genetic material for better detection. During this stage, the genetic material might also be labeled with fluorescent markers or other tags for visualization and identification during analysis. 3. **Detection and Analysis**: In the final stage, the labeled genetic material is loaded into the Gene Analyzer Automatic three-stage indirect system. The Real-Time PCR system uses complex algorithms, fluorescence detection, and other techniques to analyze the genetic material. This may involve se

RT-qPCR Instrument Display Selecting a 4-channel fluorescence quantitative real-time PCR System involves considering several key factors to ensure that the instrument aligns with your research or diagnostic needs. Here are some key considerations: 1. Throughput: Determine the throughput required for your experiments. Consider the number of samples you need to process simultaneously. A 4-channel system typically allows for the simultaneous detection of four different fluorophores, enabling multiplexing and higher throughput compared to single- or dual-channel systems. 2. Fluorescent Dyes and Probes: Evaluate which fluorescent dyes and probes are essential for your specific applications. Ensure that the PCR system is compatible with the fluorophores required for your assays. Consider the range of available detection channels and the system's ability to accommodate various fluorescent labels. 3. Assay Flexibility: Assess the flexibility to design and run a variety of assays. Look for a system that supports a broad range of assay types, including gene expression analysis, genotyping, pathogen detection, and other custom assays. Additionally, consider the system's compatibility with different chemistry formats, such as SYBR Green or probe-based assays. 4. Sensitivity and Dynamic Range: Evaluate the system's sensitivity and dynamic range to ensure robust detection of target sequences across a wide range

Introducing the Sanger sequencing medical analyzer to a forensic laboratory can greatly enhance the facility's capabilities for genetic analysis and profiling. Here's a potential introduction: --- **Title: Advancing DNA Analyzer with Sanger Sequencing in Forensic Investigations** We are excited to announce the integration of state-of-the-art Sanger sequencing PCR System technology into our forensic laboratory. This cutting-edge medical analyzer empowers our team to delve deeper into genetic analysis, delivering enhanced precision and accuracy in the field of forensic investigations. **What is Sanger Sequencing?** Sanger sequencing, a gold standard in DNA analysis, enables the precise determination of nucleotide sequences within a DNA sample. This foundational method has been pivotal in numerous scientific breakthroughs and continues to play a crucial role in forensic science. **Enhanced Capabilities:** With the introduction of Sanger sequencing, our laboratory gains the capability to conduct highly accurate DNA profiling, aiding in the identification of suspects, victims, and the resolution of complex cases. The technology's sensitivity and specificity allow for the identification of minute genetic variations, thereb

RT-qPCR Instrument Display Real Time Fluorescence Quantitative Pcr System stands for Reverse Transcription Quantitative Polymerase Chain Reaction. It is a molecular biology technique used to measure the amount of a specific RNA molecule in a sample. The RT-qPCR instrument, also known as a real-time PCR machine or a quantitative PCR machine, is a device used to perform the RT-qPCR technique. The instrument is capable of precisely controlling the temperature of the reaction mixture to enable the amplification of the specific RNA target. Additionally, it also has the ability to monitor the amplification process in real-time, allowing for the quantitative measurement of the initial amount of RNA in the sample. The Real-Time Fluorescence Quantitative Pcr Instrument instrument is crucial in various fields of research and diagnostics, including gene expression analysis, pathogen detection, and molecular diagnostics, due to its ability to accurately and quantitatively measure the levels of specific RNA molecules in biological samples.

DNA Analyzer Display The fragment analysis Genetic Analyzer sequencer is a specialized laboratory instrument used for genetic analysis. It is commonly used in research, biotechnology, and clinical laboratories for a variety of applications such as genotyping, microsatellite analysis, mutation detection, and DNA fingerprinting. Here are some common uses of a fragment analysis gene sequencer in a laboratory setting: 1. Genotyping: The gene sequencer is used to analyze genetic variations, including single nucleotide polymorphisms (SNPs) and insertions/deletions (INDELs), to identify and characterize genetic markers associated with diseases, traits, or population studies. 2. Microsatellite Analysis: It is used to study microsatellite regions in the genome for applications such as genetic mapping, population genetics, and forensic analysis. 3. Mutation Detection: The gene sequencer can be used to detect mutations in specific genes associated with genetic disorders or diseases, aiding in diagnostic and research applications. 4. DNA Fingerprinting: PCR System is used in forensic laboratories to create DNA profiles for identification and legal purposes, such as in criminal investigations or paternity testing. 5. Gene Expression Analysis: The sequencer can be used to analyze gene expression patterns and quantify gene expre

Quantitative PCR System Display QPCR (quantitative polymerase chain reaction) rapid test, Pcr Analyzer (polymerase chain reaction), and real-time PCR (polymerase chain reaction) kits are all related to molecular biology and genetic testing. 1. QPCR Rapid Test: This refers to a quantitative polymerase chain reaction rapid test, which is a method used to rapidly detect and quantify the presence of specific DNA or RNA sequences in a sample. It is commonly used for diagnostic, research, and forensic applications. The "rapid" designation typically refers to the quick turnaround time for obtaining results, making it particularly useful in time-sensitive situations such as disease diagnosis or pathogen detection. 2. PCR (Polymerase Chain Reaction): PCR is a technique used to amplify a specific segment of DNA, making it easier to analyze and study. In the context of molecular diagnostics, PCR is often used to detect the presence of pathogens, genetic mutations, or specific DNA sequences associated with diseases. It is an essential tool in molecular biology and has numerous applications in research and clinical settings. 3. Real-Time PCR Kit: Real-time Quantitative PCR Machine, also known as quantitative PCR, is a method that enables the continuous monitoring of DNA amplification during the PCR process. Real-time PCR kits typically contain the reagents and primers needed to perform a quantitative PCR assay. These kits are designed to accurately measure and quantify the amount of sp

Forensic DNA Analysis Equipment Display DNA testing analyzers are sophisticated equipment used in various scientific and medical applications to analyze and identify DNA sequences. The usage of DNA testing analyzer equipment includes: 1. Forensic Analysis: DNA Analyzer are employed to examine biological evidence collected from crime scenes, such as hair, blood, or skin cells, to match DNA profiles and aid in criminal investigations and legal proceedings. 2. Medical Diagnostics: These analyzers are utilized to identify genetic disorders, hereditary diseases, and mutations by analyzing patient DNA samples. They play a crucial role in diagnosing genetic conditions and informing personalized medical treatments. 3. Paternity Testing: DNA testing analyzers are used to establish paternity and genetic relationships by comparing the DNA profiles of potential relatives, including fathers, mothers, and children. 4. Genealogy and Ancestry Testing: Individuals use DNA testing analyzers to trace their genetic heritage, ethnic origins, and ancestral lineage by analyzing their DNA and comparing it with databases of known genetic markers. 5. Agriculture and Animal Breeding: Real-Time PCR Instrument analyzers are employed in agriculture and animal breeding to assess genetic traits, identify desirable genetic variations, and select for specific characteristics in crops, livestock, or

RT-qPCR Instrument Display The real-time PCR thermal cycler DNA test machine, also known as a quantitative PCR (polymerase chain reaction) machine, is a versatile tool used in various scientific and diagnostic applications. Its primary function is to amplify and quantify DNA or RNA molecules, making it valuable in numerous fields. Some common uses of real-time PCR thermal cyclers include: 1. Disease Diagnosis: In clinical settings, real-time PCR machines are utilized for the detection and quantification of pathogens, including viruses, bacteria, and fungi. This is crucial in diagnosing infectious diseases and monitoring patient response to treatments. 2. Genetic Testing: Real-Time Fluorescence Quantitative Pcr Instrument is employed in genetic testing to detect and quantify specific genetic mutations or variations associated with inherited diseases, cancer, and other genetic conditions. 3. Forensic Analysis: DNA profiling and forensic analysis utilize real-time PCR machines for DNA quantification and identification in criminal investigations, paternity testing, and identification of human remains. 4. Environmental Monitoring: Environmental and food safety laboratories use real-time PCR thermal cyclers to detect and quantify microbial contaminants, genetically modified organisms, and other environmental pollut

Drug Testing Equipment Display The features of a 5-in-1 urine dry immunofluorescence multi Drug Testing typically include: 1. Multi-Drug Testing: The ability to detect multiple drugs simultaneously in a single urine sample, which can include commonly abused drugs such as cocaine, marijuana (THC), opiates, amphetamines, and methamphetamines. 2. Dry Immunofluorescence Technology: Utilizes a dry reagent pad on the test device, which simplifies the testing process and eliminates the need for additional sample manipulation, reducing the risk of contamination. 3. Rapid Results: Provides fast and efficient results within a short timeframe, typically within a few minutes, allowing for immediate decision-making in drug testing scenarios. 4. Sensitivity and Accuracy: Offers high sensitivity and accuracy in detecting the presence of various drugs in urine, providing reliable test results. 5. User-Friendly Design: Easy-to-use test kits with clear instructions, making them suitable for a variety of testing environments such as workplaces, clinical settings, and drug rehabilitation centers. 6. Integrated Controls: Includes built-in quality control features to validate the accuracy and reliability of the test, ensuring consistent performance.

DNA Analyzer Display Superyears gene sequencers have a wide array of applications in forensic Real-Time PCR, enabling advanced molecular techniques for identifying individuals, solving crimes, and enhancing forensic investigations. Some of the primary usages of Superyears gene sequencers in forensic DNA analysis include: 1. Human Identification: Superyears gene sequencers are utilized in forensic DNA analysis for human identification, including the identification of suspects, victims, and missing persons. This can be critical in criminal investigations, disaster victim identification, and resolving cases of unidentified remains. 2. Crime Scene Analysis: Gene sequencers play a crucial role in analyzing DNA evidence collected from crime scenes, such as blood, hair, skin cells, and bodily fluids. This helps forensic scientists in identifying potential perpetrators, linking individuals to crime scenes, and providing key evidence in investigations. 3. Paternity Testing: Superyears gene sequencers are used in forensic laboratories to conduct paternity and kinship testing, providing valuable insights into family relationships, child custody cases, and inheritance matters. 4. Cold Case Resolution: The advanced capabilities of gene sequencers enable forensic scientists to revisit older unsolved cases (cold cases) by re-analyzing

RT-qPCR Instrument Display - Portable multiple fluorescence quantitative RT-PCR systems are used for the detection and quantification of RNA viruses in various samples, such as clinical specimens, environmental samples, and food products. - These systems are compact and portable, allowing for on-site testing in remote or resource-limited areas, as well as in the field during outbreaks and emergencies. - Real-Time PCR is also used in laboratory settings for high-throughput screening of large numbers of samples and for rapid and efficient detection of multiple RNA viruses in a single run. - The portable nature of these systems makes them particularly useful for rapid response to infectious disease outbreaks, as they can be easily transported to the affected area and set up quickly for testing. - The ability to detect and quantify multiple RNA viruses in a single run makes these systems versatile and efficient for a wide range of applications, including surveillance, epidemiological studies, and monitoring of infectious diseases. - In addition, portable multiple fluorescence quantitative Real-Time PCR Instrument is compatible with various types of sample matrices, including blood, saliva, nasal swabs, and environmental samples, making them suitable for differe

With the development of society, China's population policy is gradually relaxing. At present, the country vigorously encourages the "multiple child" policy, and the problem of birth defects is gradually becoming more prominent; At the same time, in order to intervene in diseases such as birth defects as early as possible and assist in eugenics and childbearing, hospitals and medical institutions at all levels across the country actively carry out various testing projects such as prenatal diagnosis. This measure by Genetic Analyzer greatly reduces the economic burden on society and families affected by the disease, and also effectively intervenes and controls serious congenital defects such as congenital heart disease, Down syndrome, deafness, neural tube defects, and thalassemia in newborns to a certain extent. In order to promote the high-quality development of birth defect prevention and control work and better meet the needs of the public for healthy pregnancy, the National Health Commission issued the "National Comprehensive Prevention and Control Plan for Birth Defects" in 2018, which mentioned three prevention methods, namely primary prevention (pre pregnancy), secondary prevention (pregnancy), and tertiary prevention (post pregnancy newborns). DNA Sequencer Display The specific measures for primary prevention (pre pregnancy) refer to reducing the occurrence of birth defects. Strengthen publicity and education on the prevention and contr

As the public pays more and more attention to health and medical institutions become more and more popular about medical health, Sanger Sequecing Instrument has become a common testing item in hospitals. Some genetic testing items have even been obtained from third parties outside the hospital. The laboratory recycled it into major laboratories within the hospital. Actively carrying out genetic testing in the hospital has enabled more and more difficult and complicated diseases, old and new diseases to be diagnosed and treated in a more timely and effective manner. Sanger sequencing technology is a detection technology that has become popular since the 20th century. Its inventor, Fred Sanger, also won the Nobel Prize for the invention of Sanger sequencing method. Sanger sequencing technology can be widely used in the diagnosis of various diseases and screening of genetic defects, such as Down syndrome screening, HPV gene analysis, screening of chromosomal genetic diseases, early tumor screening... In clinical practice, Sanger sequencing technology has been widely used in major clinical departments such as oncology, general surgery, urology, reproductive centers, infectious diseases, and pediatrics. The wide application of Sanger Sequencing Method technology in clinical practice can not only help patients better diagnose diseases, but also for hospitals, the introduction of gene sequencing technology can greatly improve the diagnostic capabilities of departments, improve the diagnostic technology of departments, and improve the comprehensive medical level of hospitals. Provide patients with better medical services and make positive contributions to the health of society as a whole. So how can we scientifical

PCR System Display A Thermal Cycler Real-Time Quantitative PCR Machine is a laboratory instrument used for performing real-time polymerase chain reaction (PCR) experiments. Polymerase chain reaction is a technique used to amplify and detect specific DNA sequences. It involves multiple cycles of heating and cooling to denature the DNA, prime it for replication, and amplify the target DNA region. Traditional PCR methods rely on endpoint detection, where the amplification is analyzed after the reaction is complete. In contrast, real-time PCR allows for the continuous monitoring of the DNA amplification in real-time as it occurs. This is achieved by incorporating fluorescent probes or dyes that emit a detectable signal during the amplification process. The real-time PCR machine measures the fluorescence at each cycle, providing information about the starting amount of DNA and the rate of amplification. A Thermal Cycler Real-Time Quantitative PCR System combines the temperature cycling capabilities of a standard thermal cycler with the ability to detect and measure the fluorescence emitted during the PCR reaction in real-time. It typically consists of a thermal block that can rapidly change temperature, precise temperature control, and a fluorescence detection system. The machine allows researchers to monitor the progress of the

PCR System Display Real-time quantitative PCR (qPCR) system is a molecular biology technique used to measure the amount of a specific DNA sequence or RNA transcript in real-time during the PCR amplification process. It is an improved version of traditional PCR that allows for the quantification and analysis of PCR products during each cycle of amplification. In a real-time Quantitative PCR System system, the PCR reaction mixture contains a DNA-binding fluorescent dye or a sequence-specific probe with a fluorophore and a quencher. As the PCR reaction progresses and the target DNA is amplified, the dye or probe binds to the newly synthesized DNA strands and emits fluorescent signals that can be detected by the instrument. The real-time qPCR system continuously monitors the fluorescence intensity at each cycle of amplification. It measures the increase in fluorescence signals, which is proportional to the amount of PCR product, to quantify the initial amount of the target DNA or RNA template in the sample. The real-time Quantitative PCR Machine system is widely used in various applications, including gene expression analysis, genotyping, pathogen detection, viral load quantification, and many other molecular biology studies that require accurate and precise quantification of nucleic acids.

Sanger Sequecing Instrument Display Sanger Sequecing Dna Analyzer refers to the instruments used in forensic laboratories for DNA sequencing analysis. This Sanger Sequencing Method utilize sophisticated technology to determine the precise order of nucleotide bases (A, T, G, C) in a DNA sample. By sequencing DNA, forensic analysts can identify genetic variations, mutations, and genetic markers that are unique to individuals. This information is crucial in forensic investigations, as it can be used to identify suspects, match evidence to a specific individual, or establish familial relationships. Gene sequencer forensic testing equipment typically includes DNA extraction kits, PCR machines for amplifying DNA, and DNA sequencers that can analyze the order of nucleotides. These instruments require trained forensic scientists to operate and interpret the results.