Direct reprogramming has now been applied in farm animals and has transformed the establishment of pluripotent stem cells (PSCs) in many animal species around the world. The iPSCs generated from different types of somatic cells through multiple cell reprogramming strategies represent an ethically acceptable, virtually unlimited and individual-specific source of pluripotent cells. Generation of iPSCs from domesticated animals https://www.reprogramming-tech.com/farm-animals-ipsc-reprogramming-service.html

The skin is the largest organ of the body and has multiple important functions such as maintaining the stability of the body's internal environment, protecting the body's tissues and organs from external aggressions, and sensing stress, pain and temperature. Reprogramming-Skin-Cells-into-iPSCs https://www.reprogramming-tech.com/skin-cell-reprogramming-service.html

Creative Bioarray offers a wide range of biofluids obtained from both healthy patients and those with medical conditions, as well as those obtained using thousands of different analytes with corresponding test results. Our biofluid samples cover all age groups. The biofluid subtypes are program dependent and consist of combinations of cerebrospinal, lymph, amniotic, synovial and ascites fluids, as well as urine and saliva. Human Biofluids https://www.histobiolab.com/biofluids.html

Creative Bioarray provides a complete range of digital pathology services to promote work processes and improve work efficiency，relying on advanced AI technology and medical image analysis technology. Digital Pathology Solution https://www.histobiolab.com/digital-pathology-services.html

Halogenated nucleotides such as the pyrimidine analog bromodeoxyuridine (BrdU) can be used to label nascent DNA in viable cells. During the process of DNA replication, BrdU can replace thymidine and incorporate into the synthesized DNA of actively dividing cells. methods for labelling nascent DNA http://cellassay.creative-bioarray.com/services/brdu-cell-proliferation-assay.htm

Cell necrosis is a permanent cell or living tissue death induced by external or internal physical (heat, stress, radiation), chemical (strong alkali, strong acid and poison), or biological (endotoxin and pathogen) factors. Necrosis is chaotic, disorderly, and uncontrollable. Once it happens, it is difficult to reverse. cell necrosis mechanism analysis http://cellassay.creative-bioarray.com/cell-necrosis-assay.htm

Creative Bioarray provides customized solutions based on different cell invasion assays according to different requirements to accelerate your fundamental research and drug development projects. Cell-Invasion-Assays https://cell.creative-bioarray.com/cell-invasion-assays.html

Creative Bioarray provides cytotoxicity assays to determine the number of viable and dead cells in a cell population after treatment with compounds, pharmaceutical substances or other stimuli to assess the effect on cell viability. We offer cell-based high-content cytotoxicity screening services to help in drug screening and toxicity evaluation. Our professional services can help you accelerate the process of drug discovery and development. Cytotoxicity Assays https://cell.creative-bioarray.com/cytotoxicity-assays.html

Parkinson's disease (PD) is currently the second most common age-related neurodegenerative disease after Alzheimer's disease, mainly affecting the motor system, resulting in progressive death of dopamine-generating cells in the substantia nigra pars compacta (SNpc). Beside the most obvious symptoms, movement-related symptoms such as shaking, rigidity, slowness of movement and gait, patients develop non-motor symptoms, afflicting personality and behavior (depression, anxiety, apathy), as well disturbances in cognitive function. Parkinson's Disease Model https://acroscell.creative-bioarray.com/parkinson-s-disease-model.html

Xenopus laevis (the African clawed frog) oocytes are a popular model system for a wide variety of biological studies. Microinjection of DNA or messenger RNA (mRNA) into the Xenopus oocytes leads to the functional expression of the encoded proteins. The proteins expressed in such a new environment can be functionally characterized under well-defined conditions. This makes oocytes an important expression system for studies of molecular biology and electrophysiology. Such an in vitro expression system is particularly suitable for studying not only the structure and functions of cloned and mutated proteins but also the physiology of neurotransmitter receptors, ion channels, and transporters. Xenopus Oocyte Screening Model https://acroscell.creative-bioarray.com/xenopus-oocyte-screening-model.html