Explore NTHRYS advanced organoid products, offering a diverse range of 3D cell culture systems, including customized, disease-specific, and stem cell-derived organoids. These cutting-edge models are designed for drug discovery, disease research, personalized medicine, and regenerative applications.
Tailored organoids developed to meet specific research or therapeutic needs.
Organoids designed to model specific diseases for research and therapeutic testing.
Organoids generated from stem cells for regenerative medicine and research.
Organoids created from patient tissues for personalized medicine and cancer research.
Organoids produced using 3D bioprinting techniques for advanced research applications.
Organoids that mimic brain and nervous system structures for neuroscience research.
Organoids that replicate the structure and function of the gastrointestinal tract.
Organoids that model liver tissue for studies in metabolism, toxicity, and disease.
Organoids that simulate kidney structures for research into renal function and diseases.
Organoids that reproduce lung tissue architecture for respiratory disease research.
Organoids modeling pancreatic function for diabetes and cancer research.
Organoids that simulate heart tissue for cardiovascular research.
Organoids that mimic the small intestine for studies on nutrient absorption and gut health.
Organoids modeling prostate tissue for research on prostate cancer and other conditions.
Organoids that replicate breast tissue for breast cancer research.
Organoids that simulate thyroid gland function for endocrine system research.
Organoids that mimic skin layers for dermatological research and wound healing studies.
Organoids that replicate bladder tissue for urological research.
Organoids that simulate corneal tissue for ocular research.
Organoids that model esophageal tissue for research on swallowing disorders and esophageal diseases.
Organoids that replicate the endometrium for reproductive health research.
Organoids modeling the placenta for studies on maternal-fetal interactions.
Organoids that replicate salivary gland tissue for oral and dental research.
Organoids that mimic adrenal gland function for endocrine and stress response studies.
Organoids that simulate ovarian tissue for reproductive health and cancer research.
Organoids that replicate testicular tissue for studies on male fertility and testicular cancer.
Organoids that mimic liver function for hepatic disease research and drug metabolism studies.
Organoids that simulate thymus tissue for immunology research.
Organoids that replicate blood vessel structures for cardiovascular and cancer research.
Organoids that model bone, cartilage, and muscle tissue for orthopedic research.