Creative Biolabs has developed 3D ex vivo human bladder tissue model for global researchers. Our model empowers researchers to explore disease mechanisms, discover novel therapeutic targets, and evaluate treatment responses.
The primary function of the bladder is to store and eliminate urine by optimizing the bladder pressure regulated by the detrusor muscle in the bladder wall. Bladder disorders commonly occur as complications of various severe spinal cord injuries and neurodegenerative diseases. Although not life-threatening, they significantly impact the quality of life for patients.
Several models have provided an in-depth understanding and direct experimental evidence of the pathways and intervention compounds for urinary tract diseases. However, animal models, especially commonly used rodents, exhibit significant differences from humans in terms of physiology, urine composition, and metabolism. In addition, in vitro human models often fail to replicate the complexity of the human bladder, hindering the development of various therapeutic approaches.
Fig.1 Bladder muscle cells under physiological stimuli. (Chae, 2022)
Creative Biolabs has successfully developed an advanced 3D ex vivo human bladder model system, which offers a unique tool to study intact human tissues and organs.
The utilization of this model ensures the high availability of human bladder samples for rigorous pathological examination. Our model is specifically designed to study bladder physiological movements and can reliably deliver a high success rate for any endpoint analysis required in your research. Particularly, we have also developed other 3D ex vivo human urinary system tissue models listed below. For more detailed information, please click the links below.
With our 3D ex vivo human bladder tissue model, you may conduct in-depth investigations into bladder function, disease mechanisms, and therapeutic interventions, ultimately advancing the understanding and treatment of bladder-related conditions. Contact us now to explore the endless possibilities offered by our advanced 3D model.
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