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Add to Cart The item has been addedABiEndothelial
$500.00 -
Add to Cart The item has been addedABiHepatocytes
$500.00
iPSC Derived Cells
Induced Pluripotent Stem Cells (iPSCs)
Induced pluripotent stem cells (iPSCs) are self-renewing cells capable of differentiating into virtually any somatic cell type in the human body. Their ability to provide a renewable, physiologically relevant source of human cells has transformed in vitro modeling by enabling researchers to move beyond primary cell limitations and short-lived immortalized lines.
Because iPSCs can be expanded indefinitely while maintaining genomic stability, they offer a scalable starting material for generating differentiated cell populations with defined phenotypes and functional maturity. This consistency supports improved reproducibility across experiments, making iPSC-derived models well-suited for longitudinal studies, predictive toxicology, and complex disease modeling workflows.
By providing a stable developmental platform for directed differentiation, iPSCs enable the generation of specialized human cell types that retain key functional characteristics over extended culture periods — supporting more accurate assessment of biological response in drug discovery and translational research settings.
When differentiated under optimized conditions, iPSC-derived cells can recapitulate tissue-specific morphology and metabolic activity, offering researchers access to standardized, renewable human models for applications ranging from target validation to safety assessment.
Allele's iPSC-Derived Hepatocytes (ABiHepatocytes)
Allele’s iPSC-derived hepatocytes (ABiHepatocytes) are mature, highly functional, and designed for extended culture performance. While other suppliers recommend maintaining iHeps for up to two weeks, our cultures remain healthy and active for two months or more, offering greater experimental flexibility and more biologically relevant long-term data.
These cells express key hepatic markers, demonstrate robust cytochrome P450 activity, and exhibit proper glycogen storage and albumin secretion over extended periods. Every lot is validated for viability, morphology, and metabolic function to ensure consistent, reproducible results.
Our ongoing studies show strong maintenance of hepatic phenotype and functionality in long-term culture. Additional data sets are being prepared to further illustrate gene expression stability, enzyme activity, and long-term metabolic consistency.
With their exceptional longevity and function, Allele iHeps are ideal for applications in toxicity testing, disease modeling, and drug metabolism studies — bridging the gap between short-term cultures and in vivo models.