PSC Induction Product Series

MCE CEPT Cocktail Plus (1000×) is a composite supplement specifically formulated for pluripotent stem cell culture. Through synergistic effects, it inhibits oxidative damage, blocks apoptotic pathways, and regulates protein translation, significantly reducing cellular stress levels through multiple targets. This dramatically improves the survival rate and cloning efficiency of pluripotent stem cells.

MCE ECM Gentle Dissociation Solution is a gentle ECM-degrading enzyme mixture derived from marine bacteria and Bacillus species, specifically formulated for efficient and low-damage digestion of in-vitro cell systems. It selectively degrades extracellular matrix components while minimizing disruption to the cell membrane and intercellular junctions, thereby significantly reducing mechanical stress during dissociation.

MCE Human iPSC/ESC Cortical Brain Organoid Induction Differentiation Kit is a standardized culture system specifically designed to recapitulate the developmental processes and functional features of the human cerebral cortex through forebrain ventralization-based signaling regulation. By sequentially activating the Wnt/β-catenin pathway and gradually inhibiting BMP/Smad signaling, this system efficiently drives human pluripotent stem cells (PSC) to differentiate into high-purity glutamatergic neurons (VGLUT1/2⁺ > 85%), while simultaneously promoting the formation of Pax6⁺/BLBP⁺ radial glial cells that establish a biomimetic ventricular-zone–like structure.

MCE Human iPSC/ESC Whole-Brain Organoid Induction Differentiation Kit is a non-region-specific brain organoid induction kit designed based on the neuroectoderm self-differentiation system. After 38 d of culture using this kit, the resulting whole-brain organoids stably express core neuronal markers such as TUJ1, SOX2, Nestin, and NeuN, as well as forebrain/cortical markers including FOXG1 and CTIP2.

MCE Human iPSC/ESC Cardiomyocyte Induction Differentiation Kit is based on the classical GiWi system. By precisely modulating the Wnt/β-catenin signaling pathway in a temporally controlled manner (sequential activation and inhibition), the kit enables highly efficient directed differentiation of human pluripotent stem cells into cardiomyocytes. It is suitable for cardiac disease modeling, drug cardiotoxicity assessment, and mechanistic studies.

MCE Human iPSC/ESC Hepatocyte Induction Differentiation Kit enables the efficient generation of hepatocyte-like cells with a high degree of maturation within 21 d. The resulting cells stably express multiple key hepatic functional markers, including albumin (ALB), cytochrome P450 (CYP) family enzymes, and other liver-specific functional molecules, and exhibit typical hepatocellular phenotypes and functions.

MCE Human PSC Maintenance Medium is a ready-to-use, chemically defined formulation designed to support the robust growth and self-renewal of human embryonic stem cells (hESCs) and induced pluripotent stem cells (iPSCs) under feeder-free culture conditions.

MCE Human iPSC-Derived Brain Organoid Long-term Culture Medium is a specialized culture system developed through systematic reformulation and concentration optimization based on neuronal cell culture platforms. It significantly enhances the adaptability and stability of long-term culture for brain organoids derived from human induced pluripotent stem cells (iPSCs).

MCE Human PSC Embryoid Body (EB) Induction Medium is specifically designed to support the efficient and reproducible formation of uniform embryoid bodies from pluripotent stem cells under suspension culture conditions. This optimized culture system integrates microenvironmental regulation with metabolic adaptation strategies, significantly improving the stability and reproducibility of EB formation.

MCE Human iPSC/ESC Cortical Brain Organoid Maturation Medium is a ready-to-use culture system specifically formulated for the long-term maintenance and maturation of cortical brain organoids. It serves as a seamless transition from the induction phase and supports the continued growth and functional development of the organoids. Upon switching PSC-derived cortical brain organoids to this medium, organoid viability and structural stability are markedly enhanced, enabling a robust and extended culture period of up to 180 d.