搜索结果: 'methocult media formulations for human hematopoietic cells serum containing'

We present an integrated platform comprised of a biomimetic substrate and physiologically aligned human pluripotent stem cell-derived cardiomyocytes (CMs) with optical detection and algorithms to monitor subtle changes in cardiac properties under various conditions. In the native heart,anisotropic tissue structures facilitate important concerted mechanical contraction and electrical propagation. To recapitulate the architecture necessary for a physiologically accurate heart response,we have developed a simple way to create large areas of aligned CMs with improved functional properties using shrink-wrap film. Combined with simple bright field imaging,obviating the need for fluorescent labels or beads,we quantify and analyze key cardiac contractile parameters. To evaluate the performance capabilities of this platform,the effects of two drugs,E-4031 and isoprenaline,were examined. Cardiac cells supplemented with E-4031 exhibited an increase in contractile duration exclusively due to prolonged relaxation peak. Notably,cells aligned on the biomimetic platform responded detectably down to a dosage of 3nm E-4031,which is lower than the IC50 in the hERG channel assay. Cells supplemented with isoprenaline exhibited increased contractile frequency and acceleration. Interestingly,cells grown on the biomimetic substrate were more responsive to isoprenaline than those grown on the two control surfaces,suggesting topography may help induce more mature ion channel development. This simple and low-cost platform could thus be a powerful tool for longitudinal assays as well as an effective tool for drug screening and basic cardiac research. ?? 2013 Elsevier Ltd. View Publication

Here we introduce the representative method to culture HESCs under the feeder and feeder-free conditions,the former of which is used to maintain or expand undifferentiated HESCs,and the latter can be used for the preparation of pure HESCs RNA samples,or for screening factors influential on self-renewal of HESCs. We also describe a protocol and tips for conducting gene chip analysis focusing on widely used Affymetrix Microarrays. These techniques will provide us unprecedented scale of biological information that would illuminate a key to decipher complex signaling networks controlling pluripotency. View Publication

Mitochondrial membrane potential (MMP) segregates functionally distinct subsets within highly purified hematopoietic stem cells (HSCs). Here,we detail a protocol for FACS isolation of MMP sub-fractions of phenotypically defined mouse and human HSCs. These steps are followed by high-/super-resolution immunofluorescence microscopy of HSCs' lysosomes. While the protocol describes the isolation of quiescent HSCs,which are the most potent subsets,it could also be applied to other HSC subsets. This protocol overcomes some experimental challenges associated with low HSC numbers. For complete details on the use and execution of this protocol,please refer to Liang et al. (2020) and Qiu et al. (2021). View Publication

The integration of up- and downstream unit operations can result in the elimination of hold steps,thus decreasing the footprint,and ultimately can create robust closed system operations. This type of design is desirable for the bioprocess of human mesenchymal stem cells (hMSC),where high numbers of pure cells,at low volumes,need to be delivered for therapy applications. This study reports a proof of concept of the integration of a continuous perfusion culture in bioreactors with a tangential flow filtration (TFF) system for the concentration and washing of hMSC. Moreover,we have also explored a continuous alternative for concentrating hMSC. Results show that expanding cells in a continuous perfusion operation mode provided a higher expansion ratio,and led to a shift in cells' metabolism. TFF operated either in continuous or discontinuous allowed to concentrate cells,with high cell recovery (>80%) and viability (>95%); furthermore,continuous TFF permitted to operate longer with higher cell concentrations. Continuous diafiltration led to higher protein clearance (98%) with lower cell death,when comparing to discontinuous diafiltration. Overall,an integrated process allowed for a shorter process time,recovering 70% of viable hMSC (>95%),with no changes in terms of morphology,immunophenotype,proliferation capacity and multipotent differentiation potential. View Publication

Long-chain bases are present in the oral cavity. Previously we determined that sphingosine,dihydrosphingosine,and phytosphingosine have potent antimicrobial activity against oral pathogens. Here,we determined the cytotoxicities of long-chain bases for oral cells,an important step in considering their potential as antimicrobial agents for oral infections. This information would clearly help in establishing prophylactic or therapeutic doses. To assess this,human oral gingival epithelial (GE) keratinocytes,oral gingival fibroblasts (GF),and dendritic cells (DC) were exposed to 10.0-640.0 μM long-chain bases and glycerol monolaurate (GML). The effects of long-chain bases on cell metabolism (conversion of resazurin to resorufin),membrane permeability (uptake of propidium iodide or SYTOX-Green),release of cellular contents (LDH),and cell morphology (confocal microscopy) were all determined. GE keratinocytes were more resistant to long-chain bases as compared to GF and DC,which were more susceptible. For DC,0.2-10.0 μM long-chain bases and GML were not cytotoxic; 40.0-80.0 μM long-chain bases,but not GML,were cytotoxic; and 80.0 μM long-chain bases induced cellular damage and death in less than 20 min. The LD50 of long-chain bases for GE keratinocytes,GF,and DC were considerably higher than their minimal inhibitory concentrations for oral pathogens,a finding important to pursuing their future potential in treating periodontal and oral infections. View Publication

Human induced pluripotent stem cells have the potential to become an unlimited cell source for cell replacement therapy. The realization of this potential,however,depends on the availability of culture methods that are robust,scalable,and use chemically defined materials. Despite significant advances in hiPSC technologies,the expansion of hiPSCs relies upon the use of animal-derived extracellular matrix extracts,such as Matrigel,which raises safety concerns over the use of these products. In this work,we investigated the feasibility of expanding and differentiating hiPSCs on a chemically defined,xeno-free synthetic peptide substrate,i.e. Corning Synthemax(®) Surface. We demonstrated that the Synthemax Surface supports the attachment,spreading,and proliferation of hiPSCs,as well as hiPSCs' lineage-specific differentiation. hiPSCs colonies grown on Synthemax Surfaces exhibit less spread and more compact morphology compared to cells grown on Matrigel™. The cytoskeleton characterization of hiPSCs grown on the Synthemax Surface revealed formation of denser actin filaments in the cell-cell interface. The down-regulation of vinculin and up-regulation of zyxin expression were also observed in hiPSCs grown on the Synthemax Surface. Further examination of cell-ECM interaction revealed that hiPSCs grown on the Synthemax Surface primarily utilize α(v)β(5) integrins to mediate attachment to the substrate,whereas multiple integrins are involved in cell attachment to Matrigel. Finally,hiPSCs can be maintained undifferentiated on the Synthemax Surface for more than ten passages. These studies provide a novel approach for expansion of hiPSCs using synthetic peptide engineered surface as a substrate to avoid a potential risk of contamination and lot-to-lot variability with animal derived materials. View Publication

Reprogramming of patient cells to human induced pluripotent stem cells (hiPSC) has facilitated in vitro disease modeling studies aiming at deciphering the molecular and cellular mechanisms that contribute to disease pathogenesis and progression. To fully exploit the potential of hiPSC for biomedical applications,technologies that enable the standardized generation and expansion of hiPSC from large numbers of donors are required. Paralleled automated processes for the expansion of hiPSC could provide an opportunity to maximize the generation of hiPSC collections from patient cohorts while minimizing hands-on time and costs. In order to develop a simple method for the parallel expansion of human pluripotent stem cells (hPSC) we established a protocol for their cultivation as undifferentiated aggregates in a bench-top bioreactor system (BioLevitator™). We show that long-term expansion (10 passages) of hPSCs either in mTeSR or E8 medium preserved a normal karyotype,three-germ-layer differentiation potential and high expression of pluripotency-associated markers. The system enables the expansion from low inoculation densities (0.3 × 10(5) cells/mL) and provides a simplified,cost-efficient and time-saving method for the provision of hiPSC at midi-scale. Implementation of this protocol in cell production schemes has the potential to advance cell manufacturing in many areas of hiPSC-based medical research. View Publication