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

Acute and chronic solid organ failures are costly disease processes with high mortality rates. Inflammation plays a central role in both acute and chronic organ failure,including heart,lung and kidney. In this regard,new therapies for these disorders have focused on inhibiting the mediators of inflammation,including cytokines and free radicals,with little or no success in clinical studies. Recent novel treatment strategies have been directed to cell-based rather than mediator-based approaches,designed to immunomodulate the deleterious effects of inflammation on organ function. One approach,cell therapy,replaces cells that were damaged in the acute or chronic disease process with stem/progenitor technology,to rebalance excessive inflammatory states. As an example of this approach,the use of an immunomodulatory role of renal epithelial progenitor cells to treat acute renal failure (ARF) and multiorgan failure arising from acute kidney injury is reviewed. A second therapeutic pathway,cell processing,does not incorporate stem/progenitor cells in the device,but rather biomimetic materials that remove and modulate the primary cellular components,which promote the worsening organ tissue injury associated with inflammation. The use of an immunomodulating leukocyte selective cytopheretic inhibitory device is also reviewed as an example of this cell processing approach. Both of these unconventional strategies have shown early clinical efficacy in pilot clinical trials and may transform the therapeutic approach to organ failure disorders. View Publication

Human amnion epithelial cells (hAECs) are a heterologous population positive for stem cell markers; they display multilineage differentiation potential,differentiating into cells of the endoderm (liver,lung epithelium),mesoderm (bone,fat),and ectoderm (neural cells). They have a low immunogenic profile and possess potent immunosuppressive properties. Hence,hAECs may be a valuable source of cells for cell therapy. This unit describes an efficient and effective method of hAEC isolation,culture,and cryopreservation that is animal product-free and in accordance with current guidelines on preparation of cells for clinical use. Cells isolated using this method were characterized after 5 passages by analysis of karyotype,cell cycle distribution,and changes in telomere length. The differentiation potential of hAECs isolated using this animal product-free method was demonstrated by differentiation into lineages of the three primary germ layers and expression of lineage-specific markers analyzed by PCR,immunocytochemistry,and histology. View Publication

Effective derivation of functional airway organoids from induced pluripotent stem cells (iPSCs) would provide valuable models of lung disease and facilitate precision therapies for airway disorders such as cystic fibrosis. However,limited understanding of human airway patterning has made this goal challenging. Here,we show that cyclical modulation of the canonical Wnt signaling pathway enables rapid directed differentiation of human iPSCs via an NKX2-1+progenitor intermediate into functional proximal airway organoids. We find that human NKX2-1+progenitors have high levels of Wnt activation but respond intrinsically to decreases in Wnt signaling by rapidly patterning into proximal airway lineages at the expense of distal fates. Using this directed approach,we were able to generate cystic fibrosis patient-specific iPSC-derived airway organoids with a defect in forskolin-induced swelling that is rescued by gene editing to correct the disease mutation. Our approach has many potential applications in modeling and drug screening for airway diseases. View Publication

Recent research in breast biology has provided support for the cancer stem-cell hypothesis. Two important components of this hypothesis are that tumors originate in mammary stem or progenitor cells as a result of dysregulation of the normally tightly regulated process of self-renewal. As a result,tumors contain and are driven by a cellular subcomponent that retains key stem-cell properties including self-renewal,which drives tumorigenesis and differentiation that contributes to cellular heterogeneity. Advances in stem-cell technology have led to the identification of stem cells in normal and malignant breast tissue. The study of these stem cells has helped to elucidate the origin of the molecular complexity of human breast cancer. The cancer stem-cell hypothesis has important implications for early detection,prevention,and treatment of breast cancer. Both hereditary and sporadic breast cancers may develop through dysregulation of stem-cell self-renewal pathways. These aberrant stem cells may provide targets for the development of cancer prevention strategies. Furthermore,because breast cancer stem cells may be highly resistant to radiation and chemotherapy,the development of more effective therapies for this disease may require the effective targeting of this cell population. View Publication

Human bocavirus 1 (HBoV1) is a human parvovirus that causes acute respiratory tract infections in young children. In this study,we confirmed that,when polarized/well-differentiated human airway epithelia are infected with HBoV1in vitro,they develop damage characterized by barrier function disruption and cell hypotrophy. Cell death mechanism analyses indicated that the infection induced pyroptotic cell death characterized by caspase-1 activation. Unlike infections with other parvoviruses,HBoV1 infection did not activate the apoptotic or necroptotic cell death pathway. When the NLRP3-ASC-caspase-1 inflammasome-induced pathway was inhibited by short hairpin RNA (shRNA),HBoV1-induced cell death dropped significantly; thus,NLRP3 mediated by ASC appears to be the pattern recognition receptor driving HBoV1 infection-induced pyroptosis. HBoV1 infection induced steady increases in the expression of interleukin 1α (IL-1α) and IL-18. HBoV1 infection was also associated with the marked expression of the antiapoptotic genesBIRC5andIFI6When the expression ofBIRC5and/orIFI6was inhibited by shRNA,the infected cells underwent apoptosis rather than pyroptosis,as indicated by increased cleaved caspase-3 levels and the absence of caspase-1.BIRC5and/orIFI6gene inhibition also significantly reduced HBoV1 replication. Thus,HBoV1 infection of human airway epithelial cells activates antiapoptotic proteins that suppress apoptosis and promote pyroptosis. This response may have evolved to confer a replicative advantage,thus allowing HBoV1 to establish a persistent airway epithelial infection. This is the first report of pyroptosis in airway epithelia infected by a respiratory virus.IMPORTANCEMicrobial infection of immune cells often induces pyroptosis,which is mediated by a cytosolic protein complex called the inflammasome that senses microbial pathogens and then activates the proinflammatory cytokines IL-1 and IL-18. While virus-infected airway epithelia often activate NLRP3 inflammasomes,studies to date suggest that these viruses kill the airway epithelial cells via the apoptotic or necrotic pathway; involvement of the pyroptosis pathway has not been reported previously. Here,we show for the first time that virus infection of human airway epithelia can also induce pyroptosis. Human bocavirus 1 (HBoV1),a human parvovirus,causes lower respiratory tract infections in young children. This study indicates that HBoV1 kills airway epithelial cells by activating genes that suppress apoptosis and thereby promote pyroptosis. This strategy appears to promote HBoV1 replication and may have evolved to allow HBoV1 to establish persistent infection of human airway epithelia. View Publication