Clinical performance of cuffed versus uncuffed preformed endotracheal tube in pediatric patients undergoing cleft palate surgery

Allergic reactions in the lung are characterized by the production of mediators, an influx of inflammatory cells, increased vascular permeability, and changes in airway mechanics. The mechanisms responsible for these airway changes have not been fully defined but may involve the production of reactive oxygen species (ROS) produced by the inflammatory cells. To examine whether ROS are produced by inflammatory cells at sites of antigen exposure, bronchoalveolar lavage (BAL) was performed in airway segments 19 h after challenge with saline or antigen in 14 allergic subjects. Antigen challenge increased cell recovery, predominantly as a result of an influx of eosinophils. Using electron paramagnetic resonance (EPR) spectroscopy with the spin trap 5,5-dimethyl-1-pyrroline-N-oxide (DMPO), BAL cells from saline-challenged sites produced minimal ROS. Cells from antigen-challenged sites spontaneously produced a prominent DMPO-OH signal that was inhibited by superoxide dismutase (SOD), indicating the production of superoxide anions (O2-.). Reduction of ferricytochrome c and production of luminol-dependent chemiluminescence via SOD-inhibitable reactions confirmed the spontaneous production of O2-. Following density gradient separation of the antigen-challenged BAL cells, the granulocytic cells, which were predominantly eosinophils, not the mononuclear cells, were the major source of the ROS. At the sites of antigen challenge, the degree of airway permeability as assessed by albumin concentration in BAL fluid was correlated with O2- production by BAL cells measured by EPR spectroscopy. These results demonstrate that cells at sites of antigen challenge generate ROS that may contribute to the airway injury associated with allergic inflammation.

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Further evidence that lucigenin-derived chemiluminescence monitors mitochondrial superoxide generation in rat alveolar macrophages

Rembish

Trush

1994

Free Radical Biology and Medicine

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Induction of quinone reductase and glutathione in bone marrow cells by 1,2-dithiole-3-thione: Effect on hydroquinone-induced cytotoxicity

Twerdok¹,

Rembish²,

Trush³

1992

Toxicology and Applied Pharmacology

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Analysis of target cell susceptibility as a basis for the development of a chemoprotective strategy against benzene-induced hematotoxicities.

Trush

Twerdok

Rembish

et al. 1996

Environ Health Perspect

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A goal of our research is to identify biochemical factors that underlie the susceptibility of bone marrow cell populations to benzene metabolites so as to develop a mechanistically based chemoprotective strategy that may be used in susceptible humans exposed to benzene. By doing biochemical risk analysis of bone marrow stromal cells from mice and rats and the human myeloid cell lines, HL-60 and ML-1; and by using buthionine sulfoximine and dicumarol we have observed that the susceptibility of these cell populations to hydroquinone (HQ) correlates with their concentration of glutathione (GSH) and activity of quinone reductase (QR). Accordingly, the induction of QR and GSH by 1,2-dithiole-3-thione (D3T) in these cell populations has resulted in a significant protection against the following hydroquinone-mediated toxicities: inhibition of cell proliferation and viability; reduced ability of stromal cells to support myelopoiesis; and altered differentiation of ML-1 cells to monocytes/macrophages. Preliminary in vivo experiments indicate that feeding mice D3T results in an induction of QR in the bone marrow compartment such that stromal cells are more resistant to hydroquinone-induced cytotoxicity in vitro. Overall, these studies suggest that in addition to hepatic cytochrome P4502E1, bone marrow OR and GSH are factors that could determine an individual's relative susceptibility to the toxic effects of benzene.

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Analysis of Target Cell Susceptibility as a Basis for the Development of a Chemoprotective Strategy against Benzene-Induced Hematotoxicities

Trush¹,

Twerdok²,

Rembish³

et al. 1996

Environmental Health Perspectives

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A goal of our research is to identify biochemical factors that underlie the susceptibility of bone marrow cell populations to benzene metabolites so as to develop a mechanistically based chemoprotective strategy that may be used in susceptible humans exposed to benzene. By doing biochemical risk analysis of bone marrow stromal cells from mice and rats and the human myeloid cell lines, HL-60 and ML-1; and by using buthionine sulfoximine and dicumarol we have observed that the susceptibility of these cell populations to hydroquinone (HQ) correlates with their concentration of glutathione (GSH) and activity of quinone reductase (QR). Accordingly, the induction of QR and GSH by 1,2-dithiole-3-thione (D3T) in these cell populations has resulted in a significant protection against the following hydroquinone-mediated toxicities: inhibition of cell proliferation and viability; reduced ability of stromal cells to support myelopoiesis; and altered differentiated of ML-1 cells to monocytes/macrophages. Preliminary in vivo experiments indicate that feeding mice D3T results in an induction of QR in the bone marrow compartment such that stromal cells are more resistant to hydroquinone-induced cytotoxicity in vitro. Overall, these studies suggest that in addition to hepatic cytochrome P4502E1, bone marrow QR and GSH are factors that could determine an individual's relative susceptibility to the toxic effects of benzene.

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Stephen J. Rembish

Spontaneous oxygen radical production at sites of antigen challenge in allergic subjects.

Further evidence that lucigenin-derived chemiluminescence monitors mitochondrial superoxide generation in rat alveolar macrophages

Induction of quinone reductase and glutathione in bone marrow cells by 1,2-dithiole-3-thione: Effect on hydroquinone-induced cytotoxicity

Analysis of target cell susceptibility as a basis for the development of a chemoprotective strategy against benzene-induced hematotoxicities.

Analysis of Target Cell Susceptibility as a Basis for the Development of a Chemoprotective Strategy against Benzene-Induced Hematotoxicities

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