Your search keyword '"Leaffer D"' showing total 4 results

1. Noise Barriers in Somerville

Author

Sprague L, Keppard B, Wig Zamore, Leaffer D, Sharon Ron, Doug Brugge, Botana P, and Resiner E

Subjects

Global and Planetary Change, Optics, Epidemiology, business.industry, Health, Toxicology and Mutagenesis, Public Health, Environmental and Occupational Health, Lens (geology), Sociology, business, Pollution, Noise barrier

Published

2019

2. Cell fate analysis in fetal mouse lung reveals distinct pathways for TI and TII cell development.

Author

Gonzalez R, Leaffer D, Chapin C, Gillespie AM, Eckalbar W, and Dobbs L

Subjects

Alveolar Epithelial Cells metabolism, Animals, Cell Separation, Fetus metabolism, Lung metabolism, Mice, Mice, Transgenic, Phenotype, Pulmonary Alveoli metabolism, Alveolar Epithelial Cells cytology, Cell Differentiation, Cell Lineage, Fetus cytology, Genetic Markers, Lung cytology, Pulmonary Alveoli cytology

Abstract

Alveolar type I (TI) cells are large squamous cells that cover >95% of the internal surface area of the lung; type II (TII) cells are small cuboidal cells with distinctive intracellular surfactant storage organelles. Based on autoradiographic studies in the 1970s, the long-held paradigm of alveolar epithelial development has been a linear progression from undifferentiated progenitor cells through TII cells to TI cells. Subsequent data support the existence of more complex pathways. Recently, a bipotent TI/TII progenitor cell at embryonic day E18 has been inferred both from marker expression in developing airways and from statistical analyses of gene expression data obtained from single-lung embryonic cells. To study cell lineage directly by fate mapping, we developed new transgenic mouse models in which rtTA is driven either by the rat podoplanin or the mouse Sftpc gene to mark cells irreversibly in development. Using these models, we found two distinct lineage pathways. One pathway, evident as early as E12-15, is devoted almost exclusively to TI cell development; a second pathway gives rise predominantly to TII cells but also a subpopulation of TI cells. We have defined the molecular phenotypes of these distinct progenitor populations and have identified potential regulatory factors in TI and TII cell differentiation. By analyzing gene pathways in mature TI and TII cells, we identified potential novel functions of each cell type. These results provide novel insights into lung development and suggest a basis for testing strategies to promote alveolar differentiation and repair, including potential transplantation of lineage-specific progenitor cells.

Published

2019

3. Wearable Ultrafine Particle and Noise Monitoring Sensors Jointly Measure Personal Co-Exposures in a Pediatric Population.

Author

Leaffer D, Wolfe C, Doroff S, Gute D, Wang G, and Ryan P

Subjects

Adolescent, Air Pollutants analysis, Environmental Monitoring methods, Female, Humans, Male, Particle Size, Particulate Matter analysis, Environmental Exposure analysis, Environmental Monitoring instrumentation, Noise, Transportation, Traffic-Related Pollution analysis, Wearable Electronic Devices

Abstract

Epidemiological studies have linked both traffic-related air pollution (TRAP) and noise to adverse health outcomes, including increased blood pressure, myocardial infarction, and respiratory health. The high correlation between these environmental exposures and their measurement challenges have constrained research on how simultaneous exposure to TRAP and traffic noise interact and possibly enhance each other's effect. The objective of this study was to deploy two novel personal sensors for measuring ultrafine particles (UFP, <100 nm diameter) and noise to concurrently monitor real-time exposures. Personal UFP monitors (PUFP, Enmont, LLC) were paired with NEATVIBEwear™ (Noise Exposure, Activity-Time and Vibration wearable), a personal noise monitoring device developed by the authors (Douglas Leaffer, Steve Doroff). A field-test of PUFP monitors co-deployed with NEATVIBEwear logged UFP, noise and ambient temperature exposure levels at 1-s resolution in an adolescent population in Cincinnati, OH to measure real-time exposures in microenvironments (transit, home, school). Preliminary results show that the concurrent measurement of noise exposures with UFP is feasible in a sample of physically active adolescent participants. Personal measurements of UFP and noise, measured prospectively in future studies, will enable researchers to investigate the independent and/or joint-effects of these health-relevant environmental exposures.

Published

2019

4. High-efficiency type II cell-enhanced green fluorescent protein expression facilitates cellular identification, tracking, and isolation.

Author

Vanderbilt JN, Gonzalez RF, Allen L, Gillespie A, Leaffer D, Dean WB, Chapin C, and Dobbs LG

Subjects

Animals, Antigens, Differentiation genetics, Antigens, Differentiation metabolism, Cell Separation, Chromosomes, Artificial, Bacterial, Disease Models, Animal, Intercellular Signaling Peptides and Proteins, Lung Diseases genetics, Lung Diseases metabolism, Lung Diseases pathology, Membrane Glycoproteins biosynthesis, Membrane Glycoproteins genetics, Mice, Mice, Transgenic, Pulmonary Surfactant-Associated Protein C, Rats, Cell Tracking, Gene Expression, Green Fluorescent Proteins biosynthesis, Green Fluorescent Proteins genetics, Lung cytology, Lung metabolism, Peptides genetics, Peptides metabolism, Recombinant Fusion Proteins biosynthesis, Recombinant Fusion Proteins genetics

Abstract

We have developed a transgenic mouse expressing enhanced green fluorescent protein (EGFP) in virtually all type II (TII) alveolar epithelial cells. The CBG mouse (SPC-BAC-EGFP) contains a bacterial artificial chromosome modified to express EGFP within the mouse surfactant protein (SP)-C gene 3' untranslated region. EGFP mRNA expression is limited to the lung. EGFP fluorescence is both limited to and exhibited by all cells expressing pro-SP-C; fluorescence is uniform throughout all lobes of the lung and does not change as mice age. EGFP(+) cells also express SP-B but do not express podoplanin, a type I (TI) cell marker. CBG mice show no evidence of lung disease with aging. In 3 hours, TII cells can be isolated in >99% purity from CBG mice by FACS; the yield of 3.7 ± 0.6 × 10(6) cells represents approximately 25 to 60% of the TII cells in the lung. By FACS analysis, approximately 0.9% of TII cells are in mitosis in uninjured lungs; after bleomycin injury, 4.1% are in mitosis. Because EGFP fluorescence can be detected for >14 days in culture, at a time that SP-C mRNA expression is essentially nil, this line may be useful for tracking TII cells in culture and in vivo. When CBG mice are crossed to transgenic mice expressing rat podoplanin, TI and TII cells can be easily simultaneously identified and isolated. When bred to other strains of mice, EGFP expression can be used to identify TII cells without the need for immunostaining for SP-C. These mice should be useful in models of mouse pulmonary disease and in studies of TII cell biology, biochemistry, and genetics.

Published

2015