Your search keyword '"Li, Emily Y."' showing total 12 results

1. A review of sample collection and analytical methods for detecting per- and polyfluoroalkyl substances in indoor and outdoor air

Author

Wallace, M. Ariel Geer, Smeltz, Marci G., Mattila, James M., Liberatore, Hannah K., Jackson, Stephen R., Shields, Erin P., Xhani, Xhensila, Li, Emily Y., and Johansson, Jana H.

Published

2024

2. Improving public health control of schistosomiasis with a modified WHO strategy: a model-based comparison study

Author

Li, Emily Y, Gurarie, David, Lo, Nathan C, Zhu, Xuewei, and King, Charles H

Published

2019

3. Quantifying functional group compositions of household fuel-burning emissions.

Author

Li, Emily Y., Yazdani, Amir, Dillner, Ann M., Shen, Guofeng, Champion, Wyatt M., Jetter, James J., Preston, William T., Russell, Lynn M., Hays, Michael D., and Takahama, Satoshi

Subjects

*CHARCOAL, *FUNCTIONAL groups, *FOURIER transform infrared spectroscopy, *RED oak, *INDOOR air pollution, *MEMBRANE filters, *SPECTRAL sensitivity

Abstract

Globally, billions of people burn fuels indoors for cooking and heating, which contributes to millions of chronic illnesses and premature deaths annually. Additionally, residential burning contributes significantly to black carbon emissions, which have the highest global warming impacts after carbon dioxide and methane. In this study, we use Fourier transform infrared spectroscopy (FTIR) to analyze fine-particulate emissions collected on Teflon membrane filters from 15 cookstove types and 5 fuel types. Emissions from three fuel types (charcoal, kerosene, and red oak wood) were found to have enough FTIR spectral response for functional group (FG) analysis. We present distinct spectral profiles for particulate emissions of these three fuel types. We highlight the influential FGs constituting organic carbon (OC) using a multivariate statistical method and show that OC estimates by collocated FTIR and thermal–optical transmittance (TOT) are highly correlated, with a coefficient determination of 82.5 %. As FTIR analysis is fast and non-destructive and provides complementary FG information, the analysis method demonstrated herein can substantially reduce the need for thermal–optical measurements for source emissions. [ABSTRACT FROM AUTHOR]

Published

2024

4. Characterization of PFAS air emissions from thermal application of fluoropolymer dispersions on fabrics.

Author

Wickersham, Lindsay C., Mattila, James M., Krug, Jonathan D., Jackson, Stephen R., Wallace, M. Ariel Geer, Shields, Erin P., Halliday, Hannah, Li, Emily Y., Liberatore, Hannah K., Farrior, Stanley, Preston, William, Ryan, Jeffrey V., Lee, Chun-Wai, and Linak, William P.

Subjects

FLUOROPOLYMERS, FLUOROALKYL compounds, MASS spectrometry, PROPIONIC acid, DISPERSION (Chemistry), CHEMICAL amplification, GREENHOUSE gases

Abstract

During thermal processes utilized in affixing fluoropolymer coatings dispersion to fibers and fabrics, coating components are vaporized. It is suspected that per- and polyfluoroalkyl substances (PFAS) from the dispersions may undergo chemical transformations at the temperatures used, leading to additional emitted PFAS thermal byproducts. It is important to characterize these emissions to support evaluation of the resulting environmental and health impacts. In this study, a bench-scale system was built to simulate this industrial process via thermal application of dispersions to fiberglass utilizing relevant temperatures and residence times in sequential drying, baking, and sintering steps. Experiments were performed with two commercially available dispersions and a simple model mixture containing a single PFAS (6:2 fluorotelomer alcohol [6:2 FTOH]). Vapor-phase emissions were sampled and characterized by several off-line and real-time mass spectrometry techniques for targeted and nontargeted PFAS. Results indicate that multiple PFAS thermal transformation products and multiple nonhalogenated organic species were emitted from the exit of the high temperature third (sintering) furnace when 6:2 FTOH was the only PFAS present in the aqueous mixture. This finding supports the hypothesis that temperatures typical of these industrial furnaces may also induce chemical transformations within the fluorinated air emissions. Experiments using the two commercial fluoropolymer dispersions indicate air emissions of part-per-million by volume (ppmv) concentrations of heptafluoropropyl-1,2,2,2-tetrafluoroethyl ether (Fluoroether E1), as well as other PFAS at operationally relevant temperatures. We suspect that E1 is a direct thermal decomposition product (via decarboxylation) of 2,3,3,3-tetrafluoro-2-(heptafluoropropoxy)propanoic acid (commonly referred to as HFPO-DA) present in the dispersions. Other thermal decomposition products, including the monomer, tetrafluoroethene, may originate from the PFAS used to stabilize the dispersion or from the polymer particles in suspension. This study represents the first researcher-built coating application simulator to report nontargeted PFAS emission characterization, real-time analyses, and the quantification of 30 volatile target PFAS. Implications: Thermal processes used to affix fluoropolymers to fabrics are believed to be a source of PFAS air emissions. These coating operations are used by many large and small manufacturers and typically do not currently require any air emissions control. This research designed and constructed a bench-scale system that simulates these processes and used several off-line and advanced real-time mass spectroscopy techniques to characterize PFAS air emissions from two commercial fluoropolymer dispersions. Further, as the compositions of commercial dispersions are largely unknown, a model three-component solution containing a single PFAS was used to characterize emissions of multiple PFAS thermal transformation products at operationally relevant conditions. This research shows that fluoropolymer fabric coating facilities can be sources of complex mixtures of PFAS air emissions that include volatile and semivolatile PFAS present in the dispersions, as well as PFAS byproducts formed by the thermal transformation of fluorocarbon and hydrocarbon species present in these dispersions. [ABSTRACT FROM AUTHOR]

Published

2023

5. Quantifying Functional Group Compositions of Household Fuel Burning Emissions.

Author

Li, Emily Y., Yazdani, Amir, Dillner, Ann M., Guofeng Shen, Champion, Wyatt M., Jetter, James J., Preston, William T., Russell, Lynn M., Hays, Michael D., and Satoshi Takahama

Subjects

*CHARCOAL, *FOURIER transform infrared spectroscopy, *FUNCTIONAL groups, *RED oak, *MEMBRANE filters, *INDOOR air pollution

Abstract

Globally, billions of people burn fuels indoors for cooking and heating, which contributes to millions of chronic illnesses and premature deaths annually. Additionally, residential burning contributes significantly to black carbon emissions, which have the highest global warming impacts after carbon dioxide and methane. In this study, we use Fourier transform infrared spectroscopy (FTIR) to analyze fine particulate emissions collected on Teflon membrane filters from fifteen cookstove types and five fuel types. Emissions from three fuel types (charcoal, kerosene, and red oak wood) were found to have enough FTIR spectral response for functional group (FG) analysis. We present distinct spectral profiles for particulate emissions of these three fuel types. We highlight the influential FGs constituting organic carbon (OC) using a multivariate statistical method and show that OC estimates by collocated FTIR and thermal optical transmittance (TOT) are highly correlated, with a coefficient of determination of 82.5%. As FTIR analysis is fast, non-destructive, and provides complementary FG information, the analysis method demonstrated herein can substantially reduce the need for thermal-optical measurements for source emissions. [ABSTRACT FROM AUTHOR]

Published

2023

6. Tubing material considerably affects measurement delays of gas-phase oxygenated per- and polyfluoroalkyl substances.

Author

Mattila, James M., Li, Emily Y., and Offenberg, John H.

Subjects

*FLUOROALKYL compounds, *CHEMICAL ionization mass spectrometry, *POLLUTANTS, *TUBES, *AIR pollutants, *PERSISTENT pollutants, *HIGH density polyethylene

Abstract

Per- and polyfluoroalkyl substances (PFAS) are persistent environmental pollutants associated with negative health impacts. Assessments of tubing-related measurement bias for volatile PFAS are lacking, as gas-wall interactions with tubing can delay quantification of gas-phase analytes. We use online iodide chemical ionization mass spectrometry measurements to characterize tubing delays for three gas-phase oxygenated PFAS − 4:2 fluorotelomer alcohol (4:2 FTOH), perfluorobutanoic acid (PFBA), and hexafluoropropylene oxide dimer acid (HFPO-DA). Perfluoroalkoxy alkane and high-density polyethylene tubing yielded relatively short absorptive measurement delays, with no clear dependence on tubing temperature or sampled humidity. Sampling through stainless steel tubing led to prolonged measurement delays due to reversible adsorption of PFAS to the tubing surface, with strong dependence on tubing temperature and sample humidification. Silcosteel tubing afforded shorter measurement delays than stainless steel due to diminished surface adsorption of PFAS. Characterizing and mitigating these tubing delays is crucial for reliable quantification of airborne PFAS. Implications: Per- and polyfluoroalkyl substances (PFAS) are persistent environmental contaminants. Many PFAS are sufficiently volatile to exist as airborne pollutants. Measurements and quantification of airborne PFAS can be biased from material-dependent gas-wall interactions with sampling inlet tubing. Thus, characterizing these gas-wall interactions are crucial for reliably investigating emissions, environmental transport, and fates of airborne PFAS. [ABSTRACT FROM AUTHOR]

Published

2023

7. Sequence- or Position-Specific Mutations in the Carboxyl-Terminal FL Motif of the Kidney Sodium Bicarbonate Cotransporter (NBC1) Disrupt Its Basolateral Targeting and α-Helical Structure

Author

Li, Hong C., Collier, Joel H., Shawki, Ali, Rudra, Jai S., Li, Emily Y., Mackenzie, Bryan, and Soleimani, Manoocher

Published

2009

8. Identification of a novel signal in the cytoplasmic tail of the [Na.sup.+] :HC[O.sup.-.sub.3] cotransporter NBC1 that mediates basolateral targeting

Author

Li, Hong C., Li, Emily Y., Neumeier, Lisa, Conforti, Laura, and Soleimani, Manoocher

Subjects

Cytoplasm -- Research, Cytoplasm -- Identification and classification, Amino acid metabolism -- Research, Biological sciences

Abstract

The [Na.sup.+]:HC[O.sup.-.sub.3] cotransporter NBC1 (SLC4A4, variant A, kidney specific) is located exclusively on the basolateral membrane of epithelial cells, implying that this molecule has acquired specific signals for targeting to the basolateral membrane. A motif with the sequence QQPFLS (positions 1010-1015) in the cytoplasmic tail of NBC1 was recently demonstrated to mediate targeting of NBC1 to the basolateral membrane. Here, we demonstrate that mutating the amino acid F (phenylalanine) or L (leucine) at positions 1013 or 1014 to alanine, respectively, resulted in the retargeting of NBC1 to the apical membrane. Furthermore, mutation of the FL motif to FF showed similar properties as the wild-type; however, mutation of the FL motif to LL showed significant intracellular retention of NBC1. Mutating the amino acids Q-Q-P and S (positions 1010-1011-1012 and 1015) to A-A-A and A, respectively, did not affect the membrane targeting of NBC1. Functional studies in oocytes with microelectrode demonstrated that the apically targeted mutants, as well as basolaterally targeted mutants, are all functional. We propose that the FL motif in the COOH-terminal tail of NBC1 is essential for the targeting of NBC1 to the basolateral membrane but is distinct from the membrane-targeting di-leucine motif identified in other membrane proteins. basolateral membrane; apical membrane; acid-base regulation; kidney; transmembrane domain

Published

2007

9. Constraints of FL Motif on the Targeting and Function of Sodium-Bicarbonate Cotransporter 1

Author

Li, Hong, Shawki, Ali, Park, YoonKyung, Li, Emily Y, Hahm, Kyung-Soo, Collier, Joel H., Mackenzie, Bryan, and Soleimani, Manoocher

Published

2008

10. The role of aspartic acid residues 405 and 416 of the kidney isotype of sodium-bicarbonate cotransporter 1 in its targeting to the plasma membrane.

Author

Li, Hong C., Kucher, Volodymyr, Li, Emily Y., Conforti, Laura, Zahedi, Kamyar A., and Soleimani, Manoocher

Abstract

The NH2 terminus of the sodium-bicarbonate cotransporter 1 (NBCe1) plays an important role in its targeting to the plasma membrane. To identify the amino acid residues that contribute to the targeting of NBCe1 to the plasma membrane, polarized MDCK cells were transfected with expression constructs coding for green fluorescent protein (GFP)-tagged NBCe1 NH2-terminal deletion mutants, and the localization of GFP-tagged proteins was analyzed by confocal microscopy. Our results indicate that the amino acids between residues 399 and 424 of NBCe1A contain important sequences that contribute to its localization to the plasma membrane. Site-directed mutagenesis studies showed that GFP-NBCe1A mutants D405A and D416A are retained in the cytoplasm of the polarized MDCK epithelial cells. Examination of functional activities of D405A and D416A reveals that their activities are reduced compared with the wild-type NBCe1A. Similarly, aspartic acid residues 449 and 460 of pancreatic NBCe1 (NBCe1B), which correspond to residues 405 and 416 of NBCe1A, are also required for its full functional activity and accurate targeting to the plasma membrane. In addition, while replacement of D416 with glutamic acid did not affect the targeting or functional activity of NBCe1A, substitution of D405 with glutamic acid led to the retention of the mutated protein in the intracellular compartment and impaired functional activity. These studies demonstrate that aspartic acid residues 405 and 416 in the NH2 terminus of NBCe1A are important in its accurate targeting to the plasma membrane. [ABSTRACT FROM AUTHOR]

Published

2012

11. Sequence- or position-specific mutations in the carboxyl-terminal FL motif of the kidney sodium bicarbonate cotransporter (NBC1) disrupt its basolateral targeting and alpha-helical structure.

Author

Li, Hong C., Collier, Joel H., Shawki, Ali, Rudra, Jai S., Li, Emily Y., Mackenzie, Bryan, and Soleimani, Manoocher

Subjects

SODIUM bicarbonate, BIOLOGICAL membranes, MUTAGENESIS, CELLS, RNA, PROTEIN metabolism, AMINO acids, ANIMAL experimentation, BIOCHEMISTRY, BIOLOGICAL transport, CELL lines, COMPARATIVE studies, DOGS, PHENOMENOLOGY, RESEARCH methodology, MEDICAL cooperation, MICROSCOPY, GENETIC mutation, OVUM, PROTEINS, RESEARCH, RESEARCH funding, SPECTRUM analysis, VERTEBRATES, WESTERN immunoblotting, EVALUATION research, PHYSIOLOGY

Abstract

The sodium-bicarbonate cotransporter NBC1 is targeted exclusively at the basolateral membrane. Mutagenesis of a dihydrophobic FL motif (residues 1013-1014) in the C-terminal domain disrupts the targeting of NBC1. In the present study, we determined the precise constraints of the FL motif required for basolateral targeting of NBC1 by expressing epitope-tagged wild-type and mutant NBC1 in MDCK cells and RNA-injected Xenopus oocytes and examining their subcellular localization. We assayed the functional activity of the mutants by measuring bicarbonate-induced currents in oocytes. Wild-type NBC1 (containing PFLS) was expressed exclusively on the basolateral membrane in MDCK cells. Reversal of the FL motif (PLFS) had no effect on basolateral targeting or activity. Shifting the FL motif one residue upstream (FLPS) resulted in mistargeting of the apical membrane but the FLPS mutant retained its functional activity in oocytes. Shifting the FL motif one residue downstream resulted in a mutant (PSFL) that did not efficiently translocate to the plasma membrane and was instead colocalized with the ER marker, protein disulfide isomerase (PDI). Analysis of circular dichroism (CD) revealed that a short peptide, 20 amino acid residues, of wild-type NBC1 contained a significant alpha-helical structure, whereas peptides in which the FL motif was reversed or C-terminally shifted were disordered. We therefore propose that the specific orientation and the precise location of the FL motif in the primary sequence of NBC1 are strict requirements for the alpha-helical structure of the C-terminal cytoplasmic domain and for targeting of NBC1 to the basolateral membrane. [ABSTRACT FROM AUTHOR]

Published

2009

12. Identification of a novel signal in the cytoplasmic tail of the Na+:HCO3- cotransporter NBC1 that mediates basolateral targeting.

Author

Li HC, Li EY, Neumeier L, Conforti L, and Soleimani M

Subjects

Amino Acid Motifs, Amino Acid Sequence, Animals, Dogs, Epithelial Cells physiology, Epitopes, Female, Fluorescent Antibody Technique, Humans, Microscopy, Confocal, Mutagenesis, Site-Directed, Oocytes physiology, Sodium-Bicarbonate Symporters chemistry, Sodium-Bicarbonate Symporters genetics, Transfection, Xenopus laevis, Cell Membrane physiology, Kidney Tubules, Proximal physiology, Protein Transport, Sodium-Bicarbonate Symporters physiology

Abstract

The Na(+):HCO(3)(-) cotransporter NBC1 (SLC4A4, variant A, kidney specific) is located exclusively on the basolateral membrane of epithelial cells, implying that this molecule has acquired specific signals for targeting to the basolateral membrane. A motif with the sequence QQPFLS (positions 1010-1015) in the cytoplasmic tail of NBC1 was recently demonstrated to mediate targeting of NBC1 to the basolateral membrane. Here, we demonstrate that mutating the amino acid F (phenylalanine) or L (leucine) at positions 1013 or 1014 to alanine, respectively, resulted in the retargeting of NBC1 to the apical membrane. Furthermore, mutation of the FL motif to FF showed similar properties as the wild-type; however, mutation of the FL motif to LL showed significant intracellular retention of NBC1. Mutating the amino acids Q-Q-P and S (positions 1010-1011-1012 and 1015) to A-A-A and A, respectively, did not affect the membrane targeting of NBC1. Functional studies in oocytes with microelectrode demonstrated that the apically targeted mutants, as well as basolaterally targeted mutants, are all functional. We propose that the FL motif in the COOH-terminal tail of NBC1 is essential for the targeting of NBC1 to the basolateral membrane but is distinct from the membrane-targeting di-leucine motif identified in other membrane proteins.

Published

2007