Summary of Study ST001004
This data is available at the NIH Common Fund's National Metabolomics Data Repository (NMDR) website, the Metabolomics Workbench, https://www.metabolomicsworkbench.org, where it has been assigned Project ID PR000679. The data can be accessed directly via it's Project DOI: 10.21228/M8X10M This work is supported by NIH grant, U2C- DK119886.
See: https://www.metabolomicsworkbench.org/about/howtocite.php
This study contains a large results data set and is not available in the mwTab file. It is only available for download via FTP as data file(s) here.
Study ID | ST001004 |
Study Title | Denver Asthma Panel Study-CHEAR Ancillary Study |
Study Type | Untargeted high-resolution mass spectrometry profiling |
Study Summary | Urban environments remain a poorly understood toxic environment for children with asthma, where improved exposure characterization and estimation of exposurehealth outcome relationships are clearly needed. The goal of this project is to investigate the interactions between relevant environmental exposures and asthma severity in a year-long longitudinal study of urban children with asthma. Environmental and clinical samples are being collected at 3 seasonal visits. Using these samples, we will measure the effects of multiple relevant exposures (environmental tobacco smoke (ETS), polycyclic aromatic hydrocarbons (PAHs), phthalates, and volatile organic compounds (VOCs)) on biological responses (metabolomics, oxidative stress, inflammatory markers, and endocannabinoids) and asthma outcomes. Our overall hypothesis is that relevant environmental exposures and their interactions drive disease severity in urban children with asthma. We will test this hypothesis by investigating the following aims: Aim 1: To investigate how environmental exposures (ETS, PAHs, phthalates, and VOCs) and their interactions contribute to asthma severity in urban children. Aim 2: To determine if environmental exposures in children with asthma are associated with changes in in biological responses (metabolomics, oxidative stress, inflammatory markers, and endocannabinoids). Aim 3: To determine which biological responses mediate the relationships between environmental exposures and asthma severity. Aim 4: To compare environmental exposures and biological responses in asthmatic and non-asthmatic children |
Institute | Emory University |
Department | School of Medicine |
Laboratory | Clincal Biomarkers Laboratory |
Last Name | Uppal |
First Name | Karan |
Address | 615 Michael St. Ste 225, Atlanta, GA, 30322, USA |
kuppal2@emory.edu | |
Phone | (404) 727 5027 |
Submit Date | 2018-06-21 |
Total Subjects | 66 |
Study Comments | Both CHEAR and Clinical Biomarker Laboratory pooled plasma samples were used for quality control. Study specific sample pools were not created |
Raw Data Available | Yes |
Raw Data File Type(s) | raw(Thermo) |
Chear Study | Yes |
Analysis Type Detail | LC-MS |
Release Date | 2021-08-31 |
Release Version | 1 |
Select appropriate tab below to view additional metadata details:
Project:
Project ID: | PR000679 |
Project DOI: | doi: 10.21228/M8X10M |
Project Title: | Denver Asthma Panel Study-CHEAR Ancillary Study |
Project Type: | NIH/NIEHS 1U2CES026560-01 |
Project Summary: | Urban environments remain a poorly understood toxic environment for children with asthma, where improved exposure characterization and estimation of exposurehealth outcome relationships are clearly needed. The goal of this project is to investigate the interactions between relevant environmental exposures and asthma severity in a year-long longitudinal study of urban children with asthma. Environmental and clinical samples are being collected at 3 seasonal visits. Using these samples, we will measure the effects of multiple relevant exposures (environmental tobacco smoke (ETS), polycyclic aromatic hydrocarbons (PAHs), phthalates, and volatile organic compounds (VOCs)) on biological responses (metabolomics, oxidative stress, inflammatory markers, and endocannabinoids) and asthma outcomes. Our overall hypothesis is that relevant environmental exposures and their interactions drive disease severity in urban children with asthma. We will test this hypothesis by investigating the following aims: Aim 1: To investigate how environmental exposures (ETS, PAHs, phthalates, and VOCs) and their interactions contribute to asthma severity in urban children. Aim 2: To determine if environmental exposures in children with asthma are associated with changes in in biological responses (metabolomics, oxidative stress, inflammatory markers, and endocannabinoids). Aim 3: To determine which biological responses mediate the relationships between environmental exposures and asthma severity. Aim 4: To compare environmental exposures and biological responses in asthmatic and non-asthmatic children |
Institute: | Emory University |
Department: | School of Medicine |
Laboratory: | Clinical Biomarkers Laboratory |
Last Name: | Uppal |
First Name: | Karan |
Address: | 615 Michael St. Ste 225, Atlanta, GA, 30322, USA |
Email: | kuppal2@emory.edu |
Phone: | (404) 727 5027 |
Funding Source: | NIEHS ES026560 |
Contributors: | Andrew Lui (University of Colorado Denver), Tasha Fingerlin ( University of Colorado Denver), Jonathon Thornburg (University of Colorado Denver), and Dean P. Jones (Emory University) |
Subject:
Subject ID: | SU001089 |
Subject Type: | Plasma samples |
Subject Species: | Homo sapiens |
Taxonomy ID: | 9606 |
Age Or Age Range: | Teens (12 – 17 yr) |
Species Group: | Mammals |
Factors:
Subject type: Plasma samples; Subject species: Homo sapiens (Factor headings shown in green)
mb_sample_id | local_sample_id | HRM_Sample_Type |
---|---|---|
SA070977 | q3June2014_2b_1 | Quality Control |
SA070978 | chearplasma_2f_1 | Quality Control |
SA070979 | nist2_1 | Quality Control |
SA070980 | q3June2014_1a_2 | Quality Control |
SA070981 | chearplasma_1a_2 | Quality Control |
SA070982 | chearplasma_2e_1 | Quality Control |
SA070983 | nist1_1 | Quality Control |
SA070984 | chearplasma_2c_1 | Quality Control |
SA070985 | q3June2014_1b_1 | Quality Control |
SA070986 | chearplasma_1f_1 | Quality Control |
SA070987 | q3June2014_2a_1 | Quality Control |
SA070988 | chearplasma_2a_1 | Quality Control |
SA070989 | chearplasma_1b_2 | Quality Control |
SA070990 | chearplasma_2b_1 | Quality Control |
SA070991 | chearplasma_2d_1 | Quality Control |
SA070992 | chearplasma_1c_2 | Quality Control |
SA070993 | chearplasma_2d_2 | Quality Control |
SA070994 | chearplasma_2c_2 | Quality Control |
SA070995 | chearplasma_2e_2 | Quality Control |
SA070996 | chearplasma_2f_2 | Quality Control |
SA070997 | nist2_2 | Quality Control |
SA070998 | q3June2014_2b_2 | Quality Control |
SA070999 | chearplasma_2b_2 | Quality Control |
SA071000 | chearplasma_2a_2 | Quality Control |
SA071001 | chearplasma_1e_2 | Quality Control |
SA071002 | chearplasma_1d_2 | Quality Control |
SA071003 | chearplasma_1f_2 | Quality Control |
SA071004 | q3June2014_1b_2 | Quality Control |
SA071005 | q3June2014_2a_2 | Quality Control |
SA071006 | chearplasma_1e_1 | Quality Control |
SA071007 | nist1_2 | Quality Control |
SA071008 | chearplasma_1c_1 | Quality Control |
SA071009 | chearplasma_1b_1 | Quality Control |
SA071010 | chearplasma_1d_1 | Quality Control |
SA071011 | chearplasma_1a_1 | Quality Control |
SA071012 | q3June2014_1a_1 | Quality Control |
SA071013 | C-1G900-P-00_1 | Study |
SA071014 | C-1G9J3-P-00_1 | Study |
SA071015 | C-1FXR7-P-00_2 | Study |
SA071016 | C-1G1R4-P-00_2 | Study |
SA071017 | C-1G306-P-00_1 | Study |
SA071018 | C-1G6T4-P-00_2 | Study |
SA071019 | C-1G8A4-P-00_1 | Study |
SA071020 | C-1G8P1-P-00_2 | Study |
SA071021 | C-1G9E4-P-00_2 | Study |
SA071022 | C-1G199-P-00_2 | Study |
SA071023 | C-1G397-P-00_2 | Study |
SA071024 | C-1G1P8-P-00_2 | Study |
SA071025 | C-1G850-P-00_1 | Study |
SA071026 | C-1G108-P-00_1 | Study |
SA071027 | C-1G470-P-00_2 | Study |
SA071028 | C-1G5P4-P-00_2 | Study |
SA071029 | C-1FXC0-P-00_2 | Study |
SA071030 | C-1G6A6-P-00_2 | Study |
SA071031 | C-1FZY9-P-00_2 | Study |
SA071032 | C-1G6J6-P-00_1 | Study |
SA071033 | C-1G0G9-P-00_2 | Study |
SA071034 | C-1FYH8-P-00_1 | Study |
SA071035 | C-1G7U1-P-00_2 | Study |
SA071036 | C-1G033-P-00_2 | Study |
SA071037 | C-1FY00-P-00_2 | Study |
SA071038 | C-1FX76-P-00_2 | Study |
SA071039 | C-1G579-P-00_2 | Study |
SA071040 | C-1G0N3-P-00_2 | Study |
SA071041 | C-1G3C5-P-00_2 | Study |
SA071042 | C-1GB35-P-00_2 | Study |
SA071043 | C-1G8Q9-P-00_2 | Study |
SA071044 | C-1G6M0-P-00_2 | Study |
SA071045 | C-1G041-P-00_2 | Study |
SA071046 | C-1G4E9-P-00_2 | Study |
SA071047 | C-1G7H0-P-00_2 | Study |
SA071048 | C-1G330-P-00_2 | Study |
SA071049 | C-1FZL8-P-00_2 | Study |
SA071050 | C-1G678-P-00_2 | Study |
SA071051 | C-1G9L9-P-00_2 | Study |
SA071052 | C-1G8X3-P-00_2 | Study |
SA071053 | C-1FXX3-P-00_2 | Study |
SA071054 | C-1FYU9-P-00_1 | Study |
SA071055 | C-1G4M2-P-00_1 | Study |
SA071056 | C-1FXD7-P-00_2 | Study |
SA071057 | C-1G876-P-00_2 | Study |
SA071058 | C-1G5S7-P-00_2 | Study |
SA071059 | C-1G6V0-P-00_2 | Study |
SA071060 | C-1G405-P-00_2 | Study |
SA071061 | C-1GB19-P-00_2 | Study |
SA071062 | C-1GAV9-P-00_2 | Study |
SA071063 | C-1G4F7-P-00_2 | Study |
SA071064 | C-1G363-P-00_2 | Study |
SA071065 | C-1G124-P-00_2 | Study |
SA071066 | C-1G181-P-00_2 | Study |
SA071067 | C-1G2W2-P-00_2 | Study |
SA071068 | C-1G6L2-P-00_2 | Study |
SA071069 | C-1FYC9-P-00_2 | Study |
SA071070 | C-1FYY0-P-00_2 | Study |
SA071071 | C-1G785-P-00_2 | Study |
SA071072 | C-1G9V7-P-00_1 | Study |
SA071073 | C-1G1G8-P-00_1 | Study |
SA071074 | C-1G3D2-P-00_2 | Study |
SA071075 | C-1G1N2-P-00_2 | Study |
SA071076 | C-1FYK1-P-00_2 | Study |
Collection:
Collection ID: | CO001083 |
Collection Summary: | Blood plasma samples were collected from nonfasting participants in the Denver Asthma Panel Study at enrollment (baseline). Blood samples were collected in tubes containing EDTA and after centrifugation aliquots of plasma were transferred to 1.8 ml freezer tubes and stored in a -70 degrees C freezer. |
Sample Type: | Plasma - EDTA |
Storage Conditions: | Described in summary |
Treatment:
Treatment ID: | TR001103 |
Treatment Summary: | Samples were received frozen in aliquouts of <250uL. Prior to analysis, samples were thawed and prepared for HRM analysis using the standard protocols described in the Sample Preparation section. |
Sample Preparation:
Sampleprep ID: | SP001096 |
Sampleprep Summary: | Samples were prepared for metabolomics analysis using established methods(Johnson et al. (2010). Analyst; Go et al. (2015). Tox Sci). Prior to analysis, plasma aliquots were removed from storage at -80 degrees C and thawed on ice. Each cryotube was then vortexed briefly to ensure homogeneity, and 50 microliters was transferred to a clean microfuge tube. Immediately after, the plasma was treated with 100 microliters of ice-cold LC-MS grade acetonitrile (Sigma Aldrich) containing 2.5 microliters of internal standard solution with eight stable isotopic chemicals selected to cover a range of chemical properties. Following addition of acetonitrile, urine was equilibrated for 30 min on ice, upon which precipitated proteins were removed by centrifuge (14,000 rpm at 4 degrees C for 10 min). The resulting supernatant (100 microliters) was removed, added to a low volume autosampler vial and maintained at 4 degrees C until analysis (<22 h). |
Sampleprep Protocol ID: | HRM_SP_082016_01 |
Sampleprep Protocol Filename: | EmoryUniversity_HRM_SP_082016_01.pdf |
Sampleprep Protocol Comments: | Date effective: 30 July 2016 |
Extraction Method: | 2:1 acetonitrile: sample followed by vortexing and centrifugation |
Combined analysis:
Analysis ID | AN001714 | AN001715 |
---|---|---|
Analysis type | MS | MS |
Chromatography type | HILIC | Reversed phase |
Chromatography system | Thermo Dionex Ultimate 3000 | Thermo Dionex Ultimate 3000 |
Column | Waters XBridge BEH Amide XP HILIC (50 x 2.1mm,2.5um) with Thermo Accucore HILIC guard | Higgins endcapped C18 stainless steel (50 x 2.1mm,3um),Product #TS-0521-C183; Thermo Accucore C18 guard with holder,Product #17126-014005 |
MS Type | ESI | ESI |
MS instrument type | Orbitrap | Orbitrap |
MS instrument name | Thermo Q Exactive HF hybrid Orbitrap | Thermo Q Exactive HF hybrid Orbitrap |
Ion Mode | POSITIVE | NEGATIVE |
Units | Peak Area | Peak Area |
Chromatography:
Chromatography ID: | CH001210 |
Chromatography Summary: | The HILIC column is operated parallel to reverse phase column for simultaneous analytical separation and column flushing through the use of a dual head HPLC pump equipped with 10-port and 6-port switching valves. During operation of HILIC separation method, the MS is operated in positive ion mode and 10 microliters of sample is injected onto the HILIC column while the reverse phase column is flushing with wash solution. Flow rate is maintained at 0.35 mL/min until 1.5 min, increased to 0.4 mL/min at 4 min and held for 1 min. Solvent A is 100% LC-MS grade water, solvent B is 100% LC-MS grade acetonitrile and solvent C is 2% formic acid (v/v) in LC-MS grade water. Initial mobile phase conditions are 22.5% A, 75% B, 2.5% C hold for 1.5 min, with linear gradient to 77.5% A, 20% B, 2.5% C at 4 min, hold for 1 min, resulting in a total analytical run time of 5 min. During the flushing phase (reverse phase analytical separation), the HILIC column is equilibrated with a wash solution of 77.5% A, 20% B, 2.5% C. |
Methods ID: | 2% formic acid in LC-MS grade water |
Methods Filename: | 20160920_posHILIC120kres5min_ESI_c18negwash.meth |
Chromatography Comments: | Triplicate injections for each chromatography mode |
Instrument Name: | Thermo Dionex Ultimate 3000 |
Column Name: | Waters XBridge BEH Amide XP HILIC (50 x 2.1mm,2.5um) with Thermo Accucore HILIC guard |
Column Temperature: | 60C |
Flow Gradient: | A= water, B= acetontrile, C= 2% formic acid in water; 22.5% A, 75% B, 2.5% C hold for 1.5 min, linear gradient to 77.5% A, 20% B, 2.5% C at 4 min, hold for 1 min |
Flow Rate: | 0.35 mL/min for 1.5 min; linear increase to 0.4 mL/min at 4 min, hold for 1 min |
Sample Injection: | 10 uL |
Solvent A: | 100% water |
Solvent B: | 100% acetonitrile |
Analytical Time: | 5 min |
Sample Loop Size: | 15 uL |
Sample Syringe Size: | 100 uL |
Chromatography Type: | HILIC |
Chromatography ID: | CH001211 |
Chromatography Summary: | The C18 column is operated parallel to the HILIC column for simultaneous analytical separation and column flushing through the use of a dual head HPLC pump equipped with 10-port and 6- port switching valves. During operation of the C18 method, the MS is operated in negative ion mode and 10 μL of sample is injected onto the C18 column while the HILIC column is flushing with wash solution. Flow rate is maintained at 0.4 mL/min until 1.5 min, increased to 0.5 mL/min at 2 min and held for 3 min. Solvent A is 100% LC-MS grade water, solvent B is 100% LC-MS grade acetonitrile and solvent C is 10mM ammonium acetate in LC-MS grade water. Initial mobile phase conditions are 60% A, 35% B, 5% C hold for 0.5 min, with linear gradient to 0% A, 95% B, 5% C at 1.5 min, hold for 3.5 min, resulting in a total analytical run time of 5 min. During the flushing phase (HILIC analytical separation), the C18 column is equilibrated with a wash solution of 0% A, 95% B, 5% C until 2.5 min, followed by an equilibration solution of 60% A, 35% B, 5% C for 2.5 min. |
Methods ID: | 10mM ammonium acetate in LC-MS grade water |
Methods Filename: | 20160920_negC18120kres5min_ESI_HILICposwash.meth |
Chromatography Comments: | Triplicate injections for each chromatography mode |
Instrument Name: | Thermo Dionex Ultimate 3000 |
Column Name: | Higgins endcapped C18 stainless steel (50 x 2.1mm,3um),Product #TS-0521-C183; Thermo Accucore C18 guard with holder,Product #17126-014005 |
Column Temperature: | 60C |
Flow Gradient: | A= water, B= acetontrile, C= 10mM ammonium acetate in water; 60% A, 35% B, 5% C hold for 0.5 min, linear gradient to 0% A, 95% B, 5% C at 1.5 min, hold for 3 min |
Flow Rate: | 0.4 mL/min for 1.5 min; linear increase to 0.5 mL/min at 2 min held for 3 min |
Sample Injection: | 10 uL |
Solvent A: | 100% water |
Solvent B: | 100% acetonitrile |
Analytical Time: | 5 min |
Sample Loop Size: | 15 uL |
Sample Syringe Size: | 100 uL |
Chromatography Type: | Reversed phase |
MS:
MS ID: | MS001586 |
Analysis ID: | AN001714 |
Instrument Name: | Thermo Q Exactive HF hybrid Orbitrap |
Instrument Type: | Orbitrap |
MS Type: | ESI |
Ion Mode: | POSITIVE |
Capillary Temperature: | 250C |
Collision Gas: | N2 |
Dry Gas Flow: | 45 |
Dry Gas Temp: | 150C |
Mass Accuracy: | < 3ppm |
Spray Voltage: | 3500 |
Activation Parameter: | 5.00E+05 |
Activation Time: | 118ms |
Interface Voltage: | S-Lens RF level= 55 |
Resolution Setting: | 120,000 |
Scanning Range: | 85-1275 |
Analysis Protocol File: | EmoryUniversity_HRM_QEHF-MS_092017_v1.pdf |
MS ID: | MS001587 |
Analysis ID: | AN001715 |
Instrument Name: | Thermo Q Exactive HF hybrid Orbitrap |
Instrument Type: | Orbitrap |
MS Type: | ESI |
Ion Mode: | NEGATIVE |
Capillary Temperature: | 250C |
Collision Gas: | N2 |
Dry Gas Flow: | 45 |
Dry Gas Temp: | 150C |
Mass Accuracy: | < 3ppm |
Spray Voltage: | -4000 |
Activation Parameter: | 5.00E+05 |
Activation Time: | 118ms |
Interface Voltage: | S-Lens RF level= 55 |
Resolution Setting: | 120,000 |
Scanning Range: | 85-1275 |
Analysis Protocol File: | EmoryUniversity_HRM_QEHF-MS_092017_v1.pdf |
MS ID: | MS001669 |
Analysis ID: | AN001714 |
Instrument Name: | Thermo Q Exactive HF hybrid Orbitrap |
Instrument Type: | Orbitrap |
MS Type: | ESI |
Ion Mode: | POSITIVE |
Capillary Temperature: | 250C |
Collision Gas: | N2 |
Dry Gas Flow: | 45 |
Dry Gas Temp: | 150C |
Mass Accuracy: | < 3ppm |
Spray Voltage: | 3500 |
Activation Parameter: | 5.00E+05 |
Activation Time: | 118ms |
Interface Voltage: | S-Lens RF level= 55 |
Resolution Setting: | 120,000 |
Scanning Range: | 85-1275 |
Analysis Protocol File: | EmoryUniversity_HRM_QEHF-MS_092017_v1.pdf |
MS ID: | MS001670 |
Analysis ID: | AN001715 |
Instrument Name: | Thermo Q Exactive HF hybrid Orbitrap |
Instrument Type: | Orbitrap |
MS Type: | ESI |
Ion Mode: | NEGATIVE |
Capillary Temperature: | 250C |
Collision Gas: | N2 |
Dry Gas Flow: | 45 |
Dry Gas Temp: | 150C |
Mass Accuracy: | < 3ppm |
Spray Voltage: | -4000 |
Activation Parameter: | 5.00E+05 |
Activation Time: | 118ms |
Interface Voltage: | S-Lens RF level= 55 |
Resolution Setting: | 120,000 |
Scanning Range: | 85-1275 |
Analysis Protocol File: | EmoryUniversity_HRM_QEHF-MS_092017_v1.pdf |