Summary of Study ST003031
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 PR001884. The data can be accessed directly via it's Project DOI: 10.21228/M8672X 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 | ST003031 |
Study Title | Early time-restricted eating improves markers of cardiometabolic health but has no impact on nutrient absorption in healthy adults |
Study Type | Randomized Controlled Trial |
Study Summary | Metabolomic analysis performed on 88 human plasma samples collected from 16 participants that received 2 treatments with 3 time points each. Samples were analyzed by UPLC-MS using a Waters Acquity UPLC and detected on a 4000 QTrap by multiple reaction monitoring (MRM) with negative mode electrospray ionization. |
Institute | California Polytechnic State University, San Luis Obispo |
Last Name | La Frano |
First Name | Michael |
Address | Cal Poly State University 1 Grand Avenue San Luis Obispo, CA 93407 |
mlafrano@calpoly.edu | |
Phone | (805) 756-6233 |
Submit Date | 2023-12-15 |
Num Groups | 2 |
Raw Data Available | Yes |
Raw Data File Type(s) | mzML |
Analysis Type Detail | LC-MS |
Release Date | 2024-01-23 |
Release Version | 1 |
Select appropriate tab below to view additional metadata details:
Project:
Project ID: | PR001884 |
Project DOI: | doi: 10.21228/M8672X |
Project Title: | Early time-restricted eating improves markers of cardiometabolic health but has no impact on nutrient absorption in healthy adults |
Project Type: | Randomized Controlled Trial |
Project Summary: | Early time-restricted eating (eTRE) improves aspects of cardiometabolic health. Although the circadian system appears to regulate nutrient absorption, little is known about the effects of eTRE on intestinal absorption. In this randomized crossover trial, 16 healthy adults follow a controlled, weight-maintenance diet for 9 days consuming all calories between 0800 and 1400 (eTRE schedule) or 0800 and 2000 (control schedule). We measure the energy content of the diet, stool, and urine with bomb calorimetry and calculate intestinal energy absorption. The eTRE schedule is more effective than the control eating schedule for improving markers of cardiometabolic health, including 24-h mean glucose concentrations and glycemic variability, assessed as the mean amplitude of glycemic excursions. However, eTRE has no effect on intestinal energy and macronutrient absorption, gastrointestinal transit time, colonic hydrogen gas production, or stool microbial composition, suggesting eTRE does not impact gastrointestinal function. |
Institute: | Pennington Biomedical Research Center |
Department: | Clinical Sciences |
Last Name: | Berryman |
First Name: | Claire |
Address: | 6400 Perkins Road, Baton Rouge, LA 70808 |
Email: | claire.berryman@pbrc.edu |
Phone: | (225) 763-3010 |
Subject:
Subject ID: | SU003145 |
Subject Type: | Human |
Subject Species: | Homo sapiens |
Taxonomy ID: | 9606 |
Factors:
Subject type: Human; Subject species: Homo sapiens (Factor headings shown in green)
mb_sample_id | local_sample_id | Treatment Group | Timepoint |
---|---|---|---|
SA328117 | DIG012 DP1.Fasting plasma | DP1 | Fasting |
SA328118 | DIG011 DP1.Fasting plasma | DP1 | Fasting |
SA328119 | DIG009 DP1.Fasting plasma | DP1 | Fasting |
SA328120 | DIG014 DP1.Fasting plasma | DP1 | Fasting |
SA328121 | DIG010 DP1.Fasting plasma | DP1 | Fasting |
SA328122 | DIG017 DP1.Fasting plasma | DP1 | Fasting |
SA328123 | DIG020 DP1.Fasting plasma | DP1 | Fasting |
SA328124 | DIG019 DP1.Fasting plasma | DP1 | Fasting |
SA328125 | DIG018 DP1.Fasting plasma | DP1 | Fasting |
SA328126 | DIG008 DP1.Fasting plasma | DP1 | Fasting |
SA328127 | DIG016 DP1.Fasting plasma | DP1 | Fasting |
SA328128 | DIG013 DP1.Fasting plasma | DP1 | Fasting |
SA328129 | DIG006 DP1.Fasting plasma | DP1 | Fasting |
SA328130 | DIG007 DP1.Fasting plasma | DP1 | Fasting |
SA328131 | DIG016 DP1.Hour 2 plasma | DP1 | Hour 2 |
SA328132 | DIG020 DP1.Hour 2 plasma | DP1 | Hour 2 |
SA328133 | DIG017 DP1.Hour 2 plasma | DP1 | Hour 2 |
SA328134 | DIG012 DP1.Hour 2 plasma | DP1 | Hour 2 |
SA328135 | DIG011 DP1.Hour 2 plasma | DP1 | Hour 2 |
SA328136 | DIG010 DP1.Hour 2 plasma | DP1 | Hour 2 |
SA328137 | DIG019 DP1.Hour 2 plasma | DP1 | Hour 2 |
SA328138 | DIG009 DP1.Hour 2 plasma | DP1 | Hour 2 |
SA328139 | DIG013 DP1.Hour 2 plasma | DP1 | Hour 2 |
SA328140 | DIG018 DP1.Hour 2 plasma | DP1 | Hour 2 |
SA328141 | DIG007 DP1.Hour 2 plasma | DP1 | Hour 2 |
SA328142 | DIG014 DP1.Hour 2 plasma | DP1 | Hour 2 |
SA328143 | DIG008 DP1.Hour 2 plasma | DP1 | Hour 2 |
SA328144 | DIG006 DP1.Hour 2 plasma | DP1 | Hour 2 |
SA328145 | DIG017 DP1.Hour 4 plasma | DP1 | Hour 4 |
SA328146 | DIG014 DP1.Hour 4 plasma | DP1 | Hour 4 |
SA328147 | DIG011 DP1.Hour 4 plasma | DP1 | Hour 4 |
SA328148 | DIG012 DP1.Hour 4 plasma | DP1 | Hour 4 |
SA328149 | DIG019 DP1.Hour 4 plasma | DP1 | Hour 4 |
SA328150 | DIG018 DP1.Hour 4 plasma | DP1 | Hour 4 |
SA328151 | DIG010 DP1.Hour 4 plasma | DP1 | Hour 4 |
SA328152 | DIG009 DP1.Hour 4 plasma | DP1 | Hour 4 |
SA328153 | DIG016 DP1.Hour 4 plasma | DP1 | Hour 4 |
SA328154 | DIG008 DP1.Hour 4 plasma | DP1 | Hour 4 |
SA328155 | DIG020 DP1.Hour 4 plasma | DP1 | Hour 4 |
SA328156 | DIG006 DP1.Hour 4 plasma | DP1 | Hour 4 |
SA328157 | DIG013 DP1.Hour 4 plasma | DP1 | Hour 4 |
SA328158 | DIG007 DP1.Hour 4 plasma | DP1 | Hour 4 |
SA328159 | DIG015 DP2.Fasting plasma | DP2 | Fasting |
SA328160 | DIG017 DP2.Fasting plasma | DP2 | Fasting |
SA328161 | DIG016 DP2.Fasting plasma | DP2 | Fasting |
SA328162 | DIG014 DP2.Fasting plasma | DP2 | Fasting |
SA328163 | DIG007 DP2.Fasting plasma | DP2 | Fasting |
SA328164 | DIG010 DP2.Fasting plasma | DP2 | Fasting |
SA328165 | DIG006 DP2.Fasting plasma | DP2 | Fasting |
SA328166 | DIG020 DP2.Fasting plasma | DP2 | Fasting |
SA328167 | DIG009 DP2.Fasting plasma | DP2 | Fasting |
SA328168 | DIG008 DP2.Fasting plasma | DP2 | Fasting |
SA328169 | DIG018 DP2.Fasting plasma | DP2 | Fasting |
SA328170 | DIG011 DP2.Fasting plasma | DP2 | Fasting |
SA328171 | DIG013 DP2.Fasting plasma | DP2 | Fasting |
SA328172 | DIG019 DP2.Fasting plasma | DP2 | Fasting |
SA328173 | DIG005 DP2.Fasting plasma | DP2 | Fasting |
SA328174 | DIG012 DP2.Fasting plasma | DP2 | Fasting |
SA328175 | DIG006 DP2.Hour 2 plasma | DP2 | Hour 2 |
SA328176 | DIG020 DP2.Hour 2 plasma | DP2 | Hour 2 |
SA328177 | DIG018 DP2.Hour 2 plasma | DP2 | Hour 2 |
SA328178 | DIG019 DP2.Hour 2 plasma | DP2 | Hour 2 |
SA328179 | DIG017 DP2.Hour 2 plasma | DP2 | Hour 2 |
SA328180 | DIG007 DP2.Hour 2 plasma | DP2 | Hour 2 |
SA328181 | DIG010 DP2.Hour 2 plasma | DP2 | Hour 2 |
SA328182 | DIG016 DP2.Hour 2 plasma | DP2 | Hour 2 |
SA328183 | DIG011 DP2.Hour 2 plasma | DP2 | Hour 2 |
SA328184 | DIG012 DP2.Hour 2 plasma | DP2 | Hour 2 |
SA328185 | DIG013 DP2.Hour 2 plasma | DP2 | Hour 2 |
SA328186 | DIG014 DP2.Hour 2 plasma | DP2 | Hour 2 |
SA328187 | DIG015 DP2.Hour 2 plasma | DP2 | Hour 2 |
SA328188 | DIG009 DP2.Hour 2 plasma | DP2 | Hour 2 |
SA328189 | DIG008 DP2.Hour 2 plasma | DP2 | Hour 2 |
SA328190 | DIG007 DP2.Hour 4 plasma | DP2 | Hour 4 |
SA328191 | DIG009 DP2.Hour 4 plasma | DP2 | Hour 4 |
SA328192 | DIG010 DP2.Hour 4 plasma | DP2 | Hour 4 |
SA328193 | DIG020 DP2.Hour 4 plasma | DP2 | Hour 4 |
SA328194 | DIG011 DP2.Hour 4 plasma | DP2 | Hour 4 |
SA328195 | DIG019 DP2.Hour 4 plasma | DP2 | Hour 4 |
SA328196 | DIG015 DP2.Hour 4 plasma | DP2 | Hour 4 |
SA328197 | DIG017 DP2.Hour 4 plasma | DP2 | Hour 4 |
SA328198 | DIG016 DP2.Hour 4 plasma | DP2 | Hour 4 |
SA328199 | DIG014 DP2.Hour 4 plasma | DP2 | Hour 4 |
SA328200 | DIG008 DP2.Hour 4 plasma | DP2 | Hour 4 |
SA328201 | DIG013 DP2.Hour 4 plasma | DP2 | Hour 4 |
SA328202 | DIG006 DP2.Hour 4 plasma | DP2 | Hour 4 |
SA328203 | DIG018 DP2.Hour 4 plasma | DP2 | Hour 4 |
SA328204 | DIG012 DP2.Hour 4 plasma | DP2 | Hour 4 |
Showing results 1 to 88 of 88 |
Collection:
Collection ID: | CO003138 |
Collection Summary: | Whole blood was collected from the antecubital vein while participants were fasted, and 2-and 4-h after a mixed meal challenge in EDTA vacutainer tubes (BD Vacutainer, New Jersey, USA). |
Sample Type: | Blood (plasma) |
Treatment:
Treatment ID: | TR003154 |
Treatment Summary: | This study was approved by the Florida State University Institutional Review Board and registered on clinicaltrials.gov (NCT04877262). Healthy, adults who were normal-weight (BMI:18.5-24.9 kg/m2) or overweight (BMI: 25-29.9 kg/m2) and 23-42 y, were recruited from the greater Tallahassee, Florida area between December 2021 and May 2022 and provided informed consent prior to participating. Potential participants were excluded if they had any disease or condition known to interfere with metabolism or normal gastrointestinal function (diabetes, cardiovascular disease, kidney disease, prior bariatric surgery, suspected or known fistulas, gastrointestinal obstruction, gastrointestinal disease, colonoscopy within 3 months of the study, alcoholism, substance abuse disorders); irregular menstrual cycle in the past 6 months; weight fluctuations greater that 5% during the previous 6 months; antibiotic use within 3 months of participation; allergies or intolerances to foods included in the controlled diet; habitual use of laxatives, stool softeners, or anti-diarrheal medications (≥ 1x/week); whole-gut transit time >72 h; or were pregnant or lactating. Participants followed an early time-restricted eating (eTRE) schedule (i.e., all meals consumed in a 6-h window between 0800 and 1400) and a control eating schedule (i.e., all meals consumed in a 12-h window between 0800 and 2000) for 9-d each in randomized order. On day 6 of each study period, participants arrived in the morning to the laboratory for a mixed-meal tolerance test (MMTT). Participants spent 6 hours in the laboratory to measure fasting (0h) and postprandial (2h and 4h) plasma metabolite concentrations in response to the MMTT. Whole blood was collected in EDTA vacutainer tubes (BD Vacutainer, Franklin Lakes, New Jersey, USA) and centrifuged at 3000 RPM for 15 minutes at 4°C before aliquots were frozen at -80°C until analysis. |
Sample Preparation:
Sampleprep ID: | SP003151 |
Sampleprep Summary: | Plasma (25 μL) was added to 1.5 mL Eppendorf tubes prior to the addition of 10 μL of 1 μM internal standard solution. Next, 750 μL chilled methanol was added and samples were vortexed 30 s before centrifugation at 15,000 × G for 10 min. Subsequently, the supernatant was collected and added to 1.5 mL high performance liquid chromatography (HPLC) amber glass vials, dried, and reconstituted in 100 μL 3:1 acetonitrile: methanol containing 1-cyclohexyl-ureido, 3-dodecanoic acid (CUDA; Sigma-Aldrich, St. Louis, MO, USA) solution. The solution was vortexed 30 s, transferred to microfilter tubes, and centrifuged at 10,000 × G for 3 min prior to transfer to a HPLC vial. |
Sampleprep Protocol Filename: | La_Frano_Lab_Methods_eTRE_v2.pdf |
Combined analysis:
Analysis ID | AN004968 |
---|---|
Analysis type | MS |
Chromatography type | HILIC |
Chromatography system | Waters Acquity I-Class |
Column | Phenomenex Luna NH2 (150 x 2mm,3um) |
MS Type | ESI |
MS instrument type | Triple quadrupole |
MS instrument name | ABI Sciex 4000 QTrap |
Ion Mode | NEGATIVE |
Units | Peak area |
Chromatography:
Chromatography ID: | CH003750 |
Methods Filename: | La_Frano_Lab_Methods_eTRE_v2.pdf |
Instrument Name: | Waters Acquity I-Class |
Column Name: | Phenomenex Luna NH2 (150 x 2mm,3um) |
Column Temperature: | 30 |
Flow Gradient: | 0 min 90%B, 10 min 5%B, 11 min 5%B, 13 min 90%B, 15 min 90%B |
Flow Rate: | 0.3 ml/min |
Solvent A: | 100% water with 20 mM ammonium acetate, 20 mM ammonium hydroxide |
Solvent B: | 10 mM ammonium hydroxide in 75:25 % v/v (volume %) acetonitrile/methanol |
Chromatography Type: | HILIC |
MS:
MS ID: | MS004708 |
Analysis ID: | AN004968 |
Instrument Name: | ABI Sciex 4000 QTrap |
Instrument Type: | Triple quadrupole |
MS Type: | ESI |
MS Comments: | Acquisition software AB Sciex Analyst and quantitation software Sciex MultiQuant. Metabolites detected using multiple reaction monitoring (MRM). |
Ion Mode: | NEGATIVE |
Analysis Protocol File: | La_Frano_Lab_Methods_eTRE_v2.pdf |