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Effect of a Dietary Intervention on Intracellular Lipid Levels, Insulin Sensitivity, and Glycemic Control in Type 2 Diabetes

Primary Purpose

Diabetes Mellitus, Type 2

Status
Not yet recruiting
Phase
Not Applicable
Locations
Study Type
Interventional
Intervention
Dietary intervention
Sponsored by
Physicians Committee for Responsible Medicine
About
Eligibility
Locations
Arms
Outcomes
Full info

About this trial

This is an interventional treatment trial for Diabetes Mellitus, Type 2 focused on measuring insulin sensitivity, glycemic control, intramyocellular, nutrition, hepatocellular

Eligibility Criteria

18 Years - undefined (Adult, Older Adult)All SexesDoes not accept healthy volunteers

Inclusion criteria are as follows:

  1. Men and women with type 2 diabetes treated by diet and/or oral hypoglycemic agents other that sulfonylureas
  2. Age ≥18 years
  3. Body mass index 26-40 kg/m2
  4. Medications (antidiabetic, antihypertensive, and lipid-lowering) have been stable for the past 3 months
  5. HbA1c between 6-10.5% (42-88 mmol/mol)

Exclusion criteria are as follows:

  1. Diabetes mellitus, type 1 and/or treatment with insulin or sulfonylureas
  2. Metal implants, such as a cardiac pacemaker or an aneurysm clip
  3. History of any endocrine condition that would affect body weight, such as thyroid disease, pituitary abnormality, or Cushing's syndrome
  4. Smoking during the past six months
  5. Alcohol consumption of more than 2 drinks per day or the equivalent, episodic increased drinking (e.g., more than 2 drinks per day on weekends), or a history of alcohol abuse or dependency followed by any current use
  6. Use of recreational drugs in the past 6 months
  7. Use within the preceding six months of medications that affect appetite or body weight, such as estrogens or other hormones, thyroid medications, systemic steroids, antidepressants (tricyclics, MAOIs, SSRIs), antipsychotics, lithium, anticonvulsants, appetite suppressants or other weight-loss drugs, herbs for weight loss or mood, St. John's wort, ephedra, beta blockers
  8. Pregnancy or intention to become pregnant during the study period
  9. Unstable medical or psychiatric illness
  10. Evidence of an eating disorder
  11. Likely to be disruptive in group sessions
  12. Already following a low-fat, vegan diet
  13. Lack of English fluency
  14. Inability to maintain current medication regimen
  15. Inability or unwillingness to participate in all components of the study
  16. Intention to follow another weight-loss method during the trial

Participants will also review and complete the Yale MRI Safety Questionnaire to determine eligibility for the study.

Sites / Locations

    Arms of the Study

    Arm 1

    Arm 2

    Arm Type

    Active Comparator

    Active Comparator

    Arm Label

    Low-fat, vegan diet

    Portion-controlled diet

    Arm Description

    For a 22-week period, participants will be asked to follow a low-fat vegan diet which consists of whole grains, vegetables, legumes, and fruits, with no restriction on energy intake. Animal products and added oils will be excluded. In choosing grain products and starchy vegetables (e.g., bread, potatoes), participants will be encouraged to select those retaining their natural fiber and having a glycemic index <70, using tables standardized to a value of 100 for glucose.

    For a 22-week period, participants will be asked to follow a portion-controlled diet which will include individualized diet plans that reduce daily energy intake by 500 kcal for overweight participants, and keep carbohydrate intake reasonably stable over time. It will derive 50% of total energy from carbohydrates, 20% from protein, and less than 30% from fat (≤7% saturated fat), with less than 200 mg/day of cholesterol/day.

    Outcomes

    Primary Outcome Measures

    Intramyocellular lipid content
    Proton magnetic resonance (MR) spectroscopy at 4T (Bruker) will be implemented to quantify intramyocellular lipid concentrations.
    Hepatocellular lipid content
    Proton magnetic resonance (MR) spectroscopy at 4T (Bruker) will be implemented to quantify intramyocellular lipid concentrations.
    Insulin sensitivity
    Insulin resistance will be assessed by the Homeostatic Model Assessment (HOMA) PREDIM indexes
    Concentration of glucose
    Concentration of glucose will be assessed during a standard meal test (Boost Plus, Nestle, Vevey, Switzerland; 720 kcal, 34% of energy from fat, 16% protein, 50% carbohydrate). Plasma concentrations of glucose will be measured at 0, 30, 60, 120, and 180 min.
    Concentration of C-peptide
    Concentration of C-peptide be assessed during a standard meal test (Boost Plus, Nestle, Vevey, Switzerland; 720 kcal, 34% of energy from fat, 16% protein, 50% carbohydrate). Concentration of C-peptide will be measured at 0, 30, 60, 120, and 180 min.
    Rate of glycemic control
    Rate of glycemic control will be assessed through HbA1C.

    Secondary Outcome Measures

    Resting energy expenditure
    Resting energy expenditure REE (pulse, respiratory rate and body temperature) will be measured for 20 minutes through indirect calorimetry utilizing a ventilated hood system in fasting participants.
    Postprandial metabolism
    Postprandial metabolism will be measured by indirect calorimetry. Participants will be asked to report to the laboratory within 60 minutes of waking and after a 12-hour fast. Following 30 minutes of quiet rest in a dimly lit room, pulse, respiratory rate, and body temperature will be measured. Resting energy expenditure will be measured for 20 minutes through indirect calorimetry utilizing a ventilated hood system. Postprandial metabolism will be measured four times, 20 minutes each time, over the course of 3 hours after the standard breakfast.
    Body Composition
    Body composition will be measured by dual energy x-ray absorptiometry (Lunar iDXA, GE Healthcare; Madison WI), assessing visceral adipose tissue volume and mass.
    Gut microbiome composition
    Quantitative determination of microorganisms and global analysis of microbial diversity from stool sample. The mean of the change between time points in bacteria counts.
    Concentration of plasma lipids
    Change in plasma cholesterol & triglycerides.
    Body weight
    Change in body weight measured on a calibrated scale.

    Full Information

    First Posted
    September 6, 2019
    Last Updated
    September 27, 2022
    Sponsor
    Physicians Committee for Responsible Medicine
    Collaborators
    Yale University
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    1. Study Identification

    Unique Protocol Identification Number
    NCT04088981
    Brief Title
    Effect of a Dietary Intervention on Intracellular Lipid Levels, Insulin Sensitivity, and Glycemic Control in Type 2 Diabetes
    Official Title
    Physicians Committee for Responsible Medicine, A Randomized, Crossover Trial of the Effect of a Dietary Intervention on Intracellular Lipid, Insulin Sensitivity, and Glycemic Control in Type 2 Diabetes
    Study Type
    Interventional

    2. Study Status

    Record Verification Date
    September 2022
    Overall Recruitment Status
    Not yet recruiting
    Study Start Date
    July 2023 (Anticipated)
    Primary Completion Date
    July 2023 (Anticipated)
    Study Completion Date
    July 2024 (Anticipated)

    3. Sponsor/Collaborators

    Responsible Party, by Official Title
    Sponsor
    Name of the Sponsor
    Physicians Committee for Responsible Medicine
    Collaborators
    Yale University

    4. Oversight

    Studies a U.S. FDA-regulated Drug Product
    No
    Studies a U.S. FDA-regulated Device Product
    No
    Data Monitoring Committee
    Yes

    5. Study Description

    Brief Summary
    The purpose of this study is to compare the effects of a low-fat, plant-based dietary intervention and a portion-controlled dietary intervention (compliant with current American Diabetes Association (ADA) guidelines) on changes in intramyocellular and hepatocellular lipid content in adults with type 2 diabetes. Changes in insulin sensitivity and glycemic control will also be assessed in this study. The study duration is 44 weeks.
    Detailed Description
    Type 2 diabetes is a disease characterized by discordance between the amount of insulin produced by pancreatic β-cells and the amount of insulin required to overcome insulin resistance in the liver and peripheral tissues. The development of insulin resistance has been strongly associated with the prolonged accumulation of lipids (fats) in the liver cells ("hepatocellular lipid") and muscle cells ("intramyocellular lipid"). Conventional pharmacologic therapeutics for type 2 diabetes, like metformin, are designed to reduce the accumulation of hepatocellular and intramyocellular lipids and, thereby, augment insulin sensitivity. Research has shown that a low-fat, plant-based diet, in which the consumption of lipids is limited, is a similarly effective therapeutic intervention for the reduction of hepatocellular and intramyocellular lipid content and the improvement of insulin sensitivity in type 2 diabetes. The purpose of this study is to compare the effects of low-fat, plant-based dietary intervention and a portion-controlled dietary intervention (compliant with current American Diabetes Association (ADA) guidelines) on hepatocellular and intramyocellular lipid content in adults with type 2 diabetes. Using a cross-over design, participants with type 2 diabetes will be randomly assigned to start with a plant-based or a portion-controlled diet for 22 weeks. The two groups will then switch to the opposite diet regimen for an additional 22 weeks. Before and after each intervention period, the investigators will measure intramuscular and liver fat content. The investigators will also assess the relationship between these variables, insulin sensitivity, and glycemic control. The investigators hypothesize that both dietary interventions will result in reductions in intramuscular and liver fat content, and that these changes will be associated with improvements in insulin sensitivity and glycemic control in individuals with type 2 diabetes. The investigators further hypothesize that the low-fat, plant-based dietary intervention will elicit greater changes in intracellular lipid concentration, compared with the portion-controlled dietary intervention.

    6. Conditions and Keywords

    Primary Disease or Condition Being Studied in the Trial, or the Focus of the Study
    Diabetes Mellitus, Type 2
    Keywords
    insulin sensitivity, glycemic control, intramyocellular, nutrition, hepatocellular

    7. Study Design

    Primary Purpose
    Treatment
    Study Phase
    Not Applicable
    Interventional Study Model
    Crossover Assignment
    Model Description
    randomized, cross-over
    Masking
    Outcomes Assessor
    Allocation
    Randomized
    Enrollment
    60 (Anticipated)

    8. Arms, Groups, and Interventions

    Arm Title
    Low-fat, vegan diet
    Arm Type
    Active Comparator
    Arm Description
    For a 22-week period, participants will be asked to follow a low-fat vegan diet which consists of whole grains, vegetables, legumes, and fruits, with no restriction on energy intake. Animal products and added oils will be excluded. In choosing grain products and starchy vegetables (e.g., bread, potatoes), participants will be encouraged to select those retaining their natural fiber and having a glycemic index <70, using tables standardized to a value of 100 for glucose.
    Arm Title
    Portion-controlled diet
    Arm Type
    Active Comparator
    Arm Description
    For a 22-week period, participants will be asked to follow a portion-controlled diet which will include individualized diet plans that reduce daily energy intake by 500 kcal for overweight participants, and keep carbohydrate intake reasonably stable over time. It will derive 50% of total energy from carbohydrates, 20% from protein, and less than 30% from fat (≤7% saturated fat), with less than 200 mg/day of cholesterol/day.
    Intervention Type
    Behavioral
    Intervention Name(s)
    Dietary intervention
    Intervention Description
    Low-fat, plant-based diet and a portion-controlled diet
    Primary Outcome Measure Information:
    Title
    Intramyocellular lipid content
    Description
    Proton magnetic resonance (MR) spectroscopy at 4T (Bruker) will be implemented to quantify intramyocellular lipid concentrations.
    Time Frame
    1.) Change from week 0 to week 22; 2.) Change from week 22 to week 44
    Title
    Hepatocellular lipid content
    Description
    Proton magnetic resonance (MR) spectroscopy at 4T (Bruker) will be implemented to quantify intramyocellular lipid concentrations.
    Time Frame
    1.) Change from week 0 to week 22; 2.) Change from week 22 to week 44
    Title
    Insulin sensitivity
    Description
    Insulin resistance will be assessed by the Homeostatic Model Assessment (HOMA) PREDIM indexes
    Time Frame
    Change from baseline to 22 weeks and change from 22 weeks to 44 weeks
    Title
    Concentration of glucose
    Description
    Concentration of glucose will be assessed during a standard meal test (Boost Plus, Nestle, Vevey, Switzerland; 720 kcal, 34% of energy from fat, 16% protein, 50% carbohydrate). Plasma concentrations of glucose will be measured at 0, 30, 60, 120, and 180 min.
    Time Frame
    1.) Change from week 0 to week 22; 2.) Change from week 22 to week 44
    Title
    Concentration of C-peptide
    Description
    Concentration of C-peptide be assessed during a standard meal test (Boost Plus, Nestle, Vevey, Switzerland; 720 kcal, 34% of energy from fat, 16% protein, 50% carbohydrate). Concentration of C-peptide will be measured at 0, 30, 60, 120, and 180 min.
    Time Frame
    1.) Change from week 0 to week 22; 2.) Change from week 22 to week 44
    Title
    Rate of glycemic control
    Description
    Rate of glycemic control will be assessed through HbA1C.
    Time Frame
    1.) Change from week 0 to week 22; 2.) Change from week 22 to week 44
    Secondary Outcome Measure Information:
    Title
    Resting energy expenditure
    Description
    Resting energy expenditure REE (pulse, respiratory rate and body temperature) will be measured for 20 minutes through indirect calorimetry utilizing a ventilated hood system in fasting participants.
    Time Frame
    Change from baseline to 22 weeks and change from 22 weeks to 44 weeks
    Title
    Postprandial metabolism
    Description
    Postprandial metabolism will be measured by indirect calorimetry. Participants will be asked to report to the laboratory within 60 minutes of waking and after a 12-hour fast. Following 30 minutes of quiet rest in a dimly lit room, pulse, respiratory rate, and body temperature will be measured. Resting energy expenditure will be measured for 20 minutes through indirect calorimetry utilizing a ventilated hood system. Postprandial metabolism will be measured four times, 20 minutes each time, over the course of 3 hours after the standard breakfast.
    Time Frame
    Change from Baseline to 22 weeks and change from 22 weeks to 44 weeks
    Title
    Body Composition
    Description
    Body composition will be measured by dual energy x-ray absorptiometry (Lunar iDXA, GE Healthcare; Madison WI), assessing visceral adipose tissue volume and mass.
    Time Frame
    Change from baseline to 22 weeks and change from 22 weeks to 44 weeks
    Title
    Gut microbiome composition
    Description
    Quantitative determination of microorganisms and global analysis of microbial diversity from stool sample. The mean of the change between time points in bacteria counts.
    Time Frame
    Change from baseline to 22 weeks and change from 22 weeks to 44 weeks
    Title
    Concentration of plasma lipids
    Description
    Change in plasma cholesterol & triglycerides.
    Time Frame
    Change from baseline to 22 weeks and change from 22 weeks to 44 weeks
    Title
    Body weight
    Description
    Change in body weight measured on a calibrated scale.
    Time Frame
    Change from baseline to 22 weeks and change from 22 weeks to 44 weeks
    Other Pre-specified Outcome Measures:
    Title
    Advanced Glycation Endproducts (AGEs)
    Description
    Advanced Glycation Endproducts (AGEs) will be measured using the AGE Reader mu by Diagnoptics.
    Time Frame
    1.) Change from week 0 to week 22; 2.) Change from week 22 to week 44
    Title
    Endothelial function
    Description
    Endothelial function will be measured through use of the itamar EndoPAT, which quantifies the endothelium-mediated changes in vascular tone elicited by a 5-minute occlusion of the brachial artery.
    Time Frame
    1.) Change from week 0 to week 22; 2.) Change from week 22 to week 44

    10. Eligibility

    Sex
    All
    Minimum Age & Unit of Time
    18 Years
    Accepts Healthy Volunteers
    No
    Eligibility Criteria
    Inclusion criteria are as follows: Men and women with type 2 diabetes treated by diet and/or oral hypoglycemic agents other that sulfonylureas Age ≥18 years Body mass index 26-40 kg/m2 Medications (antidiabetic, antihypertensive, and lipid-lowering) have been stable for the past 3 months HbA1c between 6-10.5% (42-88 mmol/mol) Exclusion criteria are as follows: Diabetes mellitus, type 1 and/or treatment with insulin or sulfonylureas Metal implants, such as a cardiac pacemaker or an aneurysm clip History of any endocrine condition that would affect body weight, such as thyroid disease, pituitary abnormality, or Cushing's syndrome Smoking during the past six months Alcohol consumption of more than 2 drinks per day or the equivalent, episodic increased drinking (e.g., more than 2 drinks per day on weekends), or a history of alcohol abuse or dependency followed by any current use Use of recreational drugs in the past 6 months Use within the preceding six months of medications that affect appetite or body weight, such as estrogens or other hormones, thyroid medications, systemic steroids, antidepressants (tricyclics, MAOIs, SSRIs), antipsychotics, lithium, anticonvulsants, appetite suppressants or other weight-loss drugs, herbs for weight loss or mood, St. John's wort, ephedra, beta blockers Pregnancy or intention to become pregnant during the study period Unstable medical or psychiatric illness Evidence of an eating disorder Likely to be disruptive in group sessions Already following a low-fat, vegan diet Lack of English fluency Inability to maintain current medication regimen Inability or unwillingness to participate in all components of the study Intention to follow another weight-loss method during the trial Participants will also review and complete the Yale MRI Safety Questionnaire to determine eligibility for the study.
    Central Contact Person:
    First Name & Middle Initial & Last Name or Official Title & Degree
    Hana Kahleova, MD, PhD
    Phone
    2025277379
    Email
    hkahleova@pcrm.org
    First Name & Middle Initial & Last Name or Official Title & Degree
    Tatiana Znayenko-Miller, MS
    Phone
    9192795993
    Email
    tznayenkomiller@pcrm.org
    Overall Study Officials:
    First Name & Middle Initial & Last Name & Degree
    Hana Kahleova, MD, PhD
    Organizational Affiliation
    Physicians Committee for Responsible Medicine
    Official's Role
    Principal Investigator

    12. IPD Sharing Statement

    Plan to Share IPD
    No
    IPD Sharing Plan Description
    Upon request individual participant data will be available to other researchers.
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    Effect of a Dietary Intervention on Intracellular Lipid Levels, Insulin Sensitivity, and Glycemic Control in Type 2 Diabetes

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