Clinical Trials Logo

Clinical Trial Details — Status: Completed

Administrative data

NCT number NCT00721617
Other study ID # IRB00009277
Secondary ID
Status Completed
Phase N/A
First received June 26, 2008
Last updated July 23, 2015
Start date April 2009
Est. completion date June 2011

Study information

Verified date July 2015
Source Emory University
Contact n/a
Is FDA regulated No
Health authority United States: Institutional Review Board
Study type Interventional

Clinical Trial Summary

Although a large number of obese patients develop high blood pressure, the cause is unknown. The purpose of this study is to look at the effect of high fatty acids (a type of fat) in the development of high blood pressure in obese people.


Description:

Recent studies indicate that increased levels of a circulating fat (free fatty acids or FFAs) increases blood pressure, impairs endothelial (vascular) function, and increases inflammatory markers in subjects with and without diabetes. The effects of FFA on blood pressure and vasculature have not been fully investigated. A group of 12 obese nondiabetic, normotensive subjects will be admitted to the Grady Clinical Research Center (GCRC) on separate 4 occasions. Research subjects will receive, in random order, a 8-hour intravenous (IV) infusion of Intralipid 20% at 40 mL/h (a fat solution), 8-hour IV infusion of normal saline at 40 mL/h, 8-hour IV infusion of dextrose (sugar) 10% at 40 mL/h, and a 8-hour intravenous (IV) infusion combination of Intralipid 20% and dextrose 10% at 40mL/h.


Recruitment information / eligibility

Status Completed
Enrollment 12
Est. completion date June 2011
Est. primary completion date June 2011
Accepts healthy volunteers Accepts Healthy Volunteers
Gender Both
Age group 18 Years to 65 Years
Eligibility Inclusion Criteria:

- Males or females

- Obese subjects (body mass index (BMI) = 30 kg/m^2)

- 18 and 65 years

- Blood pressure reading < 140/80 mm Hg and no prior history of hypertension

Exclusion Criteria:

- History of diabetes mellitus

- History of hypertension

- Fasting triglyceride levels > 250 mg/dL

- Liver disease (ALT 2.5x > upper limit of normal)

- Serum creatinine =1.5 mg/dL

- Smokers, drug or alcohol abuse

- Mental condition rendering the subject unable to understand the scope and possible consequences of the study

- Female subjects who are pregnant or breast feeding

Study Design

Allocation: Randomized, Endpoint Classification: Efficacy Study, Intervention Model: Parallel Assignment, Masking: Single Blind (Outcomes Assessor), Primary Purpose: Basic Science


Related Conditions & MeSH terms


Intervention

Other:
Intralipid 20%
Lean and obese normotensive subjects will receive Intralipid 20% infusion. Intralipid is an oil-in-water emulsion derived from egg phospholipids, soybean, and glycerol. The Intralipid 20% long-chain triglyceride emulsion contains: 200 g of soy bean oil; 12 g of egg yolk; 25 g of glycerol. The emulsion is composed of the following free fatty acids (FFAs): linoleic acid: 50%, oleic acid: 26%, palmitic acid: 10%, stearic acid: 9%, egg yolk, phospholipids: 3.5% It will be given intravenously at 20 ml/hr (96 g/24 h) for 24 hours.
Normal Saline
Lean and obese normotensive subjects will receive normal saline at 20 ml/hr for 24 hours.
Oral fat load
Lean and obese normotensive subjects will receive an oral fat load at 96 g/24hr. The oral liquid fat load will be given in equal amounts (16 g) every 4 hours (total 96 g over 24 hours).

Locations

Country Name City State
United States Grady Memorial Hospital Atlanta Georgia

Sponsors (2)

Lead Sponsor Collaborator
Emory University American Diabetes Association

Country where clinical trial is conducted

United States, 

Outcome

Type Measure Description Time frame Safety issue
Primary Change in Flow-mediated Dilation From Baseline to 4 Hours Endothelium-dependent brachial artery flow-mediated dilation (FMD) was assessed. Ultrasound images of the brachial artery were obtained and arterial diameters were measured with customized software. FMD is expressed as the change in diameter from baseline to 4 hours. Baseline, 4 hours No
Primary Change in Systolic Blood Pressure From Baseline to 4 Hours Systolic blood pressure is the amount of pressure the heart generates when pumping blood through the arteries to the body. Current guidelines identify normal systolic blood pressure as lower than 120 mmHg. Blood pressure was measured in triplicate with a manual cuff prior to and every 4 hours during the 8 hour infusion with subjects in supine position. Change is the difference between 4 hour systolic blood pressure from baseline systolic blood pressure. Baseline, 4 hours No
Primary Change in Systolic Blood Pressure From Baseline to 8 Hours Systolic blood pressure is the amount of pressure your heart generates when pumping blood through your arteries to the rest of your body. Current guidelines identify normal systolic blood pressure as lower than 120 mmHg. Blood pressure was measured in triplicate with a manual cuff prior to and every 4 hours during the 8 hour infusion with subjects in supine position. Change is the difference between 8 hour systolic blood pressure from baseline systolic blood pressure. Baseline, 8 hours No
Primary Change in Diastolic Blood Pressure From Baseline to 4 Hours Diastolic blood pressure is the amount of pressure in your arteries when your heart is at rest between beats. Current guidelines identify normal diastolic blood pressure as lower than 80 mmHg. Blood pressure was measured in triplicate with a manual cuff prior to and every 4 hours during the 8 hour infusion with subjects in supine position. Change is the difference between 4 hour diastolic blood pressure from baseline diastolic blood pressure. Baseline, 4 hours No
Primary Change in Diastolic Blood Pressure From Baseline to 8 Hours Diastolic blood pressure is the amount of pressure in your arteries when your heart is at rest between beats. Current guidelines identify normal diastolic blood pressure as lower than 80 mmHg. Blood pressure was measured in triplicate with a manual cuff prior to and every 4 hours during the 8 hour infusion with subjects in supine position. Change is the difference between 8 hour diastolic blood pressure from baseline diastolic blood pressure. Baseline, 8 hours No
Secondary Change in FFA (Free Fatty Acid) Levels From Baseline to 4 Hours Blood samples were collected for measurement of free fatty acids (FFA) at baseline and 4 hours after each infusion. FFA levels were determined by colorimetric method. Current guidelines identify normal range of FFA level as less than 0.72 mmol/L. Elevated plasma levels of FFA indicate a greater rate of insulin resistance. Change is the difference between 4 hour FFA levels from baseline FFA levels. Baseline, 4 hours No
Secondary Changes in FFA (Free Fatty Acid) Levels From Baseline to 8 Hours Blood samples were collected for measurement of free fatty acids (FFA) at baseline and 8 hours after each infusion. FFA levels were determined by colorimetric method. Current guidelines identify normal range of FFA level as less than 0.72 mmol/L. Elevated plasma levels of FFA indicate a greater rate of insulin resistance. Change iis the difference between 8 hour FFA levels from baseline FFA levels. Baseline, 8 hours No
Secondary Change in Triglyceride Levels From Baseline to 4 Hours Blood samples were collected for measurement of triglycerides at baseline and 4 hours after each infusion. Triglyceride levels were measured on CX7 Chemistry Analyzer. Current guidelines identify normal range of triglyceride level as less than 150 mg/dL. Elevated levels of triglycerides are associated with an increased risk of developing heart disease. Change is the difference between 4 hour triglyceride levels from baseline triglyceride levels. Baseline, 4 hours No
Secondary Change in Triglyceride Levels From Baseline to 8 Hours Blood samples were collected for measurement of triglycerides at baseline and 4 hours after each infusion. Triglyceride levels were measured on CX7 Chemistry Analyzer. Current guidelines identify normal range of triglyceride level as less than 150 mg/dL. Elevated levels of triglycerides are associated with an increased risk of developing heart disease. Change is the difference between 8 hour triglyceride levels from baseline triglyceride levels. Baseline, 8 hours No
Secondary Plasma Glucose Levels for Saline Infusion Blood samples were collected for measurement of plasma glucose levels at baseline, 4 hours after saline infusion, and 8 hours after saline infusion. Plasma glucose was measured on CX7 Chemistry Analyzer. Current guidelines identify normal fasting glucose as less than 100 mg/dL. High levels of glucose most frequently indicates diabetes. Baseline, 4 hours, 8 hours No
Secondary Plasma Glucose Levels for Intralipid Infusion Blood samples were collected for measurement of plasma glucose levels at baseline, 4 hours after intralipid infusion, and 8 hours after intralipid infusion. Plasma glucose was measured on CX7 Chemistry Analyzer. Current guidelines identify normal fasting glucose as less than 100 mg/dL. High levels of glucose most frequently indicates diabetes. Baseline, 4 hours, 8 hours No
Secondary Plasma Glucose Levels for Dextrose Infusion Blood samples were collected for measurement of plasma glucose levels at baseline, 4 hours after dextrose infusion, and 8 hours after dextrose infusion. Plasma glucose was measured on CX7 Chemistry Analyzer. Current guidelines identify normal fasting glucose as less than 100 mg/dL. High levels of glucose most frequently indicates diabetes. Baseline, 4 hours, 8 hours No
Secondary Plasma Glucose Levels for Intralipid/Dextrose Infusion Blood samples were collected for measurement of plasma glucose levels at baseline, 4 hours after intralipid/dextrose infusion, and 8 hours after intralipid/dextrose infusion. Plasma glucose was measured on CX7 Chemistry Analyzer. Current guidelines identify normal fasting glucose as less than 100 mg/dL. High levels of glucose most frequently indicates diabetes. Baseline, 4 hours, 8 hours No
Secondary Insulin Levels for Saline Infusion Blood samples were collected for the measurement of insulin levels at baseline, 4 hours after saline infusion, and 8 hours after saline infusion. Insulin was measured in plasma using a solid phase, two-site sequential chemiluminescent immunometric assays on the DPC Immulite analyzer. Current guidelines identify normal insulin levels as 8.8 µU/mL for men and 8.4 for women. High levels of insulin most frequently indicate insulin resistance or hypoglycemia, if paired with a low glucose level. Low levels of insulin paired with high glucose level can indicate diabetes. Baseline, 4 hours, 8 hours No
Secondary Insulin Levels for Intralipid Infusion Blood samples were collected for the measurement of insulin levels at baseline, 4 hours after intralipid infusion, and 8 hours after intralipid infusion. Insulin was measured in plasma using a solid phase, two-site sequential chemiluminescent immunometric assays on the DPC Immulite analyzer. Current guidelines identify normal insulin levels as 8.8 µU/mL for men and 8.4 for women. High levels of insulin most frequently indicate insulin resistance or hypoglycemia, if paired with a low glucose level. Low levels of insulin paired with high glucose level can indicate diabetes. Baseline, 4 hours, 8 hours No
Secondary Insulin Levels for Dextrose Infusion Blood samples were collected for the measurement of insulin levels at baseline, 4 hours after dextrose infusion, and 8 hours after dextrose infusion. Insulin was measured in plasma using a solid phase, two-site sequential chemiluminescent immunometric assays on the DPC Immulite analyzer. Current guidelines identify normal insulin levels as 8.8 µU/mL for men and 8.4 for women. High levels of insulin most frequently indicate insulin resistance or hypoglycemia, if paired with a low glucose level. Low levels of insulin paired with high glucose level can indicate diabetes. Baseline, 4 hours, 8 hours No
Secondary Insulin Levels for Intralipid/Dextrose Infusion Blood samples were collected for the measurement of insulin levels at baseline, 4 hours after intralipid/dextrose infusion, and 8 hours after intralipid/dextrose infusion. Insulin was measured in plasma using a solid phase, two-site sequential chemiluminescent immunometric assays on the DPC Immulite analyzer. Current guidelines identify normal insulin levels as 8.8 µU/mL for men and 8.4 for women. High levels of insulin most frequently indicate insulin resistance or hypoglycemia, if paired with a low glucose level. Low levels of insulin paired with high glucose level can indicate diabetes. Baseline, 4 hours, 8 hours No
Secondary C-peptides Levels for Saline Infusion Blood samples were collected for the measurement of C-peptide levels at baseline, 4 hours after saline infusion, and 8 hours after saline infusion. C-peptide was measured in plasma using a solid phase, two-site sequential chemiluminescent immunometric assays on the DPC Immulite analyzer. Current guidelines identify normal C-peptide levels as 0.51 to 2.72 ng/mL.
A high level of C-peptide generally indicates a high level of endogenous insulin production. This may be in response to a high blood glucose caused by glucose intake and/or insulin resistance. A high level of C-peptide is also seen with insulinomas and may be seen with low blood potassium, Cushing syndrome, and renal failure. A low level of C-peptide is associated with a low level of insulin production. This can occur when insufficient insulin is being produced by the beta cells, with diabetes for example, or when production is suppressed by treatment with exogenous insulin.
Baseline, 4 hours, 8 hours No
Secondary C-peptides Levels for Intralipid Infusion Blood samples were collected for the measurement of C-peptide levels at baseline, 4 hours after Intralipid infusion, and 8 hours after Intralipid infusion. C-peptide was measured in plasma using a solid phase, two-site sequential chemiluminescent immunometric assays on the DPC Immulite analyzer. Current guidelines identify normal C-peptide levels as 0.51 to 2.72 ng/mL.
A high level of C-peptide generally indicates a high level of endogenous insulin production. This may be in response to a high blood glucose caused by glucose intake and/or insulin resistance. A high level of C-peptide is also seen with insulinomas and may be seen with low blood potassium, Cushing syndrome, and renal failure. A low level of C-peptide is associated with a low level of insulin production. This can occur when insufficient insulin is being produced by the beta cells, with diabetes for example, or when production is suppressed by treatment with exogenous insulin.
Baseline, 4 hours, 8 hours No
Secondary C-peptides Levels for Dextrose Infusion Blood samples were collected for the measurement of C-peptide levels at baseline, 4 hours after dextrose infusion, and 8 hours after dextrose infusion. C-peptide was measured in plasma using a solid phase, two-site sequential chemiluminescent immunometric assays on the DPC Immulite analyzer. Current guidelines identify normal C-peptide levels as 0.51 to 2.72 ng/mL.
A high level of C-peptide generally indicates a high level of endogenous insulin production. This may be in response to a high blood glucose caused by glucose intake and/or insulin resistance. A high level of C-peptide is also seen with insulinomas and may be seen with low blood potassium, Cushing syndrome, and renal failure. A low level of C-peptide is associated with a low level of insulin production. This can occur when insufficient insulin is being produced by the beta cells, with diabetes for example, or when production is suppressed by treatment with exogenous insulin.
Baseline, 4 hours, 8 hours No
Secondary C-peptides Levels for Intralipid/Dextrose Infusion Blood samples were collected for the measurement of C-peptide levels at baseline, 4 hours after intralipid/dextrose infusion, and 8 hours after intralipid/dextrose infusion. C-peptide was measured in plasma using a solid phase, two-site sequential chemiluminescent immunometric assays on the DPC Immulite analyzer. Current guidelines identify normal C-peptide levels as 0.51 to 2.72 ng/mL.
A high level of C-peptide generally indicates a high level of endogenous insulin production. This may be in response to a high blood glucose caused by glucose intake and/or insulin resistance. A high level of C-peptide is also seen with insulinomas and may be seen with low blood potassium, Cushing syndrome, and renal failure. A low level of C-peptide is associated with a low level of insulin production. This can occur when insufficient insulin is being produced by the beta cells, with diabetes for example, or when production is suppressed by treatment with exogenous insulin.
Baseline, 4 hours, 8 hours No
See also
  Status Clinical Trial Phase
Recruiting NCT04243317 - Feasibility of a Sleep Improvement Intervention for Weight Loss and Its Maintenance in Sleep Impaired Obese Adults N/A
Recruiting NCT04101669 - EndoBarrier System Pivotal Trial(Rev E v2) N/A
Terminated NCT03772886 - Reducing Cesarean Delivery Rate in Obese Patients Using the Peanut Ball N/A
Completed NCT03640442 - Modified Ramped Position for Intubation of Obese Females. N/A
Completed NCT04506996 - Monday-Focused Tailored Rapid Interactive Mobile Messaging for Weight Management 2 N/A
Recruiting NCT06019832 - Analysis of Stem and Non-Stem Tibial Component N/A
Active, not recruiting NCT05891834 - Study of INV-202 in Patients With Obesity and Metabolic Syndrome Phase 2
Active, not recruiting NCT05275959 - Beijing (Peking)---Myopia and Obesity Comorbidity Intervention (BMOCI) N/A
Recruiting NCT04575194 - Study of the Cardiometabolic Effects of Obesity Pharmacotherapy Phase 4
Completed NCT04513769 - Nutritious Eating With Soul at Rare Variety Cafe N/A
Withdrawn NCT03042897 - Exercise and Diet Intervention in Promoting Weight Loss in Obese Patients With Stage I Endometrial Cancer N/A
Completed NCT03644524 - Heat Therapy and Cardiometabolic Health in Obese Women N/A
Recruiting NCT05917873 - Metabolic Effects of Four-week Lactate-ketone Ester Supplementation N/A
Active, not recruiting NCT04353258 - Research Intervention to Support Healthy Eating and Exercise N/A
Completed NCT04507867 - Effect of a NSS to Reduce Complications in Patients With Covid-19 and Comorbidities in Stage III N/A
Recruiting NCT03227575 - Effects of Brisk Walking and Regular Intensity Exercise Interventions on Glycemic Control N/A
Completed NCT01870947 - Assisted Exercise in Obese Endometrial Cancer Patients N/A
Recruiting NCT05972564 - The Effect of SGLT2 Inhibition on Adipose Inflammation and Endothelial Function Phase 1/Phase 2
Recruiting NCT06007404 - Understanding Metabolism and Inflammation Risks for Diabetes in Adolescents
Recruiting NCT05371496 - Cardiac and Metabolic Effects of Semaglutide in Heart Failure With Preserved Ejection Fraction Phase 2