Targeting Risk Factors for Diabetes in Subjects With Normal Blood Cholesterol Using Omega-3 Fatty Acids

Sponsor

Institut de Recherches Cliniques de Montreal (Other)

Overall Status

Recruiting

CT.gov ID

NCT04485871

Collaborator

Canadian Institutes of Health Research (CIHR) (Other)

Enrollment

Location

Arm

70.4

Anticipated Duration (Months)

0.7

Patients Per Site Per Month

Study Details

Study Description

Brief Summary

Every 3 minutes a new case of diabetes is diagnosed in Canada, mostly type 2 diabetes (T2D) increasing the risk for heart disease. T2D and heart disease share many common risk factors such as aging, obesity and unhealthy lifestyle.

Paradoxically however, while lowering blood LDL, commonly known as "bad cholesterol", is protective against heart disease, research over the past 10 years have shown that the lower is blood LDL, the higher is the chance of developing T2D. This phenomena is happening whether blood LDL is lowered by a common drug against heart disease called Statins, or by being born with certain variations in genes, some of which are very common (~80% of people have them).

To date, it is unclear why lowering blood LDL is associated with higher risk for diabetes, and whether this can be treated naturally with certain nutrients.

Investigators believe that lowering blood LDL by forcing LDL entry into the body tissue through their receptors promotes T2D. This is because investigators have shown that LDL entry into human fat tissue induces fat tissue dysfunction, which would promote T2D especially in subjects with excess weight.

On the other hand, investigators have shown that omega-3 fatty acids (omega-3) can directly treat the same defects induced by LDL entry into fat tissue. Omega-3 is a unique type of fat that is found mostly in fish oil.

Thus the objectives of this clinical trial to be conducted in 48 subjects with normal blood

LDL are to explore if:

Subjects with higher LDL receptors and LDL entry into fat tissue have higher risk factors for T2D compared to subjects with lower LDL receptors and LDL entry into fat tissue
6-month supplementation of omega-3 from fish oil can treat subjects with higher LDL receptors and LDL entry into fat tissue reducing their risk for T2D.

This study will thus explore and attempt to treat a new risk factor for T2D using an inexpensive and widely accessible nutraceutical, which would aid in preventing T2D in humans.

Condition or Disease	Intervention/Treatment	Phase
Type 2 Diabetes Inflammation Insulin Sensitivity/Resistance Fatty Acids, Omega-3	Dietary Supplement: Omega-3 fatty acids	N/A

Detailed Description

Type 2 (T2D) and cardiovascular disease (CVD) share many risk factors, whose accumulation over years lead to disease onset. However, while lowering plasma low-density lipoprotein cholesterol (LDLC) is cardio-protective, novel evidence over the past 10 years established a role for common LDLC-lowering variants and widely used hypocholesterolemic Statins in higher risk for T2D. This diminishes the cardio-protective role of low plasma LDLC. As these conditions decrease plasma LDLC by increasing tissue-uptake of LDL, a role for LDL receptor (LDLR) pathway was proposed. However underlying mechanisms fueling higher risk for T2D with upregulated LDLR pathway, and nutritional approaches to treat them are unclear.

The central hypothesis examined in this trial is that upregulating receptor-mediated uptake of LDL on white adipose tissue provokes the activation of an innate immunity pathway (the Nucleotide-binding domain and Leucine-rich repeat Receptor, containing a Pyrin domain 3 (NLRP3) inflammasome) leading to the accumulation of risk factors for T2D in subjects with normal plasma LDLC. This can be treated by 6-month supplementation of omega-3 fatty acids (omega-3).

To examine this hypothesis in vivo, ex vivo and in vitro, a clinical trial in conjunction with mechanistic basic research studies have been initiated at the Montreal Clinical Research Institute (IRCM). Forty eight volunteers will be recruited through advertisements in French/English newspapers and online (e.g. Google, Facebook) and placed on a 6-month supplementation of 3.6 g omega-3 per day. Participants will be stratified into 2 groups (N=24/group) with higher and lower white adipose tissue surface-expression LDL receptors (LDLR and CD36) using median plasma PCSK9 (Proprotein Convertase Subtilisin/Kexin type 9) per sex. Plasma PSCK9 will be used as investigators have shown that it is negatively associated with white adipose tissue surface-expression of LDLR and CD36.

The duration of this study is about 8 months (33 weeks) divided into 5 parts:

Screening and evaluation of eligibility for the study
Weight stabilisation (+/- 2 kg change over 4 weeks) and confirmation of eligibility after a medical examination by IRCM physician collaborators.
Baseline testing over 2 days (1- 4 weeks apart) to assess participants risk factors for T2D: white adipose tissue NLRP3 inflammasome activity, white adipose tissue physiology and function (ex vivo after a subcutaneous needle biopsy), systemic inflammation, dietary fat clearance (after a high fat meal), and insulin secretion and sensitivity (by gold-standard Botnia clamp technique). Participants will also be phenotyped for body composition (by dual energy x-ray absorptiometry), resting energy expenditure (by indirect calorimetry), dietary intake (by 3-day dietary journals) and physical activity level (by a questionnaire).
24-week intervention with omega-3 fatty acid supplementation (3.6 g eicosapentaenoic acid (EPA) and docosahexaenoic (DHA), 2:1)
Post intervention testing starting over 2 days (1- 4 weeks apart) to assess risk factors for T2D that were measured at baseline.

Investigators hypothesize that subjects with low plasma PCSK9 (i.e. with higher white adipose tissue LDLR and CD36) will have higher risk factors for T2D at baseline and that the omega-3 intervention will eliminate group-differences in these risk factors.

Study Design

Study Type:

Interventional

Anticipated Enrollment :

48 participants

Allocation:

N/A

Intervention Model:

Single Group Assignment

Intervention Model Description:

Subjects (N=48) will be recruited with the same inclusion/exclusion criteria and will received the same omega-3 intervention. After completion of recruitment, subjects will be stratified into 2 groups (24/group) based on a baseline plasma PCSK9 for group characterisation and comparison.Subjects (N=48) will be recruited with the same inclusion/exclusion criteria and will received the same omega-3 intervention. After completion of recruitment, subjects will be stratified into 2 groups (24/group) based on a baseline plasma PCSK9 for group characterisation and comparison.

Masking:

None (Open Label)

Masking Description:

However, subjects will not know into which group they were stratified.

Primary Purpose:

Prevention

Official Title:

White Adipose Tissue LDL Receptors and Omega-3 as Modulators of the Risk for Type 2 Diabetes in Subjects With Normal Plasma LDL Cholesterol

Actual Study Start Date :

Dec 19, 2019

Anticipated Primary Completion Date :

Mar 31, 2024

Anticipated Study Completion Date :

Oct 31, 2025

Arms and Interventions

Arm	Intervention/Treatment
Experimental: Omega-3 fatty acids 3.6 g EPA:DHA / day (2:1)	Dietary Supplement: Omega-3 fatty acids Tripple Strength Omega-3 from Webber Naturals; 4 oral softgels (600 mg EPA and 300 mg DHA / softgel) Other Names: Tripple Strength Omega-3 from Webber Naturals

Arm

Intervention/Treatment

Experimental: Omega-3 fatty acids

3.6 g EPA:DHA / day (2:1)

Dietary Supplement: Omega-3 fatty acids

Tripple Strength Omega-3 from Webber Naturals; 4 oral softgels (600 mg EPA and 300 mg DHA / softgel)

Other Names:

Tripple Strength Omega-3 from Webber Naturals

Outcome Measures

Primary Outcome Measures

Fasting white adipose tissue NLRP3 inflammasome activation [Baseline]
White adipose tissue medium accumulation of interleukin 1 beta (IL-1β) ex vivo over 4 hours (pg/mg tissue by AlphaLISA)
Fasting white adipose tissue NLRP3 inflammasome activation [At 24 weeks]
White adipose tissue medium accumulation of interleukin 1 beta (IL-1β) ex vivo over 4 hours (pg/mg tissue by AlphaLISA)

Secondary Outcome Measures

Fasting plasma PCSK9 concentration [Baseline]
Plasma PCSK9 (g/L by ElISA kit)
Fasting plasma PCSK9 concentration [At 24 weeks]
Plasma PCSK9 (g/L by ElISA kit)
White adipose tissue receptors for apoB-lipoproteins [Baseline]
Fasting and 4 hour-postprandial change in white adipose tissue surface-expression LDLR and CD36 (% of control by immunohistochemistry in white adipose tissue slides)
White adipose tissue receptors for apoB-lipoproteins [At 24 weeks]
Fasting and 4 hour-postprandial change in white adipose tissue surface-expression LDLR and CD36 (% of control by immunohistochemistry in white adipose tissue slides)
White adipose tissue inflammation profile [Baseline]
Fasting and 4 hour-postprandial change in NLRP3 inflammasome related inflammatory parameters; including gene expression of IL1B, NLRP3 and ADGRE1 (by RT-PCR) and secretion of IL-1β and IL-1Ra (per mg tissue by AlphaLISA)
White adipose tissue inflammation profile [At 24 weeks]
Fasting and 4 hour-postprandial change in NLRP3 inflammasome related inflammatory parameters; including gene expression of IL1B, NLRP3 and ADGRE1 (by RT-PCR) and secretion of IL-1β and IL-1Ra (per mg tissue by AlphaLISA)
White adipose tissue function ex vivo [Baseline]
Fasting and 4 hour postprandial change in situ lipoprotein lipase activity (nmol 3H-triglyceride/mg tissue)
White adipose tissue function ex vivo [At 24 weeks]
Fasting and 4 hour postprandial change in situ lipoprotein lipase activity (nmol 3H-triglyceride/mg tissue)
Postprandial fat metabolism [Baseline]
Area under the 6 hour time curve of plasma triglycerides (mmol/hour) after a high-fat meal (66% fat)
Postprandial fat metabolism [At 24 week]
Area under the 6 hour time curve of plasma triglycerides (mmol/hour) after a high-fat meal (66% fat)
Systemic inflammation [Baseline]
Fasting and 4 hour postprandial change in plasma inflammatory parameters including IL-1Ra and IL-1β (pg/mL by AlphaLISA)
Systemic inflammation [At 24 weeks]
Fasting and 4 hour postprandial change in plasma inflammatory parameters including IL-1Ra and IL-1β (pg/mLby AlphaLISA)
Disposition index [Baseline]
Calculated as glucose-induced insulin secretion (uU/mL/min) multiplied by insulin sensitivity (glucose infusion rate mg/kg/min) measured by Botnia clamp
Disposition index [At 24 weeks]
Calculated as glucose-induced insulin secretion (uU/mL/min) multiplied by insulin sensitivity (glucose infusion rate mg/kg/min) measured by Botnia clamp
Fatty acid profile in red blood cell phospholipid fraction [Baseline]
(As μmol/L by gas chromatography mass spectrometry)
Fatty acid profile in red blood cell phospholipid fraction [At 24 weeks]
(As μmol/L by gas chromatography mass spectrometry)
Body composition [Baseline]
Fat and lean body mass (as kg by dual energy x-ray absorptiometry)
Body composition [At 24 weeks]
Fat and lean body mass (as kg by dual energy x-ray absorptiometry)
Resting energy expenditure [Baseline]
(As kcal/hour by indirect calorimetry)
Resting energy expenditure [At 24 weeks]
(As kcal/day by indirect calorimetry)
Energy intake [Baseline]
(Average of 3 day energy intake as kcal/day collected by 3-day dietary records)
Energy intake [At 24 weeks]
(Average of 3 day energy intake as kcal/day collected by 3-day dietary records)
Physical activity [Baseline]
(using Godin Leisure Time Exercise Questionnaire)
Physical activity [At 24 weeks]
(using Godin Leisure Time Exercise Questionnaire)

Eligibility Criteria

Criteria

Ages Eligible for Study:

45 Years to 74 Years

Sexes Eligible for Study:

All

Accepts Healthy Volunteers:

Yes

Inclusion Criteria:

Men and post-menopausal women:

Having a body mass index (BMI= 25-40 kg/m2)
Aged between 45 and 74 years
Having confirmed menopausal status (FSH ≥ 30 U/l)
Non-smoker
Sedentary (less than 2 hours of structured physical exercise (ex: sports club) per week)
Low alcohol consumption: less than 2 alcoholic drinks/day

Exclusion Criteria:

Plasma LDL cholesterol > 3.5 mmol/L (i.e. > 75th percentile in a Canadian population).
Elevated risk of cardiovascular disease (≥ 20% of calculated Framingham Risk Score) who would require immediate medical intervention by lipid-lowering agents.
Prior history of cardiovascular events (like stroke, transient ischemic attack, myocardial infarction, angina, heart failure…)
Systolic blood pressure > 140 mmHg or diastolic blood pressure > 90 mmHg
Type 1 or 2 diabetes or fasting glucose > 7.0 mmol/L
Prior history of cancer within the last 3 years
Thyroid disease - untreated or unstable
Anemia - Hb < 120 g/L
Renal dysfunction or plasma creatinine > 100 µmol/L
Hepatic dysfunction - AST/ALT > 3 times normal limit
Blood coagulation problems (i.e. bleeding predisposition)
Autoimmune and chronic inflammatory disease (i.e. celiac, inflammatory bowel, Graves, multiple sclerosis, psoriasis, rheumatoid arthritis, and lupus).Known history of difficulties accessing a vein
Claustrophobia
Sleep apnea
Seizures
Concomitant medications: Hormone replacement therapy (except thyroid hormone at a stable dose), systemic corticosteroids, anti-psychotic medications and psycho-active medication, anticoagulant or anti-aggregates treatment (Aspirin, NSAIDs, warfarin, coumadin..), adrenergic agonist, anti-hypertensive drugs, weight-loss medication, lipid lowering medication
Known substance abuse
Already taking more than 250 mg of omega-3 supplements (EPA/DHA) per day
Allergy to seafood or fish
Allergy to Xylocaine
Unable to eat the components of the high fat meal (croissant, cheese, bacon, brownies)
None compliance to the study requirements (i.e. not being fasting) or cancellation of the same scheduled testing visit more than once.
Lack of time to participate in the full length of the study (33 weeks)
Have exceeded the annual total allowed radiation dose (like X-ray scans and/or tomography in the previous year or in the year to come) according to the physician's judgement.
All other medical or psychological conditions deemed inappropriate according to the physician