Calorie Restriction and Brain Function in Mild Cognitive Impairment

Overview

Problems with blood sugar metabolism (i.e., metabolic dysfunction) progressively develop through old age, which is primarily due to obesity and lack of physical activity. Metabolic dysfunction increases the risk for Alzheimer's disease (AD) and negatively impacts memory and related brain function. There is intense interest in developing interventions, particularly non-drug therapies, to combat AD. Recent clinical trials have found that intranasal insulin, which facilitates glucose metabolism in the brain, is able to maintain memory in participants with Mild Cognitive Impairment (MCI), the precursor to AD. While intranasal insulin is a useful, proof-of-concept intervention, it does not affect visceral fat mass and therefore metabolic dysfunction will persist in a given person. The investigators wish to engage participants with MCI in intermittent calorie restriction (CR), to reduce metabolic dysfunction and improve glucose metabolism. Intermittent calorie restriction in this case refers to eating whatever one wants for 5 days, followed by 2 consecutive days of consuming 530 calories via one protein shake with sufficient nutrients to sustain the person. This results in reliable weight loss, which itself improves glucose metabolism in the body and has a wealth of other benefits. (It should be mentioned here that weight maintenance has been shown in studies when participants restrict to 1 day/week).

Full Title of Study: “Intermittent Calorie Restriction and Brain Function in MCI”

Study Type

  • Study Type: Interventional
  • Study Design
    • Allocation: Randomized
    • Intervention Model: Parallel Assignment
    • Primary Purpose: Treatment
    • Masking: Single (Outcomes Assessor)
  • Study Primary Completion Date: December 31, 2021

Detailed Description

AD diagnosis is projected to increase from approximately 5 million to 13.8 million Americans by 2050. The Alzheimer's Association estimates that healthcare costs for AD by 2050 could be 1.2 trillion dollars per year for Americans aged 65 years or older. There is marked focus on treating AD during the MCI phase, which precedes AD. In the brain, insulin normally facilitates microvascular blood flow, glucose uptake, and glucose oxidation for adenosine triphosphate (ATP) generation. Insulin resistance (IR) is defined as a reduced cellular responsiveness to insulin, characterized by higher insulin levels needed to maintain glucose regulation in the periphery and certain brain areas. IR is found in MCI and AD patient brains. AD-related neuropathology, such as amyloid beta-containing plaques, progressive atrophy, and glucose hypometabolism first occur in brain areas that also have a high density of insulin receptors. Such areas include medial temporal lobe (MTL) and prefrontal cortex (PFC). Furthermore, as illustrated in the literature and previous work of the investigators, peripheral IR is associated with AD-like changes in MTL and PFC, including: 1) brain atrophy; 2) less glucose uptake; 3) accumulation of amyloid-beta, a hallmark of AD; and 4) increased phosphorylation of tau fibrils, another hallmark of AD. Finally, higher IR is related to deficits in memory performance and executive function. These cognitive deficits can be ameliorated with 40 IU of intranasal insulin, which increases insulin processing in the brain with minimal peripheral effects, where MCI and AD patients show stable visuospatial working memory, as well as declarative learning and memory. One limitation of intranasal insulin is that it does not change obesity, which causes IR, and may therefore be only temporarily effective. As such, the investigators are interested in dietary regimens that can lower IR and may have long-term beneficial effects on AD neuropathology and cognitive output. Critically, intermittent calorie restriction (CR) diets reliably decrease body weight and IR in human adults. Intermittent CR protects neurons against dysfunction and degeneration in AD models. The underlying cellular and molecular mechanisms involve improved cellular bioenergetics and up-regulation of protein chaperones and antioxidant pathways in neurons. For example, 5-2 CR, a diet consisting of 5 days ad libitum followed by 2 consecutive days consuming 500-600 kcal, decreases IR beyond what is achieved with daily CR, and has a compliance rate of 83% versus 55% even by 6 months. It is also important to mention that no serious Adverse Events have occurred during past 5-2 CR studies.

Interventions

  • Dietary Supplement: Meal-Replacement Therapy
    • The meal replacement shake, consumed once per day on two consecutive days, will over a given week lead to negative energy balance and induce weight loss.
  • Behavioral: Dietary Counseling
    • A Registered Dietitian of Nutrition will provide consultation on how to induce moderate weight loss.

Arms, Groups and Cohorts

  • Experimental: Intermittent Calorie Restriction + Dietary Counseling
    • Participants will be asked to consume a single 530 kilocalorie shake (i.e., “High Calorie” Boost shake) on a given day for two consecutive days each week. Participants will eat ad libitum during the remaining 5 days. Participants will also receive Registered Dietitian of Nutrition (RDN) consultations about dietary modifications to induce moderate weight loss. Participants will utilize these recommendations in addition to shake consumption. Subjects are also asked to follow RDN dietary recommendations.
  • Active Comparator: Dietary Counseling
    • A Registered Dietitian of Nutrition (RDN) will consult with subjects about dietary modifications to induce moderate weight loss. Participants will utilize these recommendations.

Clinical Trial Outcome Measures

Primary Measures

  • Body Weight
    • Time Frame: 16 weeks
    • % change in BMI (kg/m2)

Secondary Measures

  • Homeostatic Model Assessment of Insulin Resistance (HOMA-IR)
    • Time Frame: 16 weeks
    • Insulin resistance measured with fasting glucose and insulin
  • Functional Magnetic Resonance Imaging memory task activation
    • Time Frame: 16 weeks
    • Regional brain activity induced by a memory task
  • Functional Magnetic Resonance Imaging executive function task activation
    • Time Frame: 16 weeks
    • Regional brain activity induced by an executive function task
  • Cerebral blood flow
    • Time Frame: 16 weeks
    • Regional cerebral blood flow assessed using Arterial Spin Labeling
  • Neural network functional connectivity
    • Time Frame: 16 weeks
    • Degree of network strength in neural networks assessed at rest using Functional Magnetic Resonance Imaging
  • Mini-Mental State Examination
    • Time Frame: 16 weeks
    • The construct for this total score is global cognitive performance, based on performance over a series of cognitive sub-domains. The unit is correct performance on a series of cognitive sub-domain tasks. The range is 0-30. A higher number is better.
  • NIH EXAMINER Dysexecutive Errors Composite Score
    • Time Frame: 16 weeks
    • The construct for this composite score is overall impairment in various executive function domains. The unit is the total number of errors committed during several NIH EXAMINER tasks (Continuous Performance Task, Fluency, Flanker, Set Shifting). The range is 0-43. A higher score is worse.
  • California Verbal Learning Test
    • Time Frame: 16 weeks
    • The construct for this factor is Verbal Memory. There are three sub-scales of main interest with the following units: 1) the total number of correctly recalled items in a 16-item list for a given trial where that list is read, spanning 5 trials (“CVLT Trials 1-5 Total”); 2) the total number of correctly recalled items in the same 16-item list after a 5 minute delay (“CVLT Short Delay”); and 3) the total number of correctly recall items in the same 16-item list after a 20 minute delay (“CVLT Long Delay”). The ranges are 0-80 for CVLT Trials 1-5 Total, 0-16 for CVLT Short Delay, and 0-16 for CVLT Long Delay. A higher number is better.
  • Digit Span – Forward and Backward
    • Time Frame: 16 weeks
    • This construct probes working memory, a sub-domain of executive function. It requires participants to remember a list of numbers that gradually has more numbers added.

Participating in This Clinical Trial

Inclusion Criteria

1. Years of age 70-85; 2. Body Mass Index => 28 and < 40 and weight < 350 pounds; 3. Mini-Mental State Examination >= 24; 4. A subjective memory concern from the participant, caregiver/informant, or a clinician; 5. An education-adjusted score for the Logical Memory II, paragraph A Wechsler Scale (16 years: 8-10; 8-15 years: 5-7; < 0-7 years: 2-3); 6. A Clinical Dementia Rating – sum of boxes = 0.5; 7. No deficits in activities of daily living; 8. Consensus confirmation of MCI by senior investigators; 9. An informant/caregiver that is informed about the study and will be present at study visits. Exclusion Criteria:

1. A history of a major cardiovascular event(e.g., heart attack); 2. A history of cerebrovascular or other neurological disorders (e.g., stroke, epilepsy, multiple sclerosis, etc.); 3. A history of substance abuse in the past 6 months; 4. A history of eating disorders; 5. A history of clinically significant endocrine disorders (e.g., hypothyroidism); 6. A history of mood and anxiety disorders (e.g., Major Depressive Disorder, Generalized Anxiety Disorder, Bipolar disorder, etc.); 7. Taking insulin; 8. Current use of systemic corticosteroids; 9. Current use of Warfarin; 10. Having smoked tobacco products in the last 3 months; 11. Contraindications for MRI (pacemakers, ferrous metal implants or shrapnel about the face or eyes, etc.); 12. Other medical history that, in the opinion of the investigators, would constitute risk for subject participation; 13. Hypertension, defined by a diastolic/systolic blood pressure of > 160/110; 14. No current use of memantine or other Alzheimer's disease drugs.

Gender Eligibility: All

Minimum Age: 70 Years

Maximum Age: 85 Years

Are Healthy Volunteers Accepted: No

Investigator Details

  • Lead Sponsor
    • Iowa State University
  • Collaborator
    • National Institute on Aging (NIA)
  • Provider of Information About this Clinical Study
    • Principal Investigator: Auriel A. Willette, Assistant Professor – Iowa State University
  • Overall Official(s)
    • Auriel A Willette, Principal Investigator, Iowa State University

Clinical trials entries are delivered from the US National Institutes of Health and are not reviewed separately by this site. Please see the identifier information above for retrieving further details from the government database.

At TrialBulletin.com, we keep tabs on over 200,000 clinical trials in the US and abroad, using medical data supplied directly by the US National Institutes of Health. Please see the About and Contact page for details.