Study of Brain, Reward, and Kids' Eating

Not Applicable

Completed

• Conditions: Eating Behavior; Obesity, Childhood
• Interventions: Behavioral: Food Rating

• Registration Number: NCT05456516
• Lead Sponsor: Penn State University

Brief Summary

Children from rural communities are at greater risk for obesity than children from more urban communities. However, some children are resilient to obesity despite greater exposure to obesogenic influences in rural communities (e.g., fewer community-level physical activity or healthy eating resources). Identifying factors that promote this resiliency could inform obesity prevention. Eating habits are learned through reinforcement (e.g., hedonic, familial environment), the process through which environmental food cues become valued and influence behavior. Therefore, understanding individual differences in reinforcement learning is essential to uncovering the causes of obesity. Preclinical models have identified two reinforcement learning phenotypes that may have translational importance for understanding excess consumption in humans: 1) goal-tracking-environmental cues have predictive value; and 2) sign-tracking-environmental cues have predictive and hedonic value (i.e., incentive salience). Sign-tracking is associated with poorer attentional control, greater impulsivity, and lower prefrontal cortex (PFC) engagement in response to reward cues. This parallels neurocognitive deficits observed in pediatric obesity (i.e., worse impulsivity, lower PFC food cue reactivity). The proposed research aims to determine if reinforcement learning phenotype (i.e., sign- and goal-tracking) is 1) associated with adiposity due to its influence on neural food cue reactivity, 2) associated with reward-driven overconsumption and meal intake due to its influence on eating behaviors; and 3) associated with changes in adiposity over 1 year. The investigators hypothesize that goal-tracking will promote resiliency to obesity due to: 1) reduced attribution of incentive salience and greater PFC engagement to food cues; and 2) reduced reward-driven overconsumption. Finally, the investigators hypothesize reinforcement learning phenotype will be associated due to its influence on eating behaviors associated with overconsumption (e.g., larger bites, faster bite rat and eating sped). To test this hypothesis, the investigators will enroll 76, 8-10-year-old children, half with healthy weight and half with obesity based on Centers for Disease Control definitions. Methods will include computer tasks to assess reinforcement learning, dual x-ray absorptiometry to assess adiposity, and neural food cue reactivity from functional near-infrared spectroscopy (fNIRS).

Detailed Description

Not available

Study Timeline

• Study First Submitted: 2022-07-06
• Study First Submitted QC: 2022-07-12
• Study First Posted: 2022-07-13
• Study Start: 2023-01-10
• Primary Completion: 2024-12-30
• Study Completion: 2024-12-30
• Status Verified: 2025-01
• Last Update Submitted: 2025-01-14
• Last Update Posted: 2025-01-16

Recruitment & Eligibility

• Status: COMPLETED
• Sex: All
• Target Recruitment: 76

Inclusion Criteria

• In order to be enrolled, children must be of good health based on parental self-report.
• Have no neurodevelopmental disorder (e.g., attention deficit hyperactivity disorder - ADHD) or learning disabilities (e.g., dyslexia).
• Have no allergies to the foods or ingredients used in the study.
• Not be taking any medications known to influence body weight, taste, food intake, behavior, or blood flow.
• Be 8-10 years-old at enrollment.
• speaks English.

Parent Inclusion Criteria:

• The parent who has the most knowledge of the child's eating behavior, sleep and behavior must be available to attend the visits with their child. This would be decided among the parents.

Exclusion Criteria

• They are not within the age requirements (< than 8 years old or > than 10 years-old at baseline).
• If they are taking cold or allergy medication, or other medications known to influence cognitive function, taste, appetite, or blood flow.
• don't speak English.
• are colorblind.
• has a learning disability, ADHD, language delays, autism or other neurological or psychological conditions.
• has a pre-existing medical condition such as type I or type II diabetes, rheumatoid arthritis, Cushing's syndrome, Down's syndrome, severe lactose intolerance, Prader-Willi syndrome, HIV, cancer, renal failure, or cerebral palsy.
• is allergic to foods or ingredients used in the study.

Parent Exclusion Criteria:

• the parent is unable to attend the study visits

Study & Design

• Study Type: INTERVENTIONAL
• Study Design: CROSSOVER

Arm && Interventions

Group	Intervention	Description
Taste	Food Rating	Children will rate foods on taste
Wanting	Food Rating	Children will rate foods on desire to eat
Health	Food Rating	Children will rate foods on health

Primary Outcome Measures

Name	Time	Method
Child body mass index	baseline and 1 year follow-up	child height and weight will be measured
Oxy- and deoxyhemoglobin in response to food cues	baseline	Functional near infrared spectroscopy (fNIRS) will measure brain activity through oxy- and deoxyhemoglobin in response to images of high and low energy dense foods.
Food intake in grams during a standard meal	baseline and 1-year follow-up	Intake in grams from standard meal
Food intake in kcal during a standard meal	baseline and 1-year follow-up	Intake in kcal during a standard meal
Video coding of standard meal	baseline and 1-year follow-up	A digital recording of the child eating a standard meal will be saved. We have developed a behavior coding protocol to measure child meal microstructure (e.g., bites, bite size, meal duration). We have also validated a computational model to assess cumulative intake curves from video coded bite data.
Food intake in grams during a snack buffet when not hungry	baseline	Intake in grams during a snack buffet using a standard eating in the absence of hunger paradigm (i.e., non-homeostatic intake)
Food intake in kcal during a snack buffet when not hungry	baseline	Intake in kcal during a snack buffet using a standard eating in the absence of hunger paradigm (i.e., non-homeostatic intake)
Reward-related decision making during 2-stage reinforcement learning task	baseline	The 2-stage reinforcement learning task has a first stage two arm bandit with deterministic stage progression and a second stage one arm bandit. Reward distributions between the two second-stage states gradually drift throughout the task. Half the trials will be 'bonus' trials. Performance will be assessed using a computational model in addition to looking at trial-to-trial decisions.
Value modulated attentional capture	baseline	The value-modulated attentional capture task uses two phases - a training phase during which high and low reward conditions are learned and a test phase during which participants complete a task that no longer depends upon the previously learned reward contingencies. During the test phase, stimuli from the training phase are used as distractors. Attentional capture is measured by comparing performance on trials that have distractors previously associated with high reward to those with distractors previously associated with low reward.
Body Composition	baseline and 1-year follow-up	The BodPod uses air displacement plethysmography to assess body composition including fat mass and fat-free mass in children

Secondary Outcome Measures

Name	Time	Method
Oxy- and deoxyhemoglobin in response to rating food health, taste, and wanting	baseline	Functional near infrared spectroscopy will measure brain activity through oxy- and deoxyhemoglobin while children rate food images on health, taste and wanting
Oxy- and deoxyhemoglobin in response to food choice	baseline	Functional near infrared spectroscopy will measure brain activity through oxy- and deoxyhemoglobin while children choose which of two foods they would like to eat
Eye-tracking during the value-modulated attentional capture task	baseline	The extent to which previously reward distractors capture attention will be assessed with eye tracking
Eye-tracking during the food choice task (during functional near infrared spectroscopy)	baseline	Eye-tracking will be measured to determine if attention is drawn to the tastier food item prior to making a food choice
Video coding of snack buffet	baseline	A digital recording of the child during the eating in the absence of hunger protocol will be saved. We will use the video to characterize the amount of attention children give toward the food items when they are not hungry and code behaviors associated with self-control
Population density	baseline	The population density of the child's primary residence will be used as a measure of rurality
Child Pavlovian Instrumental Transfer Task	1-year follow-up	An experimental task assessing pavlovian instrumental transfer for food cues.
Oxy- and deoxyhemoglobin in response to consumption of foods	1-year follow-up	Functional near infrared spectroscopy (fNIRS) will measure brain activity through oxy- and deoxyhemoglobin in response to consumption of taste-test samples of foods both before and after a standard laboratory meal
Oxy- and deoxyhemoglobin in response to rating food taste and wanting after consumption	1-year follow-up.	Functional near infrared spectroscopy will measure brain activity through oxy- and deoxyhemoglobin while children rate how much they want foods samples and how each sample tasted after consumption. This is completed before and after a standard test meal

Trial Locations

Locations (1)

Chandlee Laboratory; 🇺🇸 University Park, Pennsylvania, United States