Clinical Trial Details
— Status: Completed
Administrative data
| NCT number |
NCT05391438 |
| Other study ID # |
CHLA-22-00119 |
| Secondary ID |
|
| Status |
Completed |
| Phase |
N/A
|
| First received |
|
| Last updated |
|
| Start date |
September 1, 2022 |
| Est. completion date |
August 1, 2023 |
Study information
| Verified date |
December 2023 |
| Source |
Children's Hospital Los Angeles |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
In adolescents, conventional obesity treatment comprehensively addresses nutritional,
activity, and behavioral topics. Due to limited resources in historically marginalized
communities, implementation of nutrition-based interventions that require easy access to
fresh food and ability to change the home environment is difficult, which may exacerbate
health disparities. It is critical to find nutrition strategies and recommendations that are
impactful, sustainable, and cost effective across all communities. There is growing interest
in time-based interventions focusing on "when" food is consumed rather than on prescribed
macronutrient composition. Time-restricted eating (TRE) is a type of meal-timing which
involves fasting for at least 14-hours per day and eating over a 10-hour eating window
initiated in the morning, mid-day, or afternoon. TRE recommendations are simple in merely
dictating when eating occurs and thus may represent a more straightforward approach for
adolescents than other caloric restriction regimens relying on numeracy (kilocalories and
macronutrients) and goal setting. In adults, early-day TRE has been shown to reduce body
weight, fasting glucose, and insulin resistance. By contrast, restricting food intake to the
evening has produced mostly null results or even worsened post prandial glucose levels and
β-cell responsiveness. To date, there has been no trial comparing early vs. late TRE on
glycemic profiles in adolescents, and it is unclear how meal-timing impacts glycemic profiles
in youth. The optimal timing of food intake for adolescents may be very different than adults
due to increasing sex steroids and growth hormone levels overnight which may contribute to
increased insulin resistance in the early morning. The proposed proof-of-concept study
addresses this question by measuring metabolic response to a test meal consumed in the
morning, afternoon, and evening among 30 adolescents with obesity using a within participant
design. These findings will provide the needed research base for the refinement of TRE
interventions in adolescence.
Description:
The prevalence of type 2 diabetes in adolescents is steadily increasing, specifically among
Latino youth. Unfortunately, there is a lack of effective preventative treatments available
to delay the progression to type 2 diabetes in youth living with obesity and pre-diabetes.
Specifically, it is challenging for many adolescents to maintain adherence to multicomponent
interventions resulting in high attrition which then decreases efficacy. There is growing
interest in time-based interventions focusing on "when" food is consumed rather than on
prescribed macronutrient composition. In the adult population there has been increasing
evidence that time-restricted eating (TRE), which consists of limiting daily food intake to
an 8 to 10-hour period or less may improve insulin sensitivity and β-cell responsiveness.
However the results of TRE in adults appear to depend on when eating occurs. Early TRE (last
eating event prior to 16:00) has been shown to reduce body weight, fasting glucose and
insulin, and insulin resistance. However, restricting food intake to the evening produced
mostly null results or worsened post prandial glucose level. One possible explanation is that
consuming food early in the day synchronizes the central and peripheral circadian clocks
involved in energy expenditure and fat oxidation and minimizes glycemic excursions and
endogenous glucose production via enhanced insulin secretion. It has been proposed that the
enhanced insulin secretion may be secondary to corresponding diurnal variations in the
release of incretin hormones such as glucagon, glucagon-like-peptide-1 (GLP-1),
glucose-dependent insulinotropic polypeptide (GIP), and pancreatic peptide (PP).
Because of its simplicity, TRE may represent a more feasible approach for adolescents than
other caloric restriction regimens. Our team recently conducted the first study examining the
feasibility of TRE in adolescents with obesity. In this study, fifty adolescents were
randomized to a self-selected 8-hour TRE compared to a prolonged eating window. TRE was found
to be feasible, safe, and acceptable but there was no difference in glycemic profiles or
weight loss between groups. These null findings may be due to the late eating window that was
selected. To date, there have been no trial comparing early vs. late TRE on glycemic profiles
in adolescents and it is unclear how meal-timing impacts glycemic profiles in youth. It
remains unknown how the timing of meal consumption directly effects glycemic profiles and
cardiometabolic endpoints in this age group. Thus, to address this question, in our
proof-of-concept study, the investigators aim to measure glycemic and metabolic responses to
a test meal (controlled for macronutrient profile and caloric amount) at various meal-timings
(early vs. afternoon vs. late) in thirty Latino adolescents (ages 13-19 years), with obesity,
without diabetes. All participants will consume three standard test meals administered in
random order at different times of day over a two-week period: (1) Early: test meal consumed
at 8 AM; (2) Afternoon: 12 PM; (3) Late: 4 PM. Test meals will be consumed on different days
at least three days apart after a minimum of a 16-hour fasting period. A continuous glucose
monitor (CGM) will be placed on the participant for the duration of the 2-week period. The
primary endpoints will be frequently sampled glucose, insulin, and c-peptide area under the
curve (AUC) collected after consumption of a standard test meal, insulinogenic index (IGI:
change in insulin/change in glucose over the first 30 min after the load), and glucose
variability as captured by percent time in range on CGM. The investigators hypothesize that
adolescents with obesity will have reduced AUC and IGI following the later meals compared to
the early meal. The investigators will test these hypotheses with the following aims:
Aim 1: Identify how timing of meal consumption after a prolonged 16-h fast affects glucose
and insulin response in Latino adolescents with obesity. The investigators will measure
insulin secretion, clearance rates, and sensitivity assessed with a) 3-h frequent sampling of
glucose, insulin, and c-peptide post meal, b) calculated insulinogenic index, and c) percent
time in range measured by CGM. The investigators expect that meal consumption at 12 and 4 PM
will be associated with lower post prandial glucose excursions, decreased AUC and IGI, and
increased percent time in range compared to that same meal consumed at 8 AM.
Aim 2: Examine the association between timing of meal consumption and incretin and pancreatic
hormones in Latino adolescents with obesity. The investigators will collect frequent sampling
of glucagon, total GLP-1, GIP, and PP concentrations post-meal to explore how diurnal
variation in these hormones impact insulin sensitivity. The investigators expect that meal
consumption at 12 and 4 PM will in greater change in incretin and pancreatic hormones
concentrations compared to that same meals consumed at 8 AM.
Future Direction: The data collected during this pilot will inform the design of a randomized
clinical trial to test the feasibility, safety, and efficacy of early vs. late TRE in
adolescents with obesity to reduce glycemic and insulin response for the prevention of type 2
diabetes.
