Bioenergetics of Exercise-Induced Menstrual Disturbances

Not Applicable

Completed

• Conditions: Menstruation Disturbances; Amenorrhea; Luteal Phase Defect; Oligomenorrhea
• Interventions: Other: 60 percent energy deficit; Other: Exercising control; Other: 15 percent energy deficit; Other: Sedentary Control; Other: 30 percent energy deficit (15/15); Other: 30 percent energy deficit

• Registration Number: NCT04938622
• Lead Sponsor: Penn State University

Brief Summary

Menstrual disturbances are frequently observed in physically active women and female athletes. Short term prospective studies have shown that diet and exercise interventions can lead to decreases in Luteinizing hormone (LH) pulsatility, however these studies are unable to capture further changes in menstrual status. One longer term prospective study over two menstrual cycles showed that weight loss elicited menstrual disturbances, but there were no quantifiable measurements of energy availability. Thus, the primary purpose of this study was to assess how varying levels of energy deficiency created through a combination of caloric restriction and exercise affect menstrual function in young, premenopausal, sedentary women.

Detailed Description

Long term energy deficiency in women can lead to functional hypothalamic amenorrhea (FHA), which can cause many health detriments such as osteopenia, stress fractures, transient infertility, dyslipidemia, and impaired endothelial function. Though studies involving diet and exercise interventions have shown how energy deficiency can lead to menstrual disturbances prospectively, this study aims to extend those findings by measuring the magnitude of energy deficit that could lead to these disturbances. Hypotheses for this study are: 1) there would be a dose-response relation between the induction of menstrual disturbances (luteal phase defects, anovulation, and oligomenorrhea) and the magnitude of energy deficiency such that the intervention groups experiencing a greater energy deficit would incur a significantly greater incidence of menstrual cycle disturbances and 2) the intervention groups experiencing a greater energy deficit would incur a greater incidence of more severe menstrual cycle disturbances.

The study included one baseline menstrual cycle and 3 intervention menstrual cycles. During the baseline period, participants were randomly assigned to an experimental group for intervention menstrual cycles 1, 2, and 3 of the study. The goal of the subject groupings was to test the impact of varying levels of an energy deficit created by the combination of caloric restriction and exercise on menstrual function. They were assigned to either a control group that did not exercise and consumed a number of calories estimated to maintain body weight, a control group that exercised but received extra food calories to remain in energy balance (EXCON), or one of four groups that exercised and were prescribed reduced energy intake to create varying levels of an energy deficit. Specifically, the four groups of energy deficit were 1) an increase of 15 percent kcal of exercise (15 percent deficit, ED1), 2) an increase of 30 percent kcal of exercise (30 percent deficit, ED2), 3) a decrease of 15 percent in dietary intake combined with an increase of 15 percent of exercise, (30 percent deficit 15/15, ED2), and 4) a decrease of 30 percent in dietary intake combined with an increase of 30 percent kcal of exercise (60 percent deficit, ED3). The number of participants for analysis was 34 participants in the following groups: EXCON (n = 8), ED1 (n = 6), ED2 (n = 12), and ED3 (n = 8).

Baseline energy needs were assessed during the baseline cycle. Resting metabolic rate and nonexercise physical activity were added to determine a caloric need for the day. Caloric intake was supervised throughout the entire study, and meals were comprised of 55 percent carbohydrates, 30 percent fat, and 15 percent protein. Exercise training was also supervised, and maximal oxygen consumption (VO2 max) was calculated. Menstrual status was assessed through analysis of daily urinary metabolites of estrone-1-glucuronide (E1G), pregnanediol glucuronide (PdG), and midcycle LH. Underwater weighing and a digital scale were used to assess body composition, and fasting blood samples were collected to assess metabolic hormones.

Study Timeline

• Study Start: 2001-05-01
• Primary Completion: 2005-04-30
• Study Completion: 2005-04-30
• Status Verified: 2021-06
• Study First Submitted: 2021-06-01
• Study First Submitted QC: 2021-06-16
• Last Update Submitted: 2021-06-16
• Study First Posted: 2021-06-24
• Last Update Posted: 2021-06-24

Recruitment & Eligibility

• Status: COMPLETED
• Sex: Female
• Target Recruitment: 47

Inclusion Criteria

• Weight 45-75 kg
• Body fat 15-35 percent
• BMI 18-25 kg/m2
• Nonsmoking
• <1 hour/week of purposeful aerobic exercise for the past 6 months
• Documentation of at least two ovulatory menstrual cycles during screening.

Exclusion Criteria

• History of serious medical conditions
• Medication use that would alter metabolic hormone levels
• Significant weight loss/gain (±2.3 kg) in the last year
• Current evidence of disordered eating or history of an eating disorder
• Taking exogenous hormonal contraceptives for the past 6 months

Study & Design

• Study Type: INTERVENTIONAL
• Study Design: PARALLEL

Arm && Interventions

Group	Intervention	Description
60 percent energy deficit (ED3)	60 percent energy deficit	Participants exercised for the equivalent of 30 percent of their daily caloric intake needs throughout the intervention cycles, and their dietary intake was decreased by 30 percent to total a 60 percent energy deficit.
Exercising control	Exercising control	Participants exercised but were given extra calories to remain in energy balance throughout the intervention (3 menstrual cycles).
15 percent energy deficit (ED1)	15 percent energy deficit	Participants exercised for the equivalent of 15 percent of their daily caloric intake needs throughout the intervention cycles.
Sedentary Control	Sedentary Control	Participants did not exercise but consumed a diet that has an appropriate number of calories to maintain body weight throughout the intervention (3 menstrual cycles).
30 percent energy deficit 15/15 (ED2)	30 percent energy deficit (15/15)	Participants exercised for the equivalent of 15 percent of their daily caloric intake needs throughout the intervention cycles, and their dietary intake was decreased by 15 percent to total a 30 percent energy deficit.
30 percent energy deficit (ED2)	30 percent energy deficit	Participants exercised for the equivalent of 30 percent of their daily caloric intake needs throughout the intervention cycles.

Primary Outcome Measures

Name	Time	Method
Change in frequency of menstrual disturbances (disturbances /cycle)	Baseline Menstrual Cycle (MC) (28 days (d) or the length of 1 MC, intervention MC 1 (28 days or the length of 1 MC), intervention MC 2 (28 days or the length of 1 MC), and intervention MC 3 (28 days or the length of 1 MC)	Frequency of menstrual disturbances including luteal phase defects, anovulation, oligomenorrhea cycles, and anovulatory cycles analyzed by daily urinary metabolites of estrone-1-glucuronide (E1G), pregnanediol glucuronide (PdG), and midcycle LH

Secondary Outcome Measures

Name	Time	Method
Change in metabolic hormones	Baseline Menstrual Cycle (MC) (28 days (d) or the length of 1 MC, Mid- study (week 3 of MC during intervention MC 2) an (28 days (d) or the length of 1 MC), & Post Study (Days (d)1-7 of cycle	Change in metabolic hormones total triiodothyronine (T3 ng/dL)) and insulin-like growth factor-1 (IGF-1 ng/ml).
Change in cycle length (days (d))	Baseline Menstrual Cycle (MC) (28 days (d) or the length of 1 MC, intervention MC 1 (28 days or the length of 1 MC), intervention MC 2 (28 days or the length of 1 MC), and intervention MC 3 (28 days or the length of 1 MC)	Change in cycle length (days (d))
Change in body weight	Baseline Menstrual Cycle (MC) (28 days (d) or the length of 1 MC, intervention MC 1 (28 days or the length of 1 MC), intervention MC 2 (28 days or the length of 1 MC), and intervention MC 3 (28 days or the length of 1 MC), & Post Study (days 1-7)	Body weight (kg)
Change in fat mass	Baseline Menstrual Cycle (MC) (28 days (d) or the length of 1 MC, intervention MC 1 (28 days or the length of 1 MC), intervention MC 2 (28 days or the length of 1 MC), and intervention MC 3 (28 days or the length of 1 MC), & Post Study (days 1-7)	Change in fat mass (kg)
Change in fat free mass	Baseline Menstrual Cycle (MC) (28 days (d) or the length of 1 MC, intervention MC 1 (28 days or the length of 1 MC), intervention MC 2 (28 days or the length of 1 MC), and intervention MC 3 (28 days or the length of 1 MC), & Post Study (days 1-7)	Change in fat free mass (kg)
Change in aerobic capacity	Baseline Menstrual Cycle (MC) (28 days (d) or the length of 1 MC, & Post Study (Days (d)1-7 of cycle	Change in aerobic capacity, VO2 max (ml/kg/min)
Change in follicular phase length	Baseline Menstrual Cycle (MC) (28 days (d) or the length of 1 MC, intervention MC 1 (28 days or the length of 1 MC), intervention MC 2 (28 days or the length of 1 MC), and intervention MC 3 (28 days or the length of 1 MC)	Change in follicular phase length (days (d))
Change in luteal phase length	Baseline Menstrual Cycle (MC) (28 days (d) or the length of 1 MC, intervention MC 1 (28 days or the length of 1 MC), intervention MC 2 (28 days or the length of 1 MC), and intervention MC 3 (28 days or the length of 1 MC)	Change in luteal phase length (days (d))
Change in percent body fat	Baseline Menstrual Cycle (MC) (28 days (d) or the length of 1 MC, intervention MC 1 (28 days or the length of 1 MC), intervention MC 2 (28 days or the length of 1 MC), and intervention MC 3 (28 days or the length of 1 MC), & Post Study (days 1-7)	Change in percent body fat (%)