View clinical trials related to Menstrual Cycle.
Filter by:The aim of this observational study was to investigate the effect of the menstrual cycle on the manual dexterity of female dentists. This study was conducted to answer the following question: - Is there any effect of the menstrual cycle on the manual dexterity of female dentists?
Despite a rise in the number of women participating in competitive sports, there remains a gender gap within sport and exercise science literature. Studying females involves potential "noise" through the change in hormone concentrations during the different phases of the female menstrual cycle (MC) which can potentially affect physiological parameters, thereby making study design and interpretation of findings difficult. Longitudinal data on the acute and chronic combined effects of training load and MC phases on circulating female hormones in elite and non-elite female athletes is lacking. The investigators aim to characterize and track the potential effects of training load and MC phases on performance, anthropometric measures, sport emotions, intestinal microbiome, serum metabolites and injury prevalence in elite and non-elite female athletes. 200 competitive premenopausal female athletes will be recruited. In a longitudinal observational design, each participant will be followed for 1 year, and tested at three time points. At each point, data will be collected on two occasions reflecting distinct phases of the MC. Finding the possible relationship between the MC phases, training load and performance or specific bio-markers for training load are of utmost importance and can assist professionals to identify periods of high load and over-training, thus preventing injuries and training adjustment.
Hormonal transition periods during the menstrual cycle may predispose women to mental disorders. Hormonal fluctuations provide specific neuroendocrine conditions that modulate brain structure and function and these actions affect cognitive and emotional behaviors and affect energy and mood homeostasis. It is thought that these changes are driven by altered dopamine transmission. Here, we aim to examine (1) how sex hormones and dopamine are linked and also (2) how hormonal changes affect motivation, mood, and energy homeostasis. To this end, dopamine intervention will be tested on effort-based decision-making and motivational circuits in three hormonal stages (i.e., women in early-follicular phase (EF), women in mid-luteal phase (ML), and men). Additionally, we are testing the effects of hormonal status on metabolic indices and its effects on mood fluctuations in a period of a month. The investigator hypothesizes that women in EF cycle phase (1) have naturally less dopamine and show less effort, and (2) they show greater improvement in effort-based decision-making after Levodopa administration. We have exploratory outcomes about (3) sex differences in reward-learning with and without Levodopa administration and explore if these differences correlate with elevated female sex hormone levels. Moreover, it is hypothesized that (4) hormonal fluctuations affect energy homeostasis, thus women in their EF cycle phase have higher energy expenditure and (5) they report more negative mood than in their mid-luteal (ML) cycle phase.
Studies across various sports and physical activities have consistently shown that females incur more injuries compared to their male counterparts, but the underlying reasons for this disparity remain poorly understood. While differences in hormone levels between males and females have been speculated to play a role, very little rigorous research has been conducted to directly examine potential connections between sex hormones and injury risk. Specifically, females have been shown to be at greater risk for hand and wrist injuries. The higher injury incidence begins at puberty and persists across the lifespan, suggesting a link to hormonal factors. However, significant gaps remain in understanding the relationships between the menstrual cycle, exogenous hormones from birth control, and risk factors for sports-related injury in females. The purpose of this study is to examine changes in muscle strength and neuromuscular activation among females using monophasic oral contraceptives, females not using oral contraceptives, and males during one week of wrist/hand immobilization.
Females treated with antipsychotics have higher rates of comorbid metabolic syndrome than males. Despite this, females have historically been excluded from many mechanistic studies due to confounding effects of menstrual cycles. Recent evidence suggests that brain insulin resistance may be an underlying mechanism through which antipsychotics may exert their metabolic side effects. This study seeks to investigate how brain insulin action differs in females according to their menstrual cycle phase, and how a high metabolic liability agent such as olanzapine might interrupt these differential insulin effects. Young healthy females will be given olanzapine and intranasal insulin to test how these treatment combinations change brain processes. Participants will be tested during both the first half of their menstrual cycle (follicular phase) and the second half of their cycle (luteal phase). We predict that intranasal insulin will change MRI-based measures in females, in a comparable way to males, in the follicular phase only. Adding olanzapine will block these effects of insulin in females in the follicular phase. This investigation has the potential to generate new knowledge in an area of significant unmet need. Demonstrating that antipsychotics disrupt brain insulin action, evidenced by inhibition of recognized effects of insulin on neuroimaging measures, will provide novel insights into currently poorly understood mechanisms.
Oxytocin is a hypothalamic neuropeptide that is best known for its peripheral physiological effects in the female organism i.e., uterine contractions during birth. The neuropeptide furthermore affects reward processing and metabolic functions such as eating behavior and body weight. Oxytocin receptors are present in brain regions associated with the processing of rewards, e.g., ventral tegmental area (VTA), nucleus accumbens (NAcc) and nucleus stria terminalis. Previous studies indicate that oxytocin interacts with sex hormones such as estradiol in a sex-specific manner. Despite known sex differences in oxytocin function, most studies i.e., on the metabolic effects of oxytocin in humans have so far focused on young, healthy men. Intranasal oxytocin administration has emerged as a method to experimentally investigate central nervous effects of oxytocin in the absence of relevant side effects. In the proposed study the investigators aim to systematically investigate the acute effect of intranasal oxytocin on reward processing in relation to circulating and synthetic sex hormones in healthy, naturally cycling women and in women taking hormonal oral contraceptive pills. The investigators will administer 24 international units (IU) of intranasal oxytocin vs. placebo and investigate neural correlates in a 3T MRI scanner including functional imaging during a reward processing task, changes in brain anatomy and connectivity. Additionally, metabolic functions, eating behavior and changes in mood and wellbeing will be assessed and blood will be drawn to assess parameters of hormonal and metabolic status.
The menstrual cycle is an important biological rhythm, whereby large cyclic fluctuations in endogenous sex hormones, such as estrogen and progesterone, are observed, which can affect performance. Evidence shows that endogenous and exogenous changes in hormone concentrations during the menstrual cycle exert many effects on the nervous and endocrine systems, in addition to the connective tissue, with consequences for the movement system. Pre-clinical studies (i.e., in animal models) show an estrogen association with the structural and mechanical properties of tendons and ligaments. Several elegant studies performed with female participants have tried to establish the mechanism underlying the effect of estrogen on collagen synthesis and its effects on exercise and functionality. Their findings suggest that the tendon properties may be affected when exposed to varying concentrations of estrogen. The largest tendon in humans, the Achilles tendon, has a direct role in functional capacity, activities of daily living, and locomotion. Studies show that the triceps surae's structural and mechanical properties may change throughout the menstrual cycle, and that these changes are related to endogenous and exogenous fluctuations in estrogen and progesterone. Musculotendinous stiffness, which is dependent on the collagen content, has been seen to vary considerably over the course of the menstrual cycle. In addition, it has been reported that females who have been taking the contraceptive pill for at least a year demonstrate lower levels of tendon strain compared to non-pill taking females, indicating a possible influence of hormonal state on tendon mechanical properties. However, the different experimental designs, the varied approaches to the evaluations and the lack of studies with high methodological quality limit our understanding of the effects of the different phases of the menstrual cycle on the triceps surae's neuromechanical properties. The aim of this observational study will be to investigate whether the morphological, mechanical (active and passive), material, and functional properties of the plantar flexor muscles and of the Achilles tendon, as well as functional parameters, change during voluntary contractions throughout the phases of the menstrual cycle in eumenorrheic women and in users of hormonal contraception. Understanding the acute effects of these properties in eumenorrheic women and users of hormonal contraception is essential so that we can adequately plan interventions and prescriptions of physical exercise and rehabilitation aimed for women.
The objective of this study was to better understand female reproductive health in the context of using wearable technology. Participants were provided and wore an Oura Ring, tracked their menstrual cycles, provided at-home ovulation test results, and had their cycles monitored via trans-vaginal ultrasounds. The study aimed to collect data from females with regular menstrual cycles.
The study was designed as an observational study
As there are fluctuations in the hormonal balance during the menstrual cycle, it is assumed that due to the interaction between the hormonal system and the immune system, some diseases might be worsened in the course of a cycle. This interaction is particularly important during the phases of the cycle when the corpus luteum is formed and secretes estrogens and progesterone (secretion phase, luteal phase), as well as during menstruation itself. To date, there is no comprehensive review regarding the molecular signaling pathways that are active during and influence the menstrual cycle. The menstrual cycle influences blood glucose levels. Women are subject to greater fluctuations in blood glucose levels than men according to the phases of the menstrual cycle (menstrual phase, proliferative phase, ovulation, luteal phase). Since there are contradictory results regarding the influence of the menstrual cycle on glucose metabolism, the glucose and insulin response, as well as the glucose-dependent intestinal hormone glucagon-like peptide 1(GLP-1) after food intake are determined in the study presented here using an oral glucose tolerance test.