5 Clinical Trials for Various Conditions
The purpose of this study is to identify the mechanism(s) by which OSA exacerbates the age-linked decline in systemic testosterone concentrations by conducting a randomized order sham-controlled crossover study that dynamically evaluates the entire hypothalamic-pituitary testicular axis across a wide age range.
The goals of this research proposal are to further our understanding of the reproductive aging process in women and to improve our ability to clinically assess and model reproductive aging. Reproductive aging is a continuous process that begins many years prior to menopause. Women in their late 30s and early 40s usually maintain normal menstrual function and ovulatory status, yet fertility in these women is considerably compromised compared to younger women. The primary mechanism of reproductive aging is through the process of ovarian primordial follicle (egg) depletion, a process that exhibits considerable variation between women. As a result, the age at which an individual begins to experience infertility and menstrual cycle changes secondary to follicle depletion also varies significantly and is difficult to predict. The clinical assessment of the number of primordial follicles remaining in the ovary has traditionally relied upon the measurement of ovarian or pituitary hormones such as FSH, estradiol, and inhibin B. Unfortunately, these measures are all indirect and poorly sensitive in the assessment of ovarian reserve. More recently, serum levels of anti-Müllerian hormone (AMH) and the ovarian antral follicle count have been utilized as clinical measures of ovarian reserve. Both have been correlated with chronological age and have some predictive power in determining stimulation quantity (the number of oocytes obtained at the time of egg-recovery) in in-vitro fertilization (IVF) treatment cycles. Reproductive aging in women; however, is more than just the depletion of oocytes from a woman's ovaries, but also involves a decline in oocyte quality. The predictive value of these clinical markers of ovarian reserve with regards to oocyte quality is unknown. Additionally, new tools developed to assess biological aging in other organ systems such as white blood cell telomere length and the measurement of advanced glycation end products (AGEs) through skin autofluorescence have not been evaluated with respect to the reproductive aging process. This proposal seeks to develop better models of normal female reproductive aging by identifying novel markers of ovarian reserve and determining their relationship with both oocyte quantity and quality obtained during IVF treatment cycles.
This is a prospective cohort study characterizing follicular fluid and serum levels of oxidative stress in women with various infertility diagnoses undergoing in vitro fertilization, and assessing the relationship of oxidative stress to oocyte competence as determined by embryo development outcomes. Furthermore, we will measure oxidative stress in sperm and correlate the overall oxidative stress within the couple with IVF and pregnancy outcomes of the resultant embryos.
Despite significant improvements in prevention and treatment of cardiovascular disease (CVD), the growing aging population suggests CVD will continue to pose a significant public health burden. Women are a special group where microvascular disease is more common and traditional risk factors may not fully identify risk. Women's reproductive history (e.g. menarcheal age, menstrual cycles, infertility, pregnancy, menopause) may pose unique risk and suggests an opportunity for new approaches. The investigators propose a women-centered approach for early identification of women at risk that investigates the unique loss of reproductive function at an age long before other vital systems fail. Despite its importance, little is known about the determinants or correlates of ovarian aging, or the health implications, especially in diverse communities. Only recently have reliable biomarkers of the remaining oocyte pool been available for use in normally cycling women. This availability gives us a unique opportunity to characterize the association between "ovarian age" (cross-sectional) and the rate of "ovarian aging" or oocyte decline over time (longitudinal) and the health implications of accelerated oocyte loss. The investigators hypothesize ovarian age/aging provides a window onto the general health of women. The investigators suggest it is not the progressive deficiency of estrogen with menopause that increases risk, but common underlying cellular aging mechanisms first evident in young populations as lower ovarian reserve (follicle number) due to the unique sensitivity of the ovary. Studies of cellular aging focused on mitochondrial dysfunction, oxidative stress, inflammation, and telomere length have identified correlations with CVD risk. Improved understanding of the mechanisms of cellular aging suggests telomere shortening and dysfunction may drive mitochondrial dysfunction and potentially the parallel between cellular aging and CVD. The oocyte is particularly sensitive to mitochondrial dysfunction, having 10 times the number of mitochondria as any somatic cell. Additionally, mitochondrial dysfunction and telomere shortening have been associated with ovarian aging. This begs the question of whether, given the susceptibility of the ovary to mitochondrial dysfunction, accelerated ovarian aging may be a harbinger of subsequent CVD risk. To address this critical question, the investigators propose to leverage the largest and most ethnically diverse population of normal reproductive-aged women, with detailed measures of ovarian age, and to deploy peripheral endothelial function testing, a non-invasive sensitive marker of early CVD risk. Ovarian aging is thought to be largely genetically determined, but the impact of race/ethnicity has not been fully explored. Evaluating the impact of ethnicity on ovarian aging, and combining this information with the impact of modifiable behavioral risk factors, may help clarify CVD risk in young, ethnically-diverse, reproductive-age women. The investigators believe improving our understanding of factors that affect the rate of oocyte/follicle loss and the relationship with CVD risk factors will promote a novel method to identify women at earlier and/or increased cardiac risk.
The purpose of this study is to identify clinical and genetic markers of ovarian aging. In this process, we will evaluate environmental factors that may affect fertility and the age at which fertility declines, and may influence the age at which women enter menopause. Wide variability exists between women both in the age at which menopause occurs and the rate of decline in oocyte number and reproductive capability. As the loss of ovarian function has profound impact on women's hormonal milieu and their subsequent risk for the development of disease, improving our understanding of the factors that determine the timing and rate of reproductive aging is critical to improving quality of life for all women. In addition, improving our understanding of reproductive aging has profound economic, and social, implications given the complex choices women face regarding the timing of childbearing and the growing burden of infertility. While the inter-individual variability in age at menopause has a large genetic component and possible environmental influences, to date no studies have addressed the relationship between oocyte number as reflected by antral follicle count (AFC) and genetic inheritance. We hypothesize that ovarian aging, as reflected by antral follicle count, is largely determined by common genetic polymorphisms that impact the initial oocyte endowment and/or the rate of oocyte loss over time thus lowering antral follicle count for any given age. We further hypothesize that antral follicle count will be an improved marker of ovarian aging. Thus, we propose a study of the genetic and environmental factors that influence age-specific variability in antral follicle count.