Precision medicine is an emerging field for disease prevention, classification, diagnosis, and targeted (individualized) treatment based on individual characteristics, including genetic variations, environmental exposures, lifestyle, and experiences across the life span (1). It derives from big science (“omics”), bioinformatics, and deep phenotyping. Big science includes the genome, epigenome, transcriptome, metabolome, microbiome, exposome, receptome, and other “omes” in which global profiling captures huge numbers of data points (e.g., whole genome sequencing). Bioinformatics is the interdisciplinary field that combines statistics, mathematics, engineering, and computer science to interpret biological data. Deep phenotyping involves extensive patient characteristics (e.g., age, body mass index (BMI), smoking, environmental exposures, zip code, socioeconomic status, pregnancy history, comorbidities, severities, symptoms, family history, and lifestyle) that get incorporated via bioinformatics to interpret findings of the big data. The end result is to diagnose and understand diseases at the individual level so that therapies are based on cross-referencing an individual’s personal history and biology with patterns found across large populations, utilizing the knowledge network to deliver care that is preventive, targeted, effective, and timely. The field is ideal for women’s health, where causes for most disorders are not well understood and there is great variability woman to woman in responses to treatments and also in outcomes. This is particularly true for the female reproductive tract and especially the endometrium, where there are unpredictable responses to the steroid hormone milieu and other factors that result in poor reproductive and other health outcomes. A long-term goal is to abandon empiric and “one-size-fits-all” therapies and adopt precision in fertility treatments, contraceptive and hormonal therapies, treating disorders of the female reproductive tract, and optimizing pregnancy outcomes. This chapter highlights the human endometrium in this context in the dawn of the age of precision medicine.

The uterus derives from the paramesonephric ducts first described by Muller in 1830 (6). The mesodermally derived paramesonephric (Mullerian) ducts differentiate into the luminal and glandular epithelial cell types of the endometrium, oviduct, cervix, and upper vagina, and the surrounding urogenital ridge mesenchyme differentiates into the endometrial stroma and inner and outer myometrial layers (7). Interactions between the mesenchyme and epithelium are essential for female reproductive tract formation and differentiation, and members of the Wnt and Hox gene families are important in these processes. In addition, mesenchymal and epithelial interactions and estrogen receptor (ER) signaling play important roles in adenogenesis and smooth muscle differentiation (7,8).

Endometrium comprises several cell types, including glandular epithelium, luminal epithelium, stromal fibroblasts, vascular smooth muscle, and endothelium; an array of immune cells; and stem or progenitor cells (4). The glandular and stromal compartments undergo profound changes in response to circulating E2 and P4 across the cycle (Figure 1.1). A brief description of these changes is included here to underscore the events and to highlight how abnormalities c...