The yolk sac is responsible for critical biologic functions during early gestation. Before the placenta is formed and can take over, the yolk sac provides nutrition and gas exchange between the mother and the developing embryo.  It is also the main organ of embryonic blood cell production via blood islands near the yolk sac. Primitive hematopoiesis takes place in the yolk sac before the liver and bone marrow sequentially take over.  Other functions of the yolk sac include the production of stem cells and primitive macrophages, production of germ cells, metabolic regulation, and synthesis of proteins such as albumin, alpha-fetoprotein, and apolipoproteins. The yolk sac also contributes to the formation of the umbilical cord.  

Embryogenesis entirely depends on the vascular system of the yolk sac, also known as vitelline circulation.  Vitelline circulation refers to the bidirectional blood flow between the yolk sac and embryo, which is critical for the exchange of nutrients until the full establishment of placental function. The yolk sac contains an extensive capillary plexus for absorbing nutrients and oxygen that pass on to the embryo. The primitive aorta supplies blood to the yolk sac where this absorption occurs at the capillaries, and then the vitelline veins drain and direct blood to the embryo.[7]

The yolk sac is clinically significant as it is the first structure that is visible sonographically during pregnancy. Clinicians can detect the yolk sac on transvaginal ultrasound starting at five weeks gestation. The gestational sac refers to the round, fluid-filled pouch within the uterus that surrounds the developing embryo and yolk sac. On transvaginal ultrasound, the gestational sac appears as a round or oval structure surrounded by a smooth, circular, and echogenic lining. The yolk sac appears as a round, hypoechoic structure inside the gestational sac with surrounding walls that are echogenic. Normal yolk sac size ranges from 3 mm to 5 mm, and normal shape is circular. A normal yolk sac seen on ultrasound confirms that the pregnancy is viable and intrauterine. If a yolk sac is not visible, either the pregnancy is not viable, or the gestational age may be incorrect, and the recommendation that clinicians repeat the transvaginal ultrasound 1 to 2 weeks later. For example, if the patient does not remember the date of her last menstrual period, the yolk sac may not be visible due to her true gestational age being less than five weeks. Having a history of irregular menstrual cycles may also cause inaccurate dating of gestational age.[8] Underlying maternal conditions and factors that may cause irregular menstrual cycles are broad.  They include polycystic ovarian syndrome, diabetes, systemic lupus erythematosus, immature hypothalamic-pituitary-ovarian axis, endometriosis, thyroid disorders, and eating disorders.[9]

During the sixth to tenth week of gestation, physiologic herniation and rotation of the embryonic bowel occur at the midgut.  Physiologic herniation of the midgut involves herniation of the embryologic bowel into the umbilical cord. At the base of the umbilical cord, the midgut undergoes two episodes of physiologic rotation.  Initially, the midgut rotates 90 degrees counterclockwise using the superior mesenteric artery as an axis. The midgut then returns to the abdomen as the abdominal cavity has enlarged. The second rotation is 180 degrees counterclockwise and takes place around ten weeks gestation. In total, 270 degrees of rotation occurs. The reason this herniation occurs is due to a lack of space inside the abdominal cavity.  The fetal midgut, kidneys, and liver are large at this time. The abdominal cavity, however, grows at a much slower rate than the midgut. Herniation allows the midgut enough space to grow rapidly outside of the peritoneum in the extra-embryonic coelom. Upon completion of herniation and rotation, the vitelline duct degenerates. Degeneration commonly occurs in the seventh week of gestation.

The yolk stalk is connected to the midgut prior to herniation and is commonly referred to as the vitelline duct. In approximately 2% of people, the vitelline duct fails to degenerate and persists. This outcome results in a gastrointestinal outpouching called Meckel's diverticulum, which is characterized by a complete or partial opening between the umbilicus and the bowel. Meckel's diverticulum is the most common congenital abnormality of the gastrointestinal tract. It sits within 2 feet of the ileocecal valve and measures approximately 2 inches long. Meckel's diverticulum may be asymptomatic or manifest as symptoms of its heterotopic gastric or pancreatic mucosa that is often present. For example, as heterotopic gastric mucosa produces acid in the bowel, it may cause gastrointestinal bleeding, ulcers, and eventual perforation if left untreated.[10]

A patent urachus is a rare congenital anomaly in which the urinary bladder remains connected to the outside world via the umbilicus. This occurs due to a failed involution of the urachus. It often presents in neonates with leakage of urine from the umbilicus after birth. If the urachus only partially involutes, a fluid-filled urachal cyst is formed. Complications of urachal anomalies include infection, urachal neoplasms, stone formation, and umbilical granulomas.[6]

The gestational sac and yolk sac are the first abnormal structures that are identifiable during a spontaneous abortion, a term synonymous with miscarriage or pregnancy loss. More specifically, an abnormal yolk sac is identifiable on ultrasound at least seven days before a spontaneous abortion, most of which occur during the first trimester. This finding is crucial for effective management and counseling of patients during a spontaneous abortion.[3]

During the first trimester, sonographic findings of the yolk sac give clinicians important information in terms of pregnancy outcomes. Absent, small, and large yolk sacs are associated with pregnancy loss in comparison to yolk sacs of pregnancies that continue past the first trimester.[3] A yolk sac is defined as small or large when it falls below the fifth percentile or surpasses the 95th percentile, respectively, for the expected size. Measurements of the yolk sac merit consideration in addition to growth percentiles. Defined abnormal measurements are less than 3 mm or greater than 6 mm in size. Small and large yolk sacs have both correlated with spontaneous abortions. Other abnormal ultrasound findings associated with spontaneous abortions include irregularly shaped yolk sacs and calcified yolk sacs. It is important to note that an abnormal yolk sac finding is not always indicative of spontaneous abortion. Although uncommon, viable pregnancies can occur with oval-shaped yolk sacs and enlarged yolk sacs.[8] Some studies have found abnormal yolk sac shape to be more specific for spontaneous abortion than abnormal size, although both are considered strong predictors.[11]