Human development week 2

Last updated: December 18, 2025

Human development week 2

Gynocology

Gynocology

Amenorrhea
Amenorrhea: Pathology review
Amenorrhea: Clinical
Cervical cancer: Pathology review
Cervical cancer: Clinical
Cervical cancer
Ovarian cysts and tumors: Pathology review
Ovarian cysts, cancer, and other adnexal masses: Clinical
Ovarian cyst
Infertility: Clinical
Pregnancy
Ectopic pregnancy
Preeclampsia & eclampsia
Hypertensive disorders of pregnancy: Clinical
Complications during pregnancy: Pathology review
Placenta previa
Potter sequence
Placental abruption
Miscarriage
Routine prenatal care: Clinical
Stages of labor
Postpartum hemorrhage
Postpartum hemorrhage: Clinical
Uterine disorders: Pathology review
Endometriosis
Endometritis
Endometrial hyperplasia
Endometrial cancer
Uterine fibroid
Ovarian surface epithelial tumors
Ovarian germ cell tumors
Ovarian sex-cord stromal tumors
Contraception: Clinical
Progestins and antiprogestins
Uterine stimulants and relaxants
Fetal alcohol syndrome
Vaginal and vulvar disorders: Pathology review
Disorders of sex chromosomes: Pathology review
Sexually transmitted infections: Vaginitis and cervicitis: Pathology review
Disorders of sexual development and sex hormones: Pathology review
Benign breast conditions: Pathology review
Polycystic ovary syndrome
Premature ovarian failure
Fallopian tube and uterus histology
Ovary histology
Cervix and vagina histology
Puberty and Tanner staging
Menstrual cycle
Menopause
Estrogen and progesterone
Anatomy and physiology of the female reproductive system
Oxytocin and prolactin
Breastfeeding
Pelvic inflammatory disease
Congenital cytomegalovirus (NORD)
Anatomy of the female reproductive organs of the pelvis
Anatomy of the female urogenital triangle
Anatomy of the perineum
Nerves and lymphatics of the pelvis
Anatomy clinical correlates: Female pelvis and perineum
Abdominal pain: Clinical
Abnormal uterine bleeding: Clinical
Vulvovaginitis: Clinical
Virilization: Clinical
Sexually transmitted infections: Clinical
Estrogens and antiestrogens
Androgens and antiandrogens
Klinefelter syndrome
Delayed puberty
Precocious puberty
Turner syndrome
Androgen insensitivity syndrome
5-alpha-reductase deficiency
Kallmann syndrome
Breast cancer
Breast cancer: Pathology review
Sexually transmitted infections: Warts and ulcers: Pathology review
HIV and AIDS: Pathology review
Urinary incontinence: Pathology review
Vulvar cancer: Clinical
Vaginal cancer: Clinical
Endometrial hyperplasia and cancer: Clinical
Vaginal versus cesarean delivery: Clinical
Gestational trophoblastic disease: Clinical
Anatomy clinical correlates: Breast
Development of the reproductive system
Antimetabolites for cancer treatment
Hypoprolactinemia
Abnormal labor: Clinical
Antepartum hemorrhage: Clinical
Premature rupture of membranes: Clinical
Gardnerella vaginalis (Bacterial vaginosis)
Newborn management: Clinical
Sudden infant death syndrome
Neonatal jaundice: Clinical
Neonatal hepatitis
Neonatal ICU conditions: Clinical
Perinatal infections: Clinical
Congenital TORCH infections: Pathology review
Congenital disorders: Clinical
Congenital gastrointestinal disorders: Pathology review
Development of twins
Omphalocele
Volvulus
Congenital neurological disorders: Pathology review
Congenital renal disorders: Pathology review
Congenital heart defects: Clinical
Dandy-Walker malformation
Precocious and delayed puberty: Clinical
Development of the placenta
Human development days 1-4
Human development days 4-7
Human development week 2
Human development week 3

Transcript

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Content Reviewers

During the second week of human development, the blastocyst attaches to the wall of the uterus.

The cells in the blastocyst’s outer layer are called trophoblast cells, and they penetrate into the uterus, establishing a connection between the blastocyst and the mother.

The cells in the blastocyst’s inner layer are called embryoblast cells, and they turn into a new, flat, two-layered structure which eventually gives rise to all of the organs and tissues of the body.

By day 7 or 8, the blastocyst implants on the surface of the endometrial wall, or decidua; the area where it implants is called the decidua basalis.

To snuggle deeper into the decidua basalis, trophoblast cells from the outer layer of the blastocyst assemble into two layers of cells.

One layer is called the cytotrophoblast, which consists of mononucleated cells, and the other is called the syncytiotrophoblast, which consists of a multinucleated cluster of cells.

Slowly, the syncytiotrophoblast expands into the decidua basalis.

By day 9, the syncytiotrophoblast has pushed deeper into the decidua basalis, and by day 11, the blastocyst is almost completely buried within it—like a seed getting pushed into soil.

Around day 12, the decidua undergoes the decidual reaction.

High levels of progesterone cause the decidual cells to enlarge, and they become coated in a sugar-rich, fatty fluid the syncytiotrophoblast can absorb to sustain its growth; this fluid also helps sustain the embryo early on.

Initially, the decidual reaction only occurs at the decidua basalis, the site of implantation, but eventually it spreads throughout the entirety of the decidua.

Around day 14 of development, syncytiotrophoblast cells start to form little protrusions called primary villi—each one looks a bit like a tree.

These primary villi trees form all the way around the fetus, and cells start to clear out from between the primary villi, leaving behind empty spaces called lacunae.

While this is all happening, arteries and veins from the parent start to grow into the decidua basalis.

Normally we think of red blood cells staying confined to blood vessels, but as the placenta develops, an interesting thing happens: tiny arteries merge with the lacunae, eventually filling these empty spaces with oxygenated blood.

Veins also merge with lacunae and bring blood back to the parent’s heart.

Over time, more and more of these little pools of blood develop, and they start merging together to form a single large pool of blood with many arteries delivering blood into it and many veins taking blood away.

Key Takeaways

At around day 8, the trophoblast gives rise to two layers; the cytotrophoblast and the syncytiotrophoblast. The cytotrophoblast which consists of mononucleated cells, makes the chorionic villi. On the other hand, the syncytiotrophoblast consists of multinucleated cells. These cells produce hCG (human chorionic gonadotropin) needed to keep the corpus luteum viable.

The corpus luteum needs to stay viable to keep producing progesterone needed to maintain the pregnancy until the placenta grows enough to take this task over. Also, the embryoblast differentiates into ventral hypoblast that makes the yolk sac, and the dorsal epiblast that later gives three embryonic germ layers.

Around days 9 to 12, the syncytiotrophoblast goes deeper into the decidua basalis for more nutrients needed to sustain growth, whereas the epiblast develops clefts that later coalesce to form the amniotic cavity. At around day 13, the hypoblast cells form the exocoelomic mesoderm cells outside the embryo. Finally, the epiblast gives rise to the three embryonic germ layers; endoderm, mesoderm, and ectoderm.