Pregnancy and Fertilization: Stages, Characteristics, and Development

1. Biology 221 Anatomy & Physiology II TOPIC 13Survey of Development Chapter 29 and others E. Lathrop-Davis / E. Gorski / S. Kabrhel

2. Pregnancy • Pregnancy refers to the events from fertilization to birth. • Pregnancy results from union of sperm and egg. • Sperm must swim from the vagina upstream to meet the secondary oocyte that was ovulated; normally they meet in the fallopian tubes. • To reach the oocyte, sperm must overcome: • the acidity of male urethra and female vagina; • the mucus plug at the entrance to the cervix; and • uterine contractions that occur during orgasm. Fig. 28.14, p. 1089

3. Fertilization • Fertilization, or the union of the haploid gametes (egg & sperm), produces a diploid zygote. • Fertilization occurs in 2 stages: • Stage 1: penetration of the egg by the sperm; • Stage 2: union of sperm & egg membranes and nuclei. • Fertilization produces a unique individual with genetic characteristics of both mother and father.

4. Fertilization: Stage 1 - Penetration • Acrosomal enzymes from many, many sperm must be released to break through corona radiata and zona pellucida of the oocyte before penetration can occur. • When one sperm finally makes it through, conditions in the oocyte change so that no more sperm can enter. Fig. 29.2, p. 1121

5. Fertilization: Stage 2 Union • Once the sperm has entered, the oocyte undergoes meiosis II and ejects the 2nd polar body. • The sperm nucleus migrates to the center of the oocyte and the rest of the sperm degenerates. • Sperm and egg nuclei unite to form the new diploid zygote. Fig. 29.3, p. 1122

6. Characteristics of Living Things • Maintenance of boundaries (cell membrane; eventually, skin) • Movement (cellular and/or organismal) • Response to stimuli (recognizes changes in environment and creates responses) • Digestion (provides nutrients in usable form) • Metabolism (chemical reactions) • Excretion (removal of wastes) • Reproduction (initially, just cellular) • Growth (increase in size by increased number of cells)

7. Pre-embryonic Development1st Through 2nd Weeks Overview • Cleavage • Blastocyst foramtion • Implantation • Placentation

8. Cleavage &Blastocyst Formation • Cleavage involves the rapid replication of DNA and mitotic cell divisions, which produces ever smaller cells resulting in a solid ball called a morula. • Continued division of the morula produces a blastocyst with two groups of cells. • The inner cell mass becomes the future embryo. • The trophoblast cells form the fetal part of the placenta. Fig. 29.4, p. 1123

9. Implantation • The blastocyst implants itself into endometrium of uterine wall • An ectopic pregnancy is one in which implantation occurs in some other location (e.g., fallopian tube or pelvic cavity). • Trophoblast cells (outer cells of blastocyst) secrete human chorionic gonadotropin (hCG) that maintains the corpus luteum through 1st four months. Fig. 29.5, p. 1124

10. Placentation • Placentation refers to the development of the placenta. • The placenta originates from the chorion (trophoblast cells) of the embryo and endometrial tissue of mother. • The placenta begins to produce estrogens and progestins that maintain the uterus. Fig. 29.7a-c, p. 1126

11. Embryonic DevelopmentWeeks 3-8 Overview During weeks 3-8, • extra-embryonic membranes develop; • primary germ layers form in a process called gastrulation; the embryo can be called a gastrula; and • rudiments of organ systems are formed in a process called organogenesis. • By the end of the 8th week, all major organ systems have been formed and the embryo is referred to as a fetus.

12. Development of Extra-Embryonic Membranes There are 4 extra-embryonic membranes: • The chorion forms part of the placenta. • The amnion becomes filled with amniotic fluid, which: • cushions the embryo; • maintains temperature; and • allows freedom of movement. Fig. 29.7d, p. 1126

13. Development of Extra-Embryonic Membranes • The yolk sac forms part of the primitive gut. • It also serves as the 1st site of blood cell formation. • Theallantois contributes to the umbilical cord. • It also becomes part of the urinary bladder. Fig. 29.7d, p. 1126

14. Gastrulation • Gastrulation is the development of primary germ layers. • Ectoderm is the outmost layer and forms the epidermis and nervous system. • Endoderm is the inner layer and forms the epithelial linings of the digestive tract, respiratory tract, urogenital system and associated glands. • Mesoderm is the middle layer and forms connective tissues and muscle. See also Table 29.1, p. 1135 Fig. 29.8, p. 1131

15. Specialization of Ectoderm • Ectoderm over most of body forms the epidermis. • Ectoderm over the middle back, forms the neural plate. • The neural plate invaginates and becomes the neural groove&neural folds (tissue lateral to the neural groove). • The neural folds join together along the back and form the neural tube. • The neural tube forms the brain & spinal cord. The opening within the tube remains as the ventricles of the brain and central canal of the spinal cord. Fig. 29.9, p. 1132

16. Specialization of Endoderm • Endoderm gives rise to the lining of the gut. • Structures that come from the gut arise as “outpocketings”. These include the: • epithelia of the lungs and respiratory tree; • thyroid and parathyroid glands; • liver and gall bladder; • pancreas; and • adenohypophysis. Fig. 29.10, p. 1133

17. Specialization of Mesoderm • Mesoderm gives rise to muscle, connective tissues, and serous membranes. • Basically, everything between the epidermis and lining of the gut, respiratory tree and lungs. • Limb buds form and move laterally in what will become shoulder and hip areas Fig. 29.11, p. 1134

18. Embryonic Development MilestonesWeeks 3-8: Organogenesis • The heart beats by week 4. • All systems are present in some form by week 8. • All major regions of brain are present by week 8. • The liver produces blood cells by week 8.

19. Fetal Milestones: 12 - 16 Weeks By 12 weeks: • Blood cell formation begins in bone marrow. • Ossification begins. By 16 weeks: • The kidneys have assumed their typical shape. • Joint (synovial) cavities are present. • The cerebellum has enlarged. • Sensory organs are differentiated. See Table 29.2, p. 1138

20. Fetal Milestones: 20-30 Weeks By 20 weeks: • Skin is covered by lanugo (silky hair). • Activity can be felt by mother (“quickening”). By 30 weeks: • Myelination of the spinal cord begins. • Finger and toe nails are present. • Bone marrow becomes the only site of blood cell formation. • The testes descend (7th month) in males. • Surfactant production begins at ~ 24 weeks. See Table 29.2, p. 1138

21. Fetal Milestones: 8 Months - Birth During the 8th to 9th months: • Development of organ systems continues. • The fetus has a significant weight gain. Weeks 38-42 – Birth occurs. • before 38 weeks, the fetus has less fat and organ systems not as well developed, so it’s not as well prepared. • After 42 weeks, the placenta begins to degenerate and the risk of oxygen deprivation increases. See Table 29.2, p. 1138

22. Development of Integumentary System See Marieb Ch. 5 pp. 165-168 • The epidermis and dermis are developed by the 4th month • Epidermal derivatives grow down into dermis • Lanugo is present from 20 weeks. This is usually shed during the 7th or 8th month. • Vellus hairs are present by the 7th month. http://www.uoguelph.ca/zoology/devobio/210labs/ecto5.html

23. Development of Skeletal System See Marieb. ch. 6 pp. 181; A&P I, Unit XII • Skeletal system development begins by the 8th week. • Primary ossification is completed by birth. • Secondary ossification continues to early adulthood. • Think About It: Which of these is affected by growth hormone (GH) levels after birth? (See A&P I, Units XI and XII) http://www.uoguelph.ca/zoology/devobio/210labs/meso2.html#osteo

24. Development of Skeletal System • Endochondral ossification occurs in hyaline cartilage models and forms most bones other than the cranial bones and clavicles. • Intramembranous ossification – occurs in membranes and forms the flat bones of the cranium and clavicles. • Fontanels are unossified membranes in the skull that are present at birth. • Fontanels allow the head to change shape slightly for easier birth. http://www.uoguelph.ca/zoology/devobio/210labs/meso2.html#osteo http://www.bio.psu.edu/faculty/strauss/anatomy/skel/fetal.htm

25. Development of Spinal Curvatures • The primary curvatures are the thoracic and sacral curvatures. • These are present at birth. • The secondary curvatures are the cervical and lumbar curvatures. • These develop as the infant lifts its head and stands, respectively. http://www.csu.edu.au/faculty/arts/humss/bioethic/abort1.htm

26. Development of Nervous System See Marieb. ch. 11; pp. 429-430, 463-464 • The nervous system develops from “neural ectoderm” along the mid back. • Neural crest cells (adjacent to the neural tube) give rise to sensory neurons whose cell bodies are outside the CNS. • Neural tube cells give rise to interneurons and motor neurons. http://www.angelfire.com/mb/jessicasjourney/info.html Fig. 12.2, p. 430

27. Development of Nervous System • The eyes develop as outgrowths of the diencephalon. (A&P I Review – Where does the optic nerve 1st synapse in the brain?) • The brain and spinal cord develop from the neural tube. • Brain regions represent enlargements of the anterior tube. • The ventricles develop from openings in the neural tube. • Anencephaly is the failure of cerebrum and part of brain stem to develop. Fig. 12.4, p. 431

28. Development of Nervous System • The spinal cord develops from the middle and posterior portions of the tube. • Spina bifidaresults from the incomplete fusion of the vertebral arches, usually in the lumbrosacral region. • Up to 70% of cases associated with inadequate folate levels in mother • some cases associated with mother’s exposure to high levels of UV radiation [DISCOVER Vol. 22 No. 2 (February 2001)] due to its affect on folate levels. http://www.abbottdiagnostics.com/medical_conditions/fertility_pregnancy/afp.htm

29. Development of Endocrine System • The development of the endocrine system is complex and includes all three germ layers. • Two glands in particular develop from two different layers, the: • pituitary; and • adrenal. http://anatomy.med.unsw.edu.au/cbl/embryo/Notes/endocrine9.htm

30. Development of Pituitary Gland • The adenohypophysis (anterior) develops from endoderm as an outgrowth from the roof of the primitive mouth. • The neurohypophysis (posterior) develops from neural ectoderm as an extension of the diencephalon, specifically, the hypothalamus. • Think About It: How does this affect the way secretion is controlled in each? http://www.teaching-biomed.man.ac.uk/histology/T270.HTML See also http://anatomy.med.unsw.edu.au/cbl/embryo/Notes/endocrine7.htm

31. Development of Adrenal Gland • The cortex develops from mesoderm. • The medulla develops from neural ectoderm. • Specifically, the medulla develops from the same embryonic tissue that gives rise to the ganglionic neurons and postgangionic fibers of the sympathetic division of the ANS (See A&P I, Unit XI). http://sprojects.mmi.mcgill.ca/embryology/ug/Adrenal_Stuff/Normal/zones.html

32. Development of Circulatory System • Blood is initially produced in the yolk sac, later in the liver, and finally in the bone marrow. • The heart develops from two tubes (blood vessels) in the thoracic cavity. • The blood vessels start in the yolk sac to bring blood into the body.

33. Development of Blood • Blood develops in first the yolk sac; later, in the liver, spleen, and bone marrow of fetus. • After birth, bone marrow is the only place most blood cells are produced. (See Topic 6) • Fetal hemoglobin (HbF) has a greater affinity for O2 than adult hemoglobin does. • Think About It: What advantage does this give the fetus? http://www.lab.anhb.uwa.edu.au/mb140/CorePages/Blood/Images/bma10he.jpg http://www.smbs.buffalo.edu/bch/faculty/garrett_sinha.html

34. Development of Heart • Development of the heart begins as 2 tubes that fuse by the 4th week. • The heart begins pumping in the 1st month (4th week). • The foramen ovale allows blood to flow from right to left atrium. • Think About It: (See Topic 2) • What is the purpose of this opening? • What would happen if this failed to close? Fig. 19.24, p. 709

35. Fetal Circulation • The umbilical arteries carry partially oxygenated blood to the placenta. • The umbilical vein returns nutrient-rich oxygenated blood from placenta to fetal liver. • The ductus venosus is shunt through liver connecting umbilical vein to inferior vena cava. • Think About It:What is the importance of this shunt? • The ductus arteriosus connects the pulmonary trunk to the aorta. • Think About It:What is the importance of this shunt? Fig. 29.13, p. 1136

36. Development of Respiratory System • The respiratory system develops as buds (outgrowths) from the throat. • Surfactant production begins in week 24 (between weeks 23-26). • Surfactant is not produced in sufficient quantities until about weeks 32-35. • Infant respiratory distress syndrome (See Topic 7) results from a failure to produce sufficient surfactant in the lungs. • Think About It: What how does this affect a premature baby born at 22 weeks? Fig. 23.28, p. 877

37. Development of Digestive System • The epithelium develops from endoderm; muscle develops from mesoderm. • Glands develop as buds from tube Fig. 24.37, p. 938

38. Development of Urinary System • Kidney development begins in the 4th week and is completed by week 9. • The fetus urinates into the amniotic fluid, which is replaced every 3 hours or so. Fig. 26.21, p. 1035

39. Development of Reproductive System • The ovaries & testes develop in the abdominal cavity. • During the first 6 weeks embryonic reproductive organs are “bipotential”. That is, they can become male or female. • Differentiation begins during week 7-8 under influence of testosterone. • The testes descend into the scrotum during the 7th month. Fig. 28.24, p. 1106; Fig. 28.25, p. 1108

40. Parturition (Birth): Stages of Labor • During the dilation stage the cervix dilates to ~ 10 cm (4”). • During the expulsion stage the fetus is delivered. • Normally, the fetus is delivered head first. • If the fetus is delivered feet first, problems may arise in trying to deliver the head. • A cesarean section is performed if the baby cannot be delivered vaginally. • During the placental stage the placenta (“afterbirth”) is delivered. Fig. 29.17, p. 1142

41. Hormonal Control of Labor • Estrogen from the ovaries induces the myometrium to make more oxytocin receptors. • Oxytocin is made by the hypothalamus and secreted by the posterior pituitary (neurohypophysis) in response to stretching of the cervix. • Oxytocin stimulates: • contraction of the uterus, which causes additional stretching of the uterus; and • production of prostaglandins, which • stimulate contraction of the uterus; and • stimulates oxytocin secretion. Fig. 29.16, p. 1141

42. Hormonal Control of Labor • The relationship between oxytocin release and stretching of the cervix and contraction of the myometrium is a positive feedback cycle. • This positive feedback cycle continues until delivery of placenta (breast feeding also causes stimulation of oxytocin secretion and helps return the uterus to its pre-pregnancy size). Fig. 29.16, p. 1141

43. Hormonal Control of Lactation • Milk formation is stimulated by prolactin from the adenohypophysis. • During breast feeding, stimulation of pressure receptors (pressoceptors) in the breast sends sensory impulses to the hypothalamus. • The hypothalamus, which produces oxytocin, stimulates the posterior pituitary to release oxytocin as part of a positive feedback cycle. • Oxytocin stimulates release of milk from breast • Baby continues sucking until he/she is full. • After baby stops sucking, hypothalamus is no longer stimulated. Fig. 29.18, p. 1144