Pregnancy and Human Development Part A

1. Pregnancy and Human Development Part A

2. From Egg to Embryo • Pregnancy – events that occur from fertilization until the infant is born • Conceptus – the developing offspring • Gestation period – from the last menstrual period until birth • Preembryo – conceptus from fertilization until it is two weeks old • Embryo – conceptus during the third through the eighth week • Fetus – conceptus from the ninth week through birth

3. Relative Size of Human Conceptus Figure 28.1

4. Accomplishing Fertilization • The oocyte is viable for 12 to 24 hours • Sperm is viable 24 to 72 hours • For fertilization to occur, coitus must occur no more than: • Three days before ovulation • 24 hours after ovulation • Fertilization – when a sperm fuses with an egg to form a zygote

5. Sperm Transport and Capacitation • Fates of ejaculated sperm • Leak out of the vagina immediately after deposition • Destroyed by the acidic vaginal environment • Fail to make it through the cervix • Dispersed in the uterine cavity or destroyed by phagocytic leukocytes • Reach the uterine tubes • Sperm must undergo capacitation before they can penetrate the oocyte

6. Acrosomal Reaction and Sperm Penetration • An ovulated oocyte is encapsulated by: • The corona radiata and zona pellucida • Extracellular matrix • Sperm binds to the zona pellucida and undergoes the acrosomal reaction • Enzymes are released near the oocyte • Hundreds of acrosomes release their enzymes to digest the zona pellucida

7. Acrosomal Reaction and Sperm Penetration • Once a sperm makes contact with the oocyte’s membrane: • Beta protein finds and binds to receptors on the oocyte membrane • Alpha protein causes it to insert into the membrane

8. Acrosomal Reaction and Sperm Penetration Figure 28.2a

9. Blocks to Polyspermy • Only one sperm is allowed to penetrate the oocyte • Two mechanisms ensure monospermy • Fast block to polyspermy – membrane depolarization prevents sperm from fusing with the oocyte membrane • Slow block to polyspermy – zonal inhibiting proteins (ZIPs): • Destroy sperm receptors • Cause sperm already bound to receptors to detach

10. Completion of Meiosis II and Fertilization • Upon entry of sperm, the secondary oocyte: • Completes meiosis II • Casts out the second polar body • The ovum nucleus swells, and the two nuclei approach each other • When fully swollen, the two nuclei are called pronuclei • Fertilization – when the pronuclei come together

11. Events Immediately Following Sperm Penetration Figure 28.3

12. Preembryonic Development • The first cleavage produces two daughter cells called blastomeres • Morula – the 16 or more cell stage (72 hours old) • By the fourth or fifth day the preembryo consists of 100 or so cells (blastocyst)

13. Preembryonic Development • Blastocyst – a fluid-filled hollow sphere composed of: • A single layer of trophoblasts • An inner cell mass • Trophoblasts take part in placenta formation • The inner cell mass becomes the embryonic disc

14. Cleavage: From Zygote to Blastocyst Degenerating zona pellucida Inner cell mass Blastocyst cavity Blastocyst cavity Trophoblast (a) Zygote(fertilized egg) (c) Morula3 days (b) 4-cell stage2 days (e) Implanting blastocyst6 days (d) Early blastocyst4 days Fertilization(sperm meets egg) (a) (b) (c) Ovary Uterine tube (d) Oocyte(egg) (e) Ovulation Uterus Endometrium Cavity of uterus Figure 28.4

15. Implantation • Begins six to seven days after ovulation when the trophoblasts adhere to a properly prepared endometrium • The trophoblasts then proliferate and form two distinct layers • Cytotrophoblast – cells of the inner layer that retain their cell boundaries • Syncytiotrophoblast – cells in the outer layer that lose their plasma membranes and invade the endometrium

16. Implantation • The implanted blastocyst is covered over by endometrial cells • Implantation is completed by the fourteenth day after ovulation

17. Implantation of the Blastocyst Figure 28.5a

18. Implantation of the Blastocyst Figure 28.5b

19. Implantation • Viability of the corpus luteum is maintained by human chorionic gonadotropin (hCG) secreted by the trophoblasts • hCG prompts the corpus luteum to continue to secrete progesterone and estrogen • Chorion – developed from trophoblasts after implantation, continues this hormonal stimulus • Between the second and third month, the placenta: • Assumes the role of progesterone and estrogen production • Is providing nutrients and removing wastes

20. Hormonal Changes During Pregnancy Figure 28.6

21. Placentation • Formation of the placenta from: • Embryonic trophoblastic tissues • Maternal endometrial tissues

22. Placentation • The chorion develops fingerlike villi, which: • Become vascularized • Extend to the embryo as umbilical arteries and veins • Lie immersed in maternal blood • Decidua basalis – part of the endometrium that lies between the chorionic villi and the stratum basalis

23. Placentation • Decidua capsularis – part of the endometrium surrounding the uterine cavity face of the implanted embryo • The placenta is fully formed and functional by the end of the third month • Embryonic placental barriers include: • The chorionic villi • The endothelium of embryonic capillaries • The placenta also secretes other hormones – human placental lactogen, human chorionic thyrotropin, and relaxin

24. Placentation Figure 28.7a-c

25. Placentation Figure 28.7d

26. Placentation Figure 28.7f

27. Germ Layers • The blastocyst develops into a gastrula with three primary germ layers: ectoderm, endoderm, and mesoderm • Before becoming three-layered, the inner cell mass subdivides into the upper epiblast and lower hypoblast • These layers form two of the four embryonic membranes

28. Embryonic Membranes • Amnion – epiblast cells form a transparent membrane filled with amniotic fluid • Provides a buoyant environment that protects the embryo • Helps maintain a constant homeostatic temperature • Amniotic fluid comes from maternal blood, and later, fetal urine

29. Embryonic Membranes • Yolk sac – hypoblast cells that form a sac on the ventral surface of the embryo • Forms part of the digestive tube • Produces earliest blood cells and vessels • Is the source of primordial germ cells

30. Embryonic Membranes • Allantois – a small outpocketing at the caudal end of the yolk sac • Structural base for the umbilical cord • Becomes part of the urinary bladder • Chorion – helps form the placenta • Encloses the embryonic body and all other membranes

31. Gastrulation • During the 3rd week, the two-layered embryonic disc becomes a three-layered embryo • The primary germ layers are ectoderm, mesoderm, and endoderm • Primitive streak – raised dorsal groove that establishes the longitudinal axis of the embryo

32. Gastrulation • As cells begin to migrate: • The first cells that enter the groove form the endoderm • The cells that follow push laterally between the cells forming the mesoderm • The cells that remain on the embryo’s dorsal surface form the ectoderm • Notochord – rod of mesodermal cells that serves as axial support

33. Primary Germ Layers • Serve as primitive tissues from which all body organs will derive • Ectoderm – forms structures of the nervous system and skin epidermis • Endoderm – forms epithelial linings of the digestive, respiratory, and urogenital systems • Mesoderm – forms all other tissues • Endoderm and ectoderm are securely joined and are considered epithelia

34. Primary Germ Layers Figure 28.8a-e

35. Primary Germ Layers Figure 28.8e-h

36. Pregnancy and Human Development Part B

37. Organogenesis • Gastrulation sets the stage for organogenesis, the formation of body organs • By the 8th week all organ systems are recognizable

38. Specialization of Ectoderm • Neurulation – the first event of organogenesis gives rise to the brain and spinal cord • Ectoderm over the notochord thickens, forming the neural plate • The neural plate folds inward as a neural groove with prominent neural folds

39. Specialization of Ectoderm • By the 22nd day, neural folds fuse into a neural tube, which pinches off into the body • The anterior end becomes the brain; the rest becomes the spinal cord • Associated neural crest cells give rise to cranial, spinal, and sympathetic ganglia

40. Specialization of Ectoderm: Neuralization Figure 28.9a, b

41. Specialization of Ectoderm: Neuralization Figure 28.9c,d

42. Specialization of Endoderm • Embryonic folding begins with lateral folds • Next, head and tail folds appear • An endoderm tube forms the epithelial lining of the GI tract • Organs of the GI tract become apparent, and oral and anal openings perforate • Endoderm forms epithelium linings of the hollow organs of the digestive and respiratory tracts

43. Folding of the Embryonic Body Figure 28.10a-d

44. Endodermal Differentiation Figure 28.11

45. Specialization of the Mesoderm • First evidence is the appearance of the notochord • Three mesoderm aggregates appear lateral to the notochord • Somites, intermediate mesoderm, and double sheets of lateral mesoderm

46. Specialization of the Mesoderm • The 40 pairs of somites have three functional parts: • Sclerotome – produce the vertebrae and ribs • Dermatome – help form the dermis of the skin on the dorsal part of the body • Myotome – form the skeletal muscles of the neck, trunk, and limbs

47. Specialization of the Mesoderm • Intermediate mesoderm forms the gonads and the kidneys • Lateral mesoderm consists of somatic and splanchnic mesoderm

48. Specialization of the Mesoderm • Somatic mesoderm forms the: • Dermis of the skin in the ventral region • Parietal serosa of the ventral body cavity • Bones, ligaments, and dermis of the limbs • Splanchnic mesoderm forms: • The heart and blood vessels • Most connective tissues of the body

49. Specialization of the Mesoderm Figure 28.12

50. Development of Fetal Circulation • By the end of the 3rd week: • The embryo has a system of paired vessels • The vessels forming the heart have fused