The fetal pig that you will dissect has been injected with a colored latex (rubber) compound. The arteries have been filled with red latex and the veins with blue. An incision was made on the side of the neck to enable the injections. The incision can be seen in the first photograph below.
Several different pig dissections were used to obtain the photographs below. As a result, a structure shown in one photograph may look different than the same structure shown in another photograph.
Click on any of the photographs to view enlargements. Links to high-resolution, unlabeled photographs are also provided for many of the photographs.
The following words will be used to help identify the location of structures.
- Anterior refers to the head end. If a structure is anterior to another, then it is closer to the head.
- Posterior refers to the tail end.
- Dorsal refers to the back side. The pig in figure 1 is lying on its dorsal side.
- Ventral is the belly side. It is opposite the dorsal side. The pig in figure 1 below has its ventral side up.
Obtain a fetal pig and identify the structures listed in figure 1. Use figures 1–4 below to identify its sex.
Use your pig and also a pig of the opposite sex to identify the structures in the photographs below. The word “urogenital” refers to an opening that serves both the urinary (excretory) and the reproductive systems.
Figure 1. Female: injection site, nipples, umbilical cord
Figure 2. Female: genital papilla, urogenital opening, anus
Figure 3. Male: scrotum
Figure 4. Male: urogenital opening, penis, anus
Preparation and Initial Cuts
Tie one front leg of the animal with a string that passes underneath the dissecting pan to the other leg. Repeat this with the back leg.
Insert one blade of scissors through the body wall on one side of the umbilical cord and cut posteriorly to the base of the leg as shown in figure 6. Continue cutting from the anterior end of this cut so that it resembles an upside-down U. Your finished cut will be anterior to the navel and along each side of the navel. The flap of body wall that contains the navel can be folded posteriorly to reveal the internal organs of the abdomen.
Extend a single cut along the midline of the ventral surface of the animal to about 2 cm. from the chin. Cut completely through the body wall in the abdominal area but keep the cut shallow in the neck region.
A cut is made on the side of the animal from the point just posterior to the diaphragm dorsally. A similar cut is made on the other side. These two cuts will enable you to spread open the abdominal cavity.
Mouth and Neck Region
Use a scalpel to cut the sides of the mouth so that the bottom jaw can be opened for easier viewing (see figure 11). You will need to cut through the musculature and the joint that holds the lower jaw to the skull.
Open the jaw wide enough so that the glottis and epiglottis are exposed. The epiglottis projects up through the soft palate into a region called the nasopharynx. The hard palate and soft palate separate the nasal and oral cavities. When breathing, air passes through the nasal passages to the pharynx. The pharynx is the space in the posterior portion of the mouth that both food and air pass through. From the pharynx, it passes through the glottis to the trachea.
Figure 12. Hard palate, soft palate, glottis, epiglottis, and tongue.
Carefully, peel the skin away from the incision in the neck region using a blunt probe (a needle or the point of scissors will do if a blunt probe is not available). Use the probe to peel away muscle tissue until the thymus gland on each side of the trachea is exposed.
Use a probe to separate the two lobes of the thymus gland and to further separate the musculature over the trachea. The thyroid gland is darker and lies between the posterior ends of the two lobes of the thymus gland.
Figure 13. Thymus
Figure 14. The surrounding tissues have been separated to reveal the thyroid gland.
Continue separating the tissue with a probe until the trachea and esophagus are exposed. The esophagus is dorsal to the trachea. The large hard structure attached to the trachea is the larynx. It contains the vocal chords.
In the photograph below, the heart and blood vessels of the neck region have been removed so that the trachea can be seen more clearly. You should not remove these structures yet because you will need to identify the blood vessels later in the dissection.
Figure 15. Esophagus, larynx, trachea, bronchus, and lungs.
Observe how the diaphragm attaches to the body wall and separates the abdominal cavity from the lung (pleural) and heart (pericardial) cavities (figure 16 and 18 below). Contraction of the diaphragm forces air into the lungs.
You have already seen the nasopharynx, hard palate, soft palate, epiglottis, glottis, trachea, and larynx. Follow the trachea to where it branches into two bronchi and observe that each bronchus leads to a lung. The left lung contains three lobes and the right lung contains four. Each lung is located in a body cavity called a pleural cavity.
Figure 16. Diaphragm.
Figure 17. Lungs
18. Lungs, diaphragm.
Figure 19. Lungs, diaphragm (cut)
Figure 20. Esophagus, larynx, trachea, bronchus, and lung.
You have already seen how the esophagus leads from the pharynx through the neck region. Using a probe, trace follow the esophagus to the stomach. Identify the small intestine and large intestine. Find the posterior part of the large intestine called the rectum and observe that it leads to the anus. Locate the cecum, a blind pouch where the small intestine joins the large intestine.
Identify the liver. Lift the right lobe and find the gallbladder. This structure stores bile produced by the liver. Find the bile duct that leads to the small intestine. The pancreas is located dorsal and posterior to the stomach. It extends along the length of the stomach from the left side of the body (your right) to the point where the stomach joins the small intestine. Lift the stomach and identify this light-colored organ.
The spleen is an elongate, flattened, brownish organ that extends along the posterior part of the stomach ventral to (above) the pancreas.
The cecum is a blind pouch where the small intestine joins the large intestine. It houses bacteria used to digest plant materials such as cellulose. The cecum is large in herbivores but much of it has been lost during evolution in humans. The appendix in humans is the evolutionary remains of a larger cecum in human ancestors.
Figure 21. Duodenum, gallbladder, liver, lungs, large intestine, pancreas, small intestine, stomach. The liver has been lifted to reveal the gallbladder.
Figure 22. bile duct, gallbladder, large intestine, liver, and small intestine. The liver has been lifted to reveal the gallbladder.
Figure 23. Large intestine, liver, small intestine, spleen, and stomach.
Figure 24. small intestine, large intestine, pancreas, spleen, stomach – The spleen has been moved aside to reveal the pancreas.
Figure 25. The stomach and liver are lifted to show the pancreas.
Figure 26. Large intestine, pancreas, small intestine, spleen, and stomach.
Figure 27. cecum, large intestine, liver, small intestine, spleen. The cecum is found at the point where the small intestine joins the large intestine.
Figure 28. Large intestine, liver, small intestine, spleen, and stomach.
Figures 29 and 30 summarize the circulatory system of a mammal.
Figure 29. Circulatory system
Figure 30. Circulatory system
The drawing below shows some of the major arteries that carry blood to the body. Blood vessels that branch from the aorta carry blood to most of the body.
The pulmonary artery is capable of delivering a large amount of blood to the lungs but the lungs are not needed to oxygenate the blood of a fetus, so most of the blood is diverted to the aorta. This diagram shows that the ductus arteriosus connects the pulmonary artery to the aorta and diverts blood that would otherwise go to the lungs.
Shortly after birth, the ductus arteriosus closes and blood in the pulmonary artery goes to the lungs instead of the body.
Blood passes from the left ventricle through the aortic arch and aorta to the body. The first branch of the aorta is the brachiocephalic artery. The second branch is the left subclavian artery which goes to the left front leg. The right subvclavian carries blood to the right front leg and the carotids carry blood to the head.
Figure 31. Major arteries
The pericardium is a membrane that surrounds the heart and lines the pericardial cavity. It contains a lubricating fluid and isolates the heart from body movements such as the expansion and contraction of the nearby pleural (lung) cavity.
To view details of the aortic arch, ductus arteriosus, and pulmonary artery, it will be helpful to remove the left lung. With the left lung removed, the heart can be pushed to the right side to reveal the aorta and other blood vessels shown in figures 33–42.
Figure 32. Diaphragm, heart, lungs, and pericardium
Figure 33. Aortic arch, coronary artery, left atrium, left ventricle, pulmonary artery, right atrium, right ventricle.
Figure 34. Aorta, aortic arch, left atrium, brachiocephalic artery, ductus arteriosus, lung, pulmonary artery, pulmonary trunk, left subclavian artery,
Figure 35. Aorta, aortic arch, left atrium, brachiocephalic artery, left common carotid artery, right common carotid artery, ductus arterious, pulmonary artery, pulmonary trunk, left subclavian artery, right subclavian artery, trachea, left ventricle
Figure 36. Aortic arch, left atrium, brachiocephalic artery, left common carotid artery, right common carotid artery, larynx, pulmonary trunk, left subclavian artery, right subclavian artery, left ventricle.
Figure 37. Anterior vena cava, coronary artery, larynx, posterior vena cava, right subclavian vein, trachea.
Figure 38. Anterior vena cava, coronary artery, right external jugular vein, right internal jugular vein, larynx, lungs, right subclavian vein, trachea
Figure 39. Anterior vena cava, posterior vena cava.
Figure 40. Heart, liver, lung, posterior vena cava, thymus, thyroid
Figure 41. Aorta, colon, kidney, posterior vena cava, renal artery, renal vein, testicular artery, testis, umbilical artery, ureter, urinary bladder, vas deferens. The renal artery passes blood from the aorta to the kidney. The renal vein returns blood from the kidney to the posterior vena cava.
Figure 42. Aorta, colon (large intestine), diaphragm, heart, kidney, lung, renal artery, posterior vena cava, renal vein, small intestine, spleen, stomach, ureter.
Figure 43. External iliac artery, kidney, large intestine, posterior vena cava, renal vein, small intestine, testis, umbilical artery, ureter, urinary bladder.
Figure 44. Left atrium, brachiocephalic artery, left common carotid artery, right common carotid artery, coronary artery, external iliac artery, external iliac vein, posterior vena cava, pulmonary trunk, renal artery, renal vein, left subclavian artery, right subclavian artery, umbilical artery, left ventricle.
Figure 45. Aorta, colon (large intestine), diaphragm, heart, kidney, lung, renal artery, posterior vena cava, renal vein, small intestine, spleen, stomach, ureter.
Figure 46. Aorta, kidney, liver, posterior vena cava, renal artery, renal vein, spleen, ureter, urinary bladder.
Figure 47. Kidney, liver, posterior vena cava, renal vein, spleen, ureter, urinary bladder
Reproductive System (Female)
Figure 48. Urogenital papilla, anus
Figure 49. Colon, horn of uterus, ovary, urinary bladder
Figure 50. Colon, body of uterus, horn of uterus, ovaries, urethra, urinary bladder, urogenital sinus
Reproductive System (Male)
Figure 51. Penis, scrotum, urogenital opening
Figure 52. Seminal vesicle, testis, ureter, urinary bladder, vas deferens
Figure 53. Bulbourethral gland, spermatic cord, testis, urethra, urinary bladder, vas deferens
Figure 54. Path of urine flow
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- Fetal Pig Dissection, Biology 102. Authored by: Michael J. Gregory, Ph.D.. Provided by: LibreTexts. Located at: http://bio.libretexts.org/Under_Construction/BioStuff/BIO_102/Laboratory_Exercises/Fetal_Pig_Dissection. Project: The Biology Web. License: CC BY-NC-SA: Attribution-NonCommercial-ShareAlike