THE HUMAN BODY—AN ORIENTATION LAB 1 Medical Terminology PAGE NO. 3 MICROSCOPY AND MEASUREMENT LAB 2 Basic Microscopy 11 LAB 3 Measurement 19 CELLS—THE LIVING UNITS LAB 4 The Cell 24 LAB 5 DNA and RNA Structure and Function 30 LAB 6 Cell Transport 33 LAB 7 The Cell Cycle 45 LAB 8 DNA Replication 48 LAB 9 Protein Synthesis 49 TISSUE—THE LIVING FABRIC LAB 10 Epithelial Tissue 52 LAB 11 Connective Tissue Proper 57 LAB 12 Cartilage and Bone Connective Tissue 62 THE INTEGUMENTARY SYSTEM LAB 13 Skin Structure and Function 68 BONES AND SKELETAL TISSUES LAB 14 Bones and Skeletal Tissues 73 THE SKELETON LAB 15 The Skeleton 79 THE MUSCULAR SYSTEM LAB 16 The Muscular System 107 THE SPECIAL SENSES LAB 17 The Eye and Vision 141 LAB 18 The Ear—Hearing and Balance 153 LAB MANUAL ANSWERS ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS 161 Page 2 OBJECTIVE To use the appropriate terms/names to describe body regions, planes of section, body regions, cavities, and abdominal regions. PART A—BODY REGIONS Study the diagram of body regions (Figure 1.7) in your text. Learn the appropriate anatomical term for each body region. After studying the regional names, label the numbered regions on the following diagrams. *Note that all regions are not numbered on the diagrams below. 2 1 4 5 6 8 9 10 11 3 7 12 13 16 14 17 15 18 20 19 22 21 23 24 25 26 27 28 29 30 31 32 33 ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 3 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 4 PART B—BODY CAVITIES Locate each of the following cavities using models and diagrams. List the major organs found in each cavity in the table below: CAVITY MAJOR ORGANS 1. Thoracic a. Pleural cavities b. Mediastinum c. Pericardial cavity 2. Abdominal cavity 3. Pelvic cavity 4. Cranial cavity 5. Vertebral (spinal) cavity Describe the location and contents of the additional cavities below: 6. Orbital― 7. Nasal cavity― 8. Oral (buccal) cavity― QUESTIONS 1. Cavities #1, #2 and #3 in the table above belong to what larger cavity? 2. Cavities #2 and #3 in the table above are cavities within what larger cavity? 3. Cavities #4 and #5 belong to what larger cavity? 4. Name the cavity that each of the following would be found in: a. Brain e. Urinary bladder b. Esophagus, trachea f. Spinal cord c. Heart g. Eye d. Liver h. Lung ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 5 PART C—LABEL THE CAVITIES NUMBERED ON THE DIAGRAMS BELOW 1 3 2 4 5 6 7 8 9 10 ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 6 PART D—ABDOMINOPELVIC REGIONS Locate the following regions on models. List the major organs found in each region using the table. REGIONS MAJOR ORGANS 1. Epigastric 2. Umbilical 3. Hypogastric 4. Right hypochondriac 5. Left hypochondriac 6. Right lumbar 7. Left lumbar 8. Right inguinal (iliac) 9. Left inguinal (iliac) Label the regions on the diagram below. NOTE: These numbers do not correspond with the numbers in the table above. 4 1 5 2 6 3 7 9 ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS 8 Page 7 PART E—BODY PLANES Label the body planes. 2 1 3 PART F—QUESTIONS 1. A patient experiences pain or injury to the right hypochondriac region. Which organ is most likely to be affected? 2. Severe upset stomach often presents as pain in the ____________________________ region. 3. The urinary bladder is found in the ____________________________ region. 4. The right kidney is mainly in the ______________________________ region. 5. A deep stab wound in the umbilical region would most likely damage what organs? 6. In order to view the lateral aspect of the heart you would need to make a _____________cut or plane of section. 7. What would you call the section you named in question 6 above when it is through the midline? If it were lateral to the midline? 8. Through what plane would one make a cut to visualize both lungs, the heart, spinal cord and ribs? 9. To view the anterior surface of both kidneys you would make a cut through what plane? ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 8 PART G—TERMINOLOGY Study the directional terms in Table 1.1 of your text and answer the questions below (Questions 7-8 pertain to serous membranes). 1. The nose is __________________________ to the mouth. 2. The fingers are _________________________ to the elbow. 3. The ear is ______________________ to the nose. 4. Muscle is ____________________________ to bone. 5. The heart is _____________________________ to the lungs. 6. The viscera are ___________________________ to the skin. 7. The serous membrane covering the surface of the lungs is the __________________________ pleura. 8. The layer of serous membrane lining the abdominal cavity is the __________________________ peritoneum. PART H—PREFIXES AND SUFFIXES A large part of anatomy and physiology is vocabulary, therefore it is helpful to learn the meaning of as many prefixes and suffixes as possible. Most of these can be found in your text. Look up the meaning of each prefix or suffix below and use it properly in a sentence. PREFIX/SUFFIX SENTENCE 1. brachi 2. epi 3. endo 4. peri 5. hypo 6. hyper 7. chondr 8. cephal 9. cardio ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 9 PREFIX/SUFFIX SENTENCE 10. neuro 11. pleur 12. para 13. a 14. hemi 15. ectomy ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 10 PART A—PARTS OF THE COMPOUND MICROSCOPE OBJECTIVES Name and identify the major parts of the microscope. State the function of each microscope part. Demonstrate proper use of the microscope. Demonstrate proper care and storage of the microscope. Determine the size of the field of vision and use it to estimate the size of an object on the microscope. Prepare a tissue wet mount and view it on the microscope. The microscope you will be using is a compound microscope which utilizes two lenses or lens systems to enlarge the object being viewed. The ocular or eyepiece is the lens near your eye while the objective is the lens located on the revolving nosepiece. Your microscope has two oculars, or binocular vision. The object is first magnified by the ocular and then once again by the objective. Total magnification of the object is therefore calculated by multiplying the magnification of the ocular times the objective. Your microscope is parfocal, which means you should not have to refocus each time you change the objective. Once the object is in focus, you should not need to use the coarse adjustment again when you change the magnification. Your instructor will assign you a microscope. LISTEN carefully as your instructor reviews the parts and use of the microscope. IDENTIFY each part listed below, STATE and LEARN the function and proper use of each part of the microscope. LABEL the name of the part in the proper location on the microscope diagram. a. Ocular b. Revolving nosepiece c. Objectives d. Microscope Frame e. Stage f. Mechanical stage clip g. Coarse focus adjustment knob h. Fine focus adjustment knob i. Condenser j. Iris diaphragm k. Base with illuminator m. Light intensity switch ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 11 THE BINOCULAR COMPOUND MICROSCOPE 1 2 9 10 11 3 12 4 5 6 13 14 7 15 8 ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 12 PART B—PROPER USE OF THE COMPOUND MICROSCOPE 1. Before using your microscope, clean the ocular and objective lenses using the lens paper and lens cleaner provided. NEVER use an ordinary tissue or paper towel to clean your microscope; it may cause permanent damage to the lenses! 2. Place the slide you are viewing under the stage clips and adjust the slide into position. Turn the revolving nosepiece until the low- power objective clicks into place. Use the coarse adjustment to move the stage as close as possible to the objective without hitting the slide (do this while you are watching and not while you are looking through the ocular!). 3. Look through the oculars. One ocular is adjustable, allowing people who wear glasses to adjust the magnification to suit each eye, eliminating the need to wear glasses while viewing. Adjust the lighting to give the best image possible by using the diaphragm lever below the stage. 4. While looking through the oculars, use the coarse adjustment knob to slowly move the stage in a downward direction until the object comes into focus. Complete the focusing with the fine adjustment knob. Adjust the light again if needed. The thicker the section of material you are viewing, the more lightly you will need. If the field of vision is dim or dark, adjust the diaphragm for more light. If the field is bright and the object is washed out, adjust the diaphragm for less light. 5. If the high-power objective is needed, you may carefully swing the objective into position once the microscope has been focused on low-power. You may need to move the slide to center the object being viewed and readjust the light (more light may be needed on a higher magnification). Use only the fine adjustment to focus the object. The coarse adjustment should not need to be used when changing objectives. 6. After using the microscope, remove the slide, rotate the revolving nosepiece until the lowest power objective is in position, and crank the coarse adjustment knob to lower the stage away from the objectives. Clean the stage, cover the microscope and return it to the cabinet. QUESTIONS 1. How do you determine total magnification when using the 4X, 10X and 40X objectives with a 10X ocular? Give the total magnification for each. 2. Why don’t you have to use coarse adjustment when focusing on high power? 3. If you are viewing an object and the object appears faint and washed out and the background is bright, what should you do to make the object more visible? ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 13 4. Define resolution 5. Which objective requires the most illumination? 6. Why should you always move the stage downward, away from the objective while focusing? PART C—PRACTICE USING THE COMPOUND MICROSCOPE 1. Begin by using the prepared slide of the Letter ‘e’. Place the letter on the stage so the bottom is towards you just as it would be if you were reading it. Focus it in on the 4X objective. Note the position of the letter in the field of vision. QUESTIONS a. What direction is the letter facing when viewed through the microscope? b. What do the microscope lenses do to images as they magnify them? 2. Now, try a prepared slide with a smaller object such as the sperm slide (obtain this slide from the tray your instructor has put out. This slide is NOT in your slide box). Focus it first on low-power, then move it to high. Be sure to use the diaphragm and adjust the light. Too much light will make the sperm invisible. a. Draw what you see on high power. ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 14 PART D—MAKING A WET MOUNT OF ANIMAL CELLS: CHEEK CELLS You will be preparing a wet mount (using stain) of both plant and animal cells. You will not be able to see most of the structures within the cells using your microscope, however, you will be able to distinguish differences between the plant and animal cell and view a few of the larger organelles. Detailed aspects of the cell will be studied in the next section. 1. Place a small drop of Methylene blue on a clean slide. 2. Rinse your mouth thoroughly before scraping to remove excess food and bacterial deposits. Lightly scrape the inner surface of your cheek using the flat side of a toothpick. Swirl the end of the toothpick with the scrapings in the methylene blue on the slide. 3. Carefully place a coverslip on the slide by sliding the coverslip along the slide at a 45-degree angle until it hits the stain and the stain forms a line on the edge of the coverslip. Lower the coverslip being careful not to form any bubbles. 4. Wait several minutes then place a drop of distilled water along one edge of the coverslip. Place a KimWipe at the other edge of the coverslip and slowly draw the stain out and the water in. Make sure the slide doesn’t get too dry. When you are finished, the background should be clear and yet the cells will remain blue from the stain. Methylene blue KimWipe 5. Focus your slide on low power. Look for cells that aren’t too clumped. Find a cell that is not folded or bunched with others and center it in the field of vision. 6. Now, move the high-power objective into place. Use only the fine adjustment if needed. Remember to adjust the light. QUESTIONS a. What structures are visible on the cell on high-power? 7. Remove the slide when finished and put the slide the GLASS DISPOSAL BOX in your lab. ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 15 PART E—MAKING A WET MOUNT OF PLANT CELLS: ONION CELLS 1. Carefully strip a thin layer of cells from a piece of onion. Lay the onion tissue out flat on a clean slide. Add a drop of iodine and put the coverslip in place. a. Cut an onion into quarters. b. Remove one of the fleshly “scale” leaves. c. Snapping the leaf backward usually produces a ragged piece of epidermis. d. Remove a small piece of epidermis and spread it evenly in a drop of iodine on a slide. e. Gently lower a coverslip to prevent trapping air bubbles. 2. Observe the onion cells first on low and then high power. QUESTIONS a. What differences can you see between the onion (plant) cell and the cheek (animal) cell? b. What cell structures can you see in the onion slide? PART F—PLANT CELLS VS. ANIMAL CELLS QUESTIONS a. What are the small, round, green structures that are visible in plant cells and what is their function? ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 16 b. Why don’t human cells or onion cells have the green structures mentioned above? c. Name the structures that differ between plant and animal cells and describe the differences. PART G—PREFIXES AND SUFFIXES Look up the following prefixes or suffixes in your text. Use each one properly in a sentence. PREFIX/SUFFIX SENTENCE 1. cyt, cyto 2. viscos 3. elle 4. stasis 5. inter 6. intra 7. macro 8. mega 9. micro 10. mito 11. mono 12. hetero ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 17 PREFIX/SUFFIX SENTENCE 13. pseudo 14. sub 15. supra ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 18 OBJECTIVE To become familiar with basic measurements and units used in the sciences. In science, the metric system is utilized to make measurements. One advantage of the metric system is that it is based on units of ten, making conversions from unit to unit easier. This section of the lab will provide you with a brief overview of some measurements often used in science and the health professions. Kilo (k) Base Centi (c) Milli (m) Micro () Nano (n) Angstrom (Å) A. LENGTH B. VOLUME C. MASS The metric base unit for length is the meter. Learn the relationships of the following related units and make the conversions indicated. (See Metric System Table). The metric base unit for volume is the liter (L), which is slightly more than a quart. Mass is the amount of matter in an object and it is constant. The unit of mass is the gram. Doses of medicine are usually milligrams or micrograms, while body weight is measured in kilograms. Meter (m) Centimeter (cm) Millimeter (mm) Micrometer/micron (m) Nanometer (nm) Angstrom (Å) Approximate Comparisons (1) 12 oz Soda = 360 mL (1) fluid ounce = 30 mL (cc) (1) teaspoon = 5 mL (cc) (1) gallon = 3.785 L A 70 kg man = Convert the following: mL 345 cm = mm 5 oz = mL 160 km = m 5 sodas = 2500 m = mm 1 L of medicine will make how many 5 mL injections? nm 1 mm = m 200 nm = 1Å= lbs Convert the following: 1L= 11 cm = Convert the following: mL 300 g = mg 4000 g = mg Mr. Grundy weighs 195 lbs. He receives a dose of medicine at 2 mg/kg body weight. How much medicine does he receive? injections 520 g = mm nm 4250 g = mg g QUESTIONS SIMILAR TO THESE WILL APPEAR ON YOUR EXAMS NOTE When converting to a smaller unit, the number increases so move the decimal point will to the right. When converting to a larger unit, the number will decrease so move the decimal point to the left. ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 19 PART D—QUESTIONS 1. How many inches equal 1 millimeter? __________________ 2. The prefix kilo means __________________ 3. What instrument would you use to measure about ⅓ cup of fluids in the metric system? ____________ 4. What units would be used to measure if a large amount of fluid (to fill a swimming pool)? ____________ 5. What units would the measurement be in if you were measuring a small amount of fluids (a full eyedropper)? __________________ PART E—USING MEASUREMENTS You can use metric measurements to estimate the size of an object under the microscope. You must begin by measuring the field of vision on the microscope with a metric ruler. EXAMPLE: A metric ruler was placed in the field of vision with the 10X objective in place. The ruler under the field of vision is shown below: 1. Assume the marks on the diagram above designate mm. What would the size of the field of vision be on the diagram above? 2. Place a metric ruler under each objective lens on your own microscope and measure the fields of view. The space between each visible line is equal to one millimeter. Record the measurement below: 4X = 10X = 40X = ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 20 3. Now that you have the size of your fields of vision, remove the ruler. You should NOT have to measure again as long as you use the same microscope. You can now use this information to estimate the size of an object in the field of vision. EXAMPLE: TRY THIS PRACTICE PROBLEM FIRST: 3 mm a. To find the length of one cell in the field of vision above, you would first visualize and estimate how many cells would fit across the length of the field of vision. In this case, approximately 6 cells fit across the length of the field. The length of one cell can be calculated using the following formula: diameter of field size of cell # cells visible b. If you plug in the proper numbers, you will find the answer by calculating: 3 mm 6 cells The answer is:_________________mm c. Now calculate the height of one cell using the same method (show your work): The answer is:________________mm 4. Find the slide of 3-colored strings in your slide box and focus it in on low-power (10X) on your microscope. a. Use the method you have just learned to estimate the width of one string (pick one of the colored strings and estimate how many times it will fit across the field of vision). ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 21 b. Do the calculations and show your work below: The width of the __________ color string is ___________ mm PART F—QUESTIONS 1. How many millimeters equal an inch? ___________________ 2. 10 cells are visible across the width of the microscope field using the 4X objective lens, and 4 cells are visible along its length. Calculate the dimensions of the cell in both millimeters and microns. (mm) (µ) LENGTH OF THE CELL WIDTH OF CELL ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 22 THE METRIC SYSTEM MEASUREMENT UNIT AND ABBREVIATION METRIC EQUIVALENT 3 1 kilometer (km) = 1000 (10 ) m 1 meter (m) = 100 (10 ) cm = 1000 mm 1 centimeter (cm) = 0.01 (10 ) m 1 millimeter (mm) = 0.001 (10 ) m 1 micrometer (m) = 0.000001 (10 ) m 1 nanometer (nm) = 0.000000001 (10 ) m 1 angstrom (Å) = 0.0000000001 (10 ) m 2 LENGTH -2 -3 1 mile = 1.61 km 1 m = 1.09 yards (yd) 1 m = 39.37 inches (in) 1 yard = 0.914 m 1 foot = 0.305 m 1 cm = 0.394 in 1 foot = 30.5 cm 1 inch = 2.54 cm 1 mm = 0.039 in -10 2 2 = 10,000 cm AREA 2 2 2 1 m = 1.1960 sq. yards 2 1 m = 10.764sq. feet 1 sq. yard = 0.8361 m 2 1 sq. foot = 0.0929 m 2 1 square centimeter (cm ) = 100 mm 1 cm2 = 0.155 sq. inch 1 sq. inch = 6.4516 cm 1 metric ton (t) = 1000 kg 1 t = 1.103 ton 1 ton = 0.907 t 1 kilogram (kg) = 1000 g 1 kg. = 2.205 pounds (lb) 1 pound = 0.4536 kg 1 gram (g) = 1000 mg 1 g = 0.0353 ounce (oz) 1 g = 15.432 grains 1 ounce = 28.35 g 1 milligram (mg) = 0.001 g 1 mg = 0.015 grain 1 microgram (g) = 0.000001 g 3 3 1 m = 1.3080 cubic yds. 3 1 m = 35.315 cubic ft. 3 1 cubic meter (m ) = 1,000,000 cm 3 1 cubic centimeter (cm or cc) 3 3 = 0.000001 m = 1 mL 3 3 1 cubic yd. = 0.7646 m 3 1 cm = 0.0610 cubic in. 1 cubic in. = 16.387 cm 3 1 cubic millimeter (mm ) = 0.000000001 m 1 kiloliter (kL) = 1000 L 1 kL = 264.17 gallons (gal) 1 gal. = 3.785 L 1 liter (L) = 1000 mL 1 L = 0.264 gal 1 L = 1.057 quarts (qt) 1 qt. = 0.946 L 1 milliliter (mL) = 0.001 L 3 = 1 cm 1 mL = 0.034 fluid oz. 1 mL = ¼ teaspoon (tsp) 1 mL = 15-16 drops (gtt.) 1 qt. = 946 mL 1 pint = 473 mL 1 fluid oz. = 29.27 mL 1 tsp. = 5 mL 1 microliter (L) = 0.000001 L 1 second (s) = 1 millisecond (ms) = 0.001 s VOLUME (LIQUIDS & GASES) TIME TEMPERATURE 1 km = 0.62 mile -9 2 VOLUME (SOLIDS) ENGLISH TO METRIC CONVERSION FACTOR -6 1 square meter (m ) MASS METRIC TO ENGLISH CONVERSION FACTOR Degrees Celsius (C) ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS 1 minute (min) 60 F = 9 5 C + 32 C = 5 (F - 32) 9 Page 23 PART A—THE STRUCTURE OF THE PLASMA MEMBRANE OBJECTIVES Describe the structure of the plasma membrane and relate it to membrane functions. Label the diagram of the cell membrane below. Extracellular Fluid 4 1 3 5 2 3 4 Cytoplasm ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 24 QUESTIONS 1. Describe 2 functions of structure #1 in the diagram on page 24. 2. Will glucose be able to diffuse freely past structure #2 in the diagram on page 24? Explain why or why not. 3. Give two possible functions for proteins such as protein #3 in the diagram on page 24. 4. What are some possible functions of structure #4 in the diagram on page 24? PART B—THE CELL: ORGANELLES AND THEIR FUNCTION OBJECTIVES Name and identify the organelles found in a cell. List the major differences between a typical plant and animal cell. Study the models and charts of the cell in your lab. Use the diagram in your text to identify the various organelles and structures. Label the diagram of the cell on the following page. Read and use the descriptions in your text to fill in the major function of each structure listed in the chart on pages 27-29. ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 25 ANIMAL CELL 1 15 2 14 13 3 12 11 4 10 9 5 8 7 6 ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 26 CELL STRUCTURE AND FUNCTION Cells differ in structure to accommodate their various functions ORGANELLE FUNCTION The cellular material: Contains: CYTOPLASM Cytosol― Site of: MITOCHONDRIA System of: Externally covered with: ROUGH ENDOPLASMIC RETICULUM ER without: SMOOTH ENDOPLASMIC RETICULUM Dense particles composed of: RIBOSOMES Flattened, stacked membranous sacs. Modifies and packages: GOLGI APPARATUS ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 27 ORGANELLE FUNCTION VACUOLES Membranous sacs containing: LYSOSOMES Membranous sacs of: PEROXISOMES A network of: CYTOSKELETON Hollow, cylindrical protein: MICROTUBULES MICROFILAMENTS Site for assembly of: CENTROSOME Contains paired: ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 28 ORGANELLE FUNCTION Cellular extensions used to: CILIA FLAGELLA Controls: NUCLEUS Double membrane whose outer membrane is: NUCLEAR ENVELOPE Dark, spherical bodies within: NUCLEOLUS Produces: DNA + CHROMATIN A selectively: PLASMA MEMBRANE ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 29 OBJECTIVE To learn the composition, structure and location of DNA and RNA and to describe the basic function of each PART A—DNA STRUCTURE Deoxyribonucleic acid is a double-stranded molecule composed of carbon, oxygen, hydrogen and nitrogen. It is constructed from structural units called nucleotides, which consist of a nitrogen-containing base, a pentose sugar (deoxyribose) and a phosphate group. Read about the structure of DNA in the chemistry chapter of your book. Label the structures on the DNA molecule below and answer the following questions. 1 2 3 5 (entire structure in box) 4 ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 30 QUESTIONS 1. ______________________ and ____________________are large two-ring bases called purines. The smaller, single-ring bases known as pyrimidines are ____________________ and _____________________ ,as well as another base found in RNA called _______________________. 2. The two sides of the DNA molecule is composed of alternating _____________________and _______________________ molecules. 3. The rungs of the DNA ladder is composed of _____________________ pairs that are bonded together by a ______________________________. 4. The entire DNA molecule is coiled into a spiral called a _______________________. 5. Bonding of the nitrogenous bases is specific, each bonding only to a complementary partner. Thymine will always bond to ____________________ while guanine bonds to ______________________. In RNA, adenine bonds to ____________________ instead of thymine. 6. Typically, DNA is found in the ________________________ of the cell. It is additionally found in organelles called_____________________. 7. What are the main functions of DNA? (Give at least 2) 8. The genetic code of an organism is determined by the nitrogenous base sequence of a DNA molecule. A segment of DNA that carries the code or instructions for the construction of polypeptide is called a ______________________. 9. Prior to cell division, the DNA in the nucleus must _______________________ to ensure the cell being produced has an identical copy of DNA. ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 31 PART B—RNA STRUCTURE Ribonucleic acid is composed of the same elements as DNA. It is also constructed from nucleotides. Read about RNA in the chemistry chapter of your text and answer the following questions: QUESTIONS 1. Name three structural differences between DNA and RNA. 2. Where can RNA typically be found in the cell? 3. What is the function of RNA? 4. Give the full names of each of the following types of RNA. Briefly describe the function of each: a. rRNA b. mRNA c. tRNA ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 32 OBJECTIVE To identify, demonstrate and explain the various processes utilized for transport of substances in the cell. To understand and explain the factors influencing movement of substances into and out of the cell. To understand and explain various tonicities and their effect on the cell. To demonstrate and explain the factors that affect the rate of diffusion. DIFFUSION Diffusion is defined as movement of solute from high to low concentration. The rate at which diffusion takes place is dependent upon 3 main factors. Conduct the following exercises to determine the factors that affect the rate of diffusion. PART A—EFFECT OF TEMPERATURE ON THE RATE OF DIFFUSION 1. Obtain two 150 mL glass beakers. Using tape, label one beaker “cold” and the other “hot.” 2. Fill the cold beaker with ice water (do not put ice in the beaker) and put hot water in the hot beaker. 3. Allow the water to become still. 4. Before starting, measure the temperature of each beaker and record the readings in the table below. 5. Start the timer as soon as you add 1 drop of food coloring to the center of each beaker. 6. Observe the distance the dye has moved in each beaker and record those observations at each time interval on the table below. 7. Observe how the dye spreads every 15 seconds for the first 30 seconds, then 1 minute thereafter for 3 minutes. Record these observations in the second table. TABLE A―DIFFUSION RESULTS FOR FOOD COLORING IN WATER TIME TEMPERATURE (°C) COLD WATER OBSERVATIONS TEMPERATURE (°C) HOT WATER OBSERVATIONS 15 sec 30 sec 1 min 2 min 3 min 8. When you are DONE with this experiment: WASH the beakers with soap and water and then DRY with paper towel ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 33 QUESTIONS 1. How did the diffusion rate in each of the beakers compare? Which one diffused the fastest? 2. How long did it take for the dye to completely diffuse in the hot water? In the cold water? 3. What effect does temperature have on the rate of diffusion? PART B—EFFECT OF PARTICLE SIZE ON THE RATE OF DIFFUSION 1. Obtain an agar plate with 1 cm wells scooped out of the middle. 2. Using a marker, label the lid of the agar plate well #1, well #2, well #3 and well #4. # Well 1 # Well 2 3. Fill the wells as follows: Well #1 with 0.02 M Alizarin Yellow (MW = 287.23 g/mol) # Well 3 # Well 4 Well #2 with 0.02 M Janus Green (MW = 511.19 g/mol) Well #3 with 0.02 M Congo Red (MW = 696.67 g/mol) Well #4 with 0.02 M Aniline Blue (MW = 737.74 g/mol) 4. Replace the lid and place the agar plate on a sheet of white paper. 5. Measure with a ruler the distance mm that each dye has diffused in 10 minute intervals for the next 50 minutes. Record the results in the table below. TABLE B―DIFFUSION RESULTS FOR 0.02 M DYES IN AGAR TIME (MIN) WELL 1 (0.02 M Alizarin Yellow) Diffusion Distance (mm) WELL 2 (0.02 M Janus Green) Diffusion Distance (mm) WELL 3 (0.02 M Congo Red) Diffusion Distance (mm) WELL 4 (0.02 M Aniline Blue Diffusion Distance (mm) 10 min 20 min 30 min 40 min 50 min ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 34 6. When you are DONE with this experiment: Discard the agar plate in the BIOHAZARD WASTE bag. QUESTIONS 1. All 4 wells contained dyes with a concentration of 0.02 M. Which one had the fastest rate of diffusion? Why? Explain the results. 2. What factor caused the difference in the rates of diffusion in all the wells? PART C—EFFECT OF CONCENTRATION ON THE RATE OF DIFFUSION 1. Obtain an agar plate with 1 cm wells scooped out of the middle. 2. Using a marker, label the lid of the agar plate well #1, well #2, and well #3. 3. Fill the wells as follows: Well #1 with 0.01 M Potassium permanganate, KMnO4 Well #2 with 0.05 M KMnO4 Well #3 with 0.10 M KMnO4 4. Measure with a ruler the distance in mm that each concentration of KMnO4 has diffused in 10 minute intervals for the next 50 minutes. Record the results in the table below. TABLE C―DIFFUSION RESULTS FOR DIFFERENT CONCENTRATIONS OF KMnO4 IN AGAR TIME (MIN) WELL 1 (0.01 M KMnO4) Diffusion Distance (mm) WELL 2 WELL 3 (0.05 M KMnO4) (0.10 M KMnO4) Diffusion Distance (mm) Diffusion Distance (mm) 10 min 20 min 30 min 40 min 50 min 5. When you are DONE with this experiment: Discard the agar plate in the BIOHAZARD WASTE bag. ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 35 QUESTIONS 1. How did the rates of diffusion compare between wells? Which one had the fastest rate of diffusion? Why? Explain the results. 2. What factor caused the difference in the rate of diffusion between the wells? 3. Name 2 places in your body where each of the following occur: a. Diffusion of a solute into a liquid b. Diffusion of a gas into a liquid c. Diffusion of a solute or liquid into a colloid OSMOSIS PART A—THISTLE TUBE OSMOMETER 1. Set up the osmometer as follows: a. Cut a 4-inch piece of dialysis membrane tubing and soak it in a dish containing distilled water (dH2O) until it is soft and pliable. b. Open the tubing with your fingers. c. With scissors, cut dialysis membrane along one edge in order to make ONE long piece of membrane. d. Have one person fill the bulb of the tube with molasses while the other person closes off the stem of the thistle tube with his/her finger. e. Place the wet dialysis membrane over the bulb of the thistle tube and secure it TIGHTLY in place by winding rubber bands over the bulb several times. Make sure that the syrup will not leak through the sides! f. Invert the tube and allow the syrup in the stem of the thistle tube to settle in the bulb before MARKING the level of the syrup with a grease pencil. g. Fill the plastic cup half full with distilled water and lower the thistle tube bulb in the cup. (SEE diagram) ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 36 2. Observe the level of the molasses for the next 30 to 40 minutes and write your observations below. Observations: 3. When you are DONE with this experiment: Dismantle the osmometer and thoroughly RINSE the thistle tube. Wash and dry the plastic cup. DISCARD dialysis membrane in trash bin. QUESTIONS 1. What happened to the level of the molasses? 2. Explain what caused the movement of the molasses. Be specific. 3. Why didn’t the molasses leave the thistle tube and enter the water in the beaker? 4. If the thistle tube were a cell and the water in the beaker were the solution surrounding the cell: a. Is the solution isotonic, hypotonic, or hypertonic? Explain. b. Are there more solutes inside or outside the cell? c. How long would water move into the cell? What might result from this? 5. Give some examples of where osmosis is taking place in your body. ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 37 6. Is osmosis diffusion? Explain. PART B—OSMOSIS IN POTATO CELLS 1. Fill one culture dish with distilled water (dH2O) and the other with 10% NaCl. 2. Using a cork borer, make SIX plugs of potato. Three plugs will be soaked in distilled water, the other three will be soaked in 10% NaCl. 3. Measure the original volume of each set of three plugs as follows: a. Place 25 mL of dH2O in BOTH 50 mL graduated cylinders. [This is the initial water volume] b. In the first cylinder, put the first set of 3 potato plugs and record the final volume of water in the table below. [This set of plugs will be soaked in the dish containing dH2O] c. Determine the ORIGINAL volume of these plugs by subtracting the initial volume of water from the final. Record this volume in the table below. d. Repeat this procedure for the other set of 3 potato plugs. [This set of plugs will be soaked in the dish containing 10% NaCl] 4. After determining the volume of the plugs, place EACH set of plugs into their designated solution and allow to soak for 30 minutes. 5. After 30 minutes, remove the potato plugs with the forceps provided and observe the texture, color and flexibility of the plugs in each set. Record these observations in the data table. 6. Remeasure the volume of each set of plugs and record the results below. If the mass increased over the 30 minutes, place a (+) in the data table next to the amount changed. If the mass decreased, place a (-) in the space. 7. When you are DONE with this experiment: WASH glassware with soap and water and then DRY the outside surfaces with paper towel. ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 38 OSMOSIS IN POTATO CELLS Distilled Water (mL) 10%NaCl (mL) 25 mL 25 mL 25 mL 25mL 1. Vol. of H2O before adding plugs 2. Vol. of H2O after adding plugs 3. Original Vol. of Potatoes (Vol in #2 – Vol in #1) 4. Volume. of H2O 30 min. later (2nd measurement) before adding plugs 5. Volume of H2O after adding plugs (2nd measurement after 30 min. in Sol’n 6. Volume Change (+) or (-) (negative change represents volume loss while positive change represents volume gain) (Vol in #5 – Vol in #4) 7. Observations QUESTIONS 1. Which group of plugs gained volume? Explain. 2. Which group of plugs lost volume? Explain 3. What type of solution was the 10% salt solution? The distilled water? 4. How did the rigidity of the plugs in the two solutions compare? Why the difference? ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 39 5. In order to maintain the normal osmolarity of a potato cell, in what type of solution would need to put the potatoes? PART C—OSMOSIS IN HUMAN CELLS 1. Clean your finger with an alcohol pad. Let it dry before you prick your finger. 2. Prick your finger with the lancet at the SIDES of the finger. 3. Prepare THREE blood slides as follows: a. Slide 1: Add one drop of distilled water + 1 drop of blood. b. Slide 2: Add one drop of 0.9% NaCl solution + 1 drop of blood. c. Slide 3: Add one drop of 5% NaCl solution + 1 drop of blood. 4. Cover each slide with a cover slip and observe under the microscope on high power. 5. Draw and record your observations below. SLIDE 1 [DISTILLED H2O] SLIDE 2 [0.9% NaCl] SLIDE 3 [5% NaCl] 6. IMPORTANT SAFETY DISOSAL INSTRUCTIONS: DISCARD the used blood lancets in the RED Sharps Container. DISCARD the used slides in the Biohazardous Disposal Pouch. DISCARD the used alcohol pads and any other materials containing blood in the large receptacle. QUESTIONS 1. Which slide contained cells in a hypertonic solution? Hypotonic? Isotonic? ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 40 2. Describe and explain the cause of the appearance of the cells in each slide. 3. What is a physiological saline solution? 4. Define the following terms: a. crenation– b. hemolysis– PART D—DIALYSIS 1. Cut approximately 15 cm (6- inch) of dialysis tubing and soak in dishpan filled with distilled water to soften. 2. Remove the tubing from the water; fold over one end and tie off with string. 3. Slip the stem of a funnel into the open end of the bag and fill the bag approximately half full with the solution labeled “Dialysis Solution.” Contents of test solution in dialysis tubing: Water Glucose Albumin (protein) Starch NaCl 4. Remove the funnel; fold and tie off the open end of the bag. 5. Place the dialysis tube ‘sausage’ into a beaker of distilled water and let sit for 30 minutes. 6. After 30 minutes, test the water in the beaker for the following substances to determine if they have left the tubing and entered the water. Record your results in the table. a. Test for NaCl i. Place several mL of water from the beaker in a test tube. ii. Add several drops of silver nitrate solution (AgNO3). iii. Formation of a white, cloudy precipitate indicates the presence of NaCl. ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 41 b. Test for Glucose i. ii. iii. iv. Place several mL of water from the beaker in a test tube. Add a squirt or 10 drops of Benedict’s solution to the tube. Warm the tube in a hot water bath for 5 to 10 minutes. Look for a color change. Any change to green, yellow, orange or red indicates the presence of glucose. c. Test for Starch i. Place several mL of water from the beaker in a test tube. ii. Add several drops of iodine solution. iii. A bluish or purplish-black color indicates the presence of starch. d. Test for Albumin (protein) i. Place several mL of water from the beaker in a test tube. ii. Carefully add several drops of nitric acid (HNO3) to the tube. iii. Formation of a white, cloudy precipitate indicates the presence of protein. RESULTS OF TESTS FOR SUBSTANCES IN BEAKER Test for Presence of Substance Added NaCl Silver nitrate Observations Following Test Substance Present? (+) or (-) Glucose Starch Albumin 7. When you are DONE with this experiment: WASH ALL glassware with soap and water and then DRY the outside surfaces with paper towel. INVERT test tubes in the rack and allow to air dry. QUESTIONS 1. Define dialysis– 2. Which of the four substances left the dialysis tube and entered the water? ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 42 3. Why did some substances get through the membrane while others didn’t? 4. What physical characteristic of albumin affected its ability to pass through the membrane? 5. When solutes move, what usually follows? FILTRATION PART A—FILTRATION OF AN UNKNOWN SOLUTION 1. Assemble the filtration apparatus shown on diagram. 2. Fold a piece of filter paper per diagram. 3. Open filter paper in a cone and place it inside the funnel. 4. Fill the funnel with the solution labeled “Filtration Solution” to determine what will pass through the filtration membrane. 5. If the filter paper gets clogged, place a new piece of filter paper in the funnel. You might have to repeat this process a few times. 6. Continue adding the solution to the filter until there is enough filtrate in the beaker to fill 4 separate test tubes about one inch high. 7. Use one test tube of filtrate to test for each of the following substances. a. Test for Salt i. See Part D 6a (dialysis experiment) for the procedure to test for NaCl. Record the results in the table. b. Test for Starch i. See Part D 6c (dialysis experiment) for the procedure to test for starch. Record the results below. c. Test for Charcoal i. Observe the filtrate in the test tube. Any gray or black particles indicate presence of charcoal. ii. Indicate that the charcoal passed through the filter. ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 43 iii. Record the results below. d. Test for Copper Sulfate (CuSO4) i. Observe the filtrate in the test tube for a bluish or aqua color. ii. A blue color indicates copper sulfate has passed through the filter. iii. Record the results below. RESULTS OF FILTRATION TESTS Test Substance Present? (+) or (-) NaCl Starch Charcoal Copper sulfate 8. When you are DONE with this experiment: WASH ALL glassware with soap and water and then DRY the outside surfaces with paper towel. INVERT test tubes in the rack and allow to air dry. QUESTIONS 1. Name three things that will determine whether a substance will pass through a filtration membrane. 2. In a closed system, what force is necessary for filtration to take place? 3. How could you increase this force? 4. Where does filtration take place in the body? ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 44 OBJECTIVES Learn the stages of the cell cycle and state the major events that occur during each stage. Name each mitotic phase in order and learn the events that take place in each phase. PART A—THE CELL CYCLE Fill in the names for each stage below. List the major events that occur in each stage below the name. S (name of stage) Events: G1 G2 (name of stage) Events: (name of stage) Events: 4th Phase 1st Phase (name of stage) (name of stage) 3rd Phase 2nd Phase (name of stage) (name of stage) ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 45 PART B—MITOSIS Mitosis (cell division) is the process by which organisms grow. A single PARENT cell undergoes mitosis and forms two DAUGHTER cells. Each daughter has the same number of CHROMOSOMES as the parent (46 or 23 pairs in humans, 2n, diploid). Division of the nuclear material is called KARYOKINESIS and division of the cytoplasm is CYTOKINESIS. Meiosis (reduction division) in contrast produces 4 cells, each with half of the chromosome number of the parent. Obtain a slide of Allium (onion) root tip. Identify the stages of mitosis. Obtain a slide of whitefish blastula. Identify the stages of mitosis. Identify the stage depicted in each picture below. Identify the major events of each stage. STAGE: MAJOR EVENTS: STAGE: MAJOR EVENTS: STAGE: MAJOR EVENTS: ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 46 STAGE: MAJOR EVENTS: STAGE: MAJOR EVENTS: PART C—TERMINOLOGY Learn the following terms: interphase centromere karyokinesis kinetochore cytokinesis microtubules centrioles spindle fibers/ mitotic spindles chromatin poles chromatids cleavage furrow chromosomes ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 47 OBJECTIVE To learn and understand the steps in the process of DNA replication and to realize the purpose of the event. PART A—DNA REPLICATION Before a cell can divide, its DNA must be duplicated so that identical copies of the cell’s genes can be passed on to each new cell. This process is called replication. Replication occurs in the cell nucleus during interphase. Read the section in your text on replication (Chapter 3). Fill in the blanks below. Label where each step (1-6) would occur on the diagram to the right. QUESTIONS 1. The enzyme _______________ causes the DNA helix to begin to ___________________. 2. The two DNA strands begin to _______________exposing the _______________. 3. Each DNA strand will serve as a template for a _________________. 4. The enzyme ______________ catalyzes the synthesis of the new DNA strands as free DNA nucleotides attach to _______________________ on the exposed DNA strands. 5. The short, new DNA segments are spliced together by the enzyme __________________. 6. The result is the formation of __________________ ______________________ identical to the original DNA helix. ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 48 OBJECTIVE To understand when, where and how the steps of protein synthesis occur. DNA serves as the master blueprint for any polypeptide or protein (including enzymes). Since DNA cannot leave the nucleus, RNA must copy the DNA code and take it out of the nucleus (transcription) where the code will be used to synthesize a protein (translation). The processes of transcription and translation must be used each time a polypeptide is produced by the cell. The process begins in the nucleus but the ultimate act of producing the protein takes place on the ribosome in the cytoplasm. PART A—TRANSCRIPTION Fill in the steps of transcription below and answer the following questions. QUESTIONS 1. The enzyme ________________________ binds to the DNA molecule causing the DNA helix to_____________________. 2. The two strands of DNA __________________ exposing the DNA nucleotides. One DNA strand, called the _________________ strand, will serve as the template for construction of a complementary __________________ molecule. _____________________ is also the enzyme responsible for bonding mRNA nucleotides to the DNA template. 3. For each triplet (three base sequence on the DNA template), a complementary three base mRNA segment called a _______________will be formed on the mRNA. 4. Before it can be used, the new mRNA strand must be edited. Noninformational regions called ___________________ must be removed. The remaining informational pieces called ____________________ are spliced together to form a functional mRNA strand. 5. The mRNA will leave the nucleus and carry the code to the ___________________ of the cell where it will attach to a ___________________. ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 49 6. Why must mRNA be used to carry the DNA code? 7. What will the mRNA strand ultimately be used for? 8. In a diagram, how can you distinguish a newly forming mRNA strand from the DNA template? PART B—TRANSLATION Fill in the blanks below and answer the following questions. Label the diagram. QUESTIONS 1. The mRNA molecule attaches to a ___________________. 2. A new type of RNA called ______________ is used to bind amino acids and carry them to the mRNA on the ribosome. 3. There are many different types of tRNA. Each type binds to a specific amino acid. The amino acid is bound to one end of the tRNA while the other end contains a three base sequence called an ___________________. 4. The anticodons of the tRNA form ________________ bonds with the complementary codons on the _________________. 5. As successive amino acids are brought to their proper positions by the tRNA, ______________________ bonds are formed between them and the formation of a _________________________ begins. 6. Where does the process of translation occur? 7. What molecule is used as a template for the construction of the polypeptide? 8. What is the job of tRNA? ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 50 9. When will the processes of transcription and translation need to be used by the cell? 6 5 7 4 2 3 1 8 ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 51 OBJECTIVES Be able to identify each tissue type. Be able to identify associated structures. Know the location of each tissue type. Know the function of each tissue type. Take a few minutes and review what you have previously learned about microscope use. Be sure you know how to use the microscope properly before you begin. STUDY THE BASIC TISSUE TYPES, CLASSIFICATION OF EPITHELIAL TISSUES AND EPITHELIAL TISSUE TYPES LISTED IN BOXES A, B AND C BELOW. PART A—BASIC TISSUE TYPES 1. 2. 3. 4. Epithelial Connective Muscle Nervous PART B—CLASSIFICATION 1. Often named by shape a. Squamous b. Cuboidal c. Columnar 2. Named by layers a. Simple i. Pseudostratified b. Stratified i. Transitional PART C—SPECIFIC EPITHELIAL TISSUE TYPES 1. 2. 3. 4. 5. 6. Simple squamous Simple cuboidal Simple columnar Pseudostratified ciliated columnar Stratified squamous Transitional ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 52 PART D—SIMPLE EPITHELIA 1. Simple squamous epithelium TISSUE LOCATIONS FUNCTION & NOTES DRAWING LOCATIONS FUNCTION & NOTES DRAWING Specific location: TISSUE Same as above Same as above Specific location: 2. Simple cuboidal epithelium TISSUE LOCATIONS FUNCTION & NOTES DRAWING LOCATIONS FUNCTION & NOTES DRAWING Specific location: 3. Simple columnar epithelium TISSUE Specific location: ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 53 4. Pseudostratified ciliated columnar epithelium TISSUE LOCATIONS FUNCTION & NOTES DRAWING FUNCTION & NOTES DRAWING LOCATIONS FUNCTION & NOTES DRAWING LOCATIONS FUNCTION & NOTES DRAWING PART E—STRATIFIED EPITHELIA 1. Nonkeratinizing stratified squamous epithelium TISSUE LOCATIONS 2. Keratinizing stratified squamous epithelium TISSUE Specific location: 3. Transitional epithelium TISSUE ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 54 PART F—QUESTIONS 1. What are goblet cells? 2. What epithelial tissues did you observe which had goblet cells? 3. What are cilia? What is their function? Give an example of where in the body ciliated cells are located. 4. What are microvilli? What is their function? Give an example of where in the body microvilli are located. 5. What is the difference between the two pictures shown under simple squamous epithelium? 6. What is a basement membrane? What is it made of? 7. What is the difference between simple and stratified epithelial tissues relative to the basement membrane? 8. How can you tell the difference between stratified squamous and transitional epithelium? ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 55 9. What is the difference in appearance and placement of nuclei in each of these tissues: simple columnar, simple cuboidal, and pseudostratified ciliated columnar? 10. What other simple and stratified epithelial types can you name? 11. Name the type of tissue that membranes such as visceral and parietal serous membranes are composed of. 12. What are the main functions of epithelial tissue? ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 56 OBJECTIVES Be able to identify each tissue type. Be able to identify associated structures. Know the location of each tissue type. Know the function of each tissue type. Before you begin today’s lab, take a few minutes to review the tissues that you have already studied. The second major group of tissues that we will study is connective tissue. Begin your study of connective tissue as outlined below. PART A—BASIC CHARACTERISTICS 1. 2. 3. 4. Multiple cell types Fibers Increased intercellular matrix Vascular PART C—Fiber Types PART B—CELL TYPES 1. 2. 3. 4. 5. 6. 7. 8. Fibroblasts Macrophages Mast cells Plasma cells Leukocytes Adipose cells (adipocytes) Chondrocytes Osteocytes 1 1. Collagen 2. Elastic 3. Reticular 2 PART D—CONNECTIVE TISSUE TYPES 1. 2. 3. 4. 5. 6. Areolar (loose) Adipose Reticular Dense regular Dense irregular Elastic connective tissue 3 6 5 4 ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 57 PART E—LOOSE CONNECTIVE TISSUE 1. Areolar connective tissue TISSUE LOCATIONS FUNCTION &NOTES DRAWING TISSUE LOCATIONS FUNCTION &NOTES DRAWING Same as above Same as above Name the cell: 2. Adipose connective tissue TISSUE LOCATIONS FUNCTION &NOTES DRAWING LOCATIONS FUNCTION &NOTES DRAWING 3. Reticular Connective Tissue TISSUE ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 58 PART F—DENSE CONNECTIVE TISSUE 1. Dense regular connective tissue (dense white fibrous) TISSUE LOCATIONS FUNCTION &NOTES DRAWING FUNCTION &NOTES DRAWING FUNCTION &NOTES DRAWING 2. Dense irregular connective tissue TISSUE LOCATIONS 3. Elastic connective tissue (dense yellow elastic) TISSUE ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS LOCATIONS Page 59 PART G—QUESTIONS 1. What is matrix and what is its composition? 2. Identify the various types of cells that can be found in connective tissue and give a function for each. a. b. c. d. e. f. g. 3. Answer these questions about fibers: a. What are they? b. How many types are there? c. What produces all 3 types of fibers? d. Where can they be found? e. What is the distinction of each fiber type? i. ii. iii. ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 60 4. List 6 characteristics of connective tissue: a. b. c. d. e. f. ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 61 OBJECTIVES Be able to identify each tissue type. Be able to identify associated structures. Know the location of each tissue type. Know the function of each tissue type. Cartilage and bone are stronger than other connective tissues because of the types of chemicals that compose their matrix. For this lab, you will look at 3 types of cartilage and a slide of compact bone. PART A—TYPES OF CARTILAGE 1. Hyaline 2. Elastic 3. Fibrocartilage PART B—GENERAL CHARACTERISTICS 1. Tough and flexible 2. Avascular 3. No innervation 4. Chondroitin sulfate and hyaluronic acid 5. Largely water 6. Chondrocytes and chondroblasts 7. Lacunae 8. Fibers PART C—QUESTIONS 1. What are lacunae? 2. What are glycosaminoglycans and what is their significance? Give two examples of GAG’s. ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 62 3. Are fibers present in cartilage? 4. Are fibers always visible in cartilage? PART D—CARTILAGE CONNECTIVE TISSUE 1. Hyaline cartilage TISSUE LOCATIONS NOTES &FUNCTION DRAWING LOCATIONS NOTES &FUNCTION DRAWING LOCATIONS NOTES &FUNCTION DRAWING 2. Elastic cartilage TISSUE 3. Fibrocartilage TISSUE ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 63 PART E—BONE (OSSEOUS) CONNECTIVE TISSUE TISSUE LOCATION NOTES &FUNCTION DRAWING TISSUE LOCATION NOTES &FUNCTION DRAWING Same as above Same as above Name the passageway: PART F—TERMS 1. Lacuna 2. Osteoblasts 3. Osteocytes 4. Osteoclasts 5. Lamellae 6. Osteon (Haversian system) 7. Haversian canal 8. Volkmann’s canal 9. Canaliculi ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 64 PART G—QUESTIONS 1. What is perichondrium? 2. What is periosteum? 3. Which cartilage type has the most visible fibers? 4. Which type of cartilage is most abundant in the body? 5. Does cartilage heal better than bone? Explain. 6. What is articular cartilage? 7. What is an epiphyseal plate? 8. What is ground substance? 9. What makes the matrix of bone hard? 10. What is the difference between the organic and inorganic matrix in bone? 11. Medically speaking, what happens to an individual who has abnormalities in the relative amounts of organic and inorganic matter? ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 65 PART H—DIAGRAMS Label the indicated structures on the diagram. 1 2 6 3 4 5 7 8 9 10 4 5 11 12 ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 66 circumferential lamella interstitial lamella concentric lamella lacunae Haversian system Haversian canal Haversian canal Volkmann’s canal spongy bone trabecula concentric lamella ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 67 OBJECTIVE Learn and understand the basic structure of skin including its layers, important structures, and functions. PART A—THE INTEGUMENT Observe the skin models and slides (scalp, thin skin, thick skin, etc.) and locate the following structures: 1. EPIDERMIS a. Layers i. Stratum basale (germinativum) 1 ii. Stratum spinosum iii. Stratum granulosum iv. Stratum lucidum 2 v. Stratum corneum b. Cells i. Keratinocytes aa. Keratin 3 ii. Dendritic (Langerhans) cells iii. Tactile (Merkel) cells iv. Melanocytes c. Epidermal peg 4 2. DERMIS a. Layers i. 5 Papillary aa. Dermal papillae bb. Meissner’s corpuscles ii. Reticular aa. Dense irregular connective tissue bb. Sudoriferous (sweat) glands cc. Sebaceous (oil) glands b. Appendages i. Hair ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 68 aa. Root bb. Follicle cc. Shaft dd. Arrector pili 3. HYPODERMIS (SUBCUTANEOUS TISSUE) a. Adipose tissue b. Pacinian corpuscle c. Blood vessels PART B—SKIN STRUCTURES Label the indicated structures of the skin. 1 5 6 2 7 8 3 9 10 4 11 12 15 13 14 ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 69 PART C—QUESTIONS 1. Name the 3 layers of skin. (Technically 2 layers with a layer beneath) 2. Name the 5 zones of the epidermis. 3. What are the characteristics of each zone of the epidermis? a. b. c. d. e. 4. What structures are responsible for fingerprints? 5. Where is melanin located in the skin? 6. What cell produces melanin? 7. How do non-melanin producing cells get melanin in them? 8. What is the function of melanin? ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 70 9. Describe what happens when a person gets a suntan. 10. What are freckles? 11. What are the differences in melanin and melanin producing cells between light and dark skin? 12. What causes goose bumps? 13. What is the function of a sebaceous gland? 14. Which specific layer of the skin is mitotic? 15. What is the function of Meissner’s corpuscles? 16. What is the function of Pacinian corpuscles? ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 71 Meissner’s corpuscle dermal papilla hair shaft Epidermis epidermal peg sebaceous gland arrector pili muscle Dermis hair follicle Hypodermis eccrine sweat gland ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 72 OBJECTIVE To learn the structure and function of bone, as well as, its developmental stages. PART A—INTRODUCTION TO BONES Study the split femur and identify the following parts. Define each term and where appropriate give a function. 1. Diaphysis 2. Epiphysis 3. Spongy (cancellous) bone 4. Compact bone 5. Medullary cavity 6. Red marrow 7. Yellow marrow 8. Endosteum 9. Periosteum 10. Epiphyseal plate QUESTIONS 1. What are the two types of bone formation? 2. Which bones are formed from each type of bone formation? 3. Are bones supplied with arteries? Veins? Nerves? Lymph? ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 73 4. Differentiate between interstitial, concentric and circumferential lamellae. PART B—DIAGRAMS Label the indicated structures on the diagram. 1 4 5 6 7 2 8 3 6 9 8 ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 74 PART C—EPIPHYSEAL PLATE Observe the slide of developing bone (endochondral ossification). Identify and draw the following zones: 1. Zone of resting (reserve) cartilage ZONE NOTES DRAWING NOTES DRAWING NOTES DRAWING 2. Zone of proliferation (growth zone) ZONE 3. Zone of hypertrophy ZONE ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 75 4. Zone of erosion (destruction) ZONE NOTES DRAWING NOTES DRAWING 5. Zone of bone formation (osteogenic) ZONE QUESTIONS 1. What type of cartilage is present on the articulating surfaces of movable joints? 2. At what age does the epiphyseal plate close? 3. Is there an epiphyseal plate at both ends of a typical long bone? 4. Why is damaged cartilage more difficult to heal than bone? ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 76 5. List the differences between cartilage and bone. CARTILAGE BONE Nerves Blood vessels Lymph channels Matrix type PART D—OSTEOLOGICAL TERMS The irregular surface of the bones is due to either projections called processes or depressions called fossae. Since processes and fossae come in a variety of shapes and size more specific terms are often used. Using the bones, locate some of these processeses and fossae. 1. PROCESSESany bony projection a. b. c. d. e. f. g. h. i. j. Condylea rounded articulating process Epicondylea projection located above a condyle Tuberositya large rounded or irregular process Tuberclea small rounded process Trochantera very large, often blunt process Spinea sharp, slender process Hamulusa hook-shaped process Linea very slighrt ridge of bone Cresta prominent ridge of bone Faceta smooth flattened articulating surface 2. FOSSAEany bony depression, and bony openings a. b. c. d. e. f. Foramena hole in a bone through which nerves and blood vesels pass Meatus or Canala tunnel-like passage through a bone Sinusa cavity within a bone Sulcus or Groovea furrow on a bone’s surface Fissurea slit-like opening in a bone Foveaa shallow depression ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 77 articular cartilage epiphyseal plate Proximal Epiphysis spongy bone periosteum medullary cavity nutrient artery compact bone yellow marrow Diaphysis nutrient foramen periosteum compact bone spongy bone Distal Epiphysis ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 78 OBJECTIVE To name, identify, describe the bones and bone markings of the axial and appendicular skeletons. ORGANIZATION OF THE SKELETAL SYSTEM PART A—AXIAL SKELETON 1. SKULL (8) 2. FACE (14) a. Cranium a. Mandible (1) b. Frontal (1) b. Maxilla (2) c. Occipital (1) c. Nasal (2) d. Parietal (2) d. Vomer (1) e. Sphenoid (1) e. Lacrimal (2) f. Ethmoid (1) f. Inferior nasal concha (2) g. Temporal (2) g. Palatine (2) h. Zygomatic (2) 3. HYOID (1) 4. VERTEBRAL COLUMN (33) a. Cervical (7) 5. THORAX (25) a. Sternum b. Thoracic (12) i. c. Lumbar (5) ii. Gladiolus (body) d. Sacrum (5) iii. Xiphoid process e. Coccyx (4) Manubrium b. Ribs (12 pairs) 6 EAR OSSICLES (6) a. Malleus b. Incus c. Stapes ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 79 PART B—APPENDICULAR SKELETON 1. PECTORAL GIRDLE (4) a. Clavicle b. Scapula 2. UPPER EXTREMITY (60) a. Humerus b. Radius 3. PELVIC GIRDLE (2) a. Os coxa i. Ilium ii. Ischium iii. Pubic 4. LOWER EXTREMITY (60) c. Ulna a. Femur d. Carpals b. Patella i. Capitate c. Tibia ii. Trapezoid d. Fibula ii. Trapezium e. Tarsals iv. Scaphoid i. Talus v. Lunate ii. Calcaneus vi. Triquetral iii. Cuboid viii. Pisiform iv. Navicular xi. Hamate v. Medial cuneiform e. Metacarpals vi. Intermediate cuneiform f. Phalanges vii. Lateral cuneiform f. Metatarsals g. Phalanges ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 80 THE AXIAL SKELETON Familiarize yourself with all the bones of the body using the plastic replicas, as well as, the real human bones. Be able to identify each bone and how they articulate with one another. PART A—VERTEBRAE OBJECTIVE Be able to identify each vertebrae type. Know the number of each type. Distinguish each type of verterbrae. What does each vertebrae articulate with? What does C1 specifically articulate with? 1. In the table below, list the regional vertebral characteristics that will allow you to distinguish one vertebra from the other. CERVICAL ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS THORACIC LUMBAR Page 81 2. VERTEBRAL LANDMARKS IDENTIFY and LEARN the following structures. LABEL them in the diagram below. Body Transverse foramen (cervical only) Demifacet (thoracic only) Lamina Superior articular process Facet (thoracic only) Pedicle Inferior articular process Vertebral foramen (spinal canal) Spinous process Inferior notch Transverse process Intervertebral foramen (formed by 2 vertebrae) 1 2 4 3 5 6 8 7 9 3. ATLAS (C1) 6 IDENTIFY and LEARN the following structures. LABEL them in the diagram. Anterior arch Posterior arch Superior articular facet Inferior articular facet 2 3 4 1 1 4. AXIS (C2) IDENTIFY and LEARN the following structures. LABEL them in the diagram. Dens (odontoid process) Superior articular facet Inferior articular facet 5 2 3 4 5 ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 82 5. SACRUM AND COCCYX IDENTIFY and LEARN the following structures. LABEL them in the diagram below. Sacral promontory Superior articular process Sacral foramina Ala Sacral canal Articular fossa for ilium Body Sacral hiatus Coccyx 1 2 3 6 5 7 8 4 9 PART A—QUESTIONS 1. What features make the cervical vertebrae unique? 2. What blood vessel is closely associated with the cervical vertebrae? How? ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 83 3. What separates vertebral bodies from each other and what are they made of? 4. What nervous structures exit the intervertebral foramina? 5. How do the ribs articulate with the thoracic vertebrae? 6. How many articulating surfaces does T8 have? PART B—THE THORACIC CAGE 1 1. STERNUM 2 IDENTIFY and LEARN the following structures. LABEL them in the diagram. 3 Manubrium 4 Gladiolus (body) Xiphoid process 5 Clavicular notch 6 Jugular (interclavicular) notch Sternal angle Costal facets 7 QUESTIONS 1. What is the clinical significance of the xiphoid process and the body? 2. Can you palpate the jugular notch? 3. How are the ribs attached to the sternum? ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 84 2. RIBS IDENTIFY and LEARN the following structures. LABEL them in the diagram below. 1st rib Neck Body Typical rib Tubercle of rib Costal groove Head Sternal end 1 2 3 4 5 6 7 QUESTIONS 1. Can you distinguish between the sternal and vertebral ends of each rib? How? 2. Which rib stands out as having a unique shape? 3. Can you clearly describe how the ribs articulate with the thoracic vertebrae? 4. What are the spaces between ribs called? ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 85 5. What structures travel in the costal groove? 6. As a group, what are the first seven pairs of ribs called? Why? 7. As a group, what the lower five pairs of ribs called? Why? 8. What name is given to the last two pairs of ribs? Why? 9. Which of the two figures in the previous page represents a RIGHT rib? PART C—THE SKULL 1. ANTERIOR ASPECT OF SKULL IDENTIFY and LEARN the following bones. LABEL them in the diagram below. Frontal Ethmoid Maxilla Nasal Lacrimal Temporal Inferior nasal concha Vomer Mandible Sphenoid Zygomatic Identify and LEARN the following structures. LABEL them in the diagram below. NOTE: Labels on the diagram do not correspond with the list below. Nasal cavity Supraorbital foramen Optic canal (foramen) Mental foramen Perpendicular plate (ethmoid) Superior orbital fissure Orbital cavity Infraorbital foramen Inferior orbital fissure Alveolar process Middle nasal concha ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 86 1 2 3 4 5 6 7 8 10 9 12 11 13 14 15 16 17 19 18 20 21 2. LATERAL ASPECT OF SKULL IDENTIFY and LEARN the following bones. LABEL them in the diagram below. Mandible Frontal Maxilla Temporal Sphenoid Nasal Occipital Lacrimal Parietal Ethmoid Identify and LEARN the following structures. LABEL them in the diagram below. **Labels on the diagram do not correspond to the list below** Zygomatic arch Condylar process (mandibular condyle) Zygomatic process (temporal) Mastoid process Temporal process (zygomatic) Squamous suture Alveolar process Styloid process Lambdoid suture External occipital protuberance External acoustic meatus Lacrimal fossa Coronoid process (mandible) ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 87 1 2 3 4 5 6 7 8 10 9 11 12 14 13 15 16 17 18 19 20 21 3. POSTERIOR ASPECT OF SKULL IDENTIFY and LEARN the following bones and structures. LABEL them in the diagram below. Parietal Sagittal suture Occipital Lambdoid suture External occipital protuberance 1 2 3 4 5 6 ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 88 4. INFERIOR ASPECT OF SKULL IDENTIFY and LEARN the following bones and structures. LABEL them in the diagram below. **Labels on the diagram do not correspond with the list below** OCCIPITAL TEMPORAL SPHENOID Occipital condyles Carotid canal Foramen ovale Foramen magnum Mastoid process Foramen spinosum External occipital protuberance Styloid process Medial pterygoid process MAXILLA Foramen lacerum Lateral pterygoid process Palatine process Jugular foramen Greater wing PALATINE Stylomastoid foramen Horizontal plate Mandibular fossa Zygomatic process External acoustic meatus VOMER 1 2 5 3 4 6 7 9 10 11 8 12 15 13 16 ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS 14 Page 89 5. SUPERIOR VIEW OF SKULL IDENTIFY and LEARN the following bones and structures. LABEL them in the diagram below. SPHENOID TEMPORAL Foramen rotundum Foramen ovale Foramen spinosum Lateral pterygoid process** Medial pterygoid process** **[SEE SECOND DIAGRAM] Greater wing Lesser wing Hypophyseal fossa of sella turcica Optic canal Anterior clinoid process Posterior clinoid process Superior orbital fissure Foramen lacerum Internal acoustic meatus OCCIPITAL Hypoglossal canal ETHMOID Cribriform plate Crista galli 1 2 4 6 8 3 5 7 9 10 11 12 13 14 15 17 16 POSTERIOR VIEW ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 90 6. ADDITIONAL SKULL BONES—ETHMOID 1 — 2 IDENTIFY and LEARN the following structures. LABEL them in the diagram. ETHMOID Perpendicular plate Crista galli Cribriform plate Superior nasal concha Middle nasal concha 3 4 ANTERIOR VIEW 7. ADDITIONAL SKULL BONES—TEMPORAL IDENTIFY and LEARN the following structures. LABEL them in the diagram below. TEMPORAL Mastoid process Styloid process Zygomatic process Foramen lacerum Stylomastoid foramen External acoustic meatus Internal acoustic meatus Carotid canal Jugular foramen Mandibular fossa 1 5 2 4 3 ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 91 8. ADDITIONAL FEATURES OF THE SKULL IDENTIFY and LEARN the following bones and structures. LABEL them in the diagram below. OCCIPITAL FRONTAL External occipital protuberance Occipital condyle Foramen magnum ZYGOMATIC PARIETAL NASAL LACRIMAL Supraorbital foramen Temporal process VOMER INFERIOR NASAL CONCHAE 1 4 2 5 3 6 7 8 9 11 ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS 10 12 Page 92 9. ADDITIONAL SKULL BONES—MAXILLA AND PALATINE IDENTIFY and LEARN the following structures. LABEL them in the diagram. 1 MAXILLA Palatine process Alveolar process Infraorbital foramen 2 PALATINE Horizontal plate 10. ADDITIONAL SKULL BONES—MANDIBLE 3 IDENTIFY and LEARN the following structures. LABEL them in the diagram below. MANDIBLE Ramus Body Angle Coronoid process Alveolar process Mandibular notch Condylar process Mandibular foramen Mental foramen POSTERIOR VIEW 1 8 9 2 7 3 4 6 5 ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 93 11. ADDITIONAL SKULL BONES—OSSICLES IDENTIFY and LEARN the following bones. LABEL them in the diagram. 1 OSSICLES Malleus Incus Stapes 2 3 QUESTIONS 1. What bones form the nasal septum? 2. What bones form the zygomatic arch 3. What bones form the hard palate? 4. Looking at the skull from above with the calvarium removed, what bone can be seen protruding through the frontal bone? 5. What bone contains the ear ossicles? 6. What bones form the sagittal suture? 7. What bones form the lambdoid suture? 8. What bones form the coronal suture? ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 94 9. What endocrine structure rests in the hypophyseal fossa of the sella turcica? 10. Name four foramina that are clustered together in the sphenoid bone? 11. What is a sinus? 12. Which bones have sinuses? 13. What bone does the mandible articulate with? APPENDICULAR SKELETON ANATOMY OBJECTIVES Be able to identify each bone type. Distinguish between RIGHT and LEFT bones. Be able to identify articulations between bones and bone markings. PART A—THE PECTORAL (SHOULDER) GIRDLE 1. CLAVICLES IDENTIFY and LEARN the following bones and structures. LABEL them in the diagrams below. Acromial end Sternal end A 1 B 2 SUPERIOR VIEW ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 95 QUESTIONS 1. Indicate which of the two figures above is a LEFT clavicle. How can you tell? 2. SCAPULA IDENTIFY and LEARN the following structures. LABEL them in the diagrams below. **Labels on the diagram do not correspond with the list below** Suprascapular notch Superior border Superior angle Vertebral (medial) border Supraglenoid tubercle Infraglenoid tubercle Coracoid process Acromion process Inferior angle Spine Axillary (lateral) border Subscapular fossa Glenoid cavity Supraspinous fossa Infraspinous fossa 1 15 6 14 5 13 2 12 11 3 4 7 16 17 ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS 10 8 9 Page 96 QUESTIONS 1. Indicate whether the figure on page 96 is a LEFT or RIGHT scapula. How can you tell? PART B—THE UPPER LIMBS 1. HUMERUS IDENTIFY and LEARN the following structures. LABEL them in the diagrams below. Head Surgical neck Deltoid tuberosity Radial groove Trochlea Medial epicondyle Anatomical neck Greater tubercle Lesser tubercle Intertubercular sulcus Lateral supracondylar ridge Lateral epicondyle Radial fossa Capitulum Medial supracondylar ridge Coronoid fossa Olecranon fossa 1 2 4 3 5 6 7 8 9 10 11 12 13 15 14 16 ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 97 QUESTIONS 1. Indicate whether the figure on page 97 is a LEFT or RIGHT humerus. How can you tell? 2. RADIUS AND ULNA IDENTIFY and LEARN the following bones and structures. LABEL them in the diagrams below. RADIUS ULNA Head Radial tuberosity Head Olecranon process Ulnar notch (fossa) Trochlear notch Styloid process Coronoid process Radial notch Styloid process 1 4 2 3 5 6 8 7 (bone) (bone) 9 11 10 12 ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 98 QUESTIONS 1. Indicate whether the figures on page 96 are of a LEFT or RIGHT forearm. How can you tell? 3. HAND IDENTIFY and LEARN the following bones. LABEL them in the diagram below. CARPALS (WRIST) Capitate Trapezoid Lunate Triquetrum Trapezium Scaphoid METACARPALS 1-5 (PALM) PHALANGES 1-5 (FINGERS) Proximal Pisiform Middle Hamate Distal 1 2 3 4 6 5 7 8 9 10 11 12 QUESTIONS 1. Indicate whether the figure above is a LEFT or RIGHT hand. How can you tell? ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 99 PART C—THE PELVIC (HIP) GIRDLE 1. OS COXAE (HIP BONES) IDENTIFY and LEARN the following bones and structures. LABEL them in the diagram below. ILIUM ISCHIUM Iliac crest Anterior superior iliac spine Anterior inferior iliac spine Posterior superior iliac spine Posterior inferior iliac spine Greater sciatic notch PUBIS Ischial spine Lesser sciatic notch Ischial tuberosity Ischiopubic ramus Inferior ramus of pubis Inferior ramus of ischium Superior ramus of pubis Acetabular fossa Acetabular notch Acetabulum Obturator foramen 1 2 (bone) 3 5 7 6 4 9 8 10 11 13 12 (bone) 17 (bone) 14 15 16 18 QUESTIONS 1. Indicate whether the figure above is a LEFT or RIGHT os coxa. How can you tell? ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 100 PART D—THE LOWER LIMB 1. FEMUR (THIGH) IDENTIFY and LEARN the following structures. LABEL them in the diagrams below. Head Fovea capitis Neck Greater trochanter Lesser trochanter Intertrochanteric crest (posterior) Intertrochanteric line (anterior) Linea aspera (posterior) Lateral epicondyle Medial epicondyle Adductor tubercle Medial condyle Lateral condyle Intercondylar fossa Gluteal tuberosity (posterior) Patellar surface 1 2 3 4 5 6 7 8 9 16 11 10 12 13 15 14 QUESTIONS 1. Indicate whether the figure above is a LEFT or RIGHT femur. How can you tell? ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 101 2. TIBIA AND FIBULA (LEG) IDENTIFY and LEARN the following bones and structures. LABEL them in the diagram below. TIBIA FIBULA Lateral condyle Medial condyle Intercondylar eminence Tibial tuberosity Anterior crest (border) Medial malleolus Head Lateral malleolus 1 2 3 4 5 7 6 QUESTIONS 1. Indicate whether the figure above is a LEFT or RIGHT leg. How can you tell? ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 102 3. FOOT IDENTIFY and LEARN the following bones. LABEL them in the diagram below. TARSALS Talus Calcaneus Cuboid Navicular METATARSALS 1-5 PHALANGES 1-5 (TOES) Lateral cuneiform Intermediate cuneiform Medial cuneiform Proximal Middle Distal 1 2 3 4 6 5 7 9 8 10 11 QUESTIONS 1. Indicate whether the figure above is a LEFT or RIGHT foot. How can you tell? ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 103 4. PATELLA IDENTIFY and LEARN the following bone. LABEL the diagrams below. this side is raised this side falls flat 1. VIEW 2. VIEW QUESTIONS 1. Indicate whether the figure above is a LEFT or RIGHT patella. How can you tell? PART E—MISCELLANEOUS BONES 1. HYOID IDENTIFY and LEARN the following bone and structure. LABEL the diagram below. 1 QUESTIONS 1. To which bone does the hyoid bone directly articulate? ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 104 Fracture is incomplete and fragments the bone into 3 or more pieces. Fracture is incomplete and only one side breaks and the other bends. Caused by twisting a bone excessively. Occurs when broken bone portion is pressed inward. Occurs when epiphysis separates from the diaphysis along the epiphyseal plate. ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Occurs when n bone is crushed. Page 105 MOVEMENT TYPE Gliding EXAMPLES Intercapal and intertarsal joints Joints between vertebral articular surfaces MOVEMENT TYPE Flexion and extension Adduction and abduction EXAMPLES Metacarpophalangeal joints (knuckles) Wrist joints ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS MOVEMENT TYPE Flexion and extension EXAMPLES Elbow joints Interphalangeal joints MOVEMENT TYPE Flexion and extension Adduction and abduction EXAMPLES Carpometacarpal joints of the thumbs MOVEMENT TYPE Rotation EXAMPLES Proximal radioulnar joints atlantoaxial joint (atlas and axis vertebrae) MOVEMENT TYPE Flexion and extension Adduction and abduction Rotation EXAMPLES Shoulder joints Hip joints Page 106 OBJECTIVES To learn the histology and physiology involved in skeletal muscle contraction. To learn the location, points of attachment and actions of the major skeletal muscles in the human muscular system. PART A—TYPES OF MUSCLE TISSUE Identify each type of muscle below. List the identifying features for each type of muscle below the picture. Review the slides of the three muscle types. Locate the distinguishing features of each so that you can identify each muscle type histologically Characteristics: Characteristics: Characteristics: Define each of the following and give their location. TERM DEFINITION LOCATION a. Sarcolemma b. Intercalated disc c. Sarcoplasm d. Fascicle e. Striations f. Myofilaments g. T-tubules ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 107 Complete the following chart comparing the three muscle types. SKELETAL CARDIAC SMOOTH Location No. nuclei per fiber Location of nuclei Striations? Branching fibers? Intercalated discs? Fiber length Contraction time Endurance? PART B—SKELETAL MUSCLE STRUCTURE Label the structures on the following diagrams. 2 1 (covering) 3 4 (covering) 8 5 (#5 enlarged) 6 (covering) 7 (#3 enlarged) ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 108 9 11 10 13 12 14 15 16 17 18 19 ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 109 20 22 21 23 25 24 QUESTIONS 1. What is released from the sarcoplasmic reticulum? 2. The T-tubule is a deep extension of what structure? 3. What is the function of the T-tubule? 4. What causes the troponin complex to change its configuration? 5. What occurs as a result of the troponin complex changing form? 6. What causes the power stroke to occur? 7. What occurs when ATP attaches to the myosin head? 8. What chemical reaction allows the myosin head to return to its high-energy state or its “cocked” position? ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 110 PART C—MAJOR SKELETAL MUSCLES OF THE HUMAN BODY Although we will be using the cat to learn the major muscles, remember that you are learning HUMAN muscles. Be sure to know each muscle on the human diagrams and models, as well as, on the cat. Begin by studying the models and diagrams of the human body. Label the superficial muscles on the diagram below. 1 2 4 3 5 6 7 8 10 9 11 12 13 15 14 16 17 18 20 19 21 23 22 25 24 26 ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 111 27 28 29 30 31 33 32 34 35 36 37 38 39 41 40 42 43 44 ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 112 PART D—CAT DISSECTION CAREFULLY dissect the cat as directed by your instructor. Learn the superficial muscles of each region first, and then dissect the opposite side to locate the deep muscles. The muscles you are responsible for knowing are listed on the table below. Your instructor will review the region you are to dissect each lab—follow his/her directions. Use the cat diagrams on the following pages to locate these muscles on the cat. For each muscle listed you are responsible for knowing: Location in both cat and human Main actions Points of attachment HEAD AND NECK MUSCLES MUSCLE Epicranius (frontal belly) Orbicularis oculi Buccinator Zygomaticus Orbicularis oris Temporalis Masseter Sternocleidomastoid ORIGIN INSERTION ACTION Aponeurosis Skin of eyebrows Elevates eyebrows Wrinkles forehead Frontal and maxillary bones Tissue of eyelids Closes eyes as in blinking Maxilla and mandible Orbicularis oris Compresses cheeks inward (whistling and sucking) Zygomatic bone Skin and muscle at corner of mouth Raises corners of mouth (smiling) Maxilla and mandible Skin and muscle around mouth Closes and puckers the lips Temporal bone Mandible (coronoid process) Closes jaw Elevates and retracts mandible Zygomatic bone (arch) Mandible (ramus) Closes jaw Elevates mandible Sternum (manubrium) Clavicle Temporal bone (mastoid process) Rotates head to opposite side (one) Flexes head (both) MUSCLES THAT MOVE THE SHOULDER MUSCLE ORIGIN INSERTION ACTION Occipital bone Thoracic vertebrae Clavicle Scapula (spine and acromion process) Elevates and adducts scapula Extends neck Levator scapulae Vertebrae (upper cervical) Superior scapula Elevates and adducts scapula Rhomboid major Rhomboid minor Vertebrae (C7–T5) Scapula (medial border) Stabilizes and adducts scapula Pectoralis minor Ribs (3-5) Scapula (coracoid process) Pulls scapula downward and forward (abduct) Serratus anterior Ribs (upper 8) Scapula (anterior vertebral border) Pulls scapula against the chest wall Trapezius ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 113 MUSCLES THAT STABILIZE THE SHOULDER JOINT MUSCLE ORIGIN INSERTION ACTION *Supraspinatus Scapula (supraspinous fossa) Humerus (greater tubercle) Holds head of humerus stable in glenoid cavity Abducts arm (30) *Infraspinatus Scapula (infraspinous fossa) Humerus (greater tubercle) Holds head of humerus stable in glenoid cavity Rotates arm laterally *Teres minor Scapula (lateral border) Humerus (greater tubercle) Holds head of humerus stable in glenoid cavity Rotates arm laterally *Subscapularis Scapula (subscapular fossa) Humerus (lesser tubercle) Holds head of humerus stable in glenoid cavity Rotates arm medially *Collectively they are referred to as the rotator cuff muscles and are a common site for shoulder injury. MUSCLES THAT MOVE THE ARM MUSCLE ORIGIN INSERTION ACTION Clavicle, sternum, & ribs (1-6) Humerus (intertubercular sulcus and greater tubercle) Adducts, flexes and medially rotates arm at shoulder joint Lateral clavicle Scapula (spine & acromion process) Humerus (deltoid tuberosity) Abducts, flexes and medially rotates arm at shoulder joint Coracobrachialis Scapula (coracoid process) Humerus (shaft) Adducts and flexes arm at shoulder joint (synergist to pectoralis major) Latissimus dorsi Vertebrae (lumbodorsal fascia) Iliac crest & ribs (lower 4) Humerus (intertubercular sulcus) Adducts, extends and medially rotates arm at shoulder joint Scapula (inferior angle) Humerus (lesser tubercle) Adducts, extends, and medially rotates arm at shoulder joint (synergist to latissimus dorsi) Pectoralis major Deltoid Teres major MUSCLES THAT MOVE THE FOREARM MUSCLE ORIGIN INSERTION Biceps brachii Short head-Scapula (coracoid process) Long head-Scapula (supraglenoid tubercle) Radius (radial tuberosity) Flexes forearm at elbow (synergist to brachiallis) Supinates forearm Humerus (anterior shaft) Ulna (coronoid process) Flexes forearm at elbow Humerus (lateral supracondylar ridge) Radius (styloid process) Flexes forearm at elbow (synergist to biceps brachii) Scapula (infraglenoid tubercle) Posterior proximal humerus Ulna (olecranon process) Extends forearm at elbow Brachialis Brachioradialis Triceps brachii (long, lateral, medial) ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS ACTION Page 114 MUSCLES THAT MOVE THE WRIST, HAND AND FINGERS MUSCLE ORIGIN Flexor carpi muscles (radialis, ulnaris) Flexor digitorum muscles (superficialis, profundus, flexor pollicis) Extensor carpi muscles (radialis, ulnaris) Extensor digitorum INSERTION ACTION Humerus (medial epicondyle) Metacarpals Flex hand at wrist Distal humerus Proximal radius or ulna Middle or distal phalanges Flex the fingers Distal, lateral humerus Metacarpals Extend hand at wrist Humerus (lateral epicondyle) Distal phalanges Extends the hands and fingers MUSCLES OF THE ANTERIOR AND LATERAL ABDOMINAL WALL MUSCLE ORIGIN **Rectus abdominis INSERTION ACTION Sternum (xiphoid process) Ribs (costal cartilages of ribs 5-7) Flexes & rotates lumbar vertebrae Stabilizes pelvis Ribs (lower 8) Ilium (iliac crest) Linea alba Flexes vertebrae and compresses abdomen Rotates and flexes trunk laterally Ilium (iliac crest) Pubis and lower ribs Linea alba Flexes vertebrae and compresses abdomen Rotates and flexes trunk laterally Ilium (iliac crest) Ribs (lower 6) Pubis Linea alba Compresses abdomen Pubic bone (crest & symphysis) Tendinous intersection: Linea alba “white line”: **External oblique **Internal oblique **Transversus abdominis **All 4 muscles above work to compress the abdominal wall and the contents within MUSCLES THAT AID IN BREATHING MUSCLE ORIGIN INSERTION ACTION External intercostals Inferior border of rib above Superior border of rib below Pull ribs towards one another to elevate rib cage Aid in inspiration (synergist to diaphragm) Internal intercostals Superior border of rib below Inferior border of rib above Draws ribs together to depress rib cage Aid in expiration (antagonist to diaphragm) Inferior border of rib cage and sternum Margins of thoracic cage Central tendon of diaphragm Contracts to cause inspiration Diaphragm ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 115 MUSCLES THAT MOVE THE THIGH MUSCLE ORIGIN Sartorius Ilium (anterior superior iliac spine) Tibia (medial surface) Flexes and rotates thigh laterally Flexes knee Ilium (iliac crest) Iliotibial tract Flexes and abducts thigh Rotates thigh medially Iliopsoas Ilium Lumbar vertebrae Femur (lesser trochanter) Flexes thigh towards the trunk Rotates thigh laterally Gluteus maximus Posterior ilium Sacrum and coccyx Femur (gluteal tuberosity) Iliotibial tract Extends thigh at the hip Rotates thigh laterally Gluteus medius Ilium (lateral surface) Femur (greater trochanter) Abducts and rotates thigh medially Gluteus minimus Ilium (lateral surface) Femur (greater trochanter) Abducts and rotates thigh medially Tensor fasciae latae INSERTION ACTION ADDUCTORS OF THE THIGH MUSCLE Adductor longus ORIGIN INSERTION ACTION Pubis (pubic symphysis) Femur (linea aspera) Adducts, flexes and rotates thigh medially Adductor brevis (Humans) Adductor femoris (Cat) Pubis (inferior ramus) Femur (linea aspera) Adducts, flexes and rotates thigh medially Adductor magnus Ischium (ramus) Pubis (ramus) Femur (adductor tubercle and linea aspera) Adducts, flexes and rotates thigh medially (anterior part) Extends thigh (posterior part) Pectineus Pubis (superior ramus) Posterior femur Adducts, flexes and rotates thigh medially Gracilis Pubis (pubic symphysis) Tibia (proximal medial surface) Adducts thigh Flexes and rotates leg medially ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 116 MUSCLES THAT MOVE THE THIGH MUSCLE ORIGIN INSERTION ACTION QUADRICEPS: Rectus femoris Ilium (iliac spine) Patella and tibia via the patellar ligament Vastus lateralis Femur (greater trochanter) Patella and tibia via the patellar ligament Extends leg at knee Vastus medialis Femur (medial surface) Patella and tibia via the patellar ligament Extends leg at knee Femur (anterior and lateral surfaces) Patella and tibia via the patellar ligament Extends leg at knee Vastus intermedius Extends leg at knee Flexes thigh at hip HAMSTRINGS: Biceps femoris (2 heads) Long head-Ischium (ischial tuberosity) Short head-Femur (linea aspera) Tibia (lateral condyle) Fibula (head) Semitendinosus Ischium (ischial tuberosity) Tibia (upper medial surface of shaft) Semimembranosus Ischium (ischial tuberosity) Tibia (medial condyle) Flexes and rotates leg laterally Extends thigh Flexes and rotates leg medially Extends thigh Flexes and rotates leg medially Extends thigh MUSCLES THAT MOVE THE FOOT MUSCLE ORIGIN INSERTION Tibia (lateral condyle and surface) Medial cuneiform and 1st metatarsal Tibia (lateral condyle) Middle and distal phalanges Fibularis longus Fibula (head) By tendon curving under the foot to 1st metatarsal and medial cuneiform Gastrocnemius (2 heads) Femur (lateral and medial condyles) Calcaneus via calcaneal tendon Tibialis anterior Extensor digitorum longus Soleus Flexor digitorum longus (tendon posterior to medial malleolus) Tibialis posterior Tibia (posterior surface) Fibula (posterior surface) Calcaneus via calcaneal tendon ACTION Dorsiflexes and inverts foot at ankle Plantar flexes and everts foot at ankle Distal phalanges of toes 2-5 Tibia (posterior surface) Fibula (posterior surface) ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Under foot medially into tarsals & metatarsals Plantar flexes foot at ankle Flexes leg at knee Plantar flexes foot at ankle Tibia (posterior surface) Dorsiflexes and everts foot at ankle Extends toes Plantar flexes and inverts foot at ankle Flexes toes Plantar flexes and inverts foot at ankle Page 117 MUSCLE Perimysium Epimysium FASCICLE MUSCLE FIBER Fascicle Muscle fiber (cell) MYOFIBRIL Endomysium Myofibril ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 118 MYOFIBRIL Z line Sarcomere Actin filament (thin) Rod-like contractile element Occupy most of cell volume Run parallel Extend entire length of muscle cell Appear banded Composed of sarcomeres Z line Contractile unit, composed of myofilaments made up of contractile proteins Center is devoid of myosin heads Myosin filament (thick) SARCOMERE Tropomyosin Troponin complex G actin THIN FILAMENT Composed of contractile protein actin Contains actin strand twisted into a helix G actin (globular) subunits are sites to which myosin cross bridges attach during contraction Tropomyosin molecules coil around actin filament for reinforcement Troponin complex attaches to each tropomyosin complex Head Tail Myosin molecule THICK FILAMENT Composed of contractile protein myosin Rod-like tail ending in two globular heads Myosin molecules are bundled together with their heads facing outward Heads or cross bridges link the thick and thin myofilaments together during contraction Portion of thick filament ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 119 Nucleus MYOFIBRIL Z line MUSCLE FIBER A band Z line Actin filament Myosin filament Z line I band I band Sarcomere Z line A band H zone Z line Actin filament RELAXED Myosin filament Z line Z line M line CONTRACTED ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 120 MUSCLE FIBER Nucleus Myofibril Sarcolemma Sarcoplasm Sarcoplasm Triad Sarcoplasmic reticulum Terminal cisterna T-tubule ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 121 Axon terminal Synaptic vesicles Ca2+ ions Synaptic cleft T-tubule Axon terminal Sarcolemma Motor end plate Terminal cisternae Sarcoplasmic reticulum Axon membrane and sarcolemma are resting (polarized) Inside is negative (in respect to the outside), while outside is positive [RMP = -70 mV] Na+ and K+ voltage-gated channels are closed Nerve impulse 1 STEP 1 Action potential travels along the axon ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 122 2 STEP 2 Nerve impulse Action potential reaches axon terminal Depolarization of axon membrane opens both Na+ and Ca2+ voltage-gated channels Ca2+ influx into axon terminal from extracellular fluid STEP 3 3 2+ Ca ions promote fusion of synaptic vesicles with axon terminal membrane 4 STEP 4 Synaptic vesicles release acetylcholine (ACh) into the synaptic cleft by exocytosis Ach diffuses across synaptic cleft and binds to Ach receptors on the motor end plate ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 123 5 Depolarization of motor end plate STEP 5 Binding of ACh to ACh receptors on sarcolemma opens chemically-gated Na+ channels Na+ ions diffuse rapidly into the cell at the motor end plate Change in membrane potential (voltage); interior becomes slightly less negative RMP decreases = depolarization of sarcolemma at motor end plate Na+-K+ pumps helps to restore the ion concentration to its original state 6 Depolarization wave STEP 6 Propagation of action potential along sarcolemma as the local depolarization wave spreads to adjacent areas of sarcolemma, opening Na+ voltage-gated channels ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 124 Repolarization wave STEP 7 7 Immediately after the depolarization wave passes, repolarization wave quickly follows Na+ channels close and K+ channels open Na+ influx stops and K+ diffuses out of cell This restores the internal negativity of sarcolemma (polarized state) Repolarization occurs in the same direction as depolarization STEP 8 8 Action potential travels down the T-tubules 9 STEP 9 Action potential triggers terminal cisternae to release Ca2+ ions into the sarcoplasm Ca2+ ions ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 125 Terminal cisternae Ca2+ ions Sarcolemma Thin filament Troponi n Tropomyosin Myosin head (high energy) Thick filament RELAXED STATE Low levels of intracellular Ca2+ Tropomyosin blocks myosin binding sites on actin Prevents attachment of myosin heads Action potential 1 STEP 1 Action potential triggers the release of Ca2+ from terminal cisternae of the sarcoplasmic reticulum 2 STEP 2 2+ Ca ions bind to troponin Troponin changes shape Moves tropomyosin away from actin’s binding sites (removes blocking action of tropomyosin) ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 126 STEP 3 Activated myosin head is attracted to the exposed actin binding sites Myosin head attaches to actin myofilament 3 STEP 4 4 Low energy 5 Myosin head pivots, changing from its highenergy configuration to its bent, low-energy configuration = power stroke ADP + Pi (inorganic phosphate) are released Bending pulls on thin filament, sliding it toward the center of sarcomere (toward M line) STEP 5 New ATP molecule binds to myosin head Causes myosin head to detach from actin ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 127 6 STEP 6 ATP hydrolysis to ADP + Pi, provides energy to return the myosin head to its highenergy or “cocked” position Myosin head is ready for the next attachment and power stroke ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 128 Sternomastoid Trapezius Cleidomastoid Pectoralis Major ANTERIOR VIEW ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 129 Sternomastoid Pectoralis major Pectoralis minor Brachioradialis Flexors Triceps brachii (long head) Latissimus dorsi External oblique ANTERIOR VIEW ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 130 Levator scapulae Pectoralis minor Coracobrachialis Pectoralis major (cut) Biceps brachii Subscapulari s Brachialis Teres major Latissimus dorsi Triceps brachii (long head) Serratus anterior Rectus abdominis External oblique ANTERIOR VIEW ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 131 Supraspinatus Subscapularis Coracobrachialis Biceps brachii Flexors Teres major Triceps brachii (long head) Triceps brachii (medial head) ANTERIOR VIEW ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 132 Trapezius Trapezius Deltoid Sternomastoid Latissimus dorsi Triceps brachii (long head) Triceps brachii (lateral head) LATERAL VIEW ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 133 Deltoid Brachioradialis Extensors Trapezius Infraspinatus Teres major Trapezius Triceps brachii (lateral head) Triceps brachii (long head) Latissimus dorsi POSTERIOR VIEW ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 134 Levator scapulae Triceps brachii (medial head) Rhomboid minor Brachialis Supraspinatus Infraspinatus Teres minor Extensors Rhomboid major Triceps brachii (long head) Teres major POSTERIOR VIEW ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 135 Iliopsoas Adductor longus Pectineus Adductor femoris Vastus medialis Sartorius Gracilis Semitendinosus Gastrocnemius Flexor digitorum longus Tibialis anterior ANTERIOR VIEW ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 136 Iliopsoas Tensor fasciae latae Rectus femoris Pectineus Adductor longus Vastus medialis Adductor femoris S Semimembranosus Semitendinosus Gastrocnemius Flexor digitorum longus Soleus Tibialis anterior MEDIAL VIEW ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 137 Tensor fasciae latae Sartorius Gluteus medius Gluteus maximus Iliotibial tract Biceps femoris Semitendinosus Gastrocnemius Tibialis anterior Extensor digitorum Soleus Fibularis longus POSTERIOR VIEW ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 138 Tensor fasciae latae Gluteus medius Gluteus maximus Vastus lateralis Adductor magnus Semimembranosus Semitendinosus Extensor digitorum Gastrocnemius Soleus POSTERIOR VIEW ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 139 Gluteus medius (cut) Sartorius Tensor fasciae latae Gluteus minimus Vastus lateralis Gluteus maximus (cut) Adductor magnus Biceps femoris (cut) Semimembranosus Semitendinosus POSTERIOR VIEW ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 140 OBJECTIVE To understand the structure and function of the eye. PART A—EXTRINSIC EYE MUSCLES Observe the models and diagrams of the eye. Identify and learn the actions and innervations of the eye muscles listed below. Label the diagram below. EXTRINSIC EYE MUSCLES Superior rectus Inferior rectus Lateral rectus Medial rectus Superior oblique Inferior oblique 1 2 3 4 5 6 ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 141 PART B—EYE STRUCTURES Observe the models of the eye. Identify and learn the functions of the structures below. Label the diagram below. INTERNAL STRUCTURES Sclera Choroid Retina Conjunctiva Cornea Optic nerve Lens Iris Pupil Anterior segment Anterior chamber Posterior chamber Posterior segment Ora serrata Ciliary body Ciliary zonule (suspensory ligament Vitreous humor Lacrimal sac Optic disc Nasolacrimal duct Optic nerve Scleral venous sinus (Canal of Schlemm) Macula lutea/Fovea centralis Lacrimal apparatus Lacrimal gland Lacrimal canaliculi Lacrimal puncta 1 15 14 13 2 3 12 11 4 10 9 8 5 6 7 ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 142 PART C—RETINAL LAYER Observe a slide of the retina. Identify and learn the functions of the following structures. a. Sclera b. Choroid c. Retina i. Photoreceptor layer aa. Rods bb. Cones d. Ganglion layer e. Bipolar layer Label the diagrams below. 1 2 3 4 5 7 6 ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS 8 Page 143 PART D—DISSECTION OF COW EYE Dissect a cow eye. Identify and learn the functions of the structures listed below. a. b. c. d. e. Conjunctiva Sclera Choroid Retina Cornea f. g. h. i. j. Optic nerve Lens Ciliary body Ciliary zonule Iris k. l. m. n. Pupil Ora serrata Vitreous humor Optic disc When you are done with the dissection: WASH the dissecting tray and dissection tools with soap and water and then DRY with paper towel. Put dissection tools back in their appropriate bins. Place the eye in a specimen bag clearly LABELED with your name(s) and lab section. Then place the bag in the plastic bin. Use the cleaning solution in the spray bottle to wipe your lab bench. PART E—VISUAL TESTS 1. Visual Acuity—Snellen Eye Chart REMOVE your glasses or contact lenses and stand or sit 20 feet from the eye chart. Keep BOTH eyes open and cover one eye with the palm of your hand, or a piece of paper without pressing on the eyelid. READ out loud the SMALLEST line of letters you can see on the chart. Cover the other eye and begin the test again. RECORD your visual acuity. Visual Acuity: If you have read the test as successfully with the right eye as with the left eye, you probably have good central acuity. 2. Astigmatism Test Place yourself at approximately 3 feet from the chart. Cover one eye with your hand, without pressing on the lid, and test whether all the lines appear black. Cover the other eye and begin the test again. If some of the lines appear grayer and some blacker, you probably have an astigmatism. 3. Dominant Eye Test Make a small hole in a piece of paper. Place a coin at your feet on the floor. Hold the paper with the hole in it at waist level. ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 144 Locate the coin through the hole and close your right eye. If the coin DISAPPEARS you have a dominant RIGHT eye. If the coin does NOT DISAPPEAR you have a dominant LEFT eye. RECORD your dominant eye. Dominant Eye: 4. Blind Spot Test Hold this page approximately centered about 20 inches in front of your face with the LEFT eye CLOSED. Focus on the cross below. At this distance both the cross and the circle should be seen. Gradually bring the page closer until the circle cannot be seen. At this point the image is focused on the blind spot. Bring the page closer to your face. The circle should reappear. Repeat the procedure using your RIGHT eye closed. + 5. Color Blindness Test (Daltonism)—Ishihara Test Identify the hidden numbers in the following plates within 5 seconds. RECORD your observations below each plate. ANSWER: ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS ANSWER: ANSWER: Page 145 ANSWER: ANSWER: ANSWER: ANSWER: ANSWER: ANSWER: PART F—VISUAL PATHWAY Review the structures of the visual pathway (in text book and lecture notes). ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 146 PART G—QUESTIONS 1. What is accommodation? 2. What is presbyopia? 3a. Explain the term “bleaching of the pigment”. 3b. What is the ultimate result of “bleaching of the pigment”? 4. Why do people say that carrots promote good vision? 5a. Explain why it is difficult to see when you first enter a darkened movie theatre. 5b. Which photoreceptors must be functioning to see in the dark? 5c. Why aren’t they working when you first enter? 6. What is the anatomical relationship of the optic chiasm to the sella turcica and what is the clinical significance of this relationship? 7. Explain anatomically why your eyes often water and become irritated after you develop an infection of the throat. ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 147 8a. What is glaucoma? 8b. What causes it? 9. Explain why cones are able to detect color while rods cannot. ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 148 Palpabrae (eyelids) Palpabral conjuctiva Pupil Bulbar (ocular) conjunctiva Iris Lateral canthus Medial canthus Caruncle Eyelashes LACRIMAL APPARATUS Lateral lacrimal canaliculi Lateral lacrimal gland Caruncle Lacrimal ducts Lacrimal sac Bulbar (ocular) conjunctiva Nasolacrimal duct Palpabral conjuctiva ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 149 Lateral rectus muscle Ora serrata Sclera Bulbar (ocular) conjunctiva Ciliary muscle Choroid Scleral venous sinus Retina Fovea centralis POSTERIOR CHAMBER Iris Macula lutea Cornea Pupil (opening) Central artery Lens Central vein ANTERIOR CHAMBER OPTIC NERVE (II) Ciliary zonule (suspensory ligament Optic disc Ciliary body Medial rectus muscle ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 150 Superior oblique Superior rectus Trochlea Medial rectus Inferior rectus Lateral rectus Inferior oblique Inferior rectus Superior oblique (CN IV) LEFT EYE Superior rectus (CN III) Lateral rectus (CN VI) Medial rectus (CN III) Inferior oblique (CN III) Inferior rectus (CN III) ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 151 Optic nerve fibers Ganglion cell layer Bipolar cell layer Photoreceptor layer Cone Rod Pigmented layer ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 152 OBJECTIVE To understand the structure and function of the ear. PART A—STRUCTURE OF THE EAR Observe the models and diagrams of the ear. Identify and learn the functions of the structures listed below. OUTER EAR Pinna External auditory canal Incus Stapes Tensor tympani muscle Stapedius muscle Cochlea Scala vestibuli Scala tympani Scala media (cochlear duct) Organ of Corti Tectorial membrane Basilar membrane Hair cells Vestibulocochlear nerve (VIII) Vestibular branch Cochlear branch MIDDLE EAR Tympanic membrane Oval (vestibular) window Round (cochlear) window Pharyngotympanic tube Malleus INNER EAR Bony labyrinth Perilymph Membranous labyrinth Endolymph Vestibule Saccule and Utricle Macula Otolith Otolithic membrane Hair cells Hair bundle Semicircular canals Ampulla Crista ampullaris Cupula Hair cells ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 153 1 PART B—EAR DIAGRAMS 2 3 Label the diagrams below. 4 6 5 8 7 9 10 11 12 Know the location of endolymph and perilymph 13 14 (inner channel) (bony channel) 16 15 17 18 19 20 ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 154 21 22 23 25 24 PART C—MICROSCOPIC STRUCTURE OF THE EAR Observe a slide of the cochlea and identify the following structures. Label the diagrams below. Scala tympani Scala vestibuli Scala media (cochlear duct) Tectorial membrane Organ of Corti Hair cells Basilar membrane Vestibular membrane 2 1 3 4 5 6 7 ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 155 PART D—QUESTIONS 1. Where specifically do you find the maculae? What do they detect (be specific). 2. What other structures detect dynamic equilibrium? Where are they found and how many total do we have? 3. Where is endolymph found? 4. What nerve carries information regarding equilibrium to the brain? (Be specific) 5. What are hair cells? What happens when the hairs on the hairs cells bend? 6. What is the function of the Organ of Corti? In which canal does it reside? 7. Explain the function of the round window. It is found at the end of which canal? 8. What is the function of the Tensor Tympani and the Stapedius muscles? In which region of the ear are they found? ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 156 OUTER EAR MIDDLE EAR INNER EAR Incus Semicircular canals Pinna Stapes Cochlea External auditory canal Pharyngotympanic (auditory) tube Malleus Tympanic membrane Lobule OSSICLES OF THE MIDDLE EAR MALLEUS INCUS STAPES Tensor tympani muscle Tympanic membrane Pharyngotympanic (auditory) tube ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 157 BONY LABYRINTH Semicircular canals Vestibule Cochlea Oval window Round window MEMBRANOUS LABYRINTH Perilymph Membranous labyrinth Membranous labyrinth Bony labyrinth Bony labyrinth Endolymph Membranous labyrinth ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 158 Semicircular canals Ampullae MEMBRANOUS LABYRINTH Utricle Endolymphatic duct Vestibule Saccule Vestibular branch Cochlear branch Vestibulocochlear nerve (VIII) Cochlea Crista ampullaris Vestibulocochlear nerve (VIII) INNER MEMBRANOUS LABYRINTH Macula of utricle Macula of saccule Cochlea Endolymphatic duct Otoliths Otolithic membrane Supporting cells Stereocilia Hair cells Vestibular nerve fibers MACULAE Contains otoliths (calcium carbonate crystals) Maculae of utricle move head from side to side Maculae of saccule move head up and down ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Stereocilia Cupula (gelled mass) Receptor cells Vestibular nerve fibers CRISTA AMPULLARIS Receptor for dynamic equilibrium Respond to changes in the velocity of rotatory (angular) movements Page 159 Scala vestibuli Scala media (cochlear duct) Organ of Corti Scala tympani Tectorial membrane Outer hair cells Stereocilia (hairs) Supporting cells Organ of Corti Basilar membrane ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 160 LAB MANUAL ANSWERS LAB 1 PART A DIAGRAM (P. 3) 1. Frontal 18. Pelvic 2. Orbital 19. lInguinal 3. Nasal 20. Coxal 4. Buccal 21. Pubic 5. Oral 22. Carpal 6. Mental 23. Pollex 7. Cervical 24. Palmar 8. Thoracic (pectoral) 25. Digital 9. Sternal 26. Femoral 10. Axillary 27. Patellar 11. Mammary 28. Crural 12. Acromial 29. Fibular (peroneal) 13. Brachial 30. Tarsal 14. Antecubital 31. Metatarsal 15. Antebrachial 32. Digital (phalangeal) 16. Abdominal 33. Hallux 17. Umbilical PART A DIAGRAM (P. 4) 34. Cephalic 42. Gluteal 35. Otic 43. Perineal 36. Occipital 44. Manus 37. Scapular 45. Popliteal 38. Vertebral 46. Sural 39. Olecranal 47. Calcaneal 40. Lumbar 48. Plantar 41. Sacral ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 161 PART B TABLE (P. 5) CAVITY 1. Thoracic a. Pleural cavities MAJOR ORGANS Lungs b. Mediastinum Pericardial cavity, heart, aorta, esophagus, and trachea c. Pericardial cavity Heart 2. Abdominal cavity Digestive: Stomach, pancreas, intestines, liver, kidneys 3. Pelvic cavity Urinary bladder, reproductive organs, rectum 4. Cranial cavity Brain 5. Vertebral (spinal) cavity Spinal cord 6. Orbital cavity―located in the anterior of the skull and contains the eyes 7. Nasal cavity―located within and posterior to the nose in the skull and is part of the respiratory system 8. Oral (buccal) cavity―located in the skull and contains the teeth and tongue; part of digestive system PART B QUESTIONS (P. 5) 1. Ventral cavity 4d. Abdominal (abdominopelvic) 2. Abdominopelvic cavity 4e. Pelvic (abdominopelvic) 3. Dorsal cavity 4f. Vertebral (dorsal) 4a. Cranial (dorsal) 4g. Orbital 4b. Mediastinum (thoracic) 4h. Pleural (thoracic) 4c. Pericardial (thoracic) PART C DIAGRAM (P. 6) 1. Cranial cavity 6. Pelvic cavity 2. Vertebral cavity 7. Superior mediastinum 3. Dorsal cavity 8. Pleural cavity 4. Thoracic cavity 9. Pericardial cavity 5. Abdominal cavity 10. Abdomino-pelvic cavity ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 162 PART D TABLE (P. 7) REGIONS MAJOR ORGANS 1. Epigastric Stomach, liver, transverse colon 2. Umbilical Small intestines 3. Hypogastric Small intestines, urinary bladder, rectum, uterus, prostate 4. Right hypochondriac Liver, gall bladder 5. Left hypochondriac Spleen, part of stomach 6. Right lumbar (R) kidney, ascending colon 7. Left lumbar (L) kidney, descending colon 8. Right inguinal (iliac) Cecum (beginning colon), appendix 9. Left inguinal (iliac) Sigmoid colon, small intestines PART D DIAGRAM (P. 7) 1. (R) Hypochondriac region 6. (L) Lumbar region 2. (R) Lumbar 7. (L) Inguinal (iliac) region 3. (R) Inguinal (iliac) region 8. Hypogastric 4. Epigastric region 9. Umbilical 5. (L) Hypochondriac region PART E DIAGRAM (P. 8) 1. Transverse 2. Coronal or frontal 3. Median sagittal PART F QUESTIONS (P. 8) 1. Liver or gallbladder 6. Sagittal 2. Epigastric 7. Midsagittal; parasagittal 3. Hypogastric 8. Transverse or cross-section 4. Right lumbar 9. Frontal or coronal 5. Small intestines ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 163 PART G QUESTIONS (P. 9) 1. Superior 5. Medial 2. Distal 6. Deep 3. Lateral 7. Visceral 4. Superficial 8. Parietal LAB 2 PART A DIAGRAM (P. 12) 1. Ocular 9. Revolving nosepiece 2. Microscope body or frame 10. Objective 3. On/Off switch 11. Stage clip 4. Light intensity knob 12. Stage 5. Y-axis stage control knob 13. Iris diaphragm lever 6. Coarse focus adjustment knob 14. Condenser 7. Fine focus adjustment knob 15. Illuminator 8. X-axis stage control knob PART B QUESTIONS (PP. 13-14) 1. Multiply ocular magnification, times objective magnification 2. Parfocal microscopes remain in focus at high power once they’ve been focused on low power 3. Lower the light intensity by closing the iris diaphragm 4. The clarity of the image being viewed 5. The higher power of the objective, the more light is necessary 6. In order not to break the slide or more importantly, to avoid damaging the objective PART C QUESTIONS (P. 14) 1a. To the left 1b. Turns the image upside down and reverses it PART D QUESTIONS (P. 15) 6a. Nucleus, plasma membrane, vacuoles or vescicles ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 164 PART E QUESTIONS (P. 16) 2a. Onion cells are rectangular shaped and onion cells have a cell wall. 2b. Cell wall, nucleus PART F QUESTIONS (PP. 16-17) 4a. Chloroplasts: contain chlorophyll for photosynthesis 4b. Human or onion cells do not possess chloroplasts. Onions do not photosynthesize because they are the roots of the plant. Humans do not use photosynthesis to produce glucose. 4c. Plants: cell wall, chloroplasts, large vacuoles, no centrioles; Animal: no cell wall, no chloroplasts, smaller vacuoles, centrioles LAB 3 PART A CONVERSIONS (P. 19) PART B CONVERSIONS (P. 19) PART C CONVERSIONS (P. 19) 1. 3450 mm 1. 1000 mL 1. 154.35 lbs 2. 160,000 m 2. 150 mL 2. 300,000 mg 3. 2.5 mm 3. 1800 mL 3. 4 mg 4. 110,000,000 nm 4. 200 injections 4. 88.45 kg x 2 = 176.9 mL 5. 0.001 m 5. 520,000 mg 6. 0.0002 mm 6. 0.00425 g 7. 0.1 nm PART D QUESTIONS (P. 20) PART E QUESTIONS (P. 20) PART E QUESTIONS (P. 21) 1. 0.039 in 2a. 4 mm 2. 1000 2b. 2 mm 3. Graduated cylinder 2c. 0.5 mm 3b. 0.5 mm 3 mm 3c. 0.272mm 11 cells 4. Depends on individual slides 4. kL 5. mL PART F QUESTIONS (P. 22) 1. 25.4 mm 4 mm 1 mm 4 cells 4 mm Width 0.4 mm 10 cells 2. Length ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS 1000 1000 1 mm 1000 0.4 mm 400 1 mm 1 mm Page 165 LAB 4 PART A DIAGRAM (P. 24) 1. Glycocalyx/carbohydrate branches 4. Peripheral protein 2. Phospholipid molecule 5. Lipid bilayer 3. Integral protein PART A QUESTIONS (P. 24) 1. Individual marker for self-recognition (so the immune system doesn’t attack our own cells); Sticky surface (glycocalyx) causes adjacent cells to adhere to one another. 2. No, because it is water soluble and the phospholipids are hydrophobic. 3. May serve as a channel for passage of substance through the membrane (i.e. ions, glucose); May have a receptor on the exterior surface for binding of chemicals/hormones 4. May be an inactive enzyme that when activated by changes in the plasma membrane will trigger a series of reactions in the cell; May be a motor protein that may cause change of the cell shape or muscle contraction PART B DIAGRAM (P. 26) 1. Nuclear envelope 9. Mitochondrion 2. Nucleus 10. Lysosome 3. Plasma membrane 11. Ribosomes 4. Rough endoplasmic reticulum 12. Cytoplasm or Cytosol 5. Golgi apparatus 13. Smooth endoplasmic reticulum 6. Vesicle (phagocytic or pinocytic) 14. Nucleolus 7. Microtubule 15. Chromatin (DNA) 8. Centriole LAB 5 PART A DIAGRAM (P. 30) 1. Phosphate 4. Deoxyribose sugar 2. Hydrogen bonds 5. Nucleotide 3. Nitrogenous base PART A QUESTIONS (P. 31) 1. Adenine; guanine; cytosine; thymine; uracil 2. Deoxyribose sugar; phosphate ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 166 3. Nitrogenous base; hydrogen bond 4. Double helix 5. Adenine; cytosine; uracil 6. Nucleus; mitochondria 7. Determines the genetic code for protein construction; makes up genes on chromosomes 8. Gene 9. Replicate PART B QUESTIONS (P. 32) 1. RNA—ribose sugar, single-stranded, and uracil base instead of thymine; DNA—deoxyribose sugar, double-stranded, and thymine base 2. Nucleus, Cytoplasm (mRNA, tRNA, rRNA), ribosomes (rRNA) and nucleolus. 3. Carries out orders of DNA 4a. Formed in nucleolus. Used to make ribosomes 4b. Carries DNA code out of nucleus to ribosomes in cytoplasm 4c. Carries amino acids to ribosomes for construction of proteins LAB 7 PART A DIAGRAM (P. 45) 1. S = Synthesis 5. 3rd phase = Anaphase 2. G2 = Gap 2 6. 4th phase = Telophase 3. 1st phase = Prophase 7. G1 = Gap 1 4. 2nd phase = Metaphase PART B DIAGRAM (PP. 45-46) 1. Interphase Nuclear envelope and nucleolus are intact and visible Centrioles and chromosomes (DNA) replicate 2. Prophase 3. Metaphase Two centrosomes are at opposite poles of cell Chromosomes line up along the equator of the cell’s spindle Chromatin condenses forming chromosomes Nucleoli disappears Centrioles separate forming mitotic spindle Nuclear envelope disappears Kinetochore microtubules attach to kinetochores on each chromosome’s centromere Centrioles migrate to opposite pole ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 167 4. Anaphase Chromosomes split at the centromere into pairs of chromatids (daughter chromosomes) Kinetochore microtubules gradually pull each chromatid towards opposite ends of the plate 5. Telophase Chromosomes uncoil and resume into chromatin form Nuclear envelope reforms and spindle breaks down Cytokinesis occurs and a cleavage furrow forms leading to the separation of the cell into 2 daughter cells LAB 8 PART A QUESTIONS (P. 48) 1. DNA helicase, uncoil or unwind 2. Separate; nitrogenous bases 3. New DNA strand 4. DNA polymerase, nitrogenous bases 5. DNA ligase 6. Two double-stranded DNA molecules LAB 9 PART A QUESTIONS (PP. 49-50) 1. RNA polymerase; unwind 5. Cytoplasm; ribosome 2. Separate; template; mRNA; RNA polymerase 6. DNA cannot leave the nucleus 3. Codon 7. A template for construction of a protein 4. Introns; exons 8. RNA has uracil as a base instead of thymine PART B QUESTIONS (PP. 50-51) 1. Ribosome 6. On the ribosomes (in cytoplasm) 2. tRNA 7. mRNA (originally from DNA) 3. Anticodon 4. Hydrogen; mRNA 8. Carries amino acids to site where they attach to mRNA and form a polypeptide 9. Whenever proteins such as enzymes, pigments, cell structures, etc. need to be produced 5. Peptide; polypeptide ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 168 PART B DIAGRAM (P. 51) 1. mRNA 6. Amino acid 2. Ribosome 7. Peptide bond 3. mRNA codon 8. Polypeptide 4. tRNA anticodon 5. tRNA LAB 10 PART F QUESTIONS (PP. 55-56) 1. Mucus producing, single-celled glands 2. Simple columnar and pseudostratified ciliated columnar 3. Tiny projections on cell surfaces that move substances; found in upper respiratory tract, fallopian tubes 4. Tiny, fuzzy projections on the free surfaces of some epithelial cells, such as cells lining digestive system; increase surface are for absorption 5. Answers vary 6. Protein fibers formed from underlying connective tissue to reinforce the epithelial tissue. Helps to keep E.T. from overstretching or tearing. 7. Simple, one layer of cells above the basement membrane; stratified–many cell layers above the membrane 8. Stratified squamous tissue cells are flat at the apical surface, whereas transitional tissue cells may be cuboidal at the apical surface 9. Simple columnar–nucleus near the basement membrane; simple cuboidal–centrally located nucleus; pseudostratified ciliated columnar–scattered nuclei giving the appearance of stratification 10. Stratified cuboidal 11. Simple squamous epithelium (mesothelium) on a connective tissue base 12. Diffusion, filtration, protection LAB 11 PART A-D DIAGRAM (P. 57) 1. Fibroblast on a collagen fiber 2. Mast cell 3. Collagen fiber 4. Reticular fiber 5. Fibroblast 6. Elastic fiber PART G QUESTIONS (PP. 60-61) 1. Ground substance (composed of interstitial fluid and proteoglycans) and fibers (collagen, elastic, reticular) 2a. Fibroblasts–produce proteoglycans and all three type of fibers (collagen, elastic, reticular) ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 169 2b. Mast cells–produce histamines and heparin for the inflammatory response 2c. Plasma cells–produce antibodies 2d. Macrophages–phagocytize foreign particles 2e. Leukocytes–white blood cells acting as body’s defense 2f. Chondroblasts (cytes)–produce matrix in cartilage 2g. Osteoblasts (cytes)–produce organic matrix in bone 3a Protein fibers that provide support for connective tissue 3b Three (collagen, elastic and reticular) 3c. Synthesized by blast cell types 3d. In the matrix 3e(i). Collagen–thick protein fibers constructed primarily of the fibrous protein collagen 3e(ii). Elastic–long, thin fibers containing elastin protein, that allows them to stretch and recoil 3e(iii). Reticular–fine collagenous fibers forming delicate networks that support soft tissue of organs 4a. Vascular or avascular 4b. Extracellular matrix composed of ground substance and fibers 4c. Loosely scattered cells 4d. Binds, supports, protects, insulates, transports 4e. Blast cell types produce organic matrix 4f. Many cells types LAB 12 PART C QUESTIONS (PP. 62-63) 1. Small spaces surrounding chrondrocytes and osteocytes. 2. Polysaccharides attached to proteoglycans; produced by blast cells to thicken the matrix. Examples: chondroitin sulfate, hyaluronic acid. 3. Yes 4. No. The fibers are not visible in hyaline cartilage. PART F TERMS (P. 64) 1. Lacunasmall space or cavity at junctions of the lamella which occupy osteocytes 2. Osteoblastsactively mitotic bone-forming cells that secrete the bone matrix 3. Osteocytesspidery, mature bone cells that occupy the lacunae and conform to their shape 4. Osteoclastsgiant multinucleate cells that resorb (break down) bone ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 170 5. Lamellaea layer of growth rings of bone matrix in an osteon of compact bone 6. Osteon (Haversian system)a group of hollow tubes that comprise the structural unit of compact bone 7. Haversian canalcentral canal running through the core of each osteon that contains blood vessels and nerve fibers that serve the osteon’s cells 8. Volkmann’s canalperforating canals lying at right angles to the long axis of bone that connect blood and nerve supply of periosteum to those in the central canals and medullary cavity 9. Canaliculihair like canals connecting the lacunae to each other PART G QUESTIONS (P. 65) 1. Fibrous, vascular connective tissue on the surface of cartilage 2. Vascular connective tissue on the surface of bone 3. Elastic cartilage, although some collagen fibers are visible in fibrocartilage 4. Hyaline cartilage 5. No because it does not have its own blood supply. Bone on the other hand is vascular so it heals well. 6. Hyaline cartilage located on the end of bones that articulate at a joint 7. A growth plate where the growth in long bones occurs 8. Gelatinous substance filling the space between cells and contains the fibers. Composed of interstitial fluid and proteoglycans 9. Mineral salts such as calcium hydroxyapatite 10. Organic matter contains fibers and ground substance produced by blast cell types; inorganic matter contains mineral salts deposited from the blood 11. Disorders such as rickets/osteomalacia PART H DIAGRAM (P. 66) 1. Spongy bone 7. Periosteum 2. Compact bone 8. Vein 3. Osteon (Haversian system) 9. Nerve 4. Central (Haversian) canal 10. Artery 5. Circumferential lamellae 11. Canaliculi 6. Volkmann’s canal 12. Osteocyte in a lacuna LAB 13 PART A DIAGRAM (P. 68) 1. Stratum corneum 4. Stratum basale (germinativum) 2. Stratum granulosum 5. Papillary layer of dermis 3. Stratum spinosum ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 171 PART B DIAGRAM (P. 69) 1. Hair shaft 9. Eccrine Sudoriferous (sweat) gland 2. Epidermis 10. Pacinian corpuscle 3. Dermis 11. Arrector pili muscle 4. Hypodermis (subcutaneous) 12. Cutaneous plexus 5. Epidermal peg 13. Hair follicle 6. Dermal papilla 14. Adipose tissue 7. Meissner’s corpuscle 15. Sebaceous gland 8. Free nerve endings PART C QUESTIONS (PP. 70-71) 1. Epidermis, dermis, and hypodermis 2. Stratum basale, stratum spinosum, stratum granulosum, stratum lucidum, and stratum corneum 3a. Stratum basale—mitotic; contains melanocytes 3b. Stratum spinosum—largest, living layer containing spiny-shaped cells 3c. Stratum granulosum—numerous keratohyaline granules 3d. Stratum lucidum—translucent, dead cell layer located only in thick skin 3e. Stratum corneum—thick layer of dead, flaking cells 4. Dermal and epidermal ridges 5. Produced by melanocytes in the stratum basale. Melanosomes (melanin granules) may be present in the stratum spinosum 6. Melanocytes 7. Melanin is transferred from the melanocytes processes to nearby keratinocytes 8. UV protection 9. UV light stimulates melanin production therefore, the skin becomes darker 10. Localized patches of melanin 11. Both have same number of melanocytes but dark skin contains more numerous and darker colored melanosomes 12. Contraction of arrector pili muscles 13. Secretes sebum to soften and lubricate skin and hair 14. Stratum basale (germinativum) 15. Detects light pressure or discriminative touch 16. Detects deep pressure or crude touch ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 172 LAB 14 PART A TERMS (P. 73) 1. Diaphysiselongated shaft of a long bone 2. Epiphysisend of a long bone attached to the shaft 3. Spongy (cancellous) boneinternal layer of skeletal bone 4. Compact bonedense external layer of skeletal bone 5. Medullary cavitycentral cavity of a long bone containing yellow or red marrow 6. Red marrowhematopoietic tissue found within the trabeculae of spongy bone and in the diploë of flat bones 7. Yellow marrowfat content in the medullary cavity of adults 8. Endosteumconnective tissue membrane covering internal bone surfaces 9. Periosteumwhite, double-layered membrane covering the external surface of the entire bone 10. Epiphyseal plateplate of hyaline cartilage at the junction of the diaphysis and epiphysis that grows during childhood to lengthen a long bone PART A QUESTIONS (PP. 73-74) 1. Intramembranous and endochondral 2. Intramembranous (skull and clavicle); endochondral (all other bones, long bones) 3. Yes; veins, arteries and lymph 4. Interstitial lamella–incomplete lamella lying between intact Haversian systems; concentric lamella– rings of lamella making up each osteon; circumferential lamella–lamella extending around the entire circumference of the bone shaft PART B DIAGRAM (P. 74) 1. Proximal epiphysis 6. Compact bone 2. Diaphysis 7. Yellow marrow 3. Distal Epiphysis 8. Periosteum 4. Epiphyseal plate 9. Cancellous bone 5. Medullary cavity (lined with endosteum) ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 173 PART C QUESTIONS (PP. 76-77) 1. Hyaline cartilage 4. Absence of blood supply 2. Following puberty 5. 3. Yes CARTILAGE BONE Absent Nerves Present Absent Blood vessels Present Absent Lymph channels Organic Matrix type Present Organic & inorganic LAB 15 PART A2 VERTEBRAL LANDMARKS DIAGRAM (P. 82) 1. Spinous process 6. Pedicle 2. Lamina 7. Demifacet 3. Facet (transverse costal) 8. Vertebral foramen 4. Transverse process 9. Body 5. Superior articular process PART A3 ATLAS DIAGRAM (P. 82) 1. Anterior arch 4. Transverse foramen 2. Superior articular facet 5. Posterior arch 3. Transverse process 6. Vertebral foramen PART A4 AXIS DIAGRAM (P. 82) 1. Spinous process 4. Superior articular facet 2. Lamina 5. Dens (odontoid process) 3. Transverse process PART A5 SACRUM AND COCCYX DIAGRAM (P. 82) 1. Sacral promontory 6. Sacral canal 2. Ala 7. Articular fossa for ilium (auricular surface) 3. Body 8. Sacral foramina 4. Coccyx 9. Sacral hiatus 5. Superior articular process ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 174 PART A QUESTIONS (PP. 83-84) 1. Transverse foramina, small bifid (split at the tip) spinous process 2. Vertebral arteries pass through transverse foramina on both sides to service the brain 3. Intervertebral discs which are made of fibrocartilage 4. Spinal nerves 5. Head of rib articulates with demifacet on the thoracic vertebrae bodies. The tubercle of rib articulates with facet on transverse process of thoracic vertebrae. 6. Twelve PART B1 STERNUM DIAGRAM (P. 84) 1. Jugular (interclavicular) notch 5. Costal facet 2. Clavicular notch 6. Gladiolus 3. Manubrium 7. Xiphoid process 4. Sternal angle PART B1 STERNUM QUESTIONS (P. 84) 1. Used to locate region for compression during CPR 2. Yes 3. By individual costal cartilages PART B2 RIBS DIAGRAM (P. 83) 1. Tubercle 5. Neck 2. Facet of rib 6. Shaft or body 3. Costal groove 7. Sternal end 4. Head of rib PART B2 RIBS QUESTIONS (PP. 83-84) 1. Vertebral end is the end with the head, neck, tubercle and facets 2. First pair is flattened and broad forming a horizontal plate 3. The head of a typical rib articulates with the bodies of the thoracic vertebra by two facets: one articulates with the demifacet of the same-numbered thoracic vertebra, the other articulates with the demifacet of the thoracic vertebra immediately superior. The tubercle of the rib articulates with the transverse process of the same-numbered thoracic vertebra. 4. Intercostal space 5. Intercostal nerves and blood vessels 6. True (vertebrosternal) ribs because they attach directly to the sternum by individual costal cartilages. ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 175 7. False (vertebrochondral) ribs. Rib pairs 8-10 attach to the sternum indirectly; each joins the costal cartilage immediately above. 8. Floating ribs because they have no anterior attachment. 9. Top figure. PART C1 ANTERIOR ASPECT OF SKULL DIAGRAM (P. 87) 1. Frontal bone 12. Zygomatic bone 2. Parietal bone 13. Middle nasal concha 3. Nasal bone 14. Infraorbital foramen 4. Supraorbital foramen 15. Perpendicular plate of ethmoid 5. Optic canal (foramen) 16. Inferior nasal concha 6. Superior orbital fissure 17. Maxillary bone (maxilla) 7. Temporal bone 18. Vomer bone 8. Sphenoid bone 19. Alveolar process 9. Lacrimal bone 20. Mandible 10. Ethmoid bone 21. Mental foramen 11. Inferior orbital fissure PART C2 LATERAL ASPECT OF SKULL DIAGRAM (P. 88) 1. Sphenoid bone 12. Occipital bone 2. Squamous suture 13. External acoustic meatus 3. Coronal (frontal) suture 14. Zygomatic bone 4. Frontal bone 15. Coronoid process 5. Parietal bone 16. Maxilla 6. Ethmoid bone 17. Mastoid process 7. Lacrimal bone 18. Styloid process 8. Temporal bone 19. Condylar process (mandibular condyle) 9. Lambdoid suture 20. Mandible 10. Nasal bone 21. Zygomatic process 11. Lacrimal fossa ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 176 PART C3 POSTERIOR ASPECT OF SKULL DIAGRAM (P. 88) 1. Sagittal suture 4. Occipital bone 2. Parietal bone 5. External occipital protuberance 3. Lambdoid suture 6. Mastoid process PART C4 INFERIOR ASPECT OF SKULL DIAGRAM (P. 89) 1. Palatine bone 7. Carotid canal 13. Jugular foramen 2. Vomer bone 8. Styloid process 14. Foramen magnum 3. Foramen lacerum 9. Temporal bone (zygomatic process) 15. Mastoid process 4. Foramen ovale 10. Mandibular fossa 5. Medial pterygoid process 11. External acoustic meatus 6. Sphenoid bone (greater wing) 12. Stylomastoid foramen 16. Occipital condyle PART C5 SUPERIOR VIEW OF SKULL DIAGRAM (P. 90) 1. Crista galli 7. Foramen rotundum 2. Hypophyseal fossa of sella turcica 8. Foramen ovale 13. Lesser wing of sphenoid bone 14. Greater wing of sphenoid 3. Cribriform plate of ethmoid 9. Foramen spinosum 15. Superior orbital fissure 4. Lesser wing of sphenoid bone 10. Posterior clinoid process 16. Medial pterygoid process 5. Optic canal 11. Foramen lacerum 17. Lateral pterygoid process 6. Anterior clinoid process 12. Hypoglossal canal PART C6 ADDITIONAL SKULL BONES—ETHMOID (P. 91) 1. Crista galli 2. Cribriform plate 3. Perpendicular plate 4. Middle nasal concha PART C7 ADDITIONAL SKULL BONES—TEMPORAL (P. 92) 1. Zygomatic process of temporal bone 2. Mandibular fossa 3. Styloid process 4. Mastoid process 5. External auditory (acoustic) meatus ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 177 PART C8 ADDITIONAL FEATURES OF THE SKULL (P. 92) 1. Parietal bone 7. Frontal bone 2. Occipital bone 8. Supraorbital foramen 3. Zygomatic bone 9. Nasal bone 4. Occipital condyle 10. Lacrimal bone 5. Foramen magnum 11. Vomer bone 6. External occipital protuberance 12. Inferior nasal concha PART C9 ADDITIONAL SKULL BONES—MAXILLA AND PALATINE (P. 93) 1. Infraorbital foramen 2. Alveolar process 3. Horizontal plate of palatine bone PART C10 ADDITIONAL SKULL BONES—MANDIBLE (P. 93) 1. Coronoid process 6. Mandibular angle 2. Mandibular foramen 7. Ramus 3. Alveolar process 8. Mandibular notch 4. Mental foramen 9. Condylar process 5. Body PART C11 ADDITIONAL SKULL BONES—OSSICLES (P. 94) 1. Incus 2. Malleus 3. Stapes PART C QUESTIONS (PP. 94-95) 1. Vomer and the perpendicular plate of ethmoid 2. Temporal bone and zygomatic bone 3. Palatine bone and maxilla 4. Ethmoid bone (cribriform plate and crista galli) 5. Temporal bone 6. Parietal bones 7. Occipital bone and the parietal bones 8. Frontal bone and the parietal bones ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 178 9. Pituitary gland (hypophysis) 10. Foramen rotundum, foramen ovale, foramen spinosum, and foramen lacerum 11. Air-filled cavity in certain skull bones 12. Frontal bone, sphenoid bone, ethmoid bone, and maxilla 13. Temporal bone PART A1 CLAVICLE DIAGRAM (P. 95) 1. Acromial end 2. Sternal end PART A1 QUESTIONS (P. 96) 1. Figure A PART A2 SCAPULAE DIAGRAMS (P. 96) 1. Coracoid process 10. Vertebral (medial) border 2. Subscapular fossa 11. Spine 3. Vertebral (medial) border 12. Supraspinous fossa 4. Axillary (lateral) border 13. Superior angle 5. Glenoid cavity 14. Superior border 6. Acromion process 15. Suprascapular notch 7. Infraspinous fossa 16. Supraglenoid tubercle 8. Axillary (lateral) border 17. Infraglenoid tubercle 9. Inferior angle PART A2 QUESTIONS (P. 97) 1. Left scapula PART B1 HUMERUS DIAGRAMS (P. 97) 1. Greater tubercle 9. Medial supracondylar ridge 2. Head 10. Lateral supracondylar ridge 3. Surgical neck 11. Coronoid fossa 4. Anatomical neck 12. Capitulum 5. Intertubercular sulcus or groove 13. Medial epicondyle 6. Lesser tubercle 14. Lateral epicondyle 7. Radial groove 15. Olecranon fossa 8. Deltoid tuberosity 16. Trochlea ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 179 PART B1 QUESTIONS (P. 98) 1. Right humerus PART B2 RADIUS AND ULNA DIAGRAMS (P. 98) 1. Trochlear notch 7. Radius 2. Radial notch 8. Ulna 3. Head of radius 9. Ulnar notch 4. Olecranon process 10. Styloid process of ulna 5. Coronoid process 11. Head of ulna 6. Radial tuberosity 12. Styloid process of radius PART B2 QUESTIONS (P. 99) 1. Left forearm PART B3 HAND DIAGRAM (P. 99) 1. Middle phalanx #4 7. Hamate 2. Proximal phalanx #2 8. Trapezium 3. Distal phalanx #1 9. Scaphoid 4. Metacarpal #3 10. Pisiform 5. Trapezoid 11. Triquetral 6. Capitate 12. Lunate PART B3 QUESTIONS (P. 99) 1. Left hand. Thumb is located on the left. REMEMBER that the hand is in anatomical position. PART C1 OS COXA DIAGRAM (P. 100) 1. Iliac crest 10. Ischial spine 2. Ilium 11. Acetabular notch 3. Anterior superior iliac spine 12. Pubis 4. Anterior inferior iliac spine 13. Lesser sciatic notch 5. Posterior superior iliac spine 14. Ischial tuberosity 6. Posterior inferior iliac spine 15. Inferior ramus of pubis 7. Acetabulum 16. Obturator foramen 8. Acetabular fossa 17. Ischium 9. Greater sciatic notch 18. Inferior ramus of ischium (ischial ramus) ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 180 PART C1 QUESTIONS (P. 100) 1. Right os coxa. Acetabulum is always lateral. PART D1 FEMUR DIAGRAM (P. 101) 1. Fovea capitis 9. Linea aspera 2. Intertrochanteric line 10. Intercondylar fossa or notch 3. Neck 11. Lateral epicondyle 4. Head 12. Medial epicondyle 5. Greater trochanter 13. Adductor tubercle 6. Intertrochanteric crest 14. Medial condyle 7. Lesser trochanter 15. Lateral condyle 8. Gluteal tuberosity 16. Patellar surface PART D1 QUESTIONS (P. 101) 1. Right femur. Head is located medially. PART D2 TIBIA AND FIBULA DIAGRAM (P. 102) 1. Intercondylar eminence 5. Anterior crest 2. Lateral condyle 6. Medial malleolus 3. Head of fibula 7. Lateral malleolus 4. Tibial tuberosity PART D2 QUESTIONS (P. 102) 1. Right leg PART D3 FOOT DIAGRAM (P. 103) 1. Middle phalanx #2 7. Intermediate or middle cuneiform 2. Distal phalanx #4 8. Cuboid 3. Proximal phalanx #1 9. Navicular 4. Metatarsals 10. Talus 5. Lateral cuneiform 11. Calcaneus 6. Medial cuneiform PART D3 QUESTIONS (P. 103) 1. Left foot ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 181 PART D4 PATELLA DIAGRAM (P. 104) 1. Anterior view 2. Posterior view PART D4 QUESTIONS (P. 104) 1. Left patella PART E1 HYOID DIAGRAM (P. 104) 1. Greater cornu PART E QUESTIONS (P. 104) 1. It does not articulate directly with any other bone. It is anchored to the styloid process of the temporal bones by ligaments. LAB 16 PART B DIAGRAMS (PP. 108-110) 1. Muscle 10. T-tubule 19. Sarcomere 2. Epimysium 11. Muscle fiber 20. Troponin complex 3. Fascicle 12. Sarcoplasmic reticulum 21. G actin 4. Perimysium 13. Terminal cisternae 22. Tropomyosin 5. Muscle fiber (cell) 14. I band 23. Thin (actin) filament 6. Endomysium 15. A band 24. Myosin head 7. Nucleus 16. Z disc 25. Thick (myosin) filament 8. Myofibril 17. H band 9. Myofibril 18. M line PART B QUESTIONS (P. 110) 1. Calcium (Ca2+) ions 2. Sarcolemma 3. Muscle contraction is controlled by action potentials travelling along sarcolemma. Since t-tubules are continuations of the sarcolemma, they conduct impulses (action potential) deep into the muscle fiber. 4. Binding of Ca2+ 5. Tropomyosin strand moves away from actin’s binding sites 6. As myosin heads bind to the active sites on the actin myofilament, it changes from its high-energy, “cocked” position to its low-energy shape, which pulls on the thin filament, sliding it toward the center of the sarcomere. 7. As a new ATP molecule binds to the myosin heads, the myosin heads detach from actin 8. Hydrolysis of ATP into ADP + Pi provides the energy needed to return the myosin head to its highenergy, or “cocked,” position. ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 182 PART C DIAGRAM (P. 111) 1. 2. 3. 4. 5. 6. 7. 8. 9. Sternocleidomastoid Pectoralis minor Serratus anterior Deltoid Pectoralis major Biceps brachii Rectus abdominis Brachialis External oblique 10. 11. 12. 13. 14. 15. 16. 17. 18. Brachioradialis Internal oblique Flexors Transversus abdominis Iliopsoas Tensor fasciae latae Pectineus Sartorius Adductor longus 19. 20. 21. 22. 23. 24. 25. 26. Gracilis Rectus femoris Vastus lateralis Vastus medialis Gastrocnemius Extensor digitorum Tibialis anterior Soleus PART C DIAGRAM (P. 112) 27. Sternocleidomastoid 33. Triceps brachii 39. Biceps femoris 28. 29. 30. 31. 32. 34. 35. 36. 37. 38. 40. 41. 42. 43. 44. Trapezius Deltoid Infraspinatus Teres major Latissimus dorsi Extensors Gluteus medius Gluteus maximus Adductor magnus Iliotibial tract Semitendinosus Semimembranosus Gastrocnemius Soleus Calcaneal tendon LAB 17 PART A DIAGRAM (P. 141) 1. Superior oblique 4. Lateral rectus 2. Superior rectus 5. Inferior rectus 3. Medial rectus 6. Inferior oblique PART B DIAGRAM (P. 142) 1. Sclera 9. Ciliary zonules or suspensory ligaments 2. Choroid 10. Lens 3. Retina 11. Cornea 4. Macula lutea & fovea centralis 12. Anterior segment (aqueous humor) 5. Optic nerve 13. Iris 6. Optic disc 14. Ciliary body 7. Posterior segment (vitreous humor) 15. Ora serrata 8. Scleral venous sinus ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 183 PART C DIAGRAM (P. 143) 1. Ganglion cell layer 5. Sclera 2. Bipolar layer 6. Photoreceptor layer 3. Retina 7. Cone 4. Choroid 8. Rod PART E VISUAL ACUITY TESTS (PP. 145-146) NORMAL COLOR VISION: “12” RED-GREEN COLOR BLINDNESS: “12” TOTAL COLOR BLINDNESS: “NOTHING” NORMAL COLOR VISION: “8” RED-GREEN COLOR BLINDNESS: “3” TOTAL COLOR BLINDNESS: “NOTHING” NORMAL COLOR VISION: “5” RED-GREEN COLOR BLINDNESS: “2” TOTAL COLOR BLINDNESS: “NOTHING” NORMAL COLOR VISION: “45” TOTAL COLOR BLINDNESS: “NOTHING” NORMAL COLOR VISION: “7” TOTAL COLOR BLINDNESS: “NOTHING” NORMAL COLOR VISION: “26” RED COLOR BLINDNESS: “6”, “faint 2” GREEN COLOR BLINDNESS: “2”, “faint 6” ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 184 NORMAL COLOR VISION: “74” RED-GREEN COLOR BLINDNESS: “21” TOTAL COLOR BLINDNESS: “NOTHING” NORMAL COLOR VISION: “6” TOTAL COLOR BLINDNESS: “NOTHING” NORMAL COLOR VISION: “3” RED-GREEN COLOR BLINDNESS: “5” TOTAL COLOR BLINDNESS: “NOTHING” Red and green deficiencies occur with the most frequency and red deficiency is known as protanopia while green deficiency is known as deuteranopia. PART G QUESTIONS (PP. 147-148) 1. Process of ciliary muscles contracting and releasing tension on the suspensory ligaments of the lens. As a result, the lens thickens to focus on a near object. 2. A condition resulting in the loss of near focusing ability due to decreased elasticity in the lens as one ages. 3a. Bleaching refers to the fact that retinal changes configuration when hit by light, releasing the opsin protein. The color of retinal changes from rose color to clear/white so therefore it is referred to as “bleaching”. 3b. The ultimate result is a series of reactions resulting in an action potential being generated from the ganglion cells and an impulse traveling down the optic nerve. 4. Carrots contain vitamin A which is necessary to form the visual pigment retinal. 5a. Because cones stop functioning in low-intensity light. Rod pigments have been bleached out by the bright light, and the rods are still initially inhibited. 5b. Rods. 5c. They are bleach out (from being in the light) and need time in the dark to reform rhodopsin (retinal + opsin). 6. Optic chiasm is superior and anterior to the sella turcica where the pituitary gland (hypophysis) sits. Any tumors or enlargements of the pituitary gland can compress the optic chiasm causing visual impairments or blindness 7. The lacrimal canals (sacs) drain the eye to the nasal cavity. Infections from the throat can spread to the nasal cavity and reach the lacrimal sac to the eye 8a. Condition in which intraocular pressure (due to blocked drainage of the aqueous humor) increases to levels that cause compression of the retina and optic nerve, resulting in blindness. 8b. Pressure on the retina caused by too much aqueous humor. 9. Cones have 3 different visual pigments and each one bleaches in response to a different wavelength (color) of light. Rods have only one pigment that bleaches out equally for all wavelengths of light. ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 185 LAB 18 PART B DIAGRAMS (PP. 154-155) 1. Outer Ear 14. Membranous labyrinth 2. Middle Ear 15. Semicircular canals 3. Inner Ear 16. Saccule 4. Pinna 17. Utricle 5. External auditory canal 18. Ampulla 6. Malleus 19. Vestibule 7. Tensor tympani muscle 20. Oval window 8. Incus 21. Vestibular nerve 9. Stapedius muscle 22. Cochlear nerve 10. Stapes 23. Cochlea 11. Tympanic membrane 24. Stapes in oval window 12. Eustachian or auditory tube 25. Cupula of crista ampullaris 13. Bony labyrinth PART C DIAGRAMS (P. 155) 1. Cochlea 5. Tectorial membrane 2. Scala vestibuli 6. Organ of Corti 3. Scala media or cochlear duct 7. Basilar membrane 4. Scala tympani PART D QUESTIONS (P. 156) 1. In the saccule and utricle of the vestibule. 2. Crista ampullaris found in the ampullas of the semicircular canals. 6 total: 3 in each ear. 3. Within the membranous labyrinth. 4. The Vestibular nerve which joins the Cochlear nerve to form Cranial nerve 8 (Vestibulocochlear). 5. Specialized neurons that function as receptors. Bending of the hairs stimulates production of an action potential. 6. Detects sound waves. Scala media. 7. Helps to reduce over vibration. Scala tympani. 8. Reduces over vibration of the ear ossicles. Middle ear. ANATOMY AND PHYSIOLOGY 2A—REBECCA LOOMIS Page 186