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Cardiovascular and Respiratory Systems Lab

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    Learning Objectives

    • State the parts of the cardiovascular and respiratory systems and give the functions of each part.
    • Identify the parts of the cardiovascular and respiratory systems on the human torso model and other models.
    • Explain how the respiratory and cardiovascular systems are interrelated.
    • Describe the path of the blood through the heart
    • Test the effects of various factors on heart rate and breathing rates
    • Measure various respiratory volumes using a spirometer.
    • Define the following terms:
      nostrils trachea spirometer nasopharynx
      bronchi pleura pharynx larynx
      forced vital capacity epiglottis lung vital capacity
      diaphragm glottis forced expiratory volume intercostal muscles
      aorta brachial artery and vein superior vena cava ventricle
      hepatic artery and vein inferior vena cava atrium renal artery and vein
      iliac artery and vein pulmonary artery and vein jugular vein systole
      diastole coronary artery and vein carotid artery systole  

    Circulatory Respiratory Lab from Lumen Learning

    Download a PDF of the lab to print.

    Activity I: Identifying Structures

    Find the following structures on the human torso model and other models.

    • Nostrils
    • Trachea
    • Nasal cavity
    • Oral cavity
    • Bronchi
    • Diaphragm
    • Pharynx
    • Pleura
    • Larynx
    • Lung
    • Epiglottis
    • Intercostal muscles
    • Glottis
    • Iliac artery and vein
    • Carotid arteries
    • Jugular veins
    • Right and left ventricle
    • Right and left atria
    • Pulmonary artery and vein
    • Brachial artery and vein
    • Coronary artery and vein
    • Renal artery and vein
    • Hepatic artery and vein
    • Femoral artery and vein
    • Superior and inferior vena cava

    Use the chart on the next page to help organize your understanding of the different arteries and veins. For each one listed, state where the blood is traveling to and from.

    Artery or Vein Where blood is traveling to and from
    Pulmonary Artery  
    Pulmonary Vein  
    Coronary Artery  
    Coronary Vein  
    Hepatic Artery  
    Hepatic Vein  
    Iliac Artery  
    Iliac Vein  
    Jugular Vein  
    Carotid Artery  
    Brachial Artery  
    Brachial Vein  
    Femoral Artery  
    Femoral Vein  
    Renal Artery  
    Renal Vein  

    Use the heart picture below and label the different atria and ventricles. Also include the aorta, superior vena cava and inferior vena cava.

    Screen Shot 2015-07-20 at 9.34.04 PM

    Activity II: Respiratory Volumes and Lung Capacities

    Spirometry is the classic pulmonary function test. A spirometer is an instrument used to measure how much air and how quickly air is expelled after a deep inhalation. The measurements can be used to calculate how efficiently and how quickly the lungs can be filled upon inspiration and emptied during expiration. The most common measurements obtained from a spirometer are listed in the table below.

    Abbreviation Measurement Description
    VC Vital Capacity Maximal amount of air exhaled steadily from full inspiration to maximal expiration
    FVC Forced vital capacity The total amount of air that you blow out in one breath
    FEV1 Forced expiratory volume in one second The amount of air you can blow out in one second. An individual with normal lungs and airways can blow out most of the air from the lungs in the first second
    FER Forced expiratory ratio (FEV1/FVC)x100 Percentage of the FVC expelled in the first second of a forced expiration
    PEF Peak expiratory flow Peak expiratory flow in liters per minute

    The spirometer we will use measures peak expiratory flow, a useful indicator of lung function to assess conditions such as asthma. Peak flow is achieved by blowing out as fast as possible after taking in as much air as possible.

    Directions to Operate Spirometer

    1. For best results, stand. If you are unable to stand, sit in a straight and upright position.
    2. Move the peak indicator (red internal piece) to the start position (all the way on the left).
    3. Hold the spirometer in your hand with your thumb and forefinger on the grips and the mouthpiece facing toward you. Avoid blocking the vent holes as much as possible and do not allow the fingers to interfere with the red peak indicator.
    4. Take as deep a breath as possible filing your lungs completely with air
    5. Place your mouth on the mouthpiece, past your teeth, and form a tight seal with your lips. Place your tongue below the mouthpiece to make sure it is not blocking the opening at any time.
    6. Blow out as hard and fast as you can. The red indicator will move indicating your peak flow.
    7. Do not reset the peak indicator. Repeat steps 4-6 two more times for a total of three. The indicator will automatically point to the best of the three efforts.
    8. Record your results in the table on the next page.
    9. Clean off the spirometer using a paper towel and rubbing alcohol.
    10. Have your partner complete the same process.
    My value  
    My partner  


    Comparing Your Results to Expected Values

    Use the normal predicted average peak expiratory flow tables in the spirometer box and any additional handouts provided by your instructor to compare your readings to expected values based on an individuals gender, age, ethnicity, and height.

    How does your average PEF compare with the value for a person your age and height?

    What do These Values Mean in the Real World?

    Individuals suffering from obstructive pulmonary disease (narrowed airways) have a low FEV1 but a normal FVC. Since the airways are narrowed less air can be blown out in one second. Individuals with obstructive lung disease also have a FER less than 70% of the predicted value. Asthma is one condition which causes narrowing of the airways. Spirometry is used to diagnose asthma and asses the efficiency of treatments.

    Individuals can also suffer from restrictive pulmonary disease. These individuals have a normal FEV1 since the airways are unobstructed but a lower FVC. The lower FVC is caused by various conditions that affect the lung tissue or the capacity of the lungs to expand.

    There are some conditions that involve both lung obstruction and restriction, such as cystic fibrous. Individuals with cystic fibrous secrete excess mucus which narrows the airways and damages the lung tissue.

    Activity III: Investigation

    How do different everyday activities affect your circulation and respiration? You and a partner will work together to come up with and implement a procedure to test the following question:

    How does body position (laying down verses sitting verses standing) affect your heart rate and your breathing?

    In the space below, write a hypothesis and null hypothesis for the question.


    Null Hypothesis:

    You have the following tools available to test these questions:

    1. Spirometer
    2. Measuring pulse
    3. Measuring breathing rate

    You need to determine how you can test both respiration and circulation. Some points to consider:

    • How long your experiment should run?
    • How many trials you should do
    • How often should you take measurements?
    • How could you create a control?

    Use the space below to write out a procedure to test each question. Make sure that your instructor approves your procedures before you begin your experiments.

    Procedure for Question 1:

    Now begin your experiments. Use the space below to record your results. Feel free to make your own tables to organize your data.

    Use your results to answer the following questions:

    1. How did your heart rate change with body position? When was it the lowest? Highest?
    2. How did your breathing rate change with body position? When was it the lowest? Highest?
    3. Why might your heart and breathing rate differ from your partner?

    As modified from Piedmont Virginia Community College’s Biology 102 Circulatory and Respiratory Systems Lab



    This page titled Cardiovascular and Respiratory Systems Lab is shared under a CC BY license and was authored, remixed, and/or curated by Lynette Hauser.

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